Neuro-Ophthalmology
Developments in Ophthalmology Vol. 40
Series Editor
W. Behrens-Baumann, Magdeburg
NeuroOphthalmology Neuronal Control of Eye Movements
Volume Editors
Andreas Straube, Munich Ulrich Büttner, Munich
39 figures, and 3 tables, 2007
Basel · Freiburg · Paris · London · New York · Bangalore · Bangkok · Singapore · Tokyo · Sydney
Andreas Straube
Ulrich Büttner
Department of Neurology Klinikum Grosshadern Marchioninistrasse 15 DE–81377 Munich
Department of Neurology Klinikum Grosshadern Marchioninistrasse 15 DE–81377 Munich
Library of Congress Cataloging-in-Publication Data Neuro-ophthalmology / volume editors, Andreas Straube, Ulrich Büttner. p. ; cm. – (Developments in ophthalmology, ISSN 0250-3751 ; v. 40) Includes bibliographical references and indexes. ISBN 978-3-8055-8251-3 (hardcover : alk. paper) 1. Neuroophthalmology. I. Straube, Andreas. II. Büttner, U. III. Series. [DNLM: 1. Eye Movements–physiology. 2. Ocular Motility Disorders. 3. Oculomotor Muscles–physiology. 4. Oculomotor Nerve-physiology. W1 DE998NG v.40 2007 / WW 400 N4946 2007] RE725.N45685 2007 617.7⬘32–dc22 2006039568
Bibliographic Indices. This publication is listed in bibliographic services, including Current Contents® and Index Medicus. Disclaimer. The statements, options and data contained in this publication are solely those of the individual authors and contributors and not of the publisher and the editor(s). The appearance of advertisements in the book is not a warranty, endorsement, or approval of the products or services advertised or of their effectiveness, quality or safety. The publisher and the editor(s) disclaim responsibility for any injury to persons or property resulting from any ideas, methods, instructions or products referred to in the content or advertisements. Drug Dosage. The authors and the publisher have exerted every effort to ensure that drug selection and dosage set forth in this text are in accord with current recommendations and practice at the time of publication. However, in view of ongoing research, changes in government regulations, and the constant flow of information relating to drug therapy and drug reactions, the reader is urged to check the package insert for each drug for any change in indications and dosage and for added warnings and precautions. This is particularly important when the recommended agent is a new and/or infrequently employed drug. All rights reserved. No part of this publication may be translated into other languages, reproduced or utilized in any form or by any means electronic or mechanical, including photocopying, recording, microcopying, or by any information storage and retrieval system, without permission in writing from the publisher. © Copyright 2007 by S. Karger AG, P.O. Box, CH–4009 Basel (Switzerland) www.karger.com Printed in Switzerland on acid-free paper by Reinhardt Druck, Basel ISSN 0250–3751 ISBN: 978–3–8055–8251–3
Contents
VII List of Contributors IX Preface Büttner, U.; Straube, A. (Munich)
1 Anatomy of the Oculomotor System Büttner-Ennever, J.A. (Munich)
15 Eye Movement Recordings: Methods Eggert, T. (Munich)
35 Vestibulo-Ocular Reflex Fetter, M. (Karlsbad)
52 Neural Control of Saccadic Eye Movements Catz, N.; Thier, P. (Tübingen)
76 Smooth Pursuit Eye Movements and Optokinetic Nystagmus Büttner, U.; Kremmyda, O. (Munich)
90 Disconjugate Eye Movements Straumann, D. (Zurich)
110 The Eyelid and Its Contribution to Eye Movements Helmchen, C.; Rambold, H. (Lübeck)
132 Mechanics of the Orbita Demer, J.L. (Los Angeles, Calif.)
V
158 Current Models of the Ocular Motor System Glasauer, S. (Munich)
175 Therapeutic Considerations for Eye Movement Disorders Straube, A. (Munich)
193 Subject Index
Contents
VI
List of Contributors
Prof. Dr. med. U. Büttner Department of Neurology Klinikum Grosshadern Marchioninistrasee 15 DE–81377 Munich (Germany) Prof. Dr. med. Jean Büttner-Ennever Institute of Anatomy Ludwig-Maximilian University Pettenkoferstrasse 11 DE–80336 Munich (Germany) Dr. N. Catz Department of Cognitive Neurology Hertie Institute for Clinical Brain Research Hoppe-Seyler Strasse 3 DE–72076 Tübingen (Germany)
Prof. Dr. med. J.L. Demer Jules Stein Eye Institute 100 Stein Plaza David Geffen School of Medicine at UCLA Los Angeles, CA 90095-7002, Calif. (USA) Dr. Ing. T. Eggert Department of Neurology Klinikum Grosshadern Marchioninistrasee 15 DE–81377 Munich (Germany) Prof. M. Fetter SRH Clinic Karlsbad-Langensteinbach Department of Neurology Guttmannstrasse 1 DE–76307 Karlsbad (Germany)
VII
PD Dr. Ing. S. Glasauer Department of Neurology Klinikum Grosshadern Marchioninistrasse 15 DE–81377 Munich (Germany)
Prof. Dr. med. A. Straube Department of Neurology Klinikum Grosshadern Marchioninistrasse 15 DE–81377 Munich (Germany)
Prof. Dr. med. Ch. Helmchen Department of Neurology University Hospitals Schleswig-Holstein Campus Lübeck Ratzeburger Allee 160 DE–23538 Lübeck (Germany)
Prof. Dr. med. D. Straumann Neurology Department Zurich University Hospital Frauenklinikstrasse 26 CH–8091 Zurich (Switzerland)
Dr. O. Kremmyda Department of Neurology Klinikum Grosshadern Marchioninistrasse 15 DE–81377 Munich (Germany)
Prof. Dr. med. P. Thier Department of Cognitive Neurology Hertie Institute for Clinical Brain Research Hoppe-Seyler Strasse 3 DE–72076 Tübingen (Germany)
PD Dr. H. Rambold Department of Neurology University Hospitals Schleswig-Holstein Campus Lübeck Ratzeburger Allee 160 DE–23538 Lübeck (Germany)
List of Contributors
VIII
Preface
Each of us performs thousands of eye movements every day without being aware of how the brain controls them. The oculomotor system is one of the best understood motor systems not only with regard to premotor centers in the central nervous system, but also with regard to the peripheral muscles moving the eye. This has been made possible by intensive multidisciplinary research, including ophthalmologists, neurologists and basic scientists, and is reflected in comprehensive textbooks [i.e. Leigh RJ, Zee DS: The Neurology of Eye Movements. New York, Oxford University Press, 2006]. Based on these studies, some basic features of the oculomotor system were formulated and put to use in clinical practice: (1) All extraocular motoneurons are involved in all eye movements and innervate basically functionally similar muscles. (2) The pulling directions of the muscles are determined by central commands. (3) There are at least 5 different types of eye movements, i.e. saccades, smooth pursuit eye movements, vestibuloocular reflex (VOR), vergence and optokinetic nystagmus. Furthermore, there are special neuronal circuits involved in fixation of an object. The premotor centers for these eye movements have different locations in the central nervous system. However, experimental evidence gathered over recent years strongly suggests that none of these basic rules are correct and they have to be modified. (1) Twitch and nontwitch motor fibers of eye muscles have different distributions in the eye muscle. They are innervated by different motoneurons with distinct locations in the oculomotor nuclei, and furthermore they receive different inputs from premotor structures in the brainstem [see the chapter by Büttner-Ennever]. Thus, there are different classes of motoneurons, which serve different functions. (2) It also becomes increasingly clear that mechanical properties of the connective tissues (pulleys including Tenon’s capsule) in the orbit are important, particularly for
IX
the implementation of 3-D eye movements, and that a pure central neuronal implementation for eye movements is probably not sufficient [see the chapter by Demer]. (3) Specifically for cortical structures, it has been shown that one area can be involved in the control of several types of eye movements, the frontal eye field being the best investigated structure. It could be shown that the frontal eye field is not only involved in saccade control [see the chapter by Catz and Thier], but also in smooth pursuit eye movement [see the chapter by Büttner and Kremmyda] and vergence [see the chapter by Straumann] control. The functional meaning of these interactions in one premotor location has yet to be determined. For undisturbed vision, particularly during natural head movements, the VOR is of uttermost importance. In this sense, the VOR is the basic machinery of all eye movements, providing a foundation on which other eye movements operate. The VOR after a head movement has a latency of only 10 ms, whereas an eye movement response to a visual stimulus occurs much later, after 100 ms. Modern tests now allow clinicians to detect even discrete vestibular deficits in all directions of head movements [see the chapter by Fetter]. The progress in neuro-ophthalmology reveals complex interactions of oculomotor signals at all levels. To understand this complexity, models based on Control Theory have been proven to be very beneficial, and often deficits can only be correctly interpreted by the use of such models [see the chapter by Glasauer]. The latter also allow predictions and can provide the basis for new surgical procedures and other interventions. In order to test the models, precise measurements of the eye movements have to be made. Methods for recording eye movements have greatly improved over the last years, particularly for recording 3-D eye movements [see the chapter by Eggert]. The main aim in clinical practice is therapy [see the chapter by Straube]. For some disorders, drug therapy has been shown to be quite efficient (i.e. for downbeat nystagmus), and some therapies are starting to be based on the understanding of the neuronal interactions and their transmitters. For others, the search for specific and affective drugs is continuing. This book presents the current state of research and clinical studies in this important and relevant field. It is aimed at ophthalmologists who want to become familiar with the latest developments in oculomotor research. Certainly, the chapters related to the oculomotor periphery [see the chapters by Demer and Büttner-Ennever] will also have some impact on the surgical approach for treating eye movement disorders (i.e. strabismus). The book is also aimed at basic scientists with interest in clinical aspects of oculomotor disorders. A continuing multidisciplinary approach will hopefully lead to further improvement of diagnostic methods and the development of new therapeutic options. Ulrich Büttner and Andreas Straube, Munich
Preface
X
Straube A, Büttner U (eds): Neuro-Ophthalmology. Dev Ophthalmol. Basel, Karger, 2007, vol 40, pp 1–14
Anatomy of the Oculomotor System Jean A. Büttner-Ennever Institute of Anatomy, Ludwig-Maximilian University, Munich, Germany
Abstract The sensory and motor control of eye muscles are considered in this chapter. Eye muscles differ from skeletal muscles in several ways. One is the absence of muscle spindles and Golgi tendon organs in the eye muscles of some species, and their poor development in others. Second, eye muscles have an inner ‘global layer’, and the outer ‘orbital layer’, each containing different types of muscle fiber. Third, eye muscles contain not only twitch muscle fibers with a single endplate zone (SIFs), but also nontwitch muscle fibers with multiple endplate zones (MIFs), which are otherwise absent from mammalian muscles. There are cuffs of nerve terminals, called palisade endings, around the myotendinous junctions of global layer MIFs. Palisade endings are unique to eye muscles, and have been found in all mammalian species investigated up to now. The function of palisade endings is uncertain, but it is possible that they are ‘sensory receptors’. Motoneurons innervating the eye muscles lie in the oculomotor, trochlear and abducens motor nuclei, and are contacted by several relatively independent premotor networks, which generate different types of eye movements such as saccades, vestibulo-ocular reflexes, optokinetic responses, smooth pursuit convergence or gaze-holding. In each motor nucleus, the motoneurons can be divided into two distinct sets: the first set innervating SIF muscle fibers and receiving inputs from all oculomotor premotor networks, and the second set innervating the MIFs and receiving premotor afferents from the gaze holding, convergence or smooth pursuit premotor networks, but not from the saccadic and vestibulo-oculomotor networks. We suggest that the SIF motoneurons and muscles are more suited to driving eye movements, and the MIF motoneurons and muscles to setting the tonic tension in eye muscles. Furthermore the ‘palisade ending – MIF unit’ may be part of a sensory feedback system in eye muscles, which should be considered in association with the causes and treatment of strabismus. Copyright © 2007 S. Karger AG, Basel
Skeletomotor function depends on a chain of activity involving (a) sensory receptors in muscles, (b) their central connections, (c) the diverse central premotor inputs onto motoneurons, (d) the properties of the muscles that are targeted. Similarly, oculomotor function depends on the activity of sensory
receptors in eye muscles, their central connections with the premotor pathways that drive the activity of extraocular motoneurons, and finally the contraction properties of the eye muscles. However, eye muscles are fundamentally different from skeletal muscles in many ways [1]: they are responsive to different metabolic and neuromuscular diseases; their myosin retains some characteristics seen only in the early stages of the embryological development of skeletal muscles, and hence they contain different muscle fiber types than skeletal muscles. In many species, eye muscles lack the classical sensory receptors, such as muscle spindles and Golgitendon organs, the receptors which would provide the central nervous system with sensory feedback signals, a fundamental principle of skeletal muscle control [2, 3]. Additional neural structures unique to eye muscles could provide a sensory feedback signal, but it is clear from the differences between eye and skeletal muscles that their sensorimotor control will follow a different pattern. A great deal is known about the motor and premotor control of eye muscles, perhaps even more than of skeletal muscles. In this chapter, we will consider how the properties of eye muscles and their neural connections contribute to the sensorimotor control of eye movements, discussing first properties of eye muscles, then their sensory receptors, the central connections of different types of extraocular motoneurons, and finally we will suggest how these pathways and structures might together contribute to different types of eye movements.
Properties of Extraocular Muscles
Eye muscles have 2–3 separate morphological subdivisions (fig. 1a), which have independent developmental features [4]. There is a C-shaped outer ‘orbital’ layer of small diameter fibers, with high mitochondrial content, a welldeveloped microvascular system and oxidative enzymes, all correlating with a high level of continuous muscle activity. The orbital layer inserts onto Tenon’s capsule or ‘pulleys’, a ring of fibroelastic connective tissue that forms sleeves around the individual eye muscles, and is fully discussed by Demer [this vol, pp 132–157]. The inner ‘global’ layer contains muscle fibers of a larger diameter; it extends the full length of the muscle and inserts on the sclera of the globe. A third thin muscle layer outside the orbital layer has been described in some species, including human [5], and is called the marginal layer. Morphological, histochemical and immunological studies have characterized six different types of muscle fibers in mammalian extraocular muscles, and their properties are fully reviewed by Spencer and Porter [1]. They distinguish between (1) the orbital singly innervated fiber type (orbital SIF), and (2) the orbital multiply innervated fiber type (orbital MIF); in the global layer, four
Büttner-Ennever
2
Orbital layer with muscle spindles
Pulleys Global layer with palisade endings
Muscle
P MIF fibre
MIF
Tendon
Global layer
a
MIF motoneuron
50m
b
Fig. 1. a Diagram of an extraocular muscle showing how muscle spindles tend to lie in (and adjacent to) the orbital layer; while the global layer is characterized by MIFs which extend throughout the length of the muscle and carry palisade endings at their tips in the myotendinous junction. b Light microscopic photograph of the tip of a MIF at the distal myotendinous junction of a human lateral rectus muscle (see rectangle in a). The MIF is identified by the presence of a palisade ending (P) surrounding the tip of the muscle fiber. Note the axon (arrow) passing into the collagen bundles of the tendon on the left.
muscle types are found: (3) the global red SIF, (4) the global white SIF, (5) the global intermediate SIF, and lastly (6) the global MIF. These fiber types can be divided morphologically and physiologically into two fundamentally different categories – the singly innervated muscle fibers and multiply innervated muscle fibers, that is SIFs and MIFs which are shown diagrammatically in figure 2. The SIFs are also called ‘twitch’ fibers, since they undergo an all-or-nothing contraction on the activation of their centrally lying endplates. Skeletal muscles contain only SIF, or twitch, fibers, with the exception of perhaps tensor tympani and vocal muscles [6]. Thus MIFs are highly unusual in mammals. In mammals, the extraocular muscles contain 10–20% of MIF muscle fibers, with the exception of levator palpebrae. These striated muscle fibers are innervated at several places along their length, as apposed to having a single endplate zone like the SIFs (fig. 2). On activation of the nerve fibers to MIFs, the small grapelike clusters of endplates, ‘en grappe’ nerve endings, generate a local contraction which is not propagated throughout the muscle fiber, but remains local to the nerve terminal [6–11]. The MIFs are often referred to as nontwitch muscle fibers. They are a regular component of the skeletal muscles in amphibians, reptiles and fish, where a spectrum of different types of nontwitch fiber can be found, with graduated properties [6]. The contraction of nontwitch muscle fibers is slower than in all other muscle types, but they can maintain the tension for long periods at less energy cost than a twitch fiber, due to the slow turnover
Anatomy of the Oculomotor System
3
‘En plaque’ endplate zone PROXIMAL TENDON SIF
DISTAL TENDON ‘En grappe’ endplates Palisade ending
MIF
? SIF motoneuron
MIF motoneuron
Fig. 2. Diagram of motoneurons innervating SIFs and MIFs of an extraocular muscle. Note the endplate zone in the central part of the muscle with ‘en plaque’ endings on the SIF, the ‘en grappe’ endings distally and proximally on the MIF, and the palisade endings associated with the MIFs (only of the global layer).
of the myosin-actin bonding. The function of MIFs in extraocular muscles is still unclear, but experiments on frogs suggest that they respond in a highly tonic fashion [12]. The MIFs appear to be primitive or immature fiber types, and they are unlike any type of skeletal muscle fiber. They also have many features in common with intrafusal muscle fibers of muscle spindles [13].
Sensory Receptors in Extraocular Muscles
Muscle Spindles All skeletal muscles possess muscle spindles, so it is curious that in extraocular muscles some animals have them, and others lack them: no muscle spindles have been found in the eye muscles of submammalian species [14]. Many mammalian species do not have muscle spindles in their eye muscles: most monkey species including Macacca fascicularis, dogs, cats, rats, guinea pigs and rabbits do not have muscle spindles, whereas they have been found in humans, some types of monkey, mice and all ungulates (artiodactyls) [15–18]. The later studies show that the spindles are associated with the orbital layer, or the transition zone of the orbital layer with the global layer; but they are not associated with the global layer (fig. 1a). Furthermore, the density of muscle
Büttner-Ennever
4
spindles in human eye muscles is extremely high and is comparable to the density of muscle spindles in hand lumbrical and short neck muscles [16]. Extraocular muscle spindles appear poorly preserved in comparison to those in skeletal muscle, even to the point that some authors have raised the question of whether or not they are functional [3, 19–22]. Most extraocular muscle spindles lack an expansion of the equatorial zone; they contain fibers of the nuclear chain type, but no nuclear bag fibers are present. Extraocular muscle spindles also have many anomalous fibers which pass through the muscle spindle capsule without any intrafusal modification. An exception to this is seen in sheep (ungulates) where the extraocular spindles are very well developed, and they appear very similar to the skeletal spindles [18]. It has long been known that MIFs are morphologically very similar to the nuclear bag fibers of muscle spindles [13]; in sheep, branches from extraocular MIFs enter the muscle spindles and build nuclear bag fibers [23]. The erratic occurrence of muscle spindles in eye muscles cannot be explained today. Recent research on skeletal muscle spindles shows that their occurrence can be a highly dynamic process. For example, their incidence is critically dependent on the timing of the sensory innervation of the developing spindles, on the presence of neurotrophins, and of specific genetic transcription factors [24–27]. Similar studies on extraocular muscle spindles could help explain their variability, particularly in view of the persistence of embryological characteristics in adult eye muscles. Palisade Endings The global layer possesses an unusual feature unique to eye muscles; it has palisade endings at the myotendinous junctions, both proximally and distally (figs. 1b and 2) [3, 15, 28, 29]. Palisade endings, or palisade-like endings, have been found in almost all species that have been investigated [30]. Several authors have suggested that palisade endings could be the source of sensory afferent signals [2, 3, 31, 32]. The vast majority of the palisade terminals make contact with collagen fibers, and only a few are associated with muscle fibers [33, 34]. But this is a controversial topic [35]. A recent demonstration in cats that palisade endings are cholinergic structures argues in favor of their motor function [34]. In man, palisade endings with both sensory-like neurotendinous contacts and a few motor-like neuromuscular contacts have been found, and some of the authors daringly proposed that palisade endings might combine sensory and motor function [33, 36, 37]. Palisade endings form a cuff of nerve branches around the muscle fiber tip, like a palisade fence (fig. 1b); but they contact only one type of muscle fiber, the MIFs of the global layer [3, 36, 38, 39]. The term ‘innervated myotendinous cylinders’ is used to describe the palisade endings along with their fibrous
Anatomy of the Oculomotor System
5
capsule. The palisade terminals arise from nerve fibers that enter the muscle at the central nerve entry zone, run the length of the muscle into the tendon and then turn back 180⬚, to contact the tip of the muscle fibers (fig. 2). The uncertainty concerning the sensory or motor nature of palisade endings is compounded by the conflicting evidence on the location of their cell soma. If the palisade endings are sensory, their ganglion cell body should be in the trigeminal ganglion or in the mesencephalic trigeminal nucleus, whereas if the endings are of a motor origin then they would have cell bodies associated with the oculomotor nucleus. Tozer and Sherrington [29] as well as Sas and Schab [40] provided evidence for their location in the extraocular motor nerves or their nuclei, a result more compatible with either a motor role for the palisade endings, or perhaps an aberrant pathway for the afferent axons [3, 41]. The results of other studies point to the trigeminal ganglion as the location of palisade ending soma [42], and imply a sensory function. At present, considerable evidence points towards a sensory function of palisade endings, but without knowledge of their afferent pathways or evidence for their function, no conclusions can be made. Golgi Tendon Organs Golgi tendon organs are very rarely found in eye muscles, but they have been reported in the tendons of extraocular eye muscles artiodactyls, that is in sheep, camel, pig and calf [3, 43, 44]. They exhibit structural features not seen in skeletal Golgi-tendon organs, and several different types have been described [44]. Of particular interest in the context of this paper are Golgi tendon organs (only found in sheep). They all lie in one specific layer of the sheep eye muscle, the outer marginal layer. Zelená and Soukup [45] studied the development of Golgi tendon organs, and made the exciting suggestion that palisade endings may represent immature Golgi tendon organs. This hypothesis fits well with the demonstration of embryological (or immature) myosin types in the eye muscles, and suggests that eye muscle development may have been arrested at an early developmental stage, and hence the appearance of ‘immature Golgi tendon organs’, i.e. palisade endings. In summary, it seems that each eye muscle layer has its own individual type of receptor, muscle spindles are associated with the orbital layer, palisade endings with the orbital layer and, albeit only in sheep, Golgi tendon organs with the outer marginal layer. An important question to answer now is whether these receptors all deliver a sensory feedback signal to the central nervous system. Does the central nervous system need them all, or will one type suffice? If palisade endings are proprioceptors, then they could deliver the sensory feedback signals in species without muscle spindles; and since palisade endings are found in all species so far investigated, they could be the major sensory receptor, i.e. proprioceptors, for eye muscles.
Büttner-Ennever
6
Central Pathways
The trigeminal nerve or the ocular motor nerves are the only two pathways available for primary sensory afferents from eye muscles to access the brainstem; however, the route that the sensory afferents take is not clear. Anastomoses between these two nerves in retro-orbital regions have been demonstrated, so that it is possible that both pathways are involved. The location of the cell bodies (i.e. pseudounipolar ganglion cells) of the eye muscle primary sensory afferents is also a subject of disagreement, and has been reviewed by both Ruskell [3] and Donaldson [2]. Some studies suggest that they lie in the mesencephalic trigeminal nucleus, others the trigeminal ganglion, and some report finding cells labeled in both structures after tracer injections into eye muscles. Furthermore, ganglion cells are regularly reported to lie between the fascicles of the ocular motor and trigeminal nerves, and could possibly belong to the eye muscle proprioceptors [46, 47]. In spite of the uncertainty of the anatomy of the sensory pathways, responses to eye muscle stimulation have been reported in numerous central nuclei [2, 3]; these include the spinal and mesencephalic trigeminal nucleus, superior colliculus, the vestibular nuclei, the cerebellum, nucleus prepositus hypoglossi, the lateral geniculate nucleus and the visual cortex. How the activity in these central nuclei affects eye movements, or rather motoneurons, is not known, but afferent signals from extraocular muscles have been shown to affect orientation selectivity in the visual cortex, binocularity, stereoacuity, spatial localization, and under some conditions eye movements [2, 48–51].
Motor and Premotor Pathways Controlling Eye Muscles
Motoneurons in the oculomotor nucleus (III) innervate the ipsilateral medial and inferior rectus (MR, IR) and the inferior oblique (IO) and contralateral superior rectus (SR); those in the trochlear nucleus (IV) control the contralateral superior oblique (SO), and motoneurons in the abducens nucleus (VI) drive the lateral rectus muscle (LR). The mammalian III also includes motoneurons which innervate the levator palpebrae superioris; they lie in a slightly separate subgroup in caudal III, called the central caudal nucleus. Although at least six different types of muscle fiber have been described in extraocular muscles, only one type of extraocular motoneuron was recognized in III, IV and VI until recently. Recordings from awake monkeys showed that motoneurons responded during all types of eye movement providing a so-called ‘final common pathway’. Neuroanatomical experiments to determine the exact localization of MIF or nontwitch motoneurons with the motor nuclei were undertaken in the
Anatomy of the Oculomotor System
7
monkey [52]. Injections of a simple retrograde tracer were placed in the muscle belly within the central endplate zone of the SIFs (fig. 2). The tracer was taken up by SIF endplates and some MIF endplates. There was retrograde filling of the classical motoneuron subgroups throughout III, or in IV or VI. Alternatively, when the injection was placed at the distal tip of the muscle the tracer involved only MIF ‘en grappe’ motor endplates. Thus, only the (global) MIF motoneurons were retrogradely filled. In fact, these experiments labeled mainly the global MIFs since the orbital MIFs did not extend into the distal tendon (fig. 1a) [see also the chapter by Demer, this vol, pp 132–157]. The MIF motoneurons lay around the periphery of the classical III, IV and VI boundaries and did not intermingle with the SIF motoneurons. In VI, the LR MIFs surrounded the medial aspect of the nucleus; the SO MIFs lay in a dorsal cap over IV; in III the MIFs of MR and IR gathered into a small group on the dorsomedial boarder of III (C group), while those of SR and IO lay around the midline between the two halves of the III (S group). It is important to note that the extraocular MIF and SIF motoneurons do not intermingle. In terms of neuroanatomy, when neuronal cell groups lie separately it is often a sign that they receive different afferent inputs. This is indeed the case, as is described in the next sections. Premotor Circuits Pioneering studies of the oculomotor system in 1960s and 1970s resulted in the realization that there were several relatively independent premotor circuits carrying vestibular, saccadic, smooth pursuit or vergence signals. They were modeled, recorded, lesioned and traced and shown to generally converge on the oculomotor system at the level of the motoneurons in the oculomotor, trochlear or abducens nuclei [53]. Clinical studies confirmed that saccadic circuits through the pontine and mesencephalic reticular formation could be lesioned, leading to the loss of gaze to the ipsilateral side, but other eye movements such as vestibular reflexes, optokinetic responses or convergence remained intact. This concept is diagrammatically represented in figure 3. One exception is the optokinetic system which converges on the vestibular nuclei and uses the vestibulo-ocular pathways to drive optokinetic eye movements. The motoneurons generate motor responses, some with more tonic activity, others with more phasic properties; but up to now electrophysiological recordings showed that the motoneurons respond with every type of eye movement [54–56]. This concept – a final common pathway – has become widely accepted, although detailed studies described below show that this concept is not yet complete [57, 58]. With the anatomical identification of the MIF motoneurons it became clear that the concept of a final common pathway is an oversimplification, because two very different sets of motoneurons were found to innervate the extraocular muscles. Recent tract tracing experiments have now shown that the MIF
Büttner-Ennever
8
RIMLF PPRF*
SC
Vestibular n.
1
Saccades
2
VOR
3
OKN
4
Smooth pursuit
5
Vergence
6
Gaze holding
Motoneuron Accessory optic n. Vestibular n. y-group marginal zone
Retina
Flocculus region
Pontine n.
Visual cortex
Perioculomotor MRF Eye muscle
Interst.n.Cajal n. prepositus*
Vestibular n.
Flocculus region
Fig. 3. Several relatively independent neural networks of the brain converge at the level of the extraocular motoneurons to drive the eye muscles. The simplified diagram of these networks shows the premotor structures involved in five different types of eye movements and in gaze holding. MRF ⫽ Mesencephalic reticular formation; OKN ⫽ optpkinetic responses; PPRF ⫽ paramedian pontine reticular formation; RIMLF ⫽ rostral interstitial nucleus of the MLF; SC ⫽ superior colliculus; VOR ⫽ vestibulo-ocular reflex.
motoneurons in the oculomotor nucleus receive different afferent inputs than the SIF motoneurons. This was done in two ways. Firstly, by tracing projections to the oculomotor nucleus, for example from the pretectum, which targeted the C and S groups of MIFs, but not the classical SIF motoneuron subgroups [59]. A very elegant approach to this system was the use of rabies virus, which is a retrograde transsynaptic tracer, and when injected into the muscle belly it retrogradely labeled all the premotor structures shown in figure 4 [60]. The injection of the virus into the distal tip of LR, avoiding the SIF endplate zone and labeling only MIF terminals, retrogradely filled pathways mainly associated with gaze holding or convergence, but did not fill the saccadic and vestibulo-ocular pathways. The premotor inputs to the LR MIF motoneurons came from areas not previously recognized as premotor: the medial mesencephalic reticular formation and the supraoculomotor area, as well as areas associated with the neural integrator, like nucleus prepositus hypoglossi and the parvocellular parts of the medial vestibular nucleus. This difference in premotor inputs to SIFs and MIFs is shown diagrammatically in figure 4.
Anatomy of the Oculomotor System
9
Saccadic pathways MIF motoneuron
SIF motoneuron
Vestibular pathways Optokinetic pathways
Smooth pursuit pathways
Smooth pursuit pathways
Convergence pathways
Convergence pathways
Gaze holding pathways
Gaze holding pathways
MIF (nontwitch muscle fibers)
Gaze holding/eye alignment?
SIF (twitch muscle fibers)
Eye movement
Fig. 4. The diagram is based on the results of transsynaptic tract tracing experiments [60], and shows that the MIF motoneurons receive afferents from premotor neural networks associated with smooth pursuit eye movements, convergence and gaze holding, but not from the networks generating saccades or the vestibulo-ocular reflex. In contrast, the SIF motoneurons receive inputs from saccadic and VOR pathways, and possibly the other networks too. The difference in connectivity of MIFs and SIFs means a difference in function, and it is suggested that the SIFs may drive fast eye movements, while MIFs control muscle tension.
It is not easy to identify MIF motoneurons physiologically, possibly because they are smaller than SIF motoneurons, or because they do not gather together to form large identifiable groups, but rather lie around the perimeter of the motor nuclei in thin sheets. Thus, the differences between SIF and MIF motoneuron activity suggested by anatomical experiments have not yet been confirmed by physiological recordings.
A Proprioceptive Hypothesis
Given that we now have recognized the identity and location of at least some of the MIF motoneurons innervating tonic nontwitch muscle fibers, and found them to possess very different properties than the SIF motoneurons, we must now ask what role they play in oculomotor control [32, 52]. The MIF muscle fibers of the global layer extend throughout the length of the eye muscle [61], contract more slowly than SIFs, are fatigue resistant [6], and are driven by ton-
Büttner-Ennever
10
ically firing units [12, 62, 63]. It is not clear how much they contribute to the tension of eye muscles in natural conditions; but experimentally exposing eye muscle to succinyl choline, which causes the contraction of MIFs alone, causes tension changes, and indicates that MIF could contribute to tension in the eye muscle [64]. As discussed earlier in this chapter, MIFs are coupled with palisade endings at their tips in the myotendinous junction. Since palisade endings are putative sensory receptors, the MIF-palisade combination has been compared to an immature Golgi tendon organ [45], or an inverted muscle spindle, where the MIF represents an overgrown nuclear bag fiber and the palisade ending its displaced primary sensory endings [65]. It is possible that this structure could provide a sensory or proprioceptive feedback signal to the central nervous system, and its afferent signal would be modulated by the activity of the MIF motoneurons. It is still too early to decide what role MIF motoneurons play in the control of eye movements, but currently evidence supports the idea that the SIF or twitch motoneurons primarily drive the eye movements, whereas the MIF or nontwitch, or tonic motoneurons participate in determining tonic muscle activity, as in eye alignment, vergence and gaze holding.
Conclusions
Current evidence supports the concept that MIF motoneurons carry a tonic eye position signal, and the SIF, or twitch, motoneurons an additional phasic signal driving the actual eye movements. The role of MIFs and palisade endings is still speculation. However, they are constant features of human eye muscles, and they draw attention to the myotendinous junction. In the light of the MIFpalisade proprioceptive hypothesis, it is possible that the myotendinous junction is a site from which sensory signals can be sent to the central nervous system, and in turn influence muscle tension and perhaps eye alignment. This hypothesis should be considered seriously in the plans for the surgical operations for strabismus. In strabismus, the myotendinous junction has been reported to be the site of muscle damage and abnormal innervation [66–68]. But further investigations and experiments are necessary before there is a full understanding of these structures in the sensory-motor control of the eye position.
Acknowledgement This research was supported by the German Research Council (DFG) (Ho 1639/4-1).
Anatomy of the Oculomotor System
11
References 1 2 3 4 5
6 7 8 9 10 11 12 13 14 15 16 17 18
19 20 21 22 23 24 25
Spencer RF, Porter JD: Biological organization of the extraocular muscles. Prog Brain Res 2006;151:43–80. Donaldson IML: The functions of the proprioceptors of the eye muscles. Philos Trans R Soc Lond B Biol Sci 2000;355:1685–1754. Ruskell GL: Extraocular muscle proprioceptors and proprioception. Prog Retin Eye Res 1999;18:269–291. Porter JD, Baker RS, Ragusa RJ, Brueckner JK: Extraocular muscles: basic and clinical aspects of structure and function. Surv Ophthalmol 1995;39:451–484. Wasicky R, Zhya-Ghazvini F, Blumer R, Lukas JR, Mayr R: Muscle fiber types of human extraocular muscles: a histochemical and immunohistochemical study. Invest Ophthal Vis Sci 2000;41:980–990. Morgan DL, Proske U: Vertebrate slow muscle: its structure, pattern of innervation, and mechanical properties. Physiol Rev 1984;64:103–138. Chiarandini DJ, Stefani E: Electrophysiological identification of two types of fibres in rat extraocular muscles. J Physiol 1979;290:453–465. Jacoby J, Chiarandini DJ, Stefani E: Electrical properties and innervation of fibers in the orbital layer of rat extraocular muscles. J Neurophysiol 1989;61:116–125. Nelson JS, Goldberg SJ, McClung JR: Motoneuron electrophysiological and muscle contractile properties of superior oblique motor units in cat. J Neurophysiol 1986;55:715–726. Chiarandini DJ, Jacoby J: Dependence of tonic tension on extracellular calcium in rat extraocular muscle. Am J Physiol 1987;253:C375–C383. Jacoby J, Ko K, Weiss C, Rushbrook JI: Systematic variation in myosin expression along extraocular muscle fibres of the adult rat. J Muscle Res Cell Motil 1990;11:25–40. Straka H, Dieringer N: Basic organization principles of the VOR: lessons from frogs. Prog Neurobiol 2004;73:259–309. Barker D: The morphology of muscle receptors; in Barker D, Hunt CC, McIntyre AK (eds): Muscle Receptors. Berlin, Springer, 1974, pp 1–190. Maier A, DeSantis M, Eldred E: The occurrence of muscle spindles in extraocular muscles of various vertebrates. J Morph 1974;143:397–408. Cilimbaris PA: Histologische Untersuchungen über die Muskelspindeln der Augenmuskeln. Arch Mikrosk Anat Entwicklungsgesch 1910;75:692–747. Lukas JR, Aigner M, Blumer R, Heinzl H, Mayr R: Number and distribution of neuromuscular spindles in human extraocular muscles. Invest Ophthalmol 1994;35:4317–4327. Mahran ZY, Sakla FB: The pattern of innervation of the extrinsic ocular muscles and the intraorbital ganglia of the albino mouse. Anat Rec 1965;152:173–184. Blumer R, Konakci KZ, Brugger PC, Blumer MJF, Moser D, Schoefer C, et al: Muscle spindles and Golgi tendon organs in bovine calf extraocular muscle studied by means of double-fluorescent labeling, electron microscopy, and three-dimensional reconstruction. Exp Eye Res 2003;77:447–462. Bruenech JR, Ruskell GL: Myotendinous nerve endings in human infant and adult extraocular muscles. Anat Rec 2000;260:132–140. Bruenech JR, Ruskell GL: Muscle spindles in extraocular muscles of human infants. Cell Tissue Organs 2001;169:388–394. Ruskell GL: The fine structure of human extraocular muscle spindles and their potential proprioceptive capacity. J Anat 1989;167:199–214. Blumer R, Lukas JR, Aigner M, Bittner R, Baumgartner I, Mayr M: Fine structural analysis of extraocular muscle spindles of a two-year-old human infant. Invest Ophthalmol 1999;40:55–64. Harker DW: The structure and innervation of sheep superior rectus and levator palpebrae extraocular eye muscles. II. Muscle spindles. Invest Ophthalmol Vis Sci 1972;11:970–979. Walro JM, Kucera J: Why adult mammalian intrafusal and extrafusal fibers contain different myosin heavy-chain isoforms. Trends Neurosci 1999;22:180–184. Sekiya S, Homma S, Miyata Y, Kuno M: Effects of nerve growth factor on differentiation of muscle spindles following nerve lesion in neonatal rats. J Neurosci 1986;6:2019–2025.
Büttner-Ennever
12
26
27 28 29 30 31 32 33 34
35 36 37
38 39 40 41 42 43 44 45 46 47
48 49 50 51
Kucera J, Cooney W, Que A, Szeder V, Stancz-Szeder H, Walro J: Formation of supernumerary muscle spindles at the expense of Golgi tendon organs in ER81-deficient mice. Dev Dyn 2002;223:389–401. Fan G, Copray S, Huang EJ, Jones K, Yan Q, Walro J, et al: Formation of a full complement of cranial proprioceptors requires multiple neurotrophins. Dev Dyn 2000;218:359–370. Dogiel AS: Die Endigungen der sensiblen Nerven in den Augenmuskeln und deren Sehnen beim Menschen und den Säugetieren. Arch Mikrosk Anat 1906;68:501–526. Tozer FM, Sherrington CS: Receptors and afferents of the third, fourth and sixth cranial nerves. Proc R Soc London Ser 1910;82:451–457. Eberhorn AC, Horn AKE, Eberhorn N, Fischer P, Boergen KP, Büttner-Ennever JA: Palisade endings in extraocular eye muscles revealed by SNAP-25 immunoreactivity. J Anat 2005;205:307–315. Weir CR, Knox PC, Dutton GN: Does extraocular muscle proprioception influence oculomotor control? Br J Ophthalmol 2000;84:1071–1074. Büttner-Ennever JA, Horn AKE, Graf W, Ugolini G: Modern concepts of brainstem anatomy: from extraocular motoneurons to proprioceptive pathways. Ann N Y Acad Sci 2002;956:75–84. Lukas JR, Blumer R, Denk M, Baumgartner I, Neuhuber W, Mayr R: Innervated myotendinous cylinders in human extraocular muscles. Invest Ophthal Vis Sci 2000;41:2422–2431. Konakci KZ, Streicher J, Hoetzenecker W, Haberl I, Blumer MJF, Wieczorek G, et al: Palisade endings in extraocular muscles of the monkey are immunoreactive for choline acetyltransferase and vesicular acetylcholine transporter. Invest Ophthalmol Vis Sci 2005;46:4548–4554. Büttner-Ennever JA, Konakci KZ, Blumer R: Sensory control of extraocular muscles. Prog Brain Res 2006;151:81–93. Richmond FJR, Johnston WSW, Baker RS, Steinbach MJ: Palisade endings in human extraocular muscle. Invest Ophthal Mol Vis Sci 1984;25:471–476. Konakci KZ, Streicher J, Hoetzenecker W, Blumer MJF, Lukas JR, Blumer R: Molecular characteristics suggest an effector function of palisade endings in extraocular muscles. Invest Ophthalmol 2005;46:155–165. Mayr R: Funktionelle Morphologie der Augenmuskeln; in Kommerell G (ed): Augenbewegungsstörungen: Neurologie und Klinik. München, JF Bergmann, 1977, pp 1–15. Alvarado-Mallart RM, Pincon Raymond M: The palisade endings of cat extraocular muscles: a light and electron microscope study. Tissue Cell 1979;11:567–584. Sas J, Schab R: Die sogenannten ‘Palisaden-Endigungen’ der Augenmuskeln. Acta Morph Acad Sci (Hungary) 1952;2:259–266. Gentle A, Ruskell GL: Pathway of the primary afferent nerve fibres serving proprioception in monkey extaocular muscles. Ophthal Mic Physiol Opt 1997;17:225–231. Billig I, Buisseret -Delmas C, Buisseret P: Identification of nerve endings in cat extraocular muscles. Anat Rec 1997;248:566–575. Ruskell GL: Golgi tendon organs in the proximal tendon of sheep extraocular muscles. Anat Rec 1990;227:25–31. Blumer R, Lukas JR, Wasicky R, Mayr R: Presence and morphological variability of Golgi tendon organs in the distal portion of sheep extraocular muscle. Anat Rec 2000;258:359–368. Zelená J, Soukup T: The development of Golgi tendon organs. J Neurocytol 1977;6:171–194. Nicholson H: On the presence of ganglion cells in the third and sixth nerves of man. J Compar Neurol 1924;37:31–36. Palmieri G, Bo Minelli L, Acone F, Corriero A, Sanna M, Gazza F, et al: Further observations on the presence of ganglion cells in the oculomotor nerves of mammals and fish: number, origin and probable functions. Anat Histol Embryol 1999;28:109–113. Donaldson IML, Long AC: Interactions between extraocular proprioceptive and visual signals in the superior colliculus of the cat. J Physiol 1980;298:85–110. Donaldson IML, Knox PC: Afferent signals from the extraocular muscles affect the gain of the horizontal vestibular-ocular reflex in the alert pigeon. Vision Res 2000;40:1001–1011. Knox PC, Weir CR, Murphy PJ: Modification of visually guided saccades by nonvisual afferent feedback signal. Invest Ophthal Mol Vis Sci 2000;41:2561–2565. Weir CR, Knox PC: Modification of smooth pursuit initiation by a nonvisual, afferent feedback signal. Invest Ophthalmol 2001;42:2297–2302.
Anatomy of the Oculomotor System
13
52
53 54 55 56 57 58
59
60
61 62 63
64
65
66 67
68
Büttner-Ennever JA, Horn AKE, Scherberger H, D’Ascanio P: Motoneurons of twitch and nontwitch extraocular muscle fibers in the abducens, trochlear, and oculomotor nuclei of monkeys. J Comp Neurol 2001;438:318–335. Büttner U, Büttner-Ennever JA: Present concepts of oculomotor organization. Prog Brain Res 2006;151:1–42. Keller EL, Robinson DA: Abducens unit behavior in the monkey during vergence movements. Vision Res 1972;12:369–382. Dean P: Motor unit recruitment in a distribution model of extraocular muscle. J Neurophysiol 1996;76:727–742. Fuchs AF, Kaneko CR, Scudder CA: Brainstem control of saccadic eye movements. Annu Rev Neurosci 1985;8:307–337. Miller JM, Bockisch CJ, Pavlovski DS: Missing lateral rectus force and absence of medial rectus co-contraction in ocular convergence. J Neurophysiol 2002;87:2421–2433. Ling L, Fuchs AF, Phillips JO, Freedman EG: Apparent dissociation between saccadic eye movements and the firing patterns of premotor neurons and motoneurons. J Neurophysiol 1999;82: 2808–2811. Wasicky R, Horn AKE, Büttner-Ennever JA: Twitch and non-twitch motoneuron subgroups of the medial rectus muscle in the oculomotor nucleus of monkeys receive different afferent projections. J Comp Neurol 2004;479:117–129. Ugolini G, Klam F, Doldan Dans M, Dubayle D, Brandi A-M, Büttner-Ennever JA, et al: Horizontal eye movement networks in primates as revealed by retrograde transneuronal transfer of rabies virus: differences in monosynaptic input to ‘slow’ and ‘fast’ abducens motoneurons. J Comp Neurol 2006;498:762–785. Mayr R, Gottschall J, Gruber H, Neuhuber W: Internal structure of cat extraocular muscle. Anat Embryol 1975;148:25–34. Dieringer N, Precht W: Functional organization of eye velocity and eye position signals in abducens motoneurons of the frog. J Comp Physiol 1986;158:179–194. Lennerstrand G: Motor units in eye muscles; in Lennerstrand G, Bach-Y-Rita P (eds): Basic Mechanisms of Ocular Motility and Their Clinical Implications. Oxford, Pergamon Press, 1975, pp 119–143. Bach-Y-Rita P, Alvarado J, Nichols K, McHolm G: Extraocular muscle fibres: ultrastructural identification of iontophoretically labeled fibers contracting in response to succinylcholine. Invest Ophthalmol Vis Sci 1977;16:561–565. Steinbach MJ: The palisade ending: an afferent source for eye position information in humans; in Lennerstrand G, Ygge J, Laurent T (eds): Advances in Strabismus Research: Basic and Clinical Aspects. London, Portland Press, 2000, pp 33–42. Corsi M, Sodi A, Salvi G, Faussone-Pellegrini MS: Morphological study of extraocular muscle proprioceptor alterations in congenital strabismus. Ophthalmologica 1990;200:154–163. Domenici-Lombardo L, Corsi M, Mencucci R, Scrivanti M, Faussone-Pellegrini MS, Salvi G: Extraocular muscles in congenital strabismus: muscle fiber and nerve ending ultrastructure according to different regions. Ophthalmologica 1992;205:29–39. McNeer KW, Spencer RF: The histopathology of human strabismic extraocular muscle; in Lennerstrand G, Zee DS, Keller EL (eds): Functional Basis of Ocular Motility Disorders. Oxford, Pergamon Press, 1981, pp 27–37.
Prof. Dr. med. Jean A. Büttner-Ennever Institute of Anatomy, Ludwig-Maximilian University Pettenkoferstrasse 11 DE–80336 Munich (Germany) Tel. ⫹49 89 5160 4851, Fax ⫹49 89 5160 4857 E-Mail
[email protected]
Büttner-Ennever
14
Straube A, Büttner U (eds): Neuro-Ophthalmology. Dev Ophthalmol. Basel, Karger, 2007, vol 40, pp 15–34
Eye Movement Recordings: Methods Thomas Eggert Department of Neurology, LMU Munich, Munich, Germany
Abstract The development of oculomotor research is closely related to the development of the technology of eye movement recordings. The first part of this chapter summarizes some cornerstones of the history of eye movement recordings from the 18th century until today and explains the technical principles of the early antecedents of modern recording devices. The four most common recording techniques (electro-oculogram, infrared reflection devices, scleral search coil, and video-oculography) are then compared with respect to the most important system parameters: spatial resolution, temporal resolution, the capability to simultaneously record the multiple degrees of freedom of the eye, the setup complexity, system specific artifacts, and invasiveness. These features determine the suitability of these devices in particular applications. Copyright © 2007 S. Karger AG, Basel
Visual perception provides us with the illusion of a visual world that is continuously available within the complete field of fixation. Subjectively we are unaware of using saccadic eye movements to scan our visual environment with a small fovea (diameter about 5⬚) because we perceive a stable visual world. Similarly, we do not directly perceive the stabilizing eye movements we make, such as the vestibular ocular reflex or the optokinetic reflex. Therefore, before the actual dynamics of eye movements could be discovered, careful examination was needed. In particular, the development of eye movement recording techniques played a crucial role in this research. Some historical cornerstones of this development will be summarized in the first part of this chapter. References to the history of eye movement research and recording techniques from the 18th and 19th centuries are mainly based on the work of Wade et al. [1] and Wade and Tatler [2], who provided excellent reviews of this field. The second part of this chapter will focus on three methods that are still relevant today.
a
b
Fig. 1. Huey’s [10] lever device to record horizontal eye movements. a Eye movements made during reading were recorded with this technique; from Huey [11]. b The tracing on the smoked drum was photographed and then engraved; from Wade et al. [1].
History of Eye Movement Recording
Very early qualitative descriptions of eye movements originated at the beginning of the 18th century [3]. More accurate descriptions, based on the observation of afterimages, were made at the end of the 18th century. Using this method, Wells [4] described the slow and fast phases of vestibular nystagmus. The occurrence of saccades during reading was first reported by Javal [5] and Lamare [6], who used a rubber tube connected to the conjunctiva and both ears. With this device, each eye movement caused a sound that was heard. Hering [7] used a similar acoustic device in combination with the technique of afterimages. The first attempts to record eye movements were made at the end of the 19th century. Ahrens [8], Delabarre [9], and Huey [10, 11] used devices consisting of a lever attached to a plaster eyecup. A bristle at the end of the lever recorded the eye movements on the smoked drum of a kymograph. A schematic outline of the system used by Huey [11] and an original recording are shown in figure 1. This method had the fundamental drawback that the inertial forces between apparatus and eye could injure the eye mechanically. The device was also too heavy for the large accelerations occurring during saccades. To overcome this problem, Javal [12] suggested recording the reflection of a light beam from a little mirror attached to the conjunctiva, a method that was not successfully applied before von Romberg and Ohm [13] used it to measure ocular torsion. This technique was, however, still too invasive to be adopted by many researchers.
Eggert
16
A more elegant approach that avoided mechanical contact with the eye was chosen by Dodge and Cline [14]. They developed the first photographic method and recorded the corneal reflection of a bright vertical line on a moving photographic plate. This system can be considered an early antecedent of the modern system that uses light reflections from the cornea and the lens to measure the orientation of the eye without having any contact with it. These so-called double Purkinje image (DPI) eye trackers [15] reach very high resolution (⬍0.017⬚), accuracy (0.017⬚), and bandwidth (500 Hz) (DPI Eyetracker Gen 5.5, Fourward Technologies, Inc., Buena Vista, Va., USA). However, their accuracy is much lower during the high accelerations and decelerations of saccades, because the lens is not rigidly but elastically connected to the eyeball. This causes the large dynamic overshoot of saccade traces recorded with DPI eye trackers [16]. The very high accuracy of the DPI eye tracker during steady fixation is due to the fact that they use the angular differences between light reflections which are insensitive to small translations between the eye and the tracker. The complex mechanics involved in DPI trackers make these devices very expensive (monocular: USD 60,000; binocular USD 115,000). The electro-oculogram (EOG) was developed as another means to avoid any mechanical contact with the eye. The history of the EOG was described by Brandt and Büchele [17]. Schott [18] and Meyers [19] measured electrical potentials with skin electrodes attached near the eye. They erroneously assumed that changes of the measured potentials were mainly related to electrical activity of the eye muscles. Mowrer et al. [20] discovered that the EOG is primarily caused by the electrical dipole between cornea and retina, which moves with the eye. Jung [21] applied this method to record horizontal and vertical components of the eye position simultaneously. This signaled a remarkable progress, since previous recording techniques had been restricted to one movement direction only. Moreover, the EOG is still the only measurement technique that allows to record eye movements while the eyes are closed. This is of particular interest for sleep research. The EOG will be described in more detail in the second part. The second noninvasive measurement technique to become widely used is based on the intensity of infrared light reflected from the eye. Infrared reflection devices (IRDs) measure the intensity of these reflections by photosensitive elements placed at different locations in front the eye. The differences between these measures are used to determine the eye position. The first system of this type was developed by Torok et al. [22]. A modern variant of the IRD will be discussed later in the second part. Because fiber optic cables can be used to spatially separate the location where light intensity is collected and the location of the photodiodes used to measure the intensity, this method was also adopted for eye movement recordings together with functional magnetic resonance imaging techniques [23].
Eye Movement Recordings: Methods
17
None of the recording methods mentioned so far were able to quantify all three rotatory degrees of freedom of the eye simultaneously. Vertical and horizontal movement components could be quantified by the EOG, IRD, or the DPI tracker, but these devices cannot measure the orientation of the eye around the axis of view (ocular torsion), which is of special interest when examining the coordination of the three pairs of eye muscles. Von Romberg and Ohm [13] measured pure ocular torsion (during straight-ahead fixation) with their mirror system mentioned above. Howard and Evans [24] give a more detailed review of the early history of the measurement of ocular torsion. Already in the 19th century, the technique of afterimages had provided important findings about ocular torsion during fixation. Ruete [25] described the relation between gaze direction and ocular torsion and attributed it to his friend Listing (professor of mathematical physics in Göttingen) [26]. Von Helmholtz [27] discovered most of the geometric implications of ‘Listing’s law’. This field of research became of increasing interest when the magnetic search coil technique developed by Robinson [28] and Collewijn et al. [29] was extended by Collewijn et al. [30] and Kasper and Hess [31] to cover 3-D movements. The method is based on the voltages induced in coils by two or three orthogonal, rapidly alternating magnetic fields. The coils are embedded in a soft plastic annulus that adheres elastically to the eyeball. One coil is sufficient to measure gaze direction. Two coils with different orientations must be molded in the plastic annulus to measure gaze direction and ocular torsion simultaneously. The search coil method combines high spatial and temporal resolution and is so far the most precise method for measuring ocular torsion during eccentric gaze. With this technique it became possible to extend Helmholtz’s 3-D analysis of fixation to the full range of oculomotor performance [32]. Like other methods based on contact lenses, the search coil technique has the main disadvantage of being invasive. Therefore, considerable effort was made to evaluate the 3-D eye position on the basis of photographic images of the eye. All photographic methods are based on the detection and localization of eye-fixed markers (pupil, limbus, iris signatures, episcleral blood vessels) in image coordinates. The eye position with respect to the head can be computed from these image coordinates if the camera is firmly attached to the head. Otherwise, head-fixed markers can be used to compensate for relative translations between head and camera. Pioneers in these techniques, Brecher [33], Miller [34], Howard and Evans [24], detected and localized these markers manually and individually for each image. Howard and Evans [24] described a method for computing 3-D angular eye positions from the image coordinates of the markers. Video-oculography (VOG), defined as the use of these methods for dynamic measure of eye movements, became feasible with the rapid development of
Eggert
18
computer-based automatic image processing. This progress is mainly reflected (1) in the frame rates being processed online and (2) in the robustness and the accuracy of the marker detection algorithms. Both improve with the increase in computational power. Young et al. [35] detected the image position and orientation of the eye marker online at a frame rate of 60 Hz. Clarke et al. [36] could process frame rates up to 400 Hz. This temporal resolution is sufficient to cover the temporal bandwidth of physiological eye movements. The automatic detection and localization of the pupil do not need very complicated image processing, are relatively robust, and do not require very complicated algorithms. Since the measurement of the 2-D gaze direction in VOG is primarily based on the localization of the pupil, the 2-D VOG works reliably in head-mounted systems and with stabilized head positions. To compute the 3-D eye position, the orientation of the iris signature can be used. This signature must be scanned along a circular path close to the limbus, in order to be insensitive to changes of the pupil diameter. Direct polar cross-correlation of the iris signature at the actual eye position with that of a reference position can be used to measure ocular torsion. This works well while gaze is pointing straight ahead, but geometric distortions of the iris occurring at eccentric gaze positions lead to large errors. Haslwanter and Moore [37] observed errors of up to 8.7⬚ for 20⬚ horizontal and vertical eccentricities, and developed a method to correctly compensate for these errors. However, this technique may be difficult to apply in subjects with little iris structure. To reduce the computational effort and to increase the precision of VOG, some applications used artificial markers on the eye because they can be detected and tracked more easily than natural markers like iris signatures or episcleral blood vessels. Young et al. [35], for example, used a human hair mounted in a soft contact lens sandwich. As already proposed by Nakayama [38], Clarke et al. [36] applied two high-contrast tincture landmarks on the limbus.
Principles of Eye Movement Recordings: Advantages and Disadvantages
The Electro-Oculogram The simplest method for measuring human eye movements is based on the feature that the human eye is an electrical dipole. The axis of this dipole and the optical axis of the human eye are roughly collinear. The retina is more negative than the cornea. The potential difference of about 6 mV results from the electrical activity of photoreceptors and neurons in the retina. Changes of this potential induced by sudden light stimulus can be used to monitor the electrical activity of the retina (electroretinogram, ERG). However, the EOG uses the fact
Eye Movement Recordings: Methods
19
that this dipole rotates with the rotation of the eye. This causes small differences between the electrical potential at the skin surface depending on eye position. A rightward eye movement will increase the surface potential at the temporal canthus of the right eye, and decrease the surface potential at the temporal canthus of the left eye. The potential differences are in the range of a few V and can be measured with a bitemporal electrode configuration. The voltages are usually referenced to a third electrode that is generally placed at one of the mastoid processes or on the earlobe [17, 39]. Placing two electrodes bitemporally has the advantage that the measured voltage is linearly related to the horizontal eye position within a range of ⫾25⬚. Because eye movements are largely conjugate under far-viewing conditions, this electrode configuration is frequently used, even though it does not permit inference about differences between left and right eye movements. To simultaneously record vertical eye movements, two additional electrodes must be placed below and above the eye. Vertical EOG signals are less reliable than horizontal ones due to lid artefacts. SchmidPriscoveanu and Allum [40] observed systematic overestimation of vertical EOG velocity compared to VOG. The resolution of both horizontal and vertical EOG signals is limited by noise. Three different noise sources can be distinguished. (1) Inductive noise related to electromagnetic fields in the environment is reduced by relating the measured voltages to the reference electrode; however, it cannot be completely eliminated due to residual asymmetries between the three electrodes. (2) Thermal noise is generated by the input resistance of the amplifier and the contact resistance of the skin electrodes. In addition, an increased contact resistance also changes the voltage divider at the input of the amplifier, which in turn leads to a further decrease of the signal-to-noise ratio. To lower the contact resistance, the skin should be cleaned with alcohol or a commercial skin-preparing material. Electrodes should be made of relatively nonpolarizeable material such as silver-silver chloride or gold. The electrodes should be applied with a conductive paste. (3) Finally, capacitive noise is due to electrical activity of muscles and neurons. Subjects should be instructed to avoid any movements except eye movements. Especially the face and chewing muscles should stay as relaxed as possible. Changes of the dark adaptation level induce slow drifts of the corneoretinal potential which are superimposed on the EOG signal. Since both the EOG and ERG measure the corneoretinal potential, the standards of ERG recordings as specified by Marmor and Zrenner (1999) [41] can also be recommended for EOG recordings. To compare EOG recordings with IRD (see below), we applied both methods simultaneously to measure horizontal saccades between ⫾5⬚ (symmetrical around the straight ahead position; amplitude: 10⬚). The EOG was recorded binocularly with the electrodes placed bitemporally. Eye position signals were
Eggert
20
filtered using a low pass filter excluding frequency components above 50 Hz. Eye position traces were calibrated separately for each saccade and for both recording systems, based on the mean eye position signals averaged across windows with a duration of 200 ms, starting 300 ms before and 500 ms after the saccade. The beginning and end of the saccade were defined by the time at which eye velocity increased above or fell below 10% of the peak velocity of the saccade. Saccade amplitude was defined as the difference of eye position between the end and the beginning of the saccade. We observed a mean saccade amplitude of 9.4⬚, which was systematically smaller than the target amplitude (10⬚). This saccadic undershoot is typical for reflexive saccades to stepping targets and does not occur with targets that are continuously visible [42]. We did not find significant differences in eye amplitude between an IRD recording and the binocular EOG. Schmid-Priscoveanu and Allum [40] evaluated average horizontal slow-phase velocities induced by optokinetic nystagmus, vestibular nystagmus, and smooth pursuit using (subsequent) EOG and IRD recordings. They observed similar slow-phase velocity estimates. To measure movements of the right or the left eye only, skin electrodes can be placed at the temporal and the nasal canthus of one eye. This nasal-temporal configuration is difficult to handle, because the EOG voltage is influenced by the electrical activity of eye muscles and eye lids (electromyogram). Whereas the electromyogram activity of the right and left lateral rectus muscle cancel each other in the symmetrical bitemporal configuration, this symmetry is not as perfect in the nasal-temporal configuration. This can cause nonlinearity in the relation between horizontal eye position and measured voltage, and it may even cause asymmetries in the velocity gain between nasal and temporal saccades. We quantified this asymmetry by measuring the same symmetrical saccade paradigm as described above (amplitude 10⬚) with a nasal-temporal EOG of the right eye. Again a simultaneous IRD recording of the same eye was performed. Consistent with results obtained with search coil recordings [42], the IRD measurement correctly indicated that abducting saccades have larger amplitudes than adducting saccades (fig. 2). Therefore, the opposite adducting-abducting asymmetry indicated by the EOG recording (fig. 2) seems to reflect a systematic error of the nasal-temporal electrode configuration. We also analyzed the noise characteristic of the EOG using the same nasaltemporal electrode configuration. Representative examples of the resulting traces are shown in figure 3. The irregular oscillation of the EOG trace reflects a peak of the spectral power of the EOG signal close to 10 Hz. The root mean square (RMS) difference between IRD and EOG position signals was 0.26⬚. Because the changes of the IRD signal during the initial fixation stayed within ⫾0.05⬚, this noise can be almost completely assigned to the EOG signal. This leads to a resolution of the EOG signal (defined as its 95% confidence interval)
Eye Movement Recordings: Methods
21
140
EOG IRD
Right eye gain (%)
120
100
80
60 Adducting
Abducting
Fig. 2. Mean gain saccades of the right eye (i.e. the ratio between saccade amplitude and target amplitude) to symmetric target steps of 10⬚ as measured with monocular EOG and IRD. The monocular EOG overestimates the amplitude of adducting saccades and underestimates the amplitude of abducting saccades. For IRD recording, a commercial system (IRIS, Skalar) was used.
of about ⫾0.5⬚. Thus, the EOG cannot reliably be used for movement amplitudes of less than 5⬚, a condition that is fulfilled in many clinical applications. Infrared Reflection Devices In contrast to DPI eye trackers, IRDs do not determine the direction of a light beam reflected from the cornea, but measure the intensity of infrared light reflected from the eye at certain fixed locations close to the eye. Light intensity is measured with photo diodes that have a high temporal resolution. The distance between eye and photoreceptors is in the range of 1 cm. At such small distances, the differences in the intensity between the different photodiodes depend mainly on the position of iris and pupil, which reflect less light than the sclera. IRDs are very sensitive to relative translations of the photodiodes and the eye because they do not evaluate the angle, but only the intensity of the reflection. For an eye radius of 1.25 cm, a translational error of 1 mm will lead to an eye position error of almost 5⬚. The system must therefore be firmly attached to the head. IRDs have a much lower noise level than EOG, but they suffer from eye lid artifacts that critically depend on the position of the photodiodes. These lid artifacts may increase dramatically if the device is not properly adjusted in front of the eye. Lid artifacts are more pronounced for vertical than for horizontal eye movements. Moreover, the position of the photodiodes is
Eggert
22
6 EOG IRD Target
Position (degrees)
4
2
0
⫺2
⫺4
⫺6 0
100
200
300
400
500
Time (ms)
Fig. 3. Recording of a horizontal symmetrical saccade to a target step starting at 5⬚ eccentricity at the right side and ending at 5⬚ eccentricity on the left side. The solid traces show the horizontal eye position of the right eye simultaneously recorded with the monocular EOG and IRD. The noise level of the EOG is much higher that of the IRD. The amplitude of the leftward saccade of the right eye (adducting) is overestimated by the EOG (fig. 2).
also critical for the system linearity. Due to these features, optimal adjustment of the device requires that the experimenter carefully controls the eye position signal of the IRD and compares it with the eye movements. A useful method to control the subject’s eye movements during the adjustment is to manually guide the head movements of the subject while the subject is fixating a space-fixed target. System setup may be very difficult or even impossible for subjects with narrow palpebral fissures. Because of the sensitivity of the overall transfer function (IRD signal/eye position) to translation, it is recommended to collect calibration data not only at the beginning or the end of a recording, but at regular time intervals. We tested the temporal stability of the calibration using a commercial IRD (IRIS, Skalar, Delft, The Netherlands). Figure 4 shows two sets of calibration data for one subject, the second was collected 10 min after the first. Targets were presented at eye level at nine equidistant horizontal positions with eccentricities between ⫾20⬚. The interpolated curves are least square fits of 3rd order polynomials. The coefficients of the polynomial were computed by minimizing
Eye Movement Recordings: Methods
23
30
Calibration 1 Calibration 2
Target position (degrees)
20 10 0 ⫺10 ⫺20 ⫺30 500
1,000
1,500
2,000
2,500
3,000
Raw units
Fig. 4. Relation between the noncalibrated raw signal of an IRD (raw units of a 12-bit analog to digital converter; abscissa) and the target position during fixation of that target. Each symbol corresponds to one fixation. The second set of data is separated from the first set by a time interval of 10 min. Solid lines indicate the fitted calibration curves (see text). Differences between the first and the second calibration are mainly due to relative movements between the IRD and the eye caused by slip of the head mount.
the mean squared distance between the IRIS signal during fixations and the fitted curve. The distance is measured along lines parallel to the abscissa of figure 4. The curvature of the calibration curve is more pronounced in the first data set (fig. 4; deviations from linearity: ⬍4.5⬚) than in the second data set (fig. 4; deviations from linearity: ⬍2.8⬚). This shows that using a nonlinear calibration is indeed profitable for accuracy. The difference between the two subsequent calibrations can largely vary between subjects and amounts up to 10⬚ in the given example. We conclude that the calibration of an IRD can be substantially improved by considering temporal drifts of gain, offset, and nonlinearity. Search Coil The scleral search coil system measures the voltages in one or two coils induced by two or three rapidly oscillating magnetic fields. The coils are molded in a soft contact annulus that is attached to the eyeball. The magnetic fields are generated by three pairs of large coils, mounted in a cubic frame. The subject’s head is positioned in its center. The field coils should be large, because the homogeneity of the magnetic field is crucial for the precision of the measurement. With pairs of square-shaped coils, arranged in a cubic configuration, the inhomogeneity inside of a central test cube stays below 5% when the edge
Eggert
24
Torsional coil
Directional coil
Fig. 5. Technique for molding two coils with almost orthogonal effective planes in a single contact annulus. The directional coil is wound in a single plane that is orthogonal to the viewing axis. The torsional coil is wound in the shape of an ‘eight’. A magnetic field aligned to the axis of view will induce identical, but opposite voltages in both parts of this ‘eight’. These voltages cancel each other. Therefore, the axis of view is a null direction of the torsional coil. Consequently, because by definition the vector of any null direction lies in the efficient plane of a coil, the efficient planes of directional and torsional coils are orthogonal.
length of the test cube approaches one fifth of the edge length of the field coil [43]. This means that when using field coils with an edge length of 1.5 m, subjects should not move by more than 7 cm. The basic principle of the relation between induced voltage and coil orientation is the following. The voltage induced by one of the magnetic fields in the scleral search coil is proportional to the projection of the coil vector (defined as the vector orthogonal to the effective coil plane) onto the magnetic field vector. Thus, the three voltages induced by three orthogonal magnetic fields form the vector components of the coil vector expressed in field coordinates. A dual search coil for recording 3-D eye orientation provides six voltages, corresponding to the two 3-D coil vectors of the directional and the torsional coil (fig. 5). Methods to compute the 3-D eye orientations from these six signals were described by Tweed et al. [44]. This simple principle is complicated by a number of potential sources of errors: (1) cross-coupling of horizontal, vertical, and frontal field caused by misalignment of the three magnetic fields and the three orthogonal axes of the head-fixed Cartesian reference frame; (2) inhomogeneity of the magnetic fields; (3) offset voltages related to induction in the connecting line of the search coil; (4) misalignment between coil vector and gaze vector. To overcome these problems, search coil recordings require a calibration procedure that is often based on multiple fixations on targets at various positions. The calibration parameters are computed by minimizing the errors between the calibrated gaze vector and target vectors. Systems with only two magnetic fields are usually calibrated in this way. The disadvantage of this method is that it cannot be used with oculomotor pathologies that prevent accurate fixation. Systems with three
Eye Movement Recordings: Methods
25
magnetic fields can be objectively calibrated [45], i.e. their calibration does not rely on accurate fixation of targets at different positions, as most other recording techniques. The calibration method described by Bartl et al. [45] evaluates the gain matrix of the 3-D search coil system based on an objective measurement of the direction of the three magnetic fields. Only a single fixation target is needed in order to determine the orientation of the coil with respect to the eye. Another important advantage of 3-field systems over 2-field systems is that the orientation of the coil vector can be determined without knowledge of the actual inductance of the scleral search coil. This is because changes in inductance will have the same proportional effect on all three voltages and can easily be eliminated by normalization. With the search coil technique, the inherent system noise of horizontal and vertical eye position has been estimated to be on the order of 0.5 min of arc (0.0083⬚) [29]. With a dual search coil and a 3-field system (Remmel Labs, Ashland, Mass., USA) using a 12-bit analog to digital converter, we measured a system noise of 0.007⬚ for horizontal and vertical eye positions and 0.025⬚ for torsional eye position. The system noise was defined as the standard deviation of the eye position signal from its mean when the coil was objectively fixed in space. Data were sampled at 1 kHz. The larger system noise of the torsional eye position is due to the smaller inductivity of the torsional coil (fig. 5). It should be noted that the actual resolution of the calibrated coil signal depends very much on the amplifier gain which should make optimal use of the dynamic range of the recording device (usually analog to digital converters). The system resolution is a very important parameter; it determines the smallest eye movement that can be detected. However, to compare the metrics of eye movements between different subjects or with a stimulus- defined requirement the accuracy is more important than the system noise. The system accuracy of search coils depends mainly on the quality of the calibration. Imai et al. [46] used an artificial eye to evaluate the coil accuracy. They obtained mean differences between coil measure and the set angle of the artificial eye of 0.458, 0.948, and 1.628⬚ for horizontal, vertical, and torsional eye position, respectively. Measurement errors are mainly caused by instabilities of the current of the field coils, temperature dependences of the electronic circuits, and metallic parts in the neighborhood of the field coils. These difficulties, however, can be controlled by careful handling of the system. Due to its large signal to noise ratio and reliability, the search coil technique has been the generally accepted reference standard for eye movement recordings for 30 years. However, the disadvantages, connected with the invasiveness of the method, have also been recognized. The search coil not only measures eye movements, but also affects them. Frens and van der Gest [47] found that saccades last longer (by about 8%) and become slower (by about 5%) when subjects wear search coils in both eyes than when they do not. When only
Eggert
26
one search coil was applied, these effects did not reach significance within the tested population, because the differences between subjects were larger. At least in some subjects, wearing a search coil in one eye only also prolonged saccade duration and reduced saccade velocity. It was also shown that the eye torsion, when evaluated with the search coil, depends on the orientation of exit point of the connecting line from the search coil. With the nasal exiting orientation of a commercial eye coil (Skalar), Bergamin et al. [48] observed that ocular torsion depended more on eye elevation than with a modified exit point that minimized the contact between wire and eyelids. Changes in static torsion associated with 40⬚ change in elevation were about 2⬚ larger with the commercial search coil than with the modified eye coil. Differences in intrasaccadic torsion between the two different coils reached up to 5⬚. These results suggest that contact between eye lid and coil wire can lead to substantial changes of the coupling between gaze direction and ocular torsion. Other disadvantages of the scleral search coil are that wearing the coil may lead to drying, and temporal deformations of the cornea, and reduced visual acuity in the eye with the search coil. Therefore, the manufacturer of the search coil limits wearing time to 30 min. Irving et al. [49] observed corneal deformations of more than 3 dpt in 2 of 6 subjects and visual acuity (Snellen) of less than 6/9 in 2 subjects. These effects appeared as early as 15 min after coil insertion and dissipated after coil removal. As the number of subjects in this study was small, it is possible that the frequency of occurrence of such effects is less across the population. However, in eye movement experiments involving visual tasks, particularly with binocular search coil recordings, visual acuity should be checked. Even though most authors feel confident that the safety risks of the search coil are relatively minor [49, 50], the discomfort induced by wearing eye coils makes it more difficult to work with untrained volunteers. Irving et al. [49] asked subjects to rate the coil-induced discomfort on a scale between none (1) and ‘extreme discomfort’ (5). The mean subject rating on this scale was 3.0 ⫾ 0.3 at the point of maximum discomfort (immediately before coil removal). Video-Oculography Video-based eye movement recordings have become more and more popular because of the rapid progress made in electronic data processing. The devices have become affordable, the robustness of the algorithms improved, and the range of applications expanded. Nowadays, commercial companies produce VOG devices that can be used in an fMRI scanner (MeyeTrack, SMI, Berlin, Germany). Most fundamental VOG techniques, as defined above, are based on tracking of the position of eye-fixed markers in a 2-D image. These positions have to be expressed in head-fixed coordinates. Since head-fixed markers are difficult to obtain with high precision, one strategy of VOG systems is to attach
Eye Movement Recordings: Methods
27
the video camera as firmly as possible to the head. As long as the system is not compensated for relative translation between camera and head, the accuracy of VOG has a problem very similar to that of the IRD. A translation of 1 mm will result in an error of about 5⬚. Head-fixed devices cause a problem under headfree conditions, because the stability of the head mount is not sufficient. Because of this problem, actual VOG systems can make highly accurate measurements of eye position, only as long as the head is fixed in space. Karmali and Shelhamer [51] compared algorithms to compensate for camera translation by tracking specific landmarks in the surrounding of the eyes that are supposed to move little with respect to the head. Karmali and Shelhamer [51] were especially interested in the differences in vertical translation between the cameras of the left and the right eye. In this study, the best results were obtained when the upper eyelid was localized using a template matching algorithm together with 20% outlier rejection. On average, the estimate of head translation differed by less than 1.5 pixels from a manual estimate of head position. Another method of compensating for head translation uses the relative position of the corneal reflex of an infrared LED (Eyelink II, SR Research, Osgode, Canada). One difficulty with this method is that using the corneal reflection adds more noise. For eye movements of about 12–15⬚ the reflection reaches the edge of the cornea, and can no longer be used for compensation. Moreover, this approach relies on the topography of the cornea, which varies between subjects. Therefore, it seems to be useful when compensating for large translations, but may be unable to provide very high accuracy. Since the pupil position is detected and evaluated in image coordinates, the nonlinearity of the VOG systems (in contrast to IRDs) is well defined by the geometry of the image projection. With parallel projection, the angular eccentricity of the eye can be approximated by the inverse sinus of the ratio of the eccentricity of the pupil center and the eye radius, both expressed in image coordinates. The main aim of the VOG calibration is therefore to determine the location of the center of rotation of the eye and the radius of the eyeball. Up to now, no objective method has been established to determine these parameters. This is due to the following difficulties. (1) Pure rotation is an insufficient mathematical model to describe the actual movement of the eyeball [52] during large changes of vergence. (2) The pupil is viewed through the cornea and therefore, the detected pupil center is subject to refractive errors. Systems that track the limbus position [53] avoid this problem, because the limbus is closer to the eye surface than the pupil. Usual calibration methods do not explicitly compensate for these effects but use 2-D interpolating functions to transform the image coordinates of the pupil to 2-D eye position. The parameters of these functions are computed by minimizing the mean squared error in a similar manner as for the IRD (see above). Van der Geest and Frens [54] used
Eggert
28
Horizontal
30
3.0 Eye position (degrees)
25 Eye position (degrees)
Vertical
3.5
20 15 10 5
2.5 2.0 1.5 1.0
Coil VOG
0.5 0.0
0 ⫺50
0
50
100
Time (ms)
150
⫺0.5 ⫺50
0
50
100
Time (ms)
Fig. 6. Simultaneous recordings of an oblique saccade with a search coil and VOG. Data from Van der Geest and Frens [54].
such a calibration (biquadratic interpolating function) for a 2-D VOG system (Eyelink version 2.04, SR Research) and compared it with a simultaneous recording of a 2-D coil system (fig. 6). This VOG system neither tracked the corneal reflex nor tried to compensate for relative translation between camera and head. While fixating targets between ⫾20⬚ horizontal and vertical eccentricity, the standard deviation of the difference of gaze position between both systems was 0.98⬚ for the horizontal errors and 1.05⬚ for the vertical errors. Since the accuracy of the 2-D search coil was estimated at about 0.5⬚ [46; see above], Van der Geest and Frens [54] concluded that the ‘…video system should be treated with care when the accuracy of fixation position is required to be smaller than 1 deg’. This statement can be generalized for any eye movement recording system using calibrations based on fixation data because the standard deviation of the eye position across repeated fixation of the same target position in healthy subjects is on the order of 1–2⬚ (fig. 4). The accuracy of a calibration based on fixations is not better than the standard error of the fixation. For example, nine fixations with a standard deviation of 1.8⬚ lead to a calibration accuracy of 0.6⬚. The resolution of the 2-D VOG defined by the standard deviation of system noise measured with an artificial eye is about 0.01⬚ (details provided by SR research). This system noise is typical and is also reached by other modern VOG devices [55]. Since these values were obtained with artificial eyes under optimal lighting conditions, system noise should be about 2–5 times higher with human eyes under natural conditions.
Eye Movement Recordings: Methods
29
150
Torsional eye position (degrees)
2
1
0
⫺1
⫺2 0
1
2
3
Time (s)
Fig. 7. Torsional eye position during galvanic vestibular stimulation of a subject instructed to fixate straight ahead. Two dark artificial markers were applied outside and close to the limbus. The two traces show the torsional eye position evaluated on the basis of the image location of the markers (upper trace) or on the basis of a cross-correlation of 16 iral segments (lower trace). For clarity, the latter has been shifted down by 1⬚. Both methods were applied offline to the same image data. The noise level of the marker method is about ten times less than the method based on iris patterns. Data from Schneider et al. [57].
Like the VOG of 2-D gaze direction, measurements of ocular torsion also reach accuracy values that are similar to those of coil measurements. Using an artificial eye, Imai et al. [46] reported mean errors of the torsional VOG signal of 0.52⬚. Occasionally, and in particular for fixations in tertiary gaze positions, larger deviations (up to 5⬚) of ocular torsion between a VOG and a simultaneous search coil recording have been observed [56]. Using an artificial eye with a very clear iris structure, Clarke et al. [55] estimated the inherent system noise of VOG measurements of ocular torsion at 0.016⬚ (RMS). This value is probably better than torsional noise levels reached with natural iris patterns. Schneider et al. [57] reported noise levels of about 0.14⬚ (RMS) (fig. 7). They demonstrated that the noise level of torsional VOG measurements can be substantially lowered by tracking two artificial marks applied outside and close to the limbus (fig. 7). With this method, the inherent system noise dropped to 0.017⬚ (RMS), which is similar to coil data. Unfortunately, marking the eyeball with tincture markers requires anesthetizing the eye. Hence, the VOG system’s main advantage of noninvasiveness is lost when this method is used.
Eggert
30
Table 1. Summary of the main features of EOG, IRD, scleral search coil and VOG EOG
IRD
Scleral search coil
VOG
Spatial resolution (inherent system noise RMS value), degrees
⬇0.5
⬇0.02
⬇0.01
⬇0.05
Temporal resolution (bandwidth), Hz
40
100
500
50–400
Vertical movements recordable
possible, confounded by eyelid artifacts
possible, confounded by eyelid artifacts
yes
yes
Torsional movements recordable
no
no
yes, also in secondary gaze positions
yes, with some difficulties in secondary gaze positions
Setup time
slow (skin preparation and electrode application)
medium (goggle adjustment to minimize nonlinearity)
slow
very fast
Accurate fixation needed for calibration
yes
yes
no
yes
Complexity of calibration
good linearity (with bitemporal configuration)
polynomial calibration necessary for larger eccentricities
nonlinearity can be compensated by model-based parameter fit
good linearity
Invasiveness
surface electrodes next to the eye, no contact with the eye, no effects on vision
head-mounted device, no contact with the eye, moderate limitations of field of view
contact lens attached to the eye, potential effects on visual acuity, considerable discomfort
head mounted device, no contact with the eye, moderate limitations of field of view
Eye Movement Recordings: Methods
31
The main features of the eye movement recording devices mentioned in this chapter are summarized in table 1. Since the EOG is still the only method that allows measurement of eye movements while the eyes are closed, it remains important for specialized applications that require this possibility. Modern VOG systems can measure 2-D gaze direction at spatial resolutions comparable to those of search coil systems. The accuracy of VOG devices is also comparable to that of the search coil, but it depends on the ability of the subjects to fixate accurately. System noise and accuracy of ocular torsion is slightly better in search coil systems than in VOG. The main disadvantage of the search coil is that it is invasive compared with the EOG, IRD, or VOG. Therefore, search coil measurements are advisable only for relatively short recordings requiring high temporal resolution, high accuracy, and an objective calibration. For most other applications, VOG seems to provide a good alternative to the search coil technique. Until recently, the IRD was still a reasonable noninvasive alternative to the search coil, at least for measuring horizontal (1-D) eye movements. In the meantime, the temporal resolution of VOG improved and is now sufficient to cover the temporal bandwidth of physiological eye movements. The robustness of the system linearity with respect to displacements between the device and the eye is much better in VOG than in the IRD. Therefore, the IRD appears to have been outdated by VOG.
References 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
Wade NJ, Tatler BW, Heller D: Dodge-ing the issue: Dodge, Javal, Hering, and the measurement of saccades in eye-movement research. Perception 2003;32:793–804. Wade NJ, Tatler BW: The Moving Tablet of the Eye: The Origins of Modern Eye Movement Research. Oxford, Oxford University Press, 2005. Porterfield W: An essay concerning the motions of our eyes. I. Of their external motions. Edinburgh Med Essays Obs 1737;3:160–263. Wells WC: An Essay Upon Single Vision with Two Eyes: Together with Experiments and Observations on Several Other Subjects in Optics. London, Cadell, 1792. Javal LE: Essai sur la physiologie de la lecture. Ann Ocul 1879;82:242–253. Lamare M: Des mouvements des yeux dans la lecture. Bull Mem Soc Fr Ophtalmol 1892;10:354–364. Hering E: Über Muskelgeräusche des Auges. Sitzungsberichte der kaiserlichen Akademie der Wissenschaften in Wien. Math Naturwiss Kl Abt III 1879;79:137–154. Ahrens A: Die Bewegungen der Augen beim Schreiben. Rostock, University of Rostock, 1891. Delabarre EB: A method of recording eye movements. Am J Psychol 1898;9:572–574. Huey EB: Preliminary experiments in the physiology and psychology of reading. Am J Psychol 1898;9:575–586. Huey EB: On the psychology and physiology of reading. Am J Psychol 1900;11:283–302. Javal LE: Essai sur la physiologie de la lecture. Ann Ocul 1878;80:240–274. von Romberg G, Ohm J: Ergebnisse der Spiegelnystagmographie. Gräfes Arch Ophtalmol 1944; 146:388–402. Dodge R, Cline TS: The angle velocity of eye movements. Psychol Rev 1901;8:145–157. Crane HD, Steele CM: Generation-V dual-Purkinjeimage eyetracker. Appl Optics 1985;24:527–537. Deubel H, Bridgeman B: Fourth Purkinje image signals reveal eye-lens deviations and retinal image distortions during saccades. Vision Res 1995;35:529–538.
Eggert
32
17 18 19 20 21 22 23 24 25
26
27 28 29 30 31 32 33 34 35 36
37 38 39 40 41 42 43
Brandt T, Büchele W: Augenbewegungsstörungen: Klinik und Elektronystagmographie. Stuttgart, Gustav Fischer, 1983. Schott E: Über die Registrierung des Nystagmus und anderen Augenbewegungen vermittels des Seitengalvanometers. Dtsch Arch Klin Med 1922:140:79–90. Meyers IL: Electronystagmographie. A graphic study of the action currents in nystagmus. Arch Neurol 1929;21:901–908. Mowrer OR, Ruch RC, Miller NE: The corneoretinal potential difference as the basis of the galvanometric method of recording eye movements. Am J Physiol 1936;114:423. Jung R: Eine Elektrische Methode zur Mehrfachen Registrierung von Augenbewegungen und Nystagmus. J Mol Med 1939;18:21–24. Torok N, Guillemin V, Barnothy JM: Photoelectric nystagmography. Ann Otol Rhinol Laryngol 1951;60:917–926. Kimmig H, Greenlee MW, Huethe F, Mergner T: MR-eyetracker: a new method for eye movement recording in functional magnetic resonance imaging. Exp Brain Res 1999;126:443–449. Howard IP, Evans JA: The measurement of eye torsion. Vision Res 1963;61:447–455. Ruete CGT: Ocular physiology. Chapter 4. The muscles of the eye. Strabismus 1999;7:43–60; translated from Lehrbuch der Ophthalmologie, ed 2. Braunschweig, Vieweg, vol 1, 1846, pp 36–37. Simonsz HJ: Christian Theodor Georg Ruete: the first strabismologist, coauthor of listing’s law, maker of the first ophthalmotrope and inventor of indirect fundoscopy. Strabismus 2004;12: 53–57. von Helmholtz H: Handbuch der Physiologischen Optik. Hamburg, Voss, 1867. Robinson DA: A method of measuring eye movement using a scleral search coil in a magnetic field. IEEE Trans Biomed Eng 1963;10:137–145. Collewijn H, van der Mark F, Jansen TC: Precise recording of human eye movements. Vision Res 1975;15:447–450. Collewijn H, Steen J, Ferman L, Jansen TC: Human ocular counterroll: assessment of static and dynamic properties from electromagnetic scleral coil recordings. Exp Brain Res 1985;59:185–196. Kasper H, Hess BJ: Magnetic search coil system for linear detection of three-dimensional angular movements. IEEE Trans Biomed Eng 1991;38:466–475. Straumann D, Zee DS, Solomon D, Kramer PD: Validity of Listing’s law during fixations, saccades, smooth pursuit eye movements, and blinks. Exp Brain Res 1996;112:135–146. Brecher GA: Die optokinetische Auslösung von Augenrollung und rotatorischen Nystagmus. Pflügers Arch Ges Physiol 1934;234:13–28. Miller EF: Counterrolling of the human eye produced by head tilt with respect to gravity. Acta Otolaryng (Stockh) 1962;59:479–501. Young LR, Lichtenberg BK, Arrott AP, Crites TA, Oman CM, Edelman ER: Ocular torsion on earth and in weightlessness. Ann N Y Acad Sci 1981;374:80–92. Clarke AH, Steineke C, Emanuel H: High image rate eye movement measurement. A novel approach using CMOS sensors and dedicated FPGA devices; in Lehmann T (ed): Bildverarbeitung in der Medizin. Berlin, Springer, 2000. Haslwanter T, Moore ST: A theoretical analysis of three-dimensional eye position measurement using polar cross-correlation. IEEE Trans Biomed Eng 1995;42:1053–1061. Nakayama K: Photographic determination of the rotational state of the eye using matrices. Am J Optom Physiol Opt 1974;51:736–741. Dieterich M, Brandt T: Elektronystagmographie: Methodik und klinische Bedeutung. EEG Labor 1989;11:13–30. Schmid-Priscoveanu A, Allum JHJ: Die Infrarot- und die Videookulographie – Alternativen zur Elektrookulographie? HNO 1999;47:472–478. Marmor MF, Zrenner E: Standard for clinical electroretinography (1999 update). Doc Ophthalmol 1999;97:143–156. Collewijn H, Erkelens CJ, Steinman RM: Binocular co-ordination of human horizontal saccadic eye movements. J Physiol 1988;404:157–182. Ditterich J, Eggert T: Improving the homogeneity of the magnetic field in the magnetic search coil technique. IEEE Trans Biomed Eng 2001;48:1178–1185.
Eye Movement Recordings: Methods
33
44 45 46
47 48 49 50 51 52 53 54 55 56 57
Tweed D, Cadera W, Vilis T: Computing three-dimensional eye position quaternions and eye velocity from search coil signals. Vision Res 1990;30:97–110. Bartl K, Siebold C, Glasauer S, Helmchen C, Büttner U: A simplified calibration method for three-dimensional eye movement recordings using search-coils. Vision Res 1996;36:997–1006. Imai T, Sekine K, Hattori K, Takeda N, Koizuka I, Nakamae K, Miura K, Fujioka H, Kubo T: Comparing the accuracy of video-oculography and the scleral search coil system in human eye movement analysis. Auris Nasus Larynx 2005;32:3–9. Frens MA, van der Geest JN: Scleral search coils influence saccade dynamics. J Neurophysiol 2002;88:692–698. Bergamin O, Ramat S, Straumann D, Zee DS: Influence of orientation of exiting wire of search coil annulus on torsion after saccades. Invest Ophthalmol Vis Sci 2004;45:131–137. Irving EL, Zacher JE, Allison RS, Callender MG: Effects of scleral search coil wear on visual function. Invest Ophthalmol Vis Sci 2003;44:1933–1938. Murphy PJ, Duncan AL, Glennie AJ, Knox PC: The effect of scleral search coil lens wear on the eye. Br J Ophthalmol 2001;85:332–335. Karmali F, Shelhamer M: Automatic detection of camera translation in eye video recordings using multiple methods. Ann N Y Acad Sci 2005;1039:470–476. Enright JT: Ocular translation and cyclotorsion due to changes in fixation distance. Vision Res 1980;20:595–601. Wang JG, Sung E: Gaze determination via images of irises. Image Vis Comput 2001;19:891–911. van der Geest JN, Frens MA: Recording eye movements with video-oculography and scleral search coils: a direct comparison of two methods. J Neurosci Methods 2002;114:185–195. Clarke AH, Ditterich J, Druen K, Schönfeld U, Steineke C: Using high frame rate CMOS sensors for three-dimensional eye tracking. Behav Res Methods Instrum Comput 2002;34:549–560. Houben MM, Goumans J, van der Steen J: Recording three-dimensional eye movements: scleral search coils versus video oculography. Invest Ophthalmol Vis Sci 2006;47:179–187. Schneider E, Glasauer S, Dieterich M: Comparison of human ocular torsion patterns during natural and galvanic vestibular stimulation. J Neurophysiol 2002;87:2064–2073.
Web Links Hain TC (2005): Eye movement recording devices; http://www.dizziness-and-balance.com/practice/eyemove.html Marmor MF, Zrenner E (1999): Standard for clinical electroretinography; http://www.iscev.org/standards/eog.html Paulson EJ, Goodman KS (1999): Influential studies in eye movement research; http://www.readingonline.org/research/eyemove.html Schneider G, Kurt J (2000): Zur Rolle der Blicksteuerung bei Lesestörungen. Kapitel 7: Technische Prinzipien zur Messung der Augenbewegungen; http://www2.hu-berlin.de/reha/eye/Studie2000/tech.pdf Wooding D (2002): Eye movement equipment database; http://ibs.derby.ac.uk/cgi-bin/emed/emedsrch.cgi?opr1 ⫽ OR&fld1 ⫽ name&key1a ⫽ *.
Dr. T. Eggert Department of Neurology, Klinikum Grosshadern Marchioninistrasse 23 DE–81377 Munich (Germany) Tel. ⫹49 89 7095 4834, Fax ⫹49 89 7095 4801 E-Mail
[email protected]
Eggert
34
Straube A, Büttner U (eds): Neuro-Ophthalmology. Dev Ophthalmol. Basel, Karger, 2007, vol 40, pp 35–51
Vestibulo-Ocular Reflex Michael Fetter Department of Neurology, SRH Clinic Karlsbad-Langensteinbach, Karlsbad, Germany
Abstract The vestibulo-ocular reflex (VOR) ensures best vision during head motion by moving the eyes contrary to the head to stabilize the line of sight in space. The VOR has three main components: the peripheral sensory apparatus (a set of motion sensors: the semicircular canals, SCCs, and the otolith organs), a central processing mechanism, and the motor output (the eye muscles). The SCCs sense angular acceleration to detect head rotation; the otolith organs sense linear acceleration to detect both head translation and the position of the head relative to gravity. The SCCs are arranged in a push-pull configuration with two coplanar canals on each side (like the left and right horizontal canals) working together. During angular head movements, if one part is excited the other is inhibited and vice versa. While the head is at rest, the primary vestibular afferents have a tonic discharge which is exactly balanced between corresponding canals. During rotation, the head velocity corresponds to the difference in the firing rate between SCC pairs. Knowledge of the geometrical arrangement of the SCCs within the head and of the functional properties of the otolith organs allows to localize and interpret certain patterns of nystagmus and ocular misalignment. This is based on the experimental observation that stimulation of a single SCC leads via the VOR to slowphase eye movements that rotate the globe in a plane parallel to that of the stimulated canal. Furthermore, knowledge of the mechanisms that underlie compensation for vestibular disorders is essential for correctly diagnosing and effectively managing patients with vestibular disturbances. Copyright © 2007 S. Karger AG, Basel
The vestibulo-ocular reflex (VOR) helps to stabilize the retinal image by rotating the eyes to compensate for movements of the head. An ideal VOR, that tries to compensate for any arbitrary movement of the head in 3-D space, would generate eye rotations at the same speed as, but in the opposite direction to, head rotation independent of the momentary rotation axis of the head. The desired result is that the eye remains still in space during head motion, enabling clear vision. The VOR has two different physical properties. The angular VOR, mediated
Sensory input
Central processing
Motor output
Visual Vestibular Proprioceptive
Vestibular nuclear complex
Oculomotor neurons
Adaptive processor (cerebellum)
Fig. 1. Schematic drawing illustrating the VOR.
by the semicircular canals (SCCs), compensates for rotation. The linear VOR, mediated by the otolith organs (saccule and utricle), compensates for translation. The angular VOR is primarily responsible for gaze stabilization. The linear VOR is most important in situations where near targets are being viewed [1, 2]. The VOR has three main components: the peripheral sensory apparatus (the labyrinth), a central processing mechanism, and the motor output (the eye muscles) [3]. The sensory input for the generation of the VOR is provided by a set of motion sensors, which send the information about head angular velocity, linear acceleration, and orientation of the head with respect to gravity to the central nervous system (specifically the vestibular nucleus complex and the cerebellum). In the central nervous system, these signals are combined with other sensory information (e.g. from the somatosensors) at as early stages as the vestibular nucleus complex to estimate head orientation. The output of the central vestibular system is sent to the ocular muscles and the spinal cord to serve the VOR and the vestibulospinal reflex (VSR), the latter generating compensatory body movement in order to maintain head and postural stability, thereby preventing falls. The information goes also to cortical structures (e.g. posterior insular vestibular cortex, PIVC) where it is further integrated with visual, proprioceptive, auditory and tactile input to generate a best possible perception of motion and space orientation [4]. The performance of the VOR and VSR is monitored by the central nervous system, and readjusted as necessary by adaptive processes with immense capability of repair and adaptation mainly involving cerebellar function (fig. 1) [5].
The Peripheral Sensory Apparatus
The peripheral vestibular system includes the membranous and bony labyrinths, and the motion sensors of the vestibular system, the hair cells. Each
Fetter
36
labyrinth consists of three SCCs, the cochlea, and the vestibule containing the utricle and saccule). The geometric arrangement of the SCCs allows for detection of head rotation about any axis in space. They are positioned in three nearly orthogonal planes in the head and act as angular accelerometers working in a push-pull arrangement with the other labyrinth (right and left lateral SCC; right anterior and left posterior SCC; left anterior and right posterior SCC). The planes of the SCCs are close to the planes of the extraocular muscles, thus allowing relatively simple neural connections between sensory neurons related to individual canals, and motor output neurons, related to individual ocular muscles (fig. 2) [6]. One end of each SCC is widened in diameter to form an ampulla containing the cupula. The cupula causes endolymphatic pressure differentials, associated with head motion, to be coupled to the hair cells embedded in the cupula. These specialized hair cells are biological sensors that convert displacement due to head motion into neural firing. When hairs are bent toward or away from the longest process of the hair cells, firing rate increases or decreases in the vestibular nerve [7, 8]. The hair cells of the saccule and utricle, the maculae, are located on the medial wall of the saccule and the floor of the utricle. The otolithic membranes are structures similar to the cupulae, but as they contain calcium carbonate crystals called otoconia, they have substantially more mass than the cupulae. The mass of the otolithic membrane causes the maculae to be sensitive to gravity. In contrast, the cupulae normally have the same density as the surrounding endolymphatic fluid and are insensitive to gravity. By virtue of their orientation, the SCC and otolith organs are able to respond selectively to head motion in particular directions [9].
Central Processing of Vestibular Signals
The coplanar pairing of canals is associated with a push-pull change in the quantity of SCC output. With rotation in the plane of a coplanar SCC pair, the neural firing increases from tonic resting discharge in one vestibular nerve and decreases on the opposite site. For the lateral canals, displacement of the cupula towards the ampulla (ampullopetal flow) is excitatory, whereas for the vertical canals, displacement of the cupula away from the ampulla (ampullofugal flow) is excitatory (fig. 3). There are certain advantages to the push-pull arrangement of coplanar pairing. First, pairing provides sensory redundancy. If disease affects the SCCs from one member of a pair (e.g. as in vestibular neuritis), the central nervous system will still receive vestibular information about head velocity within that plane from the contralateral member of the coplanar pair. Second, such a pairing allows the brain to ignore changes in neural firing that occur on both sides
Vestibulo-Ocular Reflex
37
25º
53º
10 so sr mr
III
lr
ir ir
io
sr mr
bc
IV
mlf
bc so
VI
47º
in lr ra
la
rh
lh
lp
rp
47º
Fig. 2. The VOR network: corresponding SCCs and the main brainstem connections to the oculomotor nuclei are shown. lr, sr, ir, mr ⫽ Left, superior, inferior, medial rectus muscle; IO, SO ⫽ inferior, superior oblique muscle; III ⫽ third nerve nucleus with inferior (ir), superior (sr), medial rectus (mr), and inferior oblique (io) motor neurons; IV ⫽ fourth nerve nucleus with superior oblique motor neurons (so); bc ⫽ brachium conjunctivum; VI ⫽ sixth nerve nucleus with lateral rectus (lr) and internuclear (in) motor neurons; mlf ⫽ medial longitudinal fasciculus; la, lh, lp ⫽ left anterior, horizontal and posterior SCC; ra, rh, rp ⫽ right anterior, horizontal and posterior SCC. (Courtesy of D.A. Robinson, Baltimore.)
Fetter
38
Sp/s
Inhibition
R
L
Excitation
Resting
Fig. 3. With rotation toward the left side, the neural firing increases from tonic resting discharge (shown as horizontal dotted line) in the vestibular nerve of the left lateral canal and decreases in the vestibular nerve of the right lateral canal. During rotation, the head velocity corresponds to the difference in firing rate between SCC pairs.
simultaneously, such as might occur due to changes in body temperature or chemistry. In the otoliths, as in the canals, there is a push-pull arrangement of sensors, but in addition to splitting the sensors across sides of the head, the push-pull processing arrangement for the otoliths is also incorporated into the geometry of the otolithic membranes. Within each otolithic macula, a curving zone, the striola, separates the direction of hair cell polarization on each side. Consequently, head tilt results in increased afferent discharge from one part of a macula, while reducing the afferent discharge from another portion of the same macula [10, 11]. There are two main targets for vestibular input from primary afferents: the vestibular nuclear complex and the cerebellum. The vestibular nuclear complex is the primary processor of vestibular input, and implements direct, fast connections between incoming afferent information and motor output neurons.
Vestibulo-Ocular Reflex
39
The erebellum is the adaptive processor – it monitors vestibular performance and readjusts central vestibular processing if necessary [12]. At both locations, vestibular sensory input is processed in association with somatosensory and visual sensory input [5]. The vestibular nuclear complex consists of 4 major nuclei (superior, medial, lateral, and descending) and at least 7 minor nuclei. This large structure, located primarily within the pons, also extends caudally into the medulla. The superior and medial vestibular nuclei are relays for the VOR. The medial vestibular nucleus is also involved in the VSR, and coordinates head and eye movements that occur together. The lateral vestibular nucleus is the principal nucleus for the VSR. The descending nucleus is connected to all of the other nuclei and the cerebellum, but has no primary outflow of its own [13]. The vestibular nuclei are connected via a system of commissures, which for the most part, are mutually inhibitory. The commissures allow information to be shared between the two sides of the brainstem and implements the push-pull pairing of vestibular canals. Extensive connections between the vestibular nuclear complex, cerebellum, ocular motor nuclei, and brainstem reticular activating systems convey the efferent signals to the VOR and VSR effector organs, the extraocular and skeletal muscles [14]. The output neurons of the VOR are the motor neurons of the ocular motor nuclei, which drive the extraocular muscles resulting in conjugate movements of the eyes in the same plane as head motion (fig. 2).
VOR – Pathology
It is crucial to carefully evaluate the eye movements during clinical examination, as the physiological and anatomical substrate of the ocular motor system is intimately connected with the vestibular system via the VOR. The VOR is responsible for the nystagmus phenomena seen in patients [15]. Caloric stimulation provides perhaps the clearest analogy to what the patient with pathological vertigo and nystagmus experiences. For example, warm stimulation of the left ear increases neural activity from the left lateral SCC and therefore in the left vestibular nerve; it thereby produces not only left-beating horizontal nystagmus but a sense of turning about the body long axis, toward the left. Conversely, cold stimulation of the right ear reduces neural activity in the right lateral SCC, the right vestibular nerve; and by commissural disinhibition it also increases neural activity in the left vestibular nucleus and, therefore, produces left-beating nystagmus and a sense of turning to the left (the nystagmus always beating toward the side of higher vestibular activity) [16, 17]. In a patient with sudden unilateral loss of peripheral vestibular function
Fetter
40
(such as in vestibular neuritis), the situation is in some way analogous to a cold caloric stimulus. An example of vertigo due to pathological unilateral increase in vestibular activity is benign paroxysmal positioning vertigo (BPPV), the most common vestibular disorder. With appropriate positioning, there is a sudden brief increase in activity from one SCC. The result is a sudden intense sense of selfrotation in the plane of the activated canal and a nystagmus beating in this plane. For example, if a patient with left posterior canal BPPV is rapidly placed in the provocative left lateral position, there is a sense of self-rotation in a plane halfway between the roll and the pitch plane toward the patient’s left side with a vertical – torsional nystagmus beating upward and with the torsional component to the lower ear [18–21].
Practical Aspects for Bedside Clinical Evaluation
An acute unilateral peripheral vestibular lesion reduces or eliminates input from one or more SCCs and otolith organs on that side. In the acute phase, a complete lesion abolishes the tonic neuronal discharge (resting activity) in the vestibular nerve [22]. The resulting loss of accelerometer function on one side of the head and the imbalance between the tonic inputs on the two sides lead to both spontaneous nystagmus and decreased and asymmetrical dynamic vestibular responses. Thus, there are both static and dynamic imbalances which need to be evaluated. Static Imbalance Spontaneous nystagmus (with the head still) is the hallmark of an imbalance in the tonic levels of activity mediating SCC-ocular reflexes. When peripheral in origin, spontaneous nystagmus characteristically is damped by visual fixation and is increased or only becomes apparent when fixation is eliminated. Hence, one must look for spontaneous nystagmus behind Frenzel lenses (magnifying lenses that prevent the patient from using visual fixation to suppress any spontaneous nystagmus) or during ophthalmoscopy (with the opposite eye occluded to prevent fixation). The intensity of nystagmus is compared with that observed when the patient is fixing on a visual target. Nystagmus is sometimes seen or even palpated through closed eyelids. Note that during ophthalmoscopy the direction of any horizontal or vertical slow phases is opposite to the direction of the motion of the optic disk. The nystagmus should also be inspected for dependence on the position of the eye in the orbit. Nystagmus arising from a peripheral lesion and most central lesions is more intense or may be evident only when the eye is deviated in
Vestibulo-Ocular Reflex
41
the direction of the quick phase (Alexander’s law). With central lesions, however, the opposite sometimes occurs. The axis around which the globe of each eye is rotating should be evaluated. For example, a pure vertical or a pure torsional nystagmus implies a central disturbance; a mixed horizontal-torsional nystagmus is typical for a peripheral labyrinthine dysfunction, and a mixed vertical-torsional nystagmus that becomes more vertical on looking toward one side and more torsional on looking to the other is typical for inappropriate excitation of the posterior SCC causing BPPV [19]. Skew deviation is the hallmark of an imbalance in the tonic levels of activity underlying otolith-ocular reflexes. Skew deviation is a vertical misalignment of the eyes that cannot be explained on the basis of an ocular muscle palsy. Patients with a skew deviation complain of vertical diplopia and sometimes torsional diplopia (one image tilted with respect to the other). There may also be a cyclorotation (ocular counterroll) of both eyes associated with an illusion of tilt of the visual world. The head may also be tilted, usually toward the side of the lower eye. Skew deviation, ocular counterrolling, and head tilt constitute the ocular tilt reaction: vestibulo-ocular and vestibulo-collic components of the righting reaction in response to the lateral tilt of the head and body [23]. Skew deviation is best detected with cover testing. With the alternate cover test, one looks for a vertical corrective movement on switching the cover from one eye to the other as an index of a vertical misalignment. Skew deviation tends to be relatively comitant (i.e. the degree of misalignment changes little with different direction of gaze), though it is not always the case. Ocular counterroll is difficult to detect clinically without photographic means, but if the amount of counterroll is large it can be appreciated by the tilt of the imaginary line that connects the macula and the optic disk. The ocular tilt reaction can occur with lesions anywhere in the otolith-ocular pathway. With peripheral and vestibular nucleus lesions, the lower eye is on the side of the lesion. The otolith-ocular pathway crosses at the level of the vestibular nucleus, so that with lesions above the decussation the higher eye is on the side of the lesion [24–26]. Dynamic Disturbances The SCC induced VOR can be tested at the bedside by observing the effect of head rotation on visual acuity and by looking at the eye movements themselves in response to head rotation. Measure the patient’s best corrected visual acuity using a distance acuity chart with the head still and then with the head passively rotated at a frequency of about 2 Hz. Normal individuals may lose one line of acuity during head shaking; patients with a complete loss of labyrinthine function loose up to five lines and sometimes more. The possible influence of stimulation of cervical afferents, through the cervico-ocular reflex, when the head is rotated on the body must also be considered. In normal subjects, especially at
Fetter
42
the relatively high frequencies associated with bedside testing, the cervico-ocular reflex is rudimentary and can be ignored. In patients with loss of the function of the SCCs, however, there may be potentiation of the cervico-ocular reflex or the use of cervical afferents to trigger preprogrammed compensatory slow phases or even saccades, independent of inputs from the SCCs [27]. Next, carefully apply brief, high-acceleration head thrusts, with the eyes beginning about 15⬚ away from the primary position in the orbit and the amplitude of the head movement such that the eyes end near the primary position of gaze. Instruct the patient to look carefully at the examiner’s nose. Look for a corrective saccade (usually catch-up) as a sign of an inappropriate compensatory slow phase. When interpreting an abnormal response, one must consider the potential adaptive readjustment in VOR function that may occur when a subject habitually wears a spectacle correction. Farsighted individuals (hyperopia) increase their VOR gain owing to the magnification effect of a plus lens; nearsighted individuals (myopia) decrease their VOR gain owing to the minification effect of a minus lens [28, 29]. Head-shaking nystagmus (HSN) is another way to look for an imbalance of dynamic vestibular function. First, with Frenzel lenses in place, instruct the patient to shake the head vigorously about 15–20 times, side to side. Look for any nystagmus following the head shaking. Normal individuals usually have no or occasionally just a beat or two of HSN. With a unilateral loss of labyrinthine function, however, there is usually a vigorous nystagmus with slow phases initially directed toward the lesioned side and then a reversal phase with slow phases directed oppositely [30]. The initial phase of HSN arises because there is asymmetry of peripheral inputs during high-velocity head rotations. More activity is generated during rotation toward the intact side than toward the affected side [31, 32]. This asymmetry leads to an accumulation of activity during the head shaking [33]. The nystagmus following head shaking reflects the discharge of that activity again beating towards the healthy side. Positional Testing Positional (sustained) and positioning (transient) nystagmus is best elicited with the patient wearing Frenzel lenses. For positioning nystagmus the head should be moved to the dependent position as rapidly as possible. The same positioning maneuver should be repeated to see if the nystagmus becomes attenuated. If a horizontal nystagmus is elicited with one ear down during positional testing, the patient’s head should be rotated to put the other ear down to see if the horizontal nystagmus changes direction, as occurs, for example, with the lateral canal variant of BPPV [15]. A positioning nystagmus is characteristic of BPPV. A transient burst of a mixed vertical (upbeat)-torsional (the superior pole of the globe beats toward
Vestibulo-Ocular Reflex
43
the side of the dependent ear) nystagmus, usually appearing after a latency of several seconds and lasting 20–30 s, is characteristic of the inappropriate excitation of the posterior SCC that produces typical BPPV. On reassuming the upright position, nystagmus due to BPPV may transiently reappear, but it is usually directed opposite to that in the dependent position. With successive repetitions, the nystagmus usually becomes more difficult to elicit. With the lateral canal variant, the horizontal nystagmus usually lasts much longer. The increased duration may reflect the action of the central velocity storage mechanism, which is much more effective for horizontal than vertical canal inputs. Lateral canal BPPV occurs with either ear down and may be geotropic (beats toward the ground) or ageotropic (beats away from the ground). It should be remembered that a small amount of unidirectional horizontal positional nystagmus is observed in many normal subjects. A central lesion is most likely when a positional nystagmus is purely vertical or purely torsional, or if there is a significant sustained unidirectional horizontal positional nystagmus [20]. Positional testing may also exacerbate a spontaneous nystagmus. With an acute unilateral loss of labyrinthine function, the horizontal component of the spontaneous nystagmus is increased with the patient lying with the affected ear down and decreased with the affected ear up. This effect of gravity on the horizontal component of the spontaneous nystagmus is probably mediated by the otolith-ocular reflex, which normally produces a horizontal nystagmus in response to linear accelerations associated with translation of the head. In the case of spontaneous nystagmus due to a vestibular imbalance, the change in the pull of gravity with head tilt produces a horizontal slow-phase response that either damps or increases the spontaneous nystagmus depending on whether the ear with the hypoactive labyrinth is up or down, respectively [34]. Valsalva- and Hyperventilation-Induced Nystagmus Patients with craniocervical junction anomalies, such as the Chiari malformation, perilymph fistulas, and other abnormalities involving the ossicles, oval window, and saccule may develop nystagmus with the Valsalva maneuver or by manipulation of the ossicular chain with changes in middle-ear pressure owing to noise, tragal compression, application of positive and negative pressure to the tympanic membrane (Hennebert’s sign), or opening and closing the eustachian tube [35]. Hyperventilation may induce symptoms in patients with anxiety and phobic disorders but usually does not produce nystagmus. Patients with demyelinating lesions on the vestibular nerve (such as that due to a tumor, e.g. an acoustic neuroma or cholesteatoma), compression by a small blood vessel, or in
Fetter
44
central structures (multiple sclerosis) may show hyperventilation-induced nystagmus [36].
Laboratory Evaluation: Electro-Oculography and Rotational Testing
Vestibular laboratory testing can aid in diagnosis, can be used to document an abnormality suspected at bedside evaluation, and can aid in devising a treatment plan. The ability to perform serial vestibular evaluations allows an assessment over time of patients who are undergoing treatment for their dizziness or who are undergoing treatment with a potentially ototoxic medication. Both electro-oculography (EOG) and rotational testing can provide information that is helpful for determining if a vestibular abnormality is present and, if so, whether it is located in the central or peripheral vestibular system. The choice of subtests that are preformed may vary according to the clinical suspicions of the physician ordering the test. When a peripheral vestibular abnormality is suspected caloric testing may be helpful, and when a central vestibular abnormality is suspected visual-vestibular interaction tests may prove useful. Positional testing is performed as part of the EOG battery by placing the patient in the supine and head-hanging positions, head-right and right-lateral positions, and head-left and left-lateral positions. However, BPPV may be difficult to record in the vestibular laboratory because EOG is insensitive to torsional eye movements and vertical EOG is plagued by eyeblink and muscle artifacts and has a low signal/noise ratio. Despite these limitations, patients with positioning vertigo should have Dix-Hallpike testing, as many patients with BPPV produce a recordable eye movement whose temporal characteristics can be objectified. A paroxysmal nystagmus observed during the Dix-Hallpike maneuver that does not conform to the typical pattern seen with BPPV should be considered the result of a CNS abnormality until it is proved otherwise. Examples of such nystagmus include downbeating nystagmus in a head-hanging position and nystagmus that does not fatigue with repeated positioning. Caloric testing is the mainstay of vestibular laboratory testing. The caloric response is primarily the result of the convection current caused by the combination of a thermal gradient across the horizontal SCC and placement of the lateral canal in a vertical plane. Although research from microgravity experiments has indicated that direct thermal effects generate a portion of the caloric response, the convection current theory still accounts for most of the caloric response [37]. Warm irrigation of the ear causes excitation of the lateral SCC and thus induces slow movement of the eyes away from the side of irrigation with subsequent beating toward the ear being irrigated. The irrigation of the left ear with cool water induces right-beating nystagmus. Many studies have shown
Vestibulo-Ocular Reflex
45
that the maximum slow component velocity attained after each caloric irrigation is the best determinant of the response of a particular ear to a particular stimulus [38]. A reduced vestibular response typically indicates a peripheral vestibular injury. It may include damage to the labyrinth itself, the eighth cranial nerve, or the root entry zone of the vestibular nerve. When an ear is unresponsive to warm and cold irrigation, direct irrigation with ice water may be helpful. The chief advantage of caloric testing is its ability to stimulate each ear individually. The types of rotational vestibular testing that are in common clinical use include earth-vertical axis rotation and visual-vestibular interaction. Rotational testing makes use of a natural stimulus to the labyrinth (i.e. rotational acceleration). Besides sinusoidal rotations, rotating a subject at a constant velocity for enough time for the perrotatory nystagmus to decay is widely used. The rotational chair is then stopped abruptly and the induced postrotatory nystagmus is measured. The main measures of the response to constant velocity rotation are gain and time constant. The gain is, by definition, the ratio of the magnitude of the response to the magnitude of the stimulus (maximum eye velocity divided by maximum head velocity). The time constant of the VOR is a measure of how rapidly vestibular nystagmus decays after an abrupt stop of the rotation chair [39]. Conventional Rotational Testing The hallmark of unilateral peripheral vestibular loss is a reduced vestibular response on caloric testing. With acute peripheral vestibular lesions, a brisk spontaneous nystagmus may make interpretation of caloric testing difficult, especially if nystagmus in the same direction is seen regardless of the side or temperature of the irrigation during bithermal testing. In such cases, ice-water irrigation may be helpful. Ice-water irrigation of the normal ear should stop the nystagmus in the acute phase and reverse it in compensated states [40]. Acute unilateral peripheral vestibular lesions are usually associated with a normal ocular motor screening battery and an absence of gaze-evoked nystagmus. However, with a severe acute unilateral peripheral loss there may be asymmetrical pursuit and asymmetrical optokinetic nystagmus as a result of superposition of an intense spontaneous vestibular nystagmus with visual following. Also, with an acute unilateral peripheral vestibular lesion, there may be spontaneous nystagmus during fixation. Rotational testing shortly after an acute unilateral peripheral loss usually shows severe asymmetry and drastically reduced time constants [41].
Fetter
46
Fig. 4. Electrical stimulation of a single SCC nerve induces eye movements roughly in the plane of that canal (shown for stimulation of the right posterior canal). (Courtesy of A. Boehmer, Zürich.)
Modern Vestibular Testing
Semicircular Canal Function Routine vestibular testing such as calorics and rotational testing mainly investigate the function of the lateral SCCs, while the vertical SCCs and the otoliths are basically ignored. This has changed in recent years. In the last 20 years, there has been a revival of interest in 3-D approaches to the control of eye movements. This was boosted by the fact that 3-D eye movement analysis has become practical with the development of the magnetic field search coil technique. New analytical approaches have made the mathematics of eye rotations and coordinate transformations more tractable and intuitive. Strabismus, labyrinthine dysfunction and brain disorders leading to nystagmus and other eye movement disorders are ubiquitous clinical problems and demand a 3-D approach for their understanding. This is especially true when dealing with vestibular problems. The vestibular system is intrinsically 3-D trying to stabilize the retinal image in all 3 rotational degrees of freedom. Under pathological conditions, we often find spontaneous or elicited eye movements with torsional components. The key for understanding vestibular-induced eye movements has been found in the early 60s. Since then, we know that electrical stimulation of single SCC nerves induces eye movements roughly in the plane of the canal [42, 43] (fig. 4). If more than one canal is stimulated, the different canals combine at least roughly linearly to drive the eyes. Thus, if multiple canals are stimulated, the slow phases should be in a direction that is a weighted vector sum of
Vestibulo-Ocular Reflex
47
the axes of the involved canals. Using this premise, one can stimulate the vestibular system in numerous ways (low- and high-velocity head movements in 3-D, 3-D calorics, and diverse methods of inducing positional nystagmus) and relate the resulting eye movements to the function or dysfunction of single SCCs [44–46]. Obviously, in humans one cannot stimulate with electrodes the vestibular nerve and record the resulting eye movements. We therefore tested patients in whom nature produced a situation where just one SCC is stimulated. These patients suffered from benign paroxysmal positioning nystagmus. When the nystagmus induced by positioning the subject in the offending position is measured in 3-D and the average axis of eye rotation is reconstructed and plotted into a head-fixed reference system together with the anatomical on-directions of the SCCs it can be shown that the elicited eye movements are closely aligned with the direction of the offending canal. With this proof that also in humans eye movements are produced in the plane of the stimulated SCC, it is possible to deduct which canals are responsible for the direction of eye movements found during vestibular stimulation when parts of the vestibular sensors are defective [44, 47, 48].
Otolith Function Subjective Visual Vertical The subjective visual vertical (SVV) is a sensitive measure of otolith and especially utricular function. The bilateral graviceptive input from the otoliths dominates our perception of verticality. To test for SVV, the subjects sit with their heads fixed in the upright position and look at an illuminated line (on computer display or projected with a laser galvanometer system) in complete darkness. They then have to adjust 10 times separately for each eye the line from different starting positions to their SVV. In acute peripheral vestibular lesions, including the utricles, there is an ipsiversive deviation of the SVV of about 10–15⬚. Likewise, most patients with acute unilateral brainstem infarctions exhibit pathological tilts of static SVV from the true vertical [49].
Click-Evoked Myogenic Potentials Electromyograms can be recorded from surface electrodes over the sternomastoid muscles and averaged in response to brief (0.1-ms) clicks played through headphones. In normal subjects, clicks 85–100 dB above 45 dB SPL (perceptual threshold for normal subjects) evoke reproducible changes in the
Fetter
48
averaged electromyogram beginning at a mean latency of 8.2 ms. The earliest potential changes, a biphasic positive-negative wave, is generated by afferents from the ipsilateral sacculus. The potential is abolished in patients with lesions of the inferior vestibular nerve subserving the sacculus but is preserved in subjects with severe sensorineural hearing loss. It is proposed that the response is generated by activation of vestibular afferents arising from the saccule, and transmitted via a rapidly conducting oligosynaptic pathway to anterior neck muscles [50].
Conclusions
With the new VOR test methods described, a more thorough investigation of vestibular function at the level of single SCC function and the otoliths has become possible. Modern techniques are now available such as 3-D eye movement analysis for the evaluation of SCC function, measurement of the SVV for utricular, and click-evoked myogenic potentials for saccular testing. These new techniques have the potential to significantly improve our diagnostic capabilities in dizzy patients.
References 1 2 3 4
5 6 7
8
9 10 11 12
Lorente de No R: Vestibulo-ocular reflex arc. Arch Neurol Psychiatr 1933;30:245–291. Baloh RH, Honrubia V: The vestibular system; in Baloh RH, Honrubia V (eds): Clinical Neurophysiology of the Vestibular System, ed 2. Philadelphia, FA Davis, 1990, pp 1–17. Szentágothai J: The elementary vestibulo-ocular reflex. J Neurophysiol 1950;13:395–407. Grüsser OJ, Pause M, Schreiter U: Localization and responses of neurons in the parieto-insular vestibular cortex of awake monkeys (Macaca fascicularis). J Physiol (London) 1990;430: 537–557. Lisberger SG, Miles FA, Zee DS: Signals used to compute errors in monkey vestibuloocular reflex: possible role of flocculus. J Neurophysiol 1984;52:1140–1153. Blanks RHI, Curthoys IS, Markham CH: Planar relationships of the semicircular canals in man. Acta Otolaryngol (Stockh) 1975;80:185–196. Goldberg JM, Fernandez C: Physiology of peripheral neurons innervating semicircular canals of the squirrel monkey. I. Resting discharge and response to constant angular acceleration. J Neurophysiol 1971;34:634–660. Fernandez C, Goldberg JM: Physiology of peripheral neurons innervating semicircular canals of the squirrel monkey. II. Response to sinusoidal stimulation and dynamics of the peripheral vestibular system. J Neurophysiol 1971;34:661–675. Bach-Y-Rita P: The Control of Eye Movements. New York, Academic Press, 1971. Suzuki J-I, Tokumasu K, Goto K: Eye movements from single utricular nerve stimulation in the cat. Acta Otolaryngol 1969;68:350–362. Fernandez C, Goldberg JM, Abend WK: Response to static tilts of peripheral neurons innervating otolith organs of the squirrel monkey. J Neurophysiol 1972;6:978–987. Robinson DA: Adaptive gain control of the vestibulo-ocular reflex by the cerebellum. J Neurophysiol 1976;39:954–969.
Vestibulo-Ocular Reflex
49
13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28
29
30 31 32 33 34 35 36 37 38 39 40
Brodal A: Anatomy of the vestibular nuclei and their connections; in Kornhuber HH (ed): Handbook of Sensory Physiology. The Vestibular System. New York, Springer, 1974, vol VI, part 1. Büttner-Ennever JA: Vestibular oculomotor organization; in Fuchs AF, Becker W (eds): The Neural Control of Eye Movements. Amsterdam, Elsevier, 1981. Dix R, Hallpike CS: The pathology, symptomatology and diagnosis of certain common disorders of the vestibular system. Ann Otol Rhinol Laryngol 1952;6:987–1016. Barany R: Physiologie und Pathologie des Bogengangsapparates beim Menschen. Vienna, Deuticke, 1907. Sills AW, Baloh RW, Honrubia V: Caloric testing 2. Results in normal subjects. Ann Otol Rhinol Laryngol 1977;85:7–23. Schuknecht HF: Cupulolithiasis. Arch Otolaryngol 1969;90:765–778. Baloh RW, Honrubia V, Jacobson K: Benign positional vertigo. Neurology 1987;37:371–378. Brandt T: Positional and positioning vertigo and nystagmus. J Neurol Sci 1990;95:3–28. Brandt T, Steddin S: Current view of the mechanism of benign paroxysmal positioning vertigo: cupulolithiasis or canalolithiasis? J Vestibular Res 1993;3:373–382. McCabe BF, Ryu JH, Sekitani T: Further experiments on vestibular compensation. Laryngoscope 1972;82:381–396. Brandt T, Dieterich M: Central vestibular syndromes in roll, pitch, and yaw planes. Neuroophthalmol 1995;6:291–303. Dieterich M, Brandt T, Fries W: Otolith function in man: results from a case of otolith Tullio phenomenon. Brain 1989;112:1377–1392. Halmagyi GM, Brandt T, Dieterich M, Curthoys IS, Stark RJ, Hoyt WS: Tonic contraversive ocular tilt reaction due to unilateral meso-diencephalic lesion. Neurology 1990;40:1503–1509. Brandt T, Dieterich M: Skew deviation with ocular torsion: a vestibular brainstem sign of topographic diagnostic value. Ann Neurol 1993;33:528–534. Kasai T, Zee DS: Eye-head coordination in labyrinthine-defective human beings. Brain Res 1978;144:123–141. Halmagyi GM, Curthoys IS, Cremer PD, Henderson CJ, Todd MJ, Staples MJ, D’Cruz DM: The human horizontal vestibulo-ocular reflex in response to high-acceleration stimulation before and after unilateral vestibular neurectomy. Exp Brain Res 1990;81:479–490. Cremer PD, Halmagyi GM, AW ST, Curthoys IS, McGarvie LA, Todd MJ, Black RA, Hannigan IP: Semicircular canal plane head impulses detect absent function of individual semicircular canals. Brain 1998;121:699–716. Hain TC, Fetter M, Zee DS: Head-shaking nystagmus in patients with unilateral peripheral vestibular lesions. Am J Otolaryngol 1987;8:36–47. Ewald R: Physiologische Untersuchungen über das Endorgan des Nervus Octavus. Wiesbaden, Bergmann, 1892. Baloh RW, Honrubia V, Konrad HR: Ewald’s second law re-evaluated. Acta Otolaryngol 1977;83: 474–479. Raphan T, Matsuo V, Cohen B: Velocity storage in the vestibulo-ocular reflex arc (VOR). Exp Brain Res 1979;35:229–248. Fluur E: Interaction between the utricles and the horizontal semicircular canals. IV. Tilting of human patients with acute unilateral vestibular neuritis. Acta Otolaryngol 1973;76:349–352. Singleton GT, Post KN, Karlan MS, Bock DG: Perilymph fistulas: diagnostic criteria and therapy. Ann Otol Rhinol Laryngol 1978;87:797–803. Leigh RJ, Zee DS: The Neurology of Eye Movements, ed 2. Philadelphia, F.A. Davis, 1991, pp 384–385. Scherer H, Clarke AH: The caloric vestibular reaction in space. Physiological considerations. Acta Otolaryngol 1985;100:328–336. Baloh RW, Sills AW, Honrubia V: Caloric testing. 3. Patients with peripheral and central vestibular lesions. Ann Otol Rhinol Laryngol Suppl 1977;86(suppl 43):24–30. Baloh RW, Sakala SM, Yee RD, Langhofer L, Honrubia V: Quantitative vestibular testing. Otolaryngol Head Neck Surg 1984;92:145–150. Nelson JR: The minimal ice water caloric test. Neurology 1969;19:577–585.
Fetter
50
41 42 43 44 45 46 47 48
49 50
Baloh RW, Honrubia V, Yee RD, Hess K: Changes in human vestibulo ocular reflex after loss of peripheral sensitivtiy. Ann Neurol 1984;16:222–228. Cohen B, Suzuki J: Eye movements induced by ampullary nerve stimulation. Am J Physiol 1963;204:347–351. Suzuki J, Cohen, B: Head, eye, body and limb movements from semicircular canal nerves. Exp Neurol 1964;10:333–405. Fetter M, Dichgans J: Vestibular neuritis spares the inferior division of the vestibular nerve. Brain 1996;119:755–763. Aw ST, Fetter M, Cremer PD, Karlberg M, Halmagyi GM: Individual semicircular canal function in superior and inferior vestibular neuritis. Neurology 2001;57:768–774. Aw ST, Haslwanter T, Fetter M, Dichgans J: Three-dimensional spatial characteristics of caloric nystagmus. Exp Brain Res 2000;134:289–294. Fetter M, Sievering F: Three-dimensional (3-D) eye movement analysis in patients with positioning nystagmus. Acta Otolaryngol (Stockh) 1995;520:369–371. Fetter M, Aw ST, Haslwanter T, Heimberger J, Dichgans J: Three-dimensional eye movement analysis during caloric stimulation used to test vertical semicircular canal function. Am J Otology 1998;19:180–187. Dieterich M, Brandt T: Ocular torsion and tilt of subjective visual vertical are sensitive brainstem signs. Ann Neurol 1993;33:292–299. Colebatch JB, Halmagyi GM, Skuse NF: Myogenic potentials generated by a click-evoked vestibulocollic reflex. J Neurol Neurosurg Psychiatry 1994;57:190–197.
Prof. Michael Fetter, MD SRH Clinic Karlsbad-Langensteinbach, Department of Neurology Guttmannstrasse 1 DE–76307 Karlsbad (Germany) Tel. ⫹49 7202 610, Fax ⫹49 7202 616180, E-Mail
[email protected]
Vestibulo-Ocular Reflex
51
Straube A, Büttner U (eds): Neuro-Ophthalmology. Dev Ophthalmol. Basel, Karger, 2007, vol 40, pp 52–75
Neural Control of Saccadic Eye Movements Nicolas Catz, Peter Thier Department of Cognitive Neurology, Hertie Institute for Clinical Brain Research, Tübingen, Germany
Abstract One of the major functions of the central nervous system is the generation of movement in response to sensory stimulation. The visual guidance of saccadic eye movement represents one form of sensory-to-motor transformation that has contributed significantly to our understanding of motor control and sensorimotor processing at large. The neural circuitry controlling saccadic eye movements is now understood at a level that is sufficient to link the specific roles of a number of saccade-related cortical and subcortical areas. In this chapter, we review the main subcortical areas for controlling saccades, concentrating mostly on the role of the posterior cerebellar vermis (PV), with the dorsal pontine nuclei and the nucleus reticularis tegmenti pontis as the major gateway to the PV and the fastigial nucleus as the link between the PV and the brainstem saccade generator. We argue that the PV is the key structure enabling saccadic learning and that this contribution is based on the control of saccade duration by a PV Purkinje cell population signal. Copyright © 2007 S. Karger AG, Basel
One of the major functions of the central nervous system is the generation of movement in response to sensory stimulation. Saccadic eye movements represent an example of the sensory guidance of movements that has contributed significantly to our understanding of some of the general principles underlying the sensory guidance of movement. The eyes have a simple and well-defined repertoire of movements, and the neural circuitry regulating the production of saccadic eye movements is now understood at a level that is sufficient to attribute specific roles to a number of saccade-related cortical and subcortical areas and to characterize their interactions in the generation of saccades. Different kinds of saccades can be distinguished. Resetting saccades are a major component of reflectory optokinetic and vestibular gaze-stabilizing reflexes. They regularly interrupt the smooth stabilizing movements in order to move the eyes back towards the center of the orbit, whereupon another period of
slow gaze-stabilizing movements can follow [1]. Rather than contributing to stabilizing the visual scene, target-directed saccades emphasize particular objects whose images are foveated in order to improve their scrutiny. The object serving as target of a saccade may be singled out from a number of others by a selection process that involves a careful consideration of object features and the expectations and needs of the observer. Such target-directed saccades are usually referred to as goal directed [2]. Alternatively, the target for a saccade may be an object appearing unexpectedly, requiring immediate attention and therefore prompting a reflectory orienting saccade. Objects serving as targets of saccades may be defined by visual, auditory or tactile cues. Objects whose location defines a desired location for the eyes do not have to be present at the time the saccade is carried out. Rather, fairly precise saccades can be elicited based on memorized information on the target location (memory-guided saccades). Antisaccades are a specific example of a spatial dissociation of object location and saccade goal, resulting from the instruction to invert the vector defining the object location in order to generate a saccade vector [3–5]. Finally, spontaneous saccades may be generated in the absence of any guiding sensory cues, defining goals in the external world, solely determined by endogenous goals. Irrespective of the circumstances causing a saccade, all saccades are fast ballistic eye movements, reaching maximum velocities up to 500⬚ per second and more, and are usually completed within tens of milliseconds. Despite their speed, saccade trajectories tend to be remarkably stereotyped both within and across individuals. The duration and peak velocity of saccades increases monotonically with the amplitude of the movement in a consistent way, usually referred to as the ‘main sequence’ [6] (fig. 1). Saccade latency is defined as the delay between the presentation of the cue and the onset of the saccade. Latency for saccades varies between 100 and 300 ms, depending on the type of target-directed saccade. Express saccades are especially fast orienting saccades with latencies of ⬍100 ms [7, 8] that can be observed if attention is not bound by a fixation point at the time a peripheral visual target comes up. Like the second type of target-directed eye movements, smooth-pursuit eye movements [9], also target-directed saccades obey Listing’s law, minimizing the amount of torsion that accompanies the movements of the eyes about their horizontal and vertical axes, thereby stabilizing the orientation of the object image on the retina [10, 11]. The programming and execution of a saccadic eye movement require different operations which overlap in time, rather than following in a serial manner. (1) Fixation has to be disengaged, a process that involves detaching attention from a fixated object and shifting attention to the new object or the desired spatial location. During fixation, the saccade machinery is suppressed by tonic inhibition from a cortical-subcortical network that embraces neurons in the frontal eye fields (FEF and SEF) [12–14],
Neural Control of Saccadic Eye Movements
53
10 5 Target Eye
0 0
50
100
200
400 200 0 0
Time (ms)
800
70
600 500 400 300 200
100
150
200
250
Time (ms) 80
700
50
b
900
60 50 40 30 20 10
100
0
0 0
c
600
250
Saccade duration (ms)
Peak of velocity (degrees/s)
a
150
Eye velocity (degrees/s)
Eye position (degrees)
15
2
4
6
0
8 10 12 14 16 18 20 22 24 26
Saccade amplitude (degrees)
d
2
4
6
8 10 12 14 16 18 20 22 24 26
Saccade amplitude (degrees)
Fig. 1. Example of 10⬚ horizontal saccade: horizontal position of the eye and target (a) and horizontal saccade velocity (b) as a function of time. Saccade ‘main sequence’: peak of saccade velocity (c) and saccade duration (d) as a function of saccade amplitude.
in the superior colliculus (SC; fixation region [15, 16]), and the brainstem (omnipause neurons; OPNs [17]), inhibition that has to be terminated in order to facilitate the upcoming saccade. (2) The acquisition of the spatial coordinates of the target location and their transformation into the spatial coordinates of the saccade endpoint. This step, as well as the reallocation of spatial attention alluded to before relies to a large extent on posterior parietal circuits, specifically on saccade representations in the intraparietal cortex such as area lateral intraparietal sulcus (LIP) [18–20]. (3) The transformation of the saccade vector, describing the desired change in eye position into a motor command that unfolds in time and that is responsible for the kinematics features of the observed saccade. Hence, the motor command, in order to be appropriate, must be based on a full consideration of the dynamical aspects of the movement. The elaboration of an appropriate motor command sent to the oculomotor motoneurons (MNs) is the major function of the premotor circuitry in the brainstem,
Catz/Thier
54
interacting closely with the SC and parts of the cerebellum. This review focuses on the role of the subcortical structures involved in the generation of saccades, placing special emphasis on the cerebellum and the major precerebellar nuclei. Readers interested in the cognitive control of saccades and the spatial processing preparing target-directed saccades, largely cortical functions, are referred to several excellent reviews available on the topic [13, 21].
The Brainstem Saccadic Generator
Oculomotor MNs discharge a burst of action potentials for saccades in their respective ‘on-direction’ and suppress their discharge during saccades in the ‘off-direction’. Burst amplitude is correlated with eye velocity and the number of spikes in the burst scales with saccade amplitude. These transient changes in the discharge of MNs pass over into a tonic level of activity, whose amplitude depends on eye position. Both the size of the transient change during the movement as well at the level of the subsequent tonic activity are determined by input from premotor neurons located in mesencephalic, pontine and medullary regions of the brainstem reticular formation [22]. The burst component of the MN discharge is generated by short-lead burst neurons (fig. 2). Burst neurons for horizontal saccades are located in the paramedian pontine reticular formation (PPRF) next to the abducens nucleus [23], while those for vertical saccades lie in the rostral interstitial nucleus in the midbrain reticular formation (MRF) near the oculomotor nucleus [24, 25]. As the functional architecture of the circuit subserving vertical saccades in the MRF follows the same principles as the one for horizontal saccades in the PPRF, we will restrict our description to the latter (for review on the vertical system, see [26]). The PPRF projects ipsilaterally to the abducens nucleus [27–30], to the prepositus hypoglossi nucleus (NPH) [27, 28, 30, 31], to the median vestibular nucleus (MVN) [32] and to the posterior vermis [33]. The PPRF receives input from the SC, the posterior vermis via the fastigial nuclei and the FEF. In the PPRF, two types of burst neurons can be distinguished with respect to their action: the excitatory burst neurons (EBNs, or short-lead burst neurons) and the inhibitory burst neurons (IBNs) [34–36] (fig. 2). The Excitatory and Inhibitory Burst Neurons The EBNs of the PPRF are responsible for the activation of the agonist MNs of the abducens nucleus which activate the ipsilateral lateral rectus muscle, and via internuclear neurons in the abducens nucleus neurons (INs) they are also responsible for the activation of the agonist MNs in the oculomotor nucleus controlling the contralateral medial rectus muscle [37, 38]. The EBNs are
Neural Control of Saccadic Eye Movements
55
Left
Right SC-BN
LLBNs
SC-FN
Tr
TN EBN
EBN
La
OPN IBN IBN VI
IN MN
VI
IN MN
III
Lateral rectus
Medial rectus
Medial rectus Lateral rectus
Midline
Fig. 2. Brainstem circuitry involved in the execution of leftward saccades, involving a contraction of the left lateral rectus and the right medial rectus, while the left medial rectus and the right lateral rectus are relaxed (antagonist muscles). VI ⫽ Abducens nucleus; III ⫽ oculomotor nucleus; La ⫽ latch neurons; Tr ⫽ trigger neurons. Excitatory connections are indicated by filled lines. The inhibitory connections are indicated by dashed lines.
completely silent during intersaccadic periods. On the other hand, these neurons exhibit sharp and vigorous bursts of action potentials during the saccade that starts around 5–15 ms before the ipsilateral saccade [23, 39]. The number of action potentials fired during the saccade increases with saccade amplitude as well as with instantaneous eye velocity [39]. The second type of burst neuron is represented by the IBNs. These neurons inhibit the MN and IN of the contralateral abducens nucleus [35, 40]. The IBNs are involved in the process of relaxation of the antagonist muscles. As the EBNs, the IBNs are silent during the intersaccadic periods and their saccade-related
Catz/Thier
56
burst precedes the saccade onset by around 5–15 ms [41]. The duration of the burst is proportional to the duration of the horizontal component of the movement [26]. The Omnipause Neurons The PPRF contains another distinct population of neurons, critical for the timing of saccades, the OPNs. OPNs discharge tonically during fixation at rates of more than 100 spikes per second and pause for saccades in all directions [42]. The pause starts a few milliseconds before the onset of the burst of EBNs/IBNs and ends at saccade offset. As EBNs and IBNs are subject to potent inhibition from the OPNs, the OPNs contribute to stabilizing fixation. The pause in OPN firing during the saccade, needed in order to allow the saccade to develop, is most probably due to changes in several types of signals, impinging on OPNs. First, it could be due to the cessation of the sustained activity of fixation neurons (SC-FNs) located in the rostral pole of the SC, exciting OPNs monosynaptically [43]. Second, the inhibition of the OPNs during the saccade could also be a consequence of the excitation of the long-lead burst neurons (LLBNs) in the rostral PPRF, influenced by the saccade-related burst neurons located in the SC, outside the fixation zone (SC-BN). These LLBNs, then, excite the EBNs, which inhibit the OPNs via inhibitory latch neurons. A third way to inhibit the OPNs is the excitation of inhibitory neurons located directly between SC-BN and the OPNs [44]. Fourth, inhibition of the OPNs during saccades could originate from indirect inhibitory projections from the caudal fastigial nucleus (cFN), output nucleus of the oculomotor cerebellum [45]. The Tonic Neurons The EBNs discussed before provide a signal related to eye velocity needed in order to move the eyes against velocity-dependent viscous forces to the target. However, in order to stabilize the eyes in the new position acquired by the saccade, a signal related to eye position, counteracting position-dependent elastic forces, trying to move the eyes back towards straight-ahead, is needed. This signal is provided by tonic neurons (TNs). Horizontal TNs are located in the PPRF, intermingled with horizontal EBNs, and like EBNs they make excitatory connections with MNs. Vertical TNs are found in the MRF next to vertical EBNs. The discharge of TNs is linearly related to eye position. Robinson [54] suggested that the eye position-related signal of TNs could be the result of a mathematical integration of the eye velocity-related signal provided by EBNs. A copy of the eye velocity signal would be sent to a ‘neural integrator’ (NI) in order to generate a tonic command coding for the eye position. This command would allow the MNs to offer the constant position-dependent firing rate needed in order to stabilize the eyes at an eccentric position. Lesion experiments
Neural Control of Saccadic Eye Movements
57
E*
冮dt
Step [⫽TN]
⫺ Ed
⫹
e
Pulse generator [⫽EBN]
. E‘
MN
Plant
Fig. 3. The Robinson internal feedback model for saccades. Ed ⫽ Eye-desired displacement; E* ⫽ actual eye displacement.
suggest that two structures, the MVN, located caudally to the PPRF, and the NPH, reciprocally connected to the PPRF, MVN, vestibular cerebellum (flocculus) and oculomotor cerebellar vermis (lobuli VI and VII ) are involved in the integration of the velocity command as they lead to an inability to maintain the eyes in an eccentric position: after any centrifugal saccades the eyes turn systematically back to a stable position at straight-ahead [46–48]. It has been proposed that the integration by the NI could be based on local recurrent excitation, i.e. neurons will excite their neighbors, which in turn will feed them back with excitation [49, 50]. The NPH, located caudal of the abducens nucleus, which also contains a high number of TNs coding the position of the eye, is probably part of this excitatory feedback network [51–53]. The activity of TNs increases with the ipsilateral deviation of the gaze. The types of neurons found in the PPRF have distinct roles in an influential model of the control of saccadic eye movements, put forward by Robinson [54], whose key features pervade any later models up to the present day. Probably the major feature is the idea of internal feedback as a way to deal with the unacceptably long latencies of visual feedback signals (fig. 3). An ongoing targeting saccade should be stopped once the object image has reached the fovea. However, the long latency of visual signals, having an order of magnitude of 50 ms and more, precludes the possibility to use information from the fovea to stop the saccade at the right point in time. The Robinson model (fig. 3) assumes short-latency internal or ‘local’ feedback as an alternative to visual feedback. According to the local feedback concept, the eyes are driven by a signal that is the difference between desired eye position and an estimate of current eye position, the latter provided by the eye position-related TNs. This ‘motor error’ activates the saccadic burst neurons, the EBNs, that generate a pulse of activity proportional to the size of the motor error. The EBN pulse and the TN position step signals are integrated by the ocular MNs and
Catz/Thier
58
Extrastriate visual cortex
FEF
LIP
IO
Basal ganglia
DPN Cerebellum
NRTP Retina
SC
Burst generator
Ocular MNs
Fig. 4. Simplified diagram of the major cortical and subcortical areas involved in the planning, preparation and execution of saccadic eye movements.
give rise to their characteristic burst-tonic discharge which is responsible for the movement (discharge burst ⫽ ‘pulse’) and the subsequent stabilization of the eyes in new orbital position (tonic discharge ⫽ position ‘step’). During the movement, the ‘efference copy’ of the movement, represented by the TNs, grows and consequently, the motor error is gradually reduced to zero, which is why the movement will ultimately come to a stop. The role of the OPNs in this model is basically to speed up the transition from fixation to movement and back again and, moreover, to stabilize the respective states. This is a direct consequence of the reciprocal inhibitory connections between OPNs and EBNs. The decision to start a saccade will activate EBNs directly and in addition indirectly by reducing inhibition from OPNs,
Neural Control of Saccadic Eye Movements
59
whose activity will be reduced by the decision to start a saccade as well as by the growing activity of the EBNs. Conversely, during fixation, the inhibition from OPNs will tend to suppress spurious activation of EBNs and thereby unintended saccades (fig. 4).
The Superior Colliculus
The brainstem burst generators in the PPRF and the MRF receive input from a number of brain structures such as the SC, the FEFs and the oculomotor cerebellum. The input from the SC, homologue of the optic tectum in amphibians and fishes, is probably the most important and, moreover, the best understood source of input. The SC is a multilayered structure whose intermediate layer plays a critical role in the control of visual fixation and saccadic eye movements, serving as the key structure underlying the spatiotemporal transformation for saccades. Neurons in the intermediate layer of the SC show convergence of visual, auditory, and somatosensory informations, integrated to guided saccades but also other types of orientation behavior [55–59]. The role of the intermediate layer of the SC in the guidance of saccades has first been established by electrical microstimulation [60], which evokes saccades into the contralateral hemifield with amplitudes and directions fully determined by the location of the microelectrode in the SC (fig. 5). Large saccades are elicited by microstimulation of the caudal SC, whereas small saccades are evoked by microstimulation of its more rostral part. Moving the stimulation microelectrode gradually within the intermediate layer leads to gradual changes in the metrics of evoked saccades, demonstrating that the intermediate layer of the SC contains a topographic map of saccade endpoints. The location of the endpoint of evoked saccades coincides with the location of the circumscribed movement fields of saccade-related burst neurons, found at the respective location in the intermediate layer. Moreover, the map of saccade endpoints in the intermediate layer is congruent with the retinotopic map in the overlying, purely visual superficial layer of the SC. Three other types of neurons characterize the intermediate layer of the SC. In addition to the burst neurons (SC-BNs), which are purely saccade-related, lacking any visual responses, the intermediate layer also houses purely visual as well as mixed visuomotor neurons. One variety of the latter, the so-called build-up cells play a decisive role in current models of the role of the SC in the generation of saccades. Unlike the visual and the burst cells, they are characterized by open response fields that lead to their activation by any saccade in their preferred direction, independent of amplitude. The rostral pole of the SC, adjoining to the small saccade representation, is special as it contains neurons (SC-FNs) that are active during fixation, rather than being
Catz/Thier
60
Left 15º
Right
5º
Caudal 20 10
10º
0
20 spike/s
–10
SC-BN 5º
30 20
2.5º
10 5
Rostral
Fixation region
SC-FN
20 spike/s
0 250
a
b
Time from saccade onset (ms)
Fig. 5. The superior collicular map for saccades. a The rostral-caudal (thin lines) axis represents the saccade horizontal component, while the vertical component is represented by the mediolateral axis (thick lines). b Discharge of a SC-BN and discharge of a SC-FN during a 15⬚ saccade.
activated by saccades. Conversely, these fixation neurons are silent during saccades. While the fixation zone maintains an excitatory projection to the brainstem omnipause region, the burst neurons project to the brainstem burst generators via LLBNs in the midbrain. The decision to carry out a saccade of a given amplitude and direction will activate the neurons at the corresponding location in the SC map, while at the same time inhibiting the SC fixation zone (fig. 5b). Excitatory drive will be passed on from this location to the EBNs by way of the LLBNs. At the same time, activity from this initial location in the SC spreads to buildup neurons in neighboring locations representing smaller amplitudes which will sustain the excitation of the brainstem burst generator. The drive of the EBNs will come to an end, once the spread of activity on the collicular map has reached the fixation zone, on the one hand, stopping EBNs directly, and on the other hand, activating OPNs. In sum, the spatiotemporal transformation for saccades is a direct consequence of the functional architecture of the SC and its connections with the brainstem (fig. 5). The scheme sketched out before is a simplification of more elaborated models on the role of the SC in the generation of saccades [61, 62]. Although based on an abundance of anatomical and physiological observation, they still contain a number of speculative and highly controversial elements. Alternative views on the role of the SC in saccades that have recently been proposed suggest a direct involvement in the feedback control of saccades [63, 64] or the elaboration of the ‘error signal’ needed in order to adjust the oculomotor plant
Neural Control of Saccadic Eye Movements
61
[65–67]. Bergeron et al. [67] proposed, in extension of the original assumption of Robinson [60], that the SC encodes the distance to the target rather than saccade amplitude. Distance to target is given by comparing target position on the retina with current gaze position, yielding the gaze shift needed (gaze position error) to fovealize the target. The important difference with respect to the original Robinson model is that the variable controlled is gaze, the sum of eye and head position, rather than just eye position and, secondly, that the SC is inside the feedback loop calculating the motor error.
The Basal Ganglia
The interest in the role of the basal ganglia in the control of saccadic eye movements emerged after saccade-related neurons had been demonstrated in various parts of the basal ganglia [68, 69] and, moreover, a direct projection from the substantia nigra pars reticulata (SNr) to the SC had been established [70]. This inhibitory projection is in turn under the control of an inhibitory projection coming from the caudate nucleus (CN). One of the main functions of the basal ganglia in the control of saccades seems to be the avoidance of unwanted saccades. This is demonstrated by the emergence of spurious saccades, if the tonic inhibitory input is blocked experimentally (fig. 6) [71]. For instance, in order to suppress too early saccades in a memory-guided saccade task the SNr continuously inhibits the SC-BN in the intermediate layer of the SC [71, 72]. If the context allows the execution of the saccade, the CN via its negative action on the SNr will disinhibit the SC-BN [73], allowing the SC-BN to fire and start a saccade (fig. 6).
The Oculomotor Role of the Pontine Nuclei and the Nucleus Reticularis Tegmenti Pontis
Both cortical structures we dispose of, cerebral cortex and cerebellar cortex are involved in the control of saccades. The major pathway linking the two cortices, including those areas involved in saccades, is the cerebropontocerebellar projection with the pontine nuclei (PN) in the basilar brainstem serving as intermediate station. In addition to input from saccade-related areas of the cerebral cortex such as area LIP and the FEF, the PN also receive visual and eye movement-related input from the SC. Accordingly, the PN may be regarded as a central integration unit in a major pathway subserving saccades. In this section, we will describe the role of the PN in saccades and in addition discuss the role of a neighboring major precerebellar nucleus, the nucleus reticularis tegmenti
Catz/Thier
62
CN
CN
⫺
⫺ SNr
SNr
Bicuculine ⫺
⫺
a
SC
SC
Brainstem burst generator
Brainstem burst generator
b
10º
100 ms
c
Fig. 6. a Scheme of the inhibitory projection from the basal ganglia to the SC. b The injection of the GABA antagonist (bicuculine) into the SC suppresses the inhibition and thereby induces spurious saccades shown in (c). c Saccadic jerks during fixation of a central target after injection of bicuculine into the left SC while the monkey waits for the signal to make a saccade to a memorized spatial location. The vertical line marks the end of the presence of the fixation target. Upper traces show horizontal and lower traces vertical eye position. From Hikosaka and Wurtz [71], with permission.
Neural Control of Saccadic Eye Movements
63
pontis (NRTP), a structure lying adjacent to the medial parts of the PN, but still much less dependent on input from cerebral cortex than the PN. The Pontine Nuclei The dorsolateral PN (DLPN) and neighboring parts of the PN receive ample input from a number of cerebrocortical and subcortical structures known to be involved in saccadic eye movements such as the FEF, parietal areas LIP and MP, or the SC. Hence, the anatomy strongly suggests that the PN might be involved in information processing for saccades as well, rather than being confined to the slow visually guided eye movements emphasized by the early electrophysiological and lesion work on the PN [74, 75]. Actually, as it turns out, saccade-related single units can be encountered almost as frequently as single units activated by smooth pursuit eye movements if the dorsal parts of the PN are explored without any bias for the one or the other type of oculomotor behavior. In two rhesus monkeys trained to perform smooth pursuit eye movements as well as visually and memory-guided saccades, out of 281 neurons isolated from the dorsal PN (DPN), 138 were responsive in oculomotor tasks. Forty-five were exclusively activated in saccade paradigms, 68 exclusively by smooth pursuit, and 25 neurons showed responses in both [76]. The various types of oculomotor neurons could be encountered in the lateral as well as medial parts of the DPN without any distinctive differences in their relative frequencies, further putting into perspective the notion of the DLPN as the only oculomotor part of the PN. Saccade-related neurons in the DPN were found intermingled with those discharging in conjunction with smooth pursuit eye movements. Most saccaderelated neurons had a preferred saccade direction. However, with respect to other features, they were quite heterogeneous, exhibiting a wide variety of response patterns when tested in a memory-guided saccade task. Whereas some discharged only at the time of the eye movement, others displayed additional visual responses or activity in the ‘memory’ period. Even the features of saccade-related bursts differed substantially between neurons, as among others reflected by the wide distribution of burst onset latencies, varying between substantial lead and lag relative to eye movement onset. The sources of afferents impinging on the DPN involve probably all cerebrocortical representations of saccadic eye movements, areas which house neurons with very different types of saccade-related responses. The heterogeneity of saccade-related responses in the DPN is therefore most probably a reflection of the diversity of the cerebrocortical input. While about 90% of the afferents impinging on the DPN are of cerebrocortical origin [77], there is additional input from a number of subcortical sources, including the SC [78]. Hence, in principal saccade-related signals in the DPN might also reflect saccade-related input from the SC, rather than information originating from the saccade-related areas of the cerebral cortex.
Catz/Thier
64
While some of the saccade-related neurons encountered in the DPN may indeed have been driven by input from the SC, it seems unlikely to be true for the majority of these neurons. This is suggested by the fact that the projection from the SC is not only small, compared with the one originating from cerebral cortex, but, moreover, largely restricted to the rostral DLPN proper [78]. However, saccade-related neurons were found in extended parts of the DPN, most probably also in locations far away from the putative target zones of the SC projection, and, moreover, without any clear differences in the properties of saccade-related responses in different parts of the DPN. Neurons showing combined sensitivities to saccades and to smooth pursuit, surprisingly frequent in the DPN, do not seem to have a cerebrocortical counterpart. This might suggest that they are constructed by convergence of more specialized oculomotor streams originating from different parts of the cerebral cortex. The functional role of these ‘combination’ neurons is unclear. One might speculate that they play a specific role in the generation of catch-up saccades, executed in an attempt to bring the eye back on target in case of insufficient smooth pursuit eye movements. However, such a role would probably require coinciding preferred directions for saccades and smooth pursuit, a coincidence these ‘combination’ neurons typically lack. Unlike the effects on smooth pursuit eye movements, small experimental lesions of the monkey DLPN do not affect saccades made to stationary visual targets. However, saccades made to targets moving away from the starting position of the eyes become hypometric for target movement toward the side of the lesion [74]. Larger lesions of the human basilar pons, sparing the brainstem tegmentum, may cause hypometria also of saccades made toward stationary targets without changing saccade velocity and its dependence on saccade amplitude [Bunjes and Thier, unpubl. obs.]. The Nucleus Reticularis Tegmenti Pontis The dominating type of saccade-related neurons in the NRTP produces bursts of spikes before and during a saccadic eye movement directed toward circumscribed movement fields. Unlike neurons in the nearby PPRF, the discharge intensity or duration does not reflect the saccade metrics. Some of these neurons exhibit additional visual sensitivity to spots of light turned on within the movement field. These neurons are functionally intermediate between the saccade-only neurons mentioned before and neurons with purely visual responses found in the same area. The features of these three types of neurons are reminiscent of the neurons in the SC, from which some of the input of the NRTP is derived. However, unlike movement fields of saccade neurons in the SC, those in the NRTP have a 3-D organization, reflecting eye torsion as well as the vertical and the horizontal excursions of the eye [79]. Moreover, unlike
Neural Control of Saccadic Eye Movements
65
microstimulation of the SC, which moves the eyes vertically and horizontally but not torsionally [80], stimulation of the cNRTP induces torsional deviations of the eyes. Finally, lesions of the NRTP seem to impair the ability to reset torsional errors. Taken together, these observations strongly support the idea that the NRTP is a key element in a circuit downstream of the SC stabilizing Listing’s plane against torsional errors of the saccadic system.
The Oculomotor Cerebellum
Several regions of the cerebellum house Purkinje cells that discharge in relation to saccadic eye movements. The region first identified and probably best understood is located in the posterior vermis, comprising vermal lobuli VI and VII and occasionally also referred to as the oculomotor vermis or Noda’s vermis, the latter name chosen to honor the late Hiroharu Noda, whose work has contributed considerably to our current view of this part of the cerebellum. A contribution of the posterior vermis and neighboring parts of the cerebellum to saccades was first suggested by experiments in which surgical lesions of this part of the cerebellum were carried out. For instance, Aschoff and Cohen [81] observed fewer saccades to the impaired hemifield after unilateral lesions of the cerebellar vermis, and Ritchie [82] described dysmetric saccades to visual targets following lesions of the posterior vermis. Dysmetric saccades have also been reported in the clinical literature as the consequences of cerebellar pathology involving the human vermis due to disease [83]. Ron and Robinson [84] showed that electric stimulation through electrodes placed in the posterior vermis and neighboring paravermis with currents of up to 1 mA was able to evoke saccadic eye movements. While this early work suggested a quite extended saccade representation in the posterior cerebellum, Noda and coworkers, by resorting to electric microstimulation, could show that the saccade representation was actually much smaller than hitherto assumed [85–88]. When stimulation currents were kept below 10 A, saccades could only be evoked from lobuli VIc and VIIA of the posterior vermis, but not from the adjoining regions of the vermis and paravermis. Moreover, Noda and Fujikado [89] could show that the stimulation effects were a consequence of activating Purkinje cell axons and could rule out that the antidromic activation of vermal afferents, originating from brainstem centers for saccades, contributed to the evoked saccades. The oculomotor vermis projects to the saccade representation in the cFN, which in turn projects to the brainstem centers for saccades [88, 90]. The cFN contains numerous saccade-related neurons. The properties of the saccaderelated bursts depend on the direction of the saccade being controversive or ipsiversive [91–94]. Furthermore, the unilateral inactivation of the cFN induces
Catz/Thier
66
saccadic dysmetria, ipsiversive hypermetria and controversive hypometria [95]. The induced dysmetria is accompanied by abnormalities in saccade kinematics [96]. It is therefore very likely that the effects of activating Purkinje cells artificially by electric stimulation are mediated by this pathway. Electric microstimulation has clearly been very helpful in identifying the saccade-related parts of the posterior vermis and the pathway originating from there. On the other hand, its contribution to the characterization of the functional role of cerebellar cortex in the control of saccades has been limited. Our own recent work on the posterior vermis [97] suggests that posterior vermal Purkinje cells provide a signal used to adapt the duration of the pulse offered by the brainstem pulse generator, a hypothesis which is based on the analysis of the properties of saccade-related neurons in the posterior vermis. When tested in the memory-saccade paradigm, in which center-out saccades are made in darkness towards the remembered location of a cue, turned off a couple of 100 ms before the saccade is carried out, most saccade-related Purkinje cells exhibit pure saccade bursts. They only rarely show visual responses or activity in the period of time; the monkey is waiting for the go-signal to start the saccade. Moreover, these saccade-related responses are usually direction selective. Saccade duration and amplitude are closely linked. Saccade duration increases linearly with amplitude for up to 40⬚, allowing one to change saccade duration by simply asking monkeys to make saccades of different amplitudes. When saccades of different amplitudes are carried out in the preferred direction of a given cell, the amplitude dependency of the saccade-related bursts is highly idiosyncratic. Whereas some cells may show a monotonous increase in the number of spikes fired with increasing saccade amplitude, others show preferred amplitudes or no dependency on amplitude at all within a range of amplitudes up to 40⬚. In other words, one would most probably fail if one tried to determine the duration or amplitude of a saccade made by the monkey by monitoring the discharge pattern of individual cells. Unlike individual cells, though, larger groups of these saccade-related Purkinje cells provide a precise signature of saccade duration and amplitude. This is suggested by the conspicuous relationship between saccade duration and the duration of the population burst, the instantaneous discharge rate of a larger (n ⱖ 50) group of saccade-related Purkinje cells, obtained by considering the timing of each spike fired by each cell in the sample. Figure 7 shows a plot of the simple spike (SS) population burst, based on 94 Purkinje cells from the posterior vermis as function of time around a saccadic eye movement. The population burst is plotted for three different saccade durations (fig. 7a). It starts, independent of saccade duration a couple of 10 ms before saccade onset and peaks exactly at the time the saccade starts, again independent of saccade duration. It is the decline of the population
Neural Control of Saccadic Eye Movements
67
Saccade onset 100 50
60 c Sac
Rate (1/s)
80
Rate (1/s)
30 ms 49 ms 65 ms
100
60
ade
40
atio dur
20 0
20
40 60
80
Saccade end a
b
⫺50
0 50 Time (ms)
c
Time (ms)
b
s) n (m
⫺40 ⫺20
a
40 ⫺100
⫺50
0
50
Time (ms)
d
Time (ms)
60
50
40
30
c
100
Fig. 7. Cerebellar Purkinje cells population response. a Population burst profiles for 3 saccade durations of 30, 49 and 65 ms. b Dependence of population burst on saccade duration. The x-axis plots the time relative to saccade onset at 0 ms, the y-axis saccade duration, and the z-axis the mean instantaneous discharge rate of the population of 94 Purkinje cells. c Regression plots relating different parameters characterizing the saccade timing and the burst time to each other. See the text for explanation. a, c Taken from Thier et al. [97], with permission.
burst, which depends on saccade duration: it is longer the longer the saccade lasts. This clear dependency of the time the population burst ends on the time the saccade ends is not restricted to the three saccade durations presented in figure 7a but characterizes the full range of saccade durations tested (from less than 30 ms to almost 80 ms). This is shown in figure 7b, which depicts a pseudo 3-D plot of the population burst as a function of saccade duration. In order to relate the time course
Catz/Thier
68
of the population burst more precisely to the time course of the saccade, we measured the times of onset (a), peak (b) and offset (c) of the population burst relative to saccade onset of each saccade duration as well as the population burst duration (d), given by c – a. We determined population onset and offset times as the times when the population burst reached 4 times the baseline firing rate when building up and when declining. Figure 7c plots time t as a function of a, b, c, and d, respectively. In the case of a, b and d, t corresponds to saccade duration, in the case of c to the time of saccade termination. The plots are fitted by linear regressions. Both c and d increased linearly (c: p ⫽ 0.00004, d: p ⬍ 0.01) with the time of saccade termination and saccade duration, respectively, whereas neither a nor b depended significantly (p ⬎ 0.05) on saccade duration. The end of the population burst (c) as predicted by the regression, corresponds very closely to the end of the saccades, whereas the population burst duration (d) underestimates saccade duration by 24%. This fact and the significantly higher coefficient of correlation for c compared with d indicate that the population burst reflects the time of saccade termination. Individual cells fire their bursts at different times relative to the saccade, some reaching their maximum quite early, even before saccade onset, while others fire much later. None of the individual Purkinje cells reflect the termination of the saccade as accurately as the population response [97]. Based on the number of Purkinje cells in rhesus monkeys [98] and the number of deep cerebellar nuclei neurons [99], it can be estimated that on the order of 20–30 Purkinje cells converge on individual cells in the deep cerebellar nuclei. This means that a cell in the caudal part of the fastigial nucleus, the target of the posterior vermis, is probably influenced by a compound signal, not too different from the population burst as described before. In other words, the population burst is not a mathematical artifact but most probably a direct functional consequence of the properties of the cerebellonuclear projection. In view of the GABAergic nature of this projection, the population burst will deliver a strong hyperpolarizing signal to the recipient nuclear neuron, probably turning it off while the saccade is carried out. In vitro studies have shown that nuclear neurons fire strong rebound bursts upon cessation of hyperpolarization, as a consequence of hyperpolarization-activated mixed cation and calcium channels [100]. If such rebound bursts were also generated under in vivo conditions, we would expect to see saccade-related bursts close to the end of a saccade. Actually, many saccade-related nuclear neurons show such late saccade-related bursts [92, 94, 101], a signal, which if sent to the brainstem machinery for saccades, might help to stop an ongoing saccade. Scudder et al. [102] have recently shown that the timing of these late bursts can be changed by adapting saccade amplitude. For instance, if manipulations are carried out leading to longer-lasting, larger amplitude saccades, these bursts occur even later. If we assume that
Neural Control of Saccadic Eye Movements
69
the timing of these later bursts fired by nuclear neurons is determined by the end of the vermal population burst, the conclusion obviously is that the manipulation leading to longer and larger saccades has increased the duration of the vermal simple spike (SS) population bursts. In other words, changes in the duration of the population bursts might underlie saccadic plasticity or adaptation, in which the relationship between a given retinal vector, defining the location of the target and the saccade vector is changed, if appropriate [103]. While we do not know yet how the vermal population burst duration is changed by saccadic adaptation, we do know that the vermis is indispensable for saccadic adaptation. Lesioning vermal lobule VI and VII leads to an irreversible loss of short-term saccadic plasticity [104]. Short-term saccadic plasticity is the function which allows us to generate thousands of precise saccades despite the fact that the oculomotor periphery changes continuously due to fatigue. We hypothesize that this is possible because of careful adjusting of saccade duration, realized by tuning the neuronal representation of saccade time offered by the posterior vermal population signal. In order to induce any changes of the population burst duration that may be needed in order to accommodate changes of the oculomotor periphery, the vermis should receive information on the state of the motor plant. Any inadequate consideration of the plant will lead to imprecise saccades, missing the goal and thereby generating a ‘performance error’. It is commonly assumed that such error signals underlie the changes observed during saccadic adaptation [for review, see 103]. It is close at hand to assume that the performance error leads to adaptation by modulating the duration of the posterior vermal population burst. Our recent observations on the climbing fiber input to the saccade-related posterior vermis are in full accordance with this idea [105]. Climbing fibers originate from the inferior olive (IO) and are responsible for the complex spikes (CS) fired by cerebellar Purkinje cells, which modulate the efficacy of the second line of input, in the case of saccades, fed by the dorsal PN and the NRTP. A careful analysis of the changes of CS patterns during saccadic learning shows that they would be appropriate to lead to the changes of the SS population burst, needed in order to explain the changes in saccade metrics due to learning. Note that in this scenario, the changes in the CS profile induced by learning do not reflect an error per se but adjustments, which are prompted by an error. Given the strong input from the SC to the IO, the origin of the climbing fibers, one may speculate that it is the SC that extracts the error in the first place. Irrespective of the details and the remaining open questions, the work on the posterior vermis is fully compatible with the notion that this part of the cerebellum contributes to the fine tuning needed in order to allow the brainstem saccade generator to work at the precision we observe.
Catz/Thier
70
References 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17
18 19
20 21 22 23 24 25 26
Ter Braak JWG: Untersuchungen über optokinetischen Nystagmus. Arch Neer Physiol 1936;21: 309–376. Fischer B: Visually guided eye and hand movements in man. Brain Behav Evol 1989;33:109–112. Amador N, Schlag-Rey M, Schlag J: Primate antisaccades. I. Behavioral characteristics. J Neurophysiol 1998;80:1775–1786. Zhang M, Barash S: Neuronal switching of sensorimotor transformations for antisaccades. Nature 2000;408:971–975. Munoz DP, Everling S: Look away: the anti-saccade task and the voluntary control of eye movement. Nat Rev Neurosci 2004;5:218–228. Boghen D, Troost BT, Daroff RB, Dell’Osso LF, Birkett JE: Velocity characteristics of normal human saccades. Invest Ophthalmol 1974;13:619–623. Fischer B, Ramsperger E: Human express saccades: extremely short reaction times of goal directed eye movements. Exp Brain Res 1984;57:191–195. Fischer B, Boch R, Ramsperger E: Express-saccades of the monkey: effect of daily training on probability of occurrence and reaction time. Exp Brain Res 1984;55:232–242. Thier P, Ilg UJ: The neural basis of smooth-pursuit eye movements. Curr Opin Neurobiol 2005;15:645–652. Von Helmholtz H: Ueber die normalen Bewegungen des menschlichen Auges. Arch Ophthalmol 1863;9:153–214. Tweed D, Vilis T: Geometric relations of eye position and velocity vectors during saccades. Vision Res 1990;30:111–127. Schall JD, Hanes DP: Neural basis of saccade target selection in frontal eye field during visual search. Nature 1993;366:467–469. Gaymard B, Ploner CJ, Rivaud S, Vermersch AI, Pierrot-Deseilligny C: Cortical control of saccades. Exp Brain Res 1998;123:159–163. Tehovnik EJ, Sommer MA, Chou IH, Slocum WM, Schiller PH: Eye fields in the frontal lobes of primates. Brain Res Rev 2000;32:413–448. Peck CK: Visual responses of neurones in cat superior colliculus in relation to fixation of targets. J Physiol 1989;414:301–315. Munoz DP, Wurtz RH: Fixation cells in monkey superior colliculus. I. Characteristics of cell discharge. J Neurophysiol 1993;70:559–575. Averbuch-Heller L, Kori AA, Rottach KG, Dell’Osso LF, Remler BF, Leigh RJ: Dysfunction of pontine omnipause neurons causes impaired fixation: macrosaccadic oscillations with a unilateral pontine lesion. Neuroophthalmology 1996;16:99–106. Andersen RA, Bracewell RM, Barash S, Gnadt JW, Fogassi L: Eye position effects on visual, memory, and saccade-related activity in areas LIP and 7a of macaque. J Neurosci 1990;10:1176–1196. Barash S, Bracewell RM, Fogassi L, Gnadt JW, Andersen RA: Saccade-related activity in the lateral intraparietal area. I. Temporal properties; comparison with area 7a. J Neurophysiol 1991;66: 1095–1108. Barash S, Bracewell RM, Fogassi L, Gnadt JW, Andersen RA: Saccade-related activity in the lateral intraparietal area. II. Spatial properties. J Neurophysiol 1991;66:1109–1124. Schall JD: On building a bridge between brain and behavior. Annu Rev Psychol 2004;55:23–50. Fuchs AF, Kaneko CR, Scudder CA: Brainstem control of saccadic eye movements. Annu Rev Neurosci 1985;8:307–337. Luschei ES, Fuchs AF: Activity of brain stem neurons during eye movements of alert monkeys. J Neurophysiol 1972;35:445–461. Büttner U, Büttner-Ennever JA, Henn V: Vertical eye movement related unit activity in the rostral mesencephalic reticular formation of the alert monkey. Brain Res 1977;130:239–252. Büttner-Ennever JA, Büttner U: A cell group associated with vertical eye movements in the rostral mesencephalic reticular formation of the monkey. Brain Res 1978;151:31–47. Moschovakis AK, Scudder CA, Highstein SM: The microscopic anatomy and physiology of the mammalian saccadic system. Prog Neurobiol 1996;50:133–254.
Neural Control of Saccadic Eye Movements
71
27 28 29
30 31
32
33
34 35 36 37
38 39 40
41 42 43 44
45 46 47 48
49 50
Büttner-Ennever JA, Henn V: An autoradiographic study of the pathways from the pontine reticular formation involved in horizontal eye movements. Brain Res 1976;108:155–164. Graybiel AM: Direct and indirect preoculomotor pathways of the brainstem: an autoradiographic study of the pontine reticular formation in the cat. J Comp Neurol 1977;175:37–78. Grantyn A, Grantyn R, Gaunitz U, Robine KP: Sources of direct excitatory and inhibitory inputs from the medial rhombencephalic tegmentum to lateral and medial rectus motoneurons in the cat. Exp Brain Res 1980;39:49–61. Sirkin DW, Feng AS: Autoradiographic study of descending pathways from the pontine reticular formation and the mesencephalic trigeminal nucleus in the rat. J Comp Neurol 1987;256:483–493. Hikosaka O, Igusa Y, Imai H: Inhibitory connections of nystagmus-related reticular burst neurons with neurons in the abducens, prepositus hypoglossi and vestibular nuclei in the cat. Exp Brain Res 1980;39:301–311. Fukushima K, Ohno M, Takahashi K, Kato M: Location and vestibular responses of interstitial and midbrain reticular neurons that project to the vestibular nuclei in the cat. Exp Brain Res 1982;45: 303–312. Thielert CD, Thier P: Patterns of projections from the pontine nuclei and the nucleus reticularis tegmenti pontis to the posterior vermis in the rhesus monkey: a study using retrograde tracers. J Comp Neurol 1993;337:113–126. Highstein SM, Maekawa K, Steinacker A, Cohen B: Synaptic input from the pontine reticular nuclei to abducens motoneurons and internuclear neurons in the cat. Brain Res 1976;112: 162–167. Hikosaka O, Igusa Y, Nakao S, Shimazu H: Direct inhibitory synaptic linkage of pontomedullary reticular burst neurons with abducens motoneurons in the cat. Exp Brain Res 1978;33:337–352. Igusa Y, Sasaki S, Shimazu H: Excitatory premotor burst neurons in the cat pontine reticular formation related to the quick phase of vestibular nystagmus. Brain Res 1980;182:451–456. Highstein SM, Baker R: Excitatory termination of abducens internuclear neurons on medial rectus motoneurons: relationship to syndrome of internuclear ophthalmoplegia. J Neurophysiol 1978;41: 1647–1661. Steiger HJ, Büttner-Ennever JA: Oculomotor nucleus afferents in the monkey demonstrated with horseradish peroxidase. Brain Res 1979;160:1–15. Strassman A, Highstein SM, McCrea RA: Anatomy and physiology of saccadic burst neurons in the alert squirrel monkey. I. Excitatory burst neurons. J Comp Neurol 1986;249:337–357. Hikosaka O, Nakao S, Shimazu H: Postsynaptic inhibition underlying spike suppression of secondary vestibular neurons during quick phases of vestibular nystagmus. Neurosci Lett 1980;16: 21–26. Strassman A, Highstein SM, McCrea RA: Anatomy and physiology of saccadic burst neurons in the alert squirrel monkey. II. Inhibitory burst neurons. J Comp Neurol 1986;249:358–380. Yoshida K, Iwamoto Y, Chimoto S, Shimazu H: Saccade-related inhibitory input to pontine omnipause neurons: an intracellular study in alert cats. J Neurophysiol 1999;82:1198–1208. Büttner-Ennever JA, Horn AK, Henn V, Cohen B: Projections from the superior colliculus motor map to omnipause neurons in monkey. J Comp Neurol 1999;413:55–67. Yoshida K, Iwamoto Y, Chimoto S, Shimazu H: Disynaptic inhibition of omnipause neurons following electrical stimulation of the superior colliculus in alert cats. J Neurophysiol 2001;85: 2639–2642. Langer TP, Kaneko CR: Brainstem afferents to the omnipause region in the cat: a horseradish peroxidase study. J Comp Neurol 1984;230:444–458. Cannon SC, Robinson DA: Loss of the neural integrator of the oculomotor system from brain stem lesions in monkey. J Neurophysiol 1987;57:1383–1409. Cheron G, Godaux E: Disabling of the oculomotor neural integrator by kainic acid injections in the prepositus-vestibular complex of the cat. J Physiol 1987;394:267–290. Kaneko CR, Fuchs AF: Saccadic eye movement deficits following ibotenic acid lesions of the nuclei raphe interpositus and prepositus hypoglossi in monkey. Acta Otolaryngol Suppl 1991;481: 213–215. Robinson DA: Integrating with neurons. Annu Rev Neurosci 1989;12:33–45. Koulakov AA, Raghavachari S, Kepecs A, Lisman JE: Model for a robust neural integrator. Nat Neurosci 2002;5:775–782.
Catz/Thier
72
51
52
53
54
55 56 57 58
59
60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75
McFarland JL, Fuchs AF: Discharge patterns in nucleus prepositus hypoglossi and adjacent medial vestibular nucleus during horizontal eye movement in behaving macaques. J Neurophysiol 1992;68: 319–332. Scudder CA, Fuchs AF: Physiological and behavioral identification of vestibular nucleus neurons mediating the horizontal vestibuloocular reflex in trained rhesus monkeys. J Neurophysiol 1992;68: 244–264. Cullen KE, Chen-Huang C, McCrea RA: Firing behavior of brain stem neurons during voluntary cancellation of the horizontal vestibuloocular reflex. II. Eye movement related neurons. J Neurophysiol 1993;70:844–856. Robinson DA: Oculomotor control signals; in Lennerstrandand G, Bach-y-Rita P (eds): Basic Mechanisms of Ocular Motility and Their Clinical Implications. Oxford, Pergamon Press, 1975, pp 337–374. Groh JM, Sparks DL: Saccades to somatosensory targets. I. Behavioral characteristics. J Neurophysiol 1996;75:412–427. Groh JM, Sparks DL: Saccades to somatosensory targets. II. Motor convergence in primate superior colliculus. J Neurophysiol 1996;75:428–438. Groh JM, Sparks DL: Saccades to somatosensory targets. III. Eye-position-dependent somatosensory activity in primate superior colliculus. J Neurophysiol 1996;75:439–453. Werner W, Dannenberg S, Hoffmann KP: Arm-movement-related neurons in the primate superior colliculus and underlying reticular formation: comparison of neuronal activity with EMGs of muscles of the shoulder, arm and trunk during reaching. Exp Brain Res 1997;115:191–205. Bell AH, Meredith MA, van Opstal AJ, Munoz DP: Crossmodal integration in the primate superior colliculus underlying the preparation and initiation of saccadic eye movements. J Neurophysiol 2005;93:3659–3673. Robinson DA: Eye movements evoked by collicular stimulation in the alert monkey. Vision Res 1972;12:1795–1808. Girard B, Berthoz A: From brainstem to cortex: computational models of saccade generation circuitry. Prog Neurobiol 2005;77:215–251. Goossens HH, van Opstal AJ: Dynamic ensemble coding of saccades in the monkey superior colliculus. J Neurophysiol 2006;95:2326–2341. Soetedjo R, Kaneko CR, Fuchs AF: Evidence that the superior colliculus participates in the feedback control of saccadic eye movements. J Neurophysiol 2002;87:679–695. Choi WY, Guitton D: Responses of collicular fixation neurons to gaze shift perturbations in headunrestrained monkey reveal gaze feedback control. Neuron 2006;50:491–505. Krauzlis RJ, Basso MA, Wurtz RH: Shared motor error for multiple eye movements. Science 1997;276:1693–1695. Bergeron A, Guitton D: In multiple-step gaze shifts: omnipause (OPNs) and collicular fixation neurons encode gaze position error; OPNs gate saccades. J Neurophysiol 2002;88:1726–1742. Bergeron A, Matsuo S, Guitton D: Superior colliculus encodes distance to target, not saccade amplitude, in multi-step gaze shifts. Nat Neurosci 2003;6:404–413. Hikosaka O, Wurtz RH: The basal ganglia. Rev Oculomot Res 1989;3:257–281. Hikosaka O, Sakamoto M, Usui S: Functional properties of monkey caudate neurons. I. Activities related to saccadic eye movements. J Neurophysiol 1989;61:780–798. Hikosaka O, Takikawa Y, Kawagoe R: Role of the basal ganglia in the control of purposive saccadic eye movements. Physiol Rev 2000;80:953–978. Hikosaka O, Wurtz RH: Modification of saccadic eye movements by GABA-related substances. II. Effects of muscimol in monkey substantia nigra pars reticulata. J Neurophysiol 1985;53:292–308. Hikosaka O, Wurtz RH: Visual and oculomotor functions of monkey substantia nigra pars reticulata. IV. Relation of substantia nigra to superior colliculus. J Neurophysiol 1983;49:1285–1301. Wurtz RH, Hikosaka O: Role of the basal ganglia in the initiation of saccadic eye movements. Prog Brain Res 1986;64:175–190. May JG, Keller EL, Suzuki DA: Smooth-pursuit eye movement deficits with chemical lesions in the dorsolateral pontine nucleus of the monkey. J Neurophysiol 1988;59:952–977. Gaymard B, Pierrot-Deseilligny C, Rivaud S, Velut S: Smooth pursuit eye movement deficits after pontine nuclei lesions in humans. J Neurol Neurosurg Psychiatry 1993;56:799–807.
Neural Control of Saccadic Eye Movements
73
76 Dicke PW, Barash S, Ilg UJ, Thier P: Single-neuron evidence for a contribution of the dorsal pontine nuclei to both types of target-directed eye movements, saccades and smooth-pursuit. Eur J Neurosci 2004;19:609–624. 77 Brodal P, Bjaalie JG: Organization of the pontine nuclei. Neurosci Res 1992;13:83–118. 78 Harting JK: Descending pathways from the superior colliculus: an autoradiographic analysis in the rhesus monkey (Macaca mulatta). J Comp Neurol 1977;173:583–612. 79 Van Opstal J, Hepp K, Suzuki Y, Henn V: Role of monkey nucleus reticularis tegmenti pontis in the stabilization of Listing’s plane. J Neurosci 1996;16:7284–7296. 80 van Opstal AJ, Hepp K, Hess BJ, Straumann D, Henn V: Two- rather than three-dimensional representation of saccades in monkey superior colliculus. Science 1991;252:1313–1315. 81 Aschoff JC, Cohen B: Changes in saccadic eye movements produced by cerebellar cortical lesions. Exp Neurol 1971;32:123–133. 82 Ritchie L: Effects of cerebellar lesions on saccadic eye movements. J Neurophysiol 1976;39: 1246–1256. 83 Botzel K, Rottach K, Buttner U: Normal and pathological saccadic dysmetria. Brain 1993;116(pt 2): 337–353. 84 Ron S, Robinson DA: Eye movements evoked by cerebellar stimulation in the alert monkey. J Neurophysiol 1973;36:1004–1022. 85 Yamada J, Noda H: Afferent and efferent connections of the oculomotor cerebellar vermis in the macaque monkey. J Comp Neurol 1987;265:224–241. 86 Noda H, Fujikado T: Involvement of Purkinje cells in evoking saccadic eye movements by microstimulation of the posterior cerebellar vermis of monkeys. J Neurophysiol 1987;57:1247–1261. 87 Fujikado T, Noda H: Saccadic eye movements evoked by microstimulation of lobule VII of the cerebellar vermis of macaque monkeys. J Physiol 1987;394:573–594. 88 Noda H, Sugita S, Ikeda Y: Afferent and efferent connections of the oculomotor region of the fastigial nucleus in the macaque monkey. J Comp Neurol 1990;302:330–348. 89 Noda H, Fujikado T: Topography of the oculomotor area of the cerebellar vermis in macaques as determined by microstimulation. J Neurophysiol 1987;58:359–378. 90 Yamada T, Suzuki DA, Yee RD: Smooth pursuitlike eye movements evoked by microstimulation in macaque nucleus reticularis tegmenti pontis. J Neurophysiol 1996;76:3313–3324. 91 Ohtsuka K, Noda H: Saccadic burst neurons in the oculomotor region of the fastigial nucleus of macaque monkeys. J Neurophysiol 1991;65:1422–1434. 92 Fuchs AF, Robinson FR, Straube A: Role of the caudal fastigial nucleus in saccade generation. I. Neuronal discharge pattern. J Neurophysiol 1993;70:1723–1740. 93 Kleine JF, Guan Y, Buttner U: Discharge properties of saccade-related neurons in the primate fastigial oculomotor region. Ann N Y Acad Sci 2003;1004:252–261. 94 Kleine JF, Guan Y, Buttner U: Saccade-related neurons in the primate fastigial nucleus: what do they encode? J Neurophysiol 2003;90:3137–3154. 95 Robinson FR, Straube A, Fuchs AF: Role of the caudal fastigial nucleus in saccade generation. II. Effects of muscimol inactivation. J Neurophysiol 1993;70:1741–1758. 96 Goffart L, Chen LL, Sparks DL: Deficits in saccades and fixation during muscimol inactivation of the caudal fastigial nucleus in the rhesus monkey. J Neurophysiol 2004;92:3351–3367. 97 Thier P, Dicke PW, Haas R, Barash S: Encoding of movement time by populations of cerebellar Purkinje cells. Nature 2000;405:72–76. 98 Lange W: Cell number and cell density in the cerebellar cortex of man and some other mammals. Cell Tissue Res 1975;157:115–124. 99 Gould BB, Rakic P: The total number, time or origin and kinetics of proliferation of neurons comprising the deep cerebellar nuclei in the rhesus monkey. Exp Brain Res 1981;44:195–206. 100 Czubayko U, Sultan F, Thier P, Schwarz C: Two types of neurons in the rat cerebellar nuclei as distinguished by membrane potentials and intracellular fillings. J Neurophysiol 2001;85:2017–2029. 101 Ohtsuka K, Noda H: Direction-selective saccadic-burst neurons in the fastigial oculomotor region of the macaque. Exp Brain Res 1990;81:659–662. 102 Scudder CA, Batourina EY, Tunder GS: Comparison of two methods of producing adaptation of saccade size and implications for the site of plasticity. J Neurophysiol 1998;79:704–715.
Catz/Thier
74
103 Hopp JJ, Fuchs AF: The characteristics and neuronal substrate of saccadic eye movement plasticity. Prog Neurobiol 2004;72:27–53. 104 Barash S, Melikyan A, Sivakov A, Zhang M, Glickstein M, Thier P: Saccadic dysmetria and adaptation after lesions of the cerebellar cortex. J Neurosci 1999;19:10931–10939. 105 Catz N, Dicke PW, Thier P: Cerebellar complex spike firing is suitable to induce as well as to stabilize motor learning. Curr Biol 2005;15:2179–2189.
Prof. Dr. P. Thier Department of Cognitive Neurology, Hertie Institute for Clinical Brain Research Hoppe-Seyler Strasse 3 DE–72076 Tübingen (Germany) Tel. ⫹49 7071 2983057, Fax ⫹49 7071 295326, E-Mail
[email protected]
Neural Control of Saccadic Eye Movements
75
Straube A, Büttner U (eds): Neuro-Ophthalmology. Dev Ophthalmol. Basel, Karger, 2007, vol 40, pp 76–89
Smooth Pursuit Eye Movements and Optokinetic Nystagmus Ulrich Büttner, Olympia Kremmyda Department of Neurology, Ludwig-Maximilians University, Munich, Germany
Abstract Smooth pursuit eye movements are used to track small moving visual objects and depend on an intact fovea. Optokinetic nystagmus is the oculomotor response to large moving visual fields. In addition, the ocular following response is considered, which reflects short latency, involuntary eye movements to large moving visual fields. This chapter will consider the general characteristics and the anatomical and physiological basis of these eye movements. It will conclude with disorders, particularly those seen in clinical investigations. Copyright © 2007 S. Karger AG, Basel
General Characteristics
Smooth Pursuit Eye Movements The performance of smooth pursuit eye movements (SPEM) is a voluntary task and depends on motivation and attention. SPEM are only found in species with a fovea and are used to maintain a clear image of small moving visual objects on the retina. The latency for the initiation of SPEM is 100–150 ms [1], which is generally shorter than for a saccade. During initiation (eye acceleration) SPEM depend mainly on visual signals, and during maintained pursuit on a ‘velocity memory’ signal [2]. In contrast to saccades, SPEM are usually considered as ‘slow’ eye movements, although velocities above 100⬚/s can be reached [man: 3; monkey: 4]. Cats, with a coarse area centralis can track larger stimuli only up to 20⬚/s [5]. In man, there is a clear age dependence of SPEM [6]. They are already present in 4-week-old infants and reach a gain close to 1 at 3 months [7]. As a rule, maximal velocity decreases every year by 1⬚/s starting at the age of 20 [3]. There seems to be no further decline above the age of 75 [8].
Under normal circumstances, tracking of small moving visual objects is done by eye and head movements. Head movements induce the vestibulo-ocular reflex (VOR), which drives the eyes in the direction opposite to the eye movements. During visual tracking the VOR has to be suppressed, and it is assumed that the central nervous system actually generates a smooth pursuit signal to cancel the VOR [9]. Thus, a SPEM deficit is generally accompanied by impaired VOR suppression. Usually SPEM are tested with sinusoidal stimuli which only refer to steady state conditions. They are different from the initial 20–40 ms, when SPEM are independent from stimulus parameters. To account for the different motor programs on a neuronal level for SPEM generation, often the step-ramp (Rashbass) paradigm is used. So far, only few clinical studies addressed the question of partial dysfunction in SPEM generation [10]. Both SPEM and saccades are voluntary eye movements. Traditionally they have been considered as two distinct systems. However, it is becoming increasingly evident that both types of eye movements share similar anatomical networks at the cortical and subcortical level. These networks are presumably used for selection processes involving attention, perception, memory and expectation [11]. Optokinetic Response Large moving visual fields (with the head stationary) lead to slow compensatory eye movements. These eye movements are driven by the optokinetic system. During continuous motion of the visual surround, fast resetting eye movements occur, which are basically saccades. The combination of slow compensatory and fast resetting eye movements is called optokinetic nystagmus (OKN), the direction being labeled after the fast phase. Two components can be distinguished in the generation of the slow compensatory phase [12]. One is called the ‘direct’ component, because it occurs directly after the onset of the optokinetic stimulus and is considered to reflect the ocular following response (OFR) [13]. It can best be demonstrated by the rapid increase in slow-phase eye velocity after the sudden presentation of a constant optokinetic stimulus. In contrast, the second component is called the ‘indirect’ component, because it leads to a more gradual increase in slow-phase eye velocity during continuous stimulation. The best demonstration of the ‘indirect’ component alone is optokinetic after-nystagmus (OKAN) – the nystagmus that continues in the dark after the light has been turned off [12]. The ‘indirect’ or ‘velocity storage’ component can be related to concomitant activity changes in the vestibular nuclei [14–16]. There is also some evidence that the ‘direct’ component is more involved in translational optical flow in contrast to rotational optical flow for the ‘indirect’ component [17].
Smooth Pursuit and Optokinetic Nystagmus
77
In birds and lateral-eyed animals (rat, rabbit) the optokinetic response consists almost entirely of the ‘indirect’ component. In the monkey, both components are well developed, and maximal OKN velocities can reach more than 180⬚/s [12, 18]. In contrast, in humans the ‘indirect’ component is often weak (as indicated by OKAN), variable, and sometimes virtually missing [3, 19]. Maximal OKN velocities in the horizontal plane seldom exceed 120⬚/s in humans and can be mainly related to the ‘direct’ component. Clinically, values above 60⬚/s are considered normal [3]. There seems to be some age-related decline in OKN responses for subjects aged ⬎75 years [8]. At constant stimulus velocities below 60⬚/s, the gain (eye/stimulus velocity) is about 0.8 [20]. Responses can still be obtained at sinusoidal stimulation above 1 Hz [21]. OKN is also used to determine residual visual capacities in patients with severe motor and intellectual disabilities [22]. Vertical OKN has been less intensively investigated. In general, vertical OKN is slower than horizontal OKN and upward stimulation is more effective than downward stimulation [23]. At the bedside, normal function can be assumed as long as up and down OKN can be elicited. In the upright body position, vertical OKAN is often missing or only present after upward optokinetic stimulation [23]. With a rotating visual field, also torsional OKN with a low gain (⬍0.2) can be elicited [24, 25].
Ocular Following Response The immediate involuntary response to a large moving visual field is called OFR. OFR in humans can have latencies as short as 60–70 ms, which are shorter than those for SPEM. The size of the visual stimulus and the involuntary character are further features to distinguish these eye movements. The OFR is functionally linked to the translational VOR in contrast to OKN being related to the rotational VOR [26]. Experiments in humans with moving square waves and stimuli, in which the fundamental frequency of the square wave pattern was removed, revealed that the eyes always move in the direction of the strongest Fourier component, which is in the latter case the third harmonic. Under these conditions the eyes can move in the opposite direction (due to the third harmonic) of the movement of the general stimulus pattern [27]. Longer interstimulus intervals can reverse the direction of the OFR [27]. These findings support the hypothesis that visual motion detection for OFR is sensed by low-level (energy-based) rather than feature-based (high-level) mechanisms [28]. The middle temporal visual area (MT) and medial superior temporal visual area (MST) appear to be early cortical stages involved in motion responses [29] and in the initiation of OFR [30].
Büttner/Kremmyda
78
Frontal cortex FEF, SEF
Posterior cortex MT, MST
NRTP
PN
Cerebellum Vermis
Floccular region VPFL (FL)
FOR
MVN, Y group
Motoneurons
Fig. 1. Major SPEM-related structures and their connections. The cortical structures (FEF, SEF, MT, MST) project via pontine structures (NRTP, PN) to the cerebellum [vermis, VPFL (FL)]. From here, activity travels via deep cerebellar nuclei (FOR) and the vestibular nuclei (MVN, Y group) to the oculomotor neurons in the brainstem. The anatomical pathway from the FOR to the motoneurons is not well established (dashed line). There is some evidence that the frontal cortex projects mainly via NRTP to the vermis and the posterior cortex mainly via PN to the FL
Anatomy and Physiology
Smooth Pursuit Eye Movements SPEM are the result of a complex visuo-oculomotor transformation process, which involves many structures at the cortical as well as the cerebellar and brainstem level [31, 32] (fig. 1). Frontal as well parietotemporal areas are involved in smooth pursuit generation. The main areas posterior to the central sulcus are the occipital cortex, the MT, the MST and the parietal cortex. With lesions in the occipital cortex SPEM are abolished in the contralateral hemifield, when step-ramp stimuli are used [33]. However, with sinusoidal stimuli SPEM remain intact due to the use of predictive SPEM properties and the sparing of the macular projection. Area 17 (occipital cortex) projects ipsilaterally to the MT (also called V5). Neurons here have large receptive fields and encode the speed and the direction of moving visual stimuli [34]. In the monkey, small lesions in the extrafoveal part of the MT cause a deficit in SPEM initiation [35]. Based on functional MRI, the MT in humans is located posterior to the superior temporal sulcus at the parieto-temporo-occipital junction (Brodmann areas 19, 37 and 39) [36].
Smooth Pursuit and Optokinetic Nystagmus
79
The MST is adjacent to the MT, from where it receives an input. Also neurons in the MST have large receptive fields and are well suited for the analysis of optic flow [37]. In contrast to the MT, MST neurons can still be active without retinal motion being present [38]. Experimental lesions of the MST produce a SPEM deficit to the ipsilateral side in both visual hemifields [39]. The MST appears to be largely involved in SPEM maintenance, whereas the MT is more involved in SPEM initiation [32]. In man, the homologues of the MT and MST are also adjacent to each other at the occipitotemporoparietal junction. Over the last years, it became increasingly clear that also the frontal eye fields (FEFs) and the supplementary eye field (SEF) in the frontal cortex are involved in SPEM generation. Both structures, FEF and SEF, have been known for their involvement in saccade generation. The SPEM-area of the FEF is anatomically distinct of the saccade area [40]. Lesions in monkeys [41] and humans [42] cause a severe ipsidirectional deficit particularly in predictive aspects of SPEM. Interestingly, optokinetic responses can be preserved [43]. Also the SEF appears to be involved in predictive aspects of SPEM [44]. It has been suggested that SEF is particularly involved in the planning of SPEM [32]. Evidence starts to emerge that also the basal ganglia [45] and the thalamus are involved in SPEM control. Anatomically, it has been shown that both the saccade and the SPEM-related division of the FEF project to separate areas in the caudate nucleus [46]. Also, the saccade and the SPEM-related division of FEF receive different thalamic inputs [47]. Recent single unit studies indicate that the thalamus regulates and monitors SPEM by providing a corollary discharge to the cortex [48]. There is some evidence that FEF projects mainly to the nucleus reticularis tegmenti pontis (NRTP) [49] and MT/MST more strongly to the dorsolateral pontine nuclei (DLPN) [50] (fig. 1). The DLPN projects only to the cerebellum. Here afferents terminate in lobulus VI and VII of the vermis (oculomotor vermis; OV) [51] and the paraflocculus [49]. Neuronal activity in DLPN would preferentially allow a role in maintaining steady-state SPEM [49]. Discrete chemical lesions in DLPN in monkeys produce mainly an ipsilateral SPEM deficit [52]. NRTP projects to the OV [51] and to a lesser degree to the paraflocculus [53]. Neurons here encode primarily eye acceleration, which would indicate a larger role of NRTP in smooth pursuit initiation [49]. In the cerebellar cortex, the floccular region (FL) and OV are most intensively investigated in relation to SPEM. In monkeys, lesions in both the FL [54] and OV [55] lead to SPEM deficits. OV lesions in monkeys lead to a smooth pursuit gain reduction particularly during the first 100 ms (in the open-loop period). Deficits are also seen in humans after OV lesions [56]. The OV projects to the caudal part of the fastigial nucleus (fastigial oculomotor region; FOR) (fig. 1), where lesions also cause a SPEM deficit (to the contralateral side) [57].
Büttner/Kremmyda
80
The FL projects directly to the vestibular nuclei, from where SPEM signals can reach the oculomotor nuclei. It is not quite clear yet, how the SPEM signals from FOR reach the oculomotor nuclei. There is some evidence for two parallel pathways from the cortex for SPEM. The parietotemporal structures (MT, MST) project preferentially to the pontine nuclei, which in turn send afferents to the FL. In contrast, the FEF mainly sends signals via NRTP to the OV and FOR (fig. 1). The functional differences for these two routes at all levels still have to be determined. Optokinetic Nystagmus As outlined above, here only the ‘indirect’ or ‘velocity storage’ component of OKN will be considered. Although the ‘velocity storage’ component can be transmitted solely via brainstem pathways, it is important to remember, that these pathways are under cortical control. Bilateral occipital lesions lead to a loss of optokinetic responses in both humans [58] and monkeys [59]. Fibers from the retina terminate in the brainstem in the nuclei of the accessory optic tract (AOT) and the nucleus of the optic tract (NOT), only the latter being part of the pretectal nuclear complex [60]. Both AOT [61] and NOT [50] receive cortical inputs. Being located in the mesencephalon, they project to more caudal brainstem areas like the pontine nuclei, NRTP, the inferior olive, nucleus prepositus hypoglossi and the vestibular nuclei. Neurons in AOT and NOT have large receptive fields and respond best to large textured stimuli moving in specific directions [62]. It is well known that vestibular nuclei neurons not only respond to vestibular stimulation in the dark but also to large moving visual stimuli that cause OKN [15, 14]. During OKAN, vestibular nuclei activity and slow-phase eye velocity change in parallel. The cerebellum does not appear to play a major role in mediating the ‘indirect’ component of OKN [63]. Cerebellectomy in cat does not greatly affect optokinetic responses. The nodulus and uvula appear to have an inhibitory effect. In the monkey, ablation maximizes the ‘indirect’ component [64]. This lack of inhibition is considered as the cause for periodic alternating nystagmus. Ocular Following Response Single unit recordings and chemical lesion studies indicate that the OFR is mediated by a pathway including the MST, DLPN and the ventral paraflocculus (VPFL), i.e. pathways involved in SPEM. Detailed analysis of the neural activity suggests that the MST locally encodes the dynamic properties of the visual stimulus, whereas the VPFL provides the motor command for OFR [65].
Smooth Pursuit and Optokinetic Nystagmus
81
Disorders
Smooth Pursuit Eye Movements Cortex Both frontal and parietal lesions in patients lead to SPEM deficits [66]. Lesions of the MT region cause a deficit [67] similar to that seen in monkeys [68]. Moving stimuli within the contralateral visual field defect cannot be adequately tracked independent of the movement direction, whereas saccades to the defective area remain intact. In contrast, lesions of the neighboring MST lead to a directional (ipsiversive) deficit independent of the retinal location. Also lesions of the FEF lead to an ipsiversive SPEM deficit [69]. The MT, MST, FEF and SEF project via the internal capsula to the pons. Accordingly, an ipsiversive deficit is also seen after lesions in the internal capsula [70]. Pontine Structures Lesions of the pontine nuclei lead to a predominantly ipsiversive SPEM deficit [71, 72]. However, even bilateral lesions of the pontine nuclei do not abolish SPEM. This might reflect that also the NRTP is involved in SPEM generation. Smooth pursuit deficits in ‘progressive supranuclear palsy’ [73] and spinocerebellar ataxia types 1, 2 and 3 [74] have also been related to lesions of the pontine structures. Cerebellum In the cerebellar cortex, lesions of the OV and the FL lead to SPEM deficits. Patients with cerebellar ataxia and bilateral vestibulopathy show a reduced SPEM gain [75]. A total loss of SPEM is only seen when both structures are lesioned (total cerebellectomy, monkey). In the OV, SPEM- as well as saccade-related neurons are found. Lesions always lead to related deficits [76] (table 1). A bilateral lesion of the OV leads to hypometric saccades and SPEM with a reduced gain. This is also seen in patients [77, 78]. Effects of unilateral lesions have not yet been described in patients. The Purkinje cells of the OV project to the FOR and have an inhibitory effect. Consequently, a bilateral lesion of the FOR leads to hypermetric saccades. This should be combined with an increased SPEM gain (gain ⬎1). In this case, back up instead of catch up saccades should occur during SPEM. However, this pattern is only rarely seen [79] (fig. 2). Still, a patient with a severe hypermetria due to a bilateral FOR lesion showed highly normal values with a SPEM gain close to 1 [80]. Experimental (monkey) unilateral lesions lead to a SPEM gain reduction and hypometric saccades to the contralateral side and normal SPEM and hypermetric saccades to the ipsilateral side [57] (table 1).
Büttner/Kremmyda
82
Table 1. The effect of cerebellar midline lesions and lateral medullary infarction on SPEM and saccades Smooth pursuit unilateral ipsi-
Saccades bilateral
unilateral ipsi-
contra-
⇓
hypo-
hyper-
hypo-
normal
hyper-
hypo-
hyper-
contra-
OV (lobulus VI, VII)
bilateral
FOR
normal
⇓
Rostral cerebellum (cereb. outflow)
⇓
⇓
hypo-
hyper-
Lateral medulla (Wallenberg)
normal
⇓
hyper-
hypo-
In general, a reduced SPEM gain is combined with hypometric saccades. This is not the case for lesions in the rostral cerebellum since not only FOR efferents but also pathways to and from the FL are affected.
T RT 10º H (NORM) LT
H (MUSC)
*
*
* *
*
Fig. 2. Effect of transient inactivation by local muscimol injection in the right FOR on SPEM. T ⫽ Target position; H (NORM) ⫽ horizontal eye position before muscimol injection; H (MUSC) ⫽ horizontal eye position after muscimol injection; RT ⫽ right; LT ⫽ left. During rightward movements, the SPEM gain is ⬎1 and back-up saccades (marked by asterisks) occur. During leftward movements, the smaller gain is corrected by catch-up saccades; from Fuchs et al. [79].
Smooth Pursuit and Optokinetic Nystagmus
83
Efferent pathways from the FOR cross immediately to the other side before they enter the brainstem. Accordingly, patients with a lesion to the rostral cerebellum show saccadic contrapulsion [81], i.e. the reverse pattern of a unilateral FOR lesion. It is usually found with lesions in the territory of the superior cerebellar artery. In this case, saccades to the contralateral side are hypermetric and hypometric to the ipsilateral side. However, SPEM show a low gain in both directions [82] occasionally more pronounced to the ipsilateral side [83]. The reason probably is that lesions of the rostral cerebellum do not only affect the FOR pathways but also the pathways to and from the FL. Lesions of the FL lead to a partial SPEM deficit, more pronounced to the ipsilateral side. In contrast to OV and FOR lesions, the SPEM deficit is usually combined with gaze-evoked nystagmus due to a gaze holding deficit [84]. Medulla The most common ischemic lesion of the brainstem is the lateral medulla infarction (Wallenberg’s syndrome); in patients, it always (100%) leads to oculomotor deficits [85]. This includes a SPEM deficit to the contralateral side [86]. As pointed out above for OV and FOR lesions, also this deficit corresponds with hypometric saccades to the contralateral side (table 1). It is postulated that this deficit is caused by interruption of olivocerebellar pathways after their crossing in the medulla [87, 88] (fig. 3).
Optokinetic Nystagmus For patients, there are no good methods available to test the ‘indirect’ component of OKN in isolation. One possible method would be to test their OKAN. However, even in normals OKAN can be missing [19]. On the bedside, usually a handheld optokinetic cylinder is rotated for several seconds in one direction. This however only activates the ‘direct’ (smooth pursuit-related) component, since the time is not sufficient to provide a substantial contribution of the ‘indirect’ component [16]. When optokinetic stimuli are used, a side difference of up to 20⬚/s for the maximal velocity is still considered normal [89]. Pathological side differences are more obvious with the use of smaller stimuli [90]. For the monkey, it could be shown that mesencephalic lesions in the pretectum lead to a reduction in the ‘indirect’ component to the ipsilateral side. Also the OKAN in this direction is missing or reduced [91]. There is also some evidence that in addition pretectal lesions can affect the ‘direct’ component [92]. Clinical reports on this topic are still missing.
Büttner/Kremmyda
84
Vermis
FN
? VN PPRF
Floccular region Climbing fiber
IO
Fig. 3. Schematic drawing of the climbing fiber pathway from the medulla (lower part) to the cerebellar cortex (vermis). It originates in the inferior olive (IO) and is interrupted by lateral medullary infarction (shaded area). The lesions causes disinhibition of Purkinje cell simple spike resting activity in the vermis, and as a consequence increased inhibition in the FN. The resulting SPEM and saccade deficits are shown in table 1; from Helmchen et al. [88].
References 1 2 3 4
Robinson DA: The mechanics of human smooth pursuit eye movements. J Physiol 1965;180: 569–591. Morris EJ, Lisberger SG: Different responses to small visual errors during initiation and maintenance of smooth-pursuit eye movements in monkeys. J Neurophysiol 1987;58:1351–1369. Simons B, Büttner U: The influence of age on optokinetic nystagmus. Eur Arch Psychiatry Neurol Sci 1985;234:369–373. Lisberger SG, Miles FA, Optican LM, Eighmy BB: Optokinetic response in monkey: underlying mechanisms and their sensitivity to long-term adaptive changes in vestibuloocular reflex. J Neurophysiol 1981;45:869–890.
Smooth Pursuit and Optokinetic Nystagmus
85
5 6 7 8 9 10 11 12 13 14 15 16 17
18 19 20 21 22
23 24
25 26 27 28 29
30
Robinson DA: The use of control systems analysis in the neurophysiology of eye movements. Ann Rev Neurosci 1981;4:463–503. Morrow MJ, Sharpe JA: Smooth pursuit initiation in young and elderly subjects. Vision Res 1993;33:203–310. Phillips JO, Finocchio DV, Ong L, Fuchs AF: Smooth pursuit in 1- to 4-month-old infants. Vision Res 1997;37:3009–3020. Kerber KA, Ishiyama GP, Baloh RW: A longitudinal study of oculomotor function in normal older people. Neurobiol Aging 2006;27:1346–1353. Leigh RJ, Zee DS: The Neurology of Eye Movements. Oxford University Press, New York, 2006. Thurston SE, Leigh RJ, Crawford T, Thompson A, Kennard C: Two distinct deficits of visual tracking caused by unilateral lesions of cerebral cortex in humans. Ann Neurol 1988;23:266–273. Krauzlis RJ: The control of voluntary eye movements: new perspectives. Neuroscientist 2005;11: 124–137. Cohen B, Matsuo V, Raphan T: Quantitative analysis of the velocity characteristics of optokinetic nystagmus and optokinetic after-nystagmus, J Physiol 1977;270:321–344. Miles FA: The neural processing of 3-D visual information: evidence from eye movements. Eur J Neurosci 1998;10:811–822. Waespe W, Henn V: Neuronal activity in the vestibular nuclei of the alert monkey during vestibular and optokinetic stimulation. Exp Brain Res 1977;27:523–538. Waespe W, Henn V: Vestibular nuclei activity during optokinetic after-nystagmus (OKAN) in the alert monkey. Exp Brain Res 1977;30:323–330. Boyle R, Büttner U, Markert G: Vestibular nuclei activity and eye movements in the alert monkey during sinusoidal optokinetic stimulation. Exp Brain Res 1985;57:362–369. Miles FA: The sensing of rotational and translational optic flow by the primate optokinetic system; in Miles FA, Wallman J (eds): Visual Motion and Its Role in the Stabilization of Gaze. Amsterdam, London, New York, Tokyo, Elsevier, 1993, pp 393–403. Büttner U, Meienberg O, Schimmelpfennig B: The effect of central retinal lesions on optokinetic nystagmus in the monkey. Exp Brain Res 1983;52:248–256. Waespe W, Henn V: Conflicting visual-vestibular stimulation and vestibular nucleus activity in alert monkeys. Exp Brain Res 1978;33:203–211. van-den-Berg AV, Collewijn H: Directional asymmetries of human optokinetic nystagmus. Exp Brain Res 1988;70:597–604. Barnes GR: Visual-vestibular interaction in the control of head and eye movement: the role of visual feedback and predictive mechanisms. Prog Neurobiol 1993;41:435–472. Sakai S, Hirayama K, Iwasaki S, Yamadori A, Sato N, Ito A, Kato M, Sudo M, Tsuburaya K: Contrast sensitivity of patients with severe motor and intellectual disabilities and cerebral visual impairment. J Child Neurol 2002;17:731–737. Murasugi CM, Howard IP: Updown asymmetry in human vertical optokinetic nystagmus and afternystagmus: contributions of the central and periphral retinae. Exp Brain Res 1988;77:183–192. Collewijn H, Van-der-Steen J, Ferman L, Jansen TC: Human ocular counterroll: assessment of static and dynamic properties from electromagnetic scleral coil recordings. Exp Brain Res 1985;59:185–196. Van-Rijn LJ, Van-der-Steen J, Collewijn H: Visually induced cycloversion and cyclovergence. Vision Res 1992;32:1875–1883. Adeyemo B, Angelaki DE: Similar kinematic properties for ocular following and smooth pursuit eye movements. J Neurophysiol 2005;93:1710–1717. Chen KJ, Sheliga BM, Fitzgibbon EJ, Miles FA: Initial ocular following in humans depends critically on the Fourier components of the motion stimulus. Ann N Y Acad Sci 2005;1039:260–271. Sheliga BM, Chen KJ, Fitzgibbon EJ, Miles FA: Initial ocular following in humans: a response to first-order motion energy. Vision Res 2005;45:3307–3321. Maunsell JH, Nealey TA, DePriest DD: Magnocellular and parvocellular contributrions to responses in the middle temporal visual area (MT) of the macaque monkey. J Neurosci 1990;10:3323–3334. Takemura A, Inoue Y, Kawano K: Visually driven eye movements elicited at ultra-short latency are severely impaired by MST lesions. Ann NY Acad Sci 2002;956:456–459.
Büttner/Kremmyda
86
31 32 33 34
35
36
37 38 39 40
41 42 43 44 45 46 47 48 49 50
51
52 53 54
Thier P, Ilg UP: The neural basis of smooth-pursuit eye movements. Curr Opin Neurobiol 2005;15:1–8. Krauzlis RJ: Recasting the smooth pursuit eye movement system. J Neurophysiol 2004;91: 591–603. Segraves MA, Goldberg JM, Deng SY, Bruce CJ, Ungerleider LG, Mishkin M: The role of striate cortex in the guidance of eye movements in the monkey. J Neurosci 1987;7:3040–3058. Maunsell JHR, Van Essen DC: Functional properties of neurons in middle temporal visual area of the macaque monkey. I. Selectivity for stimulus direction, speed, and orientation. J Neurophysiol 1983;49:1127–1147. Newsome WT, Wurtz RH, Dürsteler MR, Mikami A: Deficits in visual motion processing following ibotenic acid lesions of the middle temporal visual area of the macaque monkey. J Neurosci 1985;5:825–840. Watson JD, Myers R, Frackowiak RS, Hajnal JV, Woods RP, Mazziotta JC, Shipp S, Zeki S: Area V5 of the human brain: evidence from a combined study using positron emission tomography and magnetic resonance imaging. Cereb Cortex 2004;3:79–94. Duffy CJ, Wurtz RH: Planar directional contributions to optic flow responses in MST neurons. J Neurophysiol 1997;77:782–796. Ilg UJ, Thier P: Visual tracking neurons in primate area MST are activated by smooth-pursuit eye movements of an ‘imaginary’ target. J Neurophysiol 2003;90:1489–1502. Dürsteler MR, Wurtz RH: Pursuit and optokinetic deficits following chemical lesion of cortical areas MT and MST. J Neurophysiol 1988;60:940–965. Tanaka M, Lisberger SG: Role of acurate frontal cortex of monkeys in smooth pursuit eye movements. I. Basic response properties to retinal image motion and position. J Neurophysiol 2002;87:2684–2699. Shi D, Friedman HR, Bruce CJ: Deficits in smooth-pursuit eye movements after muscimol inactivation within the primate’s frontal eye field. J Neurophysiol 1998;80:458–464. Morrow MJ, Sharpe JA: Deficits of smooth-pursuit eye movement after unilateral frontal lobe lesions. Ann Neurol 1995;37:443–451. Keating EG, Pierre A, Chopra S: Ablation of the pursuit area in the frontal cortex of the primate degrades foveal but not optokinetic smooth eye movements. J Neurophysiol 1996;76:637–641. Heinen SJ, Liu M: Single-neurons activity in the dorsomedial frontal cortex during smooth-pursuit eye movements to predictable target motion, Vis Neurosci 1997;14:853–865. Basso MA, Pokorny JJ, Liu P: Activity of substantia nigra pars reticulata neurons during smooth pursuit eye movements in monkeys. Eur J Neurosci 2005;22:448–464. Cui DM, Yan YJ, Lynch JC: Pursuit subregion of the frontal eye field projects to the caudate nucleus in monkeys. J Neurophysiol 2003;89:2678–2684. Tian J-R, Lynch JC: Subcortical input to the smooth and saccadic eye movement subregions of the frontal eye field in Cebus monkey. J Neurosci 1997;17:9233–9247. Tanaka M: Involvement of the central thalamus in the control of smooth pursuit eye movements. J Neurosci 2005;25:5866–5876. Ono S, Das VE, Economides JR, Mustari MJ: Modeling of smooth pursuit-related neuronal responses in the DLPN and NRTP of the Rhesus Macaque. J Neurophysiol 2005;93:108–116. Distler C, Mustari MJ, Hoffmann KP: Cortical projections to the nucleus of the optic tract and dorsal terminal nucleus and to the dorsolateral pontine nucleus in macaques: a dual retrograde tracing study. J Comp Neurol 2002;444:144–158. Thielert CD, Thier P: Patterns of projections from the pontine nuclei and the nucleus reticularis tegmenti pontis to the posterior vermis in the rhesus monkey – a study using retrograde tracers. J Comp Neurol 1993;337:113–126. May JG, Keller EL, Suzuki DA: Smooth-pursuit eye movement deficits with chemical lesions in the dorsolateral pontine nucleus of the monkey. J Neurophysiol 1988;59:952–977. Glickstein M, Gerrits N, Kralj-Hans I, Mercier B, Stein J, Voogd J: Visual pontocerebellar projections in the macaque. J Comp Neurol 1994;349:51–72. Zee DS, Yamazaki A, Butler PH, Gücer G: Effects of ablation of flocculus and paraflocculus on eye movements in primates. J Neurophysiol 1981;46:878–899.
Smooth Pursuit and Optokinetic Nystagmus
87
55 56 57 58 59 60 61
62 63 64 65 66 67 68 69 70 71 72 73
74
75 76 77 78
79
Takagi M, Zee DS, Tamargo RJ: Effects of lesions of the oculomotor cerebellar vermis on eye movements in primate: smooth pursuit. J Neurophysiol 2000;83:2047–2062. Vahedi K, Rivaud S, Amarenco P, Pierrot-Deseilligny C: Horizontal eye movement disorders after posterior vermis infarctions. J Neurol Neurosurg Psychiatry 1995;58:91–94. Robinson FR, Straube A, Fuchs AF: Participation of caudal fastigial nucleus in smooth pursuit eye movements. II. Effects of muscimol inactivation. J Neurophysiol 1997;78:848–859. Verhagen W, Huygens P, Mulleners W: Lack of optokinetic nystagmus and visual motion perception in acquired cortical blindness. Neuro-ophthalmol 1997;17:211–216. Zee DS, Tusa RJ, Herdman SJ, Butler PH, Gücer G: Effects of occipital lobectomy upon eye movements in primate. J Neurophysiol 1987;58:883–907. Simpson JI, Giolli RA, Blanks RHI: The pretectal nuclear complex and the accessory optic system. Rev Oculomot Res 1988;2:335–364. Blanks RHI, Giolli RA, van der Wandt JJL: Neuronal circuitry and neurotransmitters in the pretectal and accessory optic systems; in Beitz AJ, Anderson JH (eds): Neurochemistry of the Vestibular System. Boca Raton, FL, CRC Press, 2000, pp 303–328. Ilg UJ, Hoffmann KP: Responses of neurons of the nucleus of the optic tract and the dorsal terminal nucleus of the accessory optic tract in the awake monkey. Eur J Neurosci 1996;8:92–105. Waespe W, Henn V: Gaze stabilization in the primate. The interaction of the vestibulo-ocular reflex, optokinetic nystagmus, and smooth pursuit. Rev Physiol Biochem Pharmacol 1987;106:37–125. Waespe W, Cohen B, Raphan T: Dynamic modification of the vestibulo-ocular reflex by the nodulus and uvula. Science 1985;228:199–202. Takemura A, Kawano K: Sensory-to-motor processing of the ocular-following response. Neurosci Res 2002;43:201–206. Heide W, Kurzidim K, Kömpf D: Deficits of smooth pursuit eye movements after frontal and parietal lesions. Brain 1996;119:1951–1969. Leigh RJ: The cortical control of ocular pursuit movements. Rev Neurol (Paris) 1989;145:605–612. Newsome WT, Wurtz RH: Probing visual cortical function with discrete chemical lesions. Trends Neurosci 1988;11:393–399. Rivaud S, Müri RM, Gaymard B, Vermersch AI, Pierrot-Deseilligny C: Eye movement disorders after frontal eye field lesions in humans. Exp Brain Res 1994;102:110–120. Brigell M, Babikian V, Goodwin JA: Hypometric saccades and low-gain pursuit resulting from a thalamic hemorrhage. Ann Neurol 1984;15:374–378. Gaymard B, Pierrot-Deseilligny C, Rivaud S, Velut S: Smooth pursuit eye movement deficits after pontine nuclei lesions in humans. J Neurol Neurosurg Psychiatry 1993;56:799–807. Thier P, Bachor A, Faiss J, Dichgans J, Koenig E: Selective impairment of smooth-pursuit eye movements due to an ischemic lesion of the basal pons. Ann Neurol 1991;29:443–448. Malessa S, Gaymard B, Rivaud S, Cerevera P, Hirsch E, Verny M, Duyckaerts C, Agid Y, .PierrotDeseilligny C: Role of pontine nuclei damage in smooth pursuit impairment of progressive supranuclear palsy: a clinical-pathologic study. Neurology 1994;44:716–721. Rüb U, Bürk K, Schöls L, Brunt ER, de Vos RAI, Orozco Diaz G, Gierga K, Ghebremedhin E, Schultz C, Del Turco D, Mittelbronn M, Auburger G, Deller T, Braak H: Damage to the reticulotegmental nucleus of the pons in spinocerebellar ataxia type 1,2 and 3. Neurology 2004;63:1258–1263. Migliaccio AA, Halmagyi GM, McGarvie LA, Cremer PD: Cerebellar ataxia with bilateral vestibulopathy: description of a syndrome and its characteristic clinical sign. Brain 2004;127:280–293. Büttner U, Straube A: The effect of cerebellar midline lesions on eye movements. Neuro-ophthalmol 1995;15:75–82. Pierrot-Deseilligny C, .Amarenco P, Roullet E, Marteau R: Vermal infarct with pursuit eye movement disorders. J Neurol Neurosurg Psychiatry 1990;53:519–521. Thier P, Herbst H, Thielert C-D, Erickson RG: A cortico-ponto-cerebellar pathway for smoothpursuit eye movements; in Delgado-Garcia JM, Godaux E, Vidal P-P (eds): Information Processing Underlying Gaze Control. Oxford, Pergamon, 1994, pp 237–249. Fuchs AF, Robinson FR, Straube A: Preliminary observations on the role of the caudal fastigial nucleus in the generation of smooth-pursuit eye movements; in Fuchs AF, Brandt T, Büttner U, Zee D (eds): Contemporary Ocular Motor and Vestibular Research: A Tribute to David A. Robinson. Stuttgart, Georg Thieme Verlag, 1994, pp 165–170.
Büttner/Kremmyda
88
80 81 82
83 84 85 86 87 88 89
90
91 92
Büttner U, Straube A, Spuler A: Saccadic dysmetria and ‘intact’ smooth pursuit eye movements after bilateral deep cerebellar nuclei lesions. J Neurol Neurosurg Psychiatry 1994;57:832–834. Ranalli PJ, Sharpe JA: Contrapulsion of saccades and ipsilateral ataxia: a unilateral disorder of the rostral cerebellum. Ann Neurol 1986;20:311–316. Uno A, Mukuno K, Sekiya H, Ishikawa S, Suzuki S, Hata T: Lateropulsion in Wallenberg’s syndrome and contrapulsion in the proximal type of the superior cerebellar artery syndrome. Neuroophthalmol 1989;9:75–80. Straube A, Büttner U: Pathophysiology of saccadic contrapulsion in unilateral rostral cerebellar lesions. Neuro-ophthalmol 1994;1:3–7. Büttner U, Grundei T: Gaze-evoked nystagmus and smooth pursuit deficits: their relationship studied in 52 patients. J Neurol 1995;242:384–389. Norrving B, Cronqvist S: Lateral medullary infarction: prognosis in an unselected series. Neurology 1991;41:244–248. Kommerell G, Hoyt WF: Lateropulsion of saccadic eye movements. Arch Neurol 1973;28: 313–318. Waespe W, Wichmann W: Oculomotor disturbances during visual-vestibular interaction in Wallenberg’s lateral medullary syndrome. Brain 1990;113:821–846. Helmchen C, Straube A, Büttner U: Saccadic lateropulsion in Wallenberg’s syndrome may be caused by a functional lesion of the fastigial nucleus. J Neurol 1994;241:421–426. Jung R, Kornhuber HH: Results of electronystagmography in man: the value of optokinetic, vestibular and spontaneous nystagmus for neurological diagnosis and research; in Bender MB (ed): The Oculomotor System. New York, Harper & Row, 1964, pp 428–488. Dichgans J, Kolb B, Wolpert E: Provokation optokinetischer Seitendifferenzen durch Einschränkung der Reizfeldbreite und ihre Bedeutung für die Klinik. Arch Psychiatr Nervenkr 1974;219:117–131. Schiff D, Cohen B, Büttner-Ennever J, Matsuo V: Effects of lesions of the nucleus of the optic tract on optokinetic nystagmus and after-nystagmus in the monkey. Exp Brain Res 1990;79:225–239. Mustari MJ, Fuchs AF, Kaneko CRS, Robinson FR, Kaneko CR: Anatomical connections of the primate pretectal nucleus of the optic tract. J Comp Neurol 1994;349:111–128.
Prof. Dr. U. Büttner Department of Neurology Klinikum Grosshadern, Marchioninistrasse 15 DE–81377 Munich (Germany) Tel. ⫹49 89 7095 2560, Fax ⫹49 89 7095 5561, E-Mail
[email protected]
Smooth Pursuit and Optokinetic Nystagmus
89
Straube A, Büttner U (eds): Neuro-Ophthalmology. Dev Ophthalmol. Basel, Karger, 2007, vol 40, pp 90–109
Disconjugate Eye Movements Dominik Straumann Neurology Department, Zurich University Hospital, Zurich, Switzerland
Abstract To foveate targets in different depths, the movements of the two eyes must be disconjugate. Fine measurements of eye rotations about the three principal axes have demonstrated that disconjugate eye movements may appear not only in the horizontal, but also in the vertical and torsional directions. In the presence of visual targets, disconjugate eye movements are driven by the vergence system, but they may also appear during vestibular stimulation. Disconjugate eye movements are highly adaptable by visual disparities, but under normal condition the effects of adaptation only persist when one eye is covered. Finally, disorders of the brainstem and cerebellum may lead to abnormal disconjugate eye movements that are often specific for the topography of the lesion. This chapter reviews the literature on the phenomenology of disconjugate eye movements over the last 15 years. Copyright © 2007 S. Karger AG, Basel
The goal of normal disconjugate eye movements is to direct the corresponding retinal points of the two eyes to a visual object that is nearer or farther than the previous object. Such vergence movements can also be smooth when the object of interest moves slowly in depth. Both disparity and accommodation-vergence synkinesis can drive vergence movements. Recently, it has also been shown that perceived depth alone elicits vergence eye movements [1]. Geometrically, binocular movements are disconjugate, if amplitude and/or direction are unequal for both eyes. Considering the full kinematics of eye rotations, the term ‘direction’ includes ocular rotation about the line of sight, which is an important degree of freedom to ensure extrafoveal retinal correspondence. If one takes into account the rigid geometric specifications for 3-D – i.e. horizontal, vertical, and torsional – binocular rotations, it is not surprising that normal eye movements are generally disconjugate when subjects view near targets. As we shall see, even eye movements for foveation of targets at infinity exhibit some disconjugacy due to neural and mechanical factors.
This paper reviews the literature on the phenomenology, including pathophenomenology, of disconjugate eye movements over the last 15 years.
Horizontal Vergence Movements
Under natural viewing conditions, horizontal vergence movements are usually dysmetric, i.e. moving gaze from a near to a far target leads to excessive convergence, and moving gaze from a far to a near target to insufficient convergence [2]. The degree of this physiological vergence weakness can be reduced by increased attention [3] and instruction [4], but vergence is always less precise than version [5]. In subjects with strong monocular preference, vergence movements are typically associated with small horizontal saccades [6]. Upon symmetric step stimulation with horizontal disparity, convergence is usually faster than divergence [7]. While the dynamics of convergence movements is independent of target location, divergence movements become faster the closer the initial target is to the eyes [8]. When visual feedback is eliminated during vergence, the position trajectories are step-like, not smooth. This openloop response consists of a pulse-like or transient component and a step-like or sustained component [9, 10]. While both components are adaptable, only the pulse-like component influences the dynamics of the adapted vergence response [11]. Experiments eliciting vergence movements by velocity steps of horizontal disparities suggest that the vergence open-loop response may originate from monocular visual pathways [12]. Disparity-driven convergence eye movements frequently show large asymmetries, which vary from trial to trial and are usually compensated in the later phase of the convergence movement [13]. While this later phase probably uses visual feedback, the initial phase seems to be preprogrammed [14]. The occasional appearance of two closely spaced high-velocity vergence movements in response to disparity supports the notion that the initial vergence component is evoked by an internal, not visual, feedback mechanism that is switched on and off, analogous to the saccadic system [15, 16]. Small or large dichoptic displays that are counterphasically oscillated in the horizontal direction elicit dynamic convergence/divergence [17]. Brief horizontal (or vertical) disparity steps of 2⬚ or less evoke short-latency vergence movements, which are enhanced when the stimulus is presented shortly after a saccade [18–20]. Similar vergence movements with short latencies are also driven by radial flow [21]. When vergence movements with or without accompanying saccades are elicited with a gap period before target onset, vergence latency decreases significantly [22].
Disconjugate Eye Movements
91
Vertical Vergence Movements
A vertical prism placed in front of one eye induces divergent eye movements in the vertical direction. Training with vertical prisms can increase the vertical fusional amplitude, predominantly by enhancing the motor, not the sensory component [23]. The motor capability to fuse vertical disparities increases with convergence. This increase is due to the motor component, while the sensory component for far and near viewing is practically the same [24]. Similarly, skew deviation associated with static counterroll (intorting eye hypertropic) increases with convergence [25]. Vertical fusion is accompanied by conjugate torsion toward the higher eye [26], a pattern that qualitatively resembles the one seen in patients with dissociated vertical deviation [27]. Whether the binocular torsion associated with vertical fusion is mediated by the superior oblique muscles (SO) [26] or is of central origin [28] remains to be answered. 3-D eye movement trajectories during vertical fusion suggest that patients with congenital trochlear nerve palsy use predominantly the vertical recti, while patients with acquired trochlear nerve palsy show various patterns of vertical and oblique eye muscle activations [29]. Dichoptic counterphasic oscillation of displays in the vertical direction elicits vertical vergence [30]. These movements show increased gain and reduced phase lag with larger stimulus diameter, which contrasts horizontal dichoptic display oscillation, in which display diameter is less important [31].
Cyclovergence
Spontaneous fluctuation of torsional eye position is generally conjugate, i.e. cyclovergence is considerably more stable than cycloversion [32]. Opposite cyclorotation of the images presented to the two eyes evokes static cyclovergence, which adds to the eye position-dependent cyclovergence [33]. The latter results from the outward rotations of Listing’s planes during convergence (see below). Dynamic cyclovergence can be elicited by fusible visual patterns projected to each eye separately and oscillated out of phase in the frontal plane [34, 35]. The gain of dynamic cyclovergence is highest for low frequencies and low amplitudes and therefore is appropriate to correct for drifts in binocular stereoscopic alignment, which are both slow and small [35]. Occlusion of the central area does not influence the gain of cyclovergence, although the gain of cycloversion decreases [36].
Straumann
92
␣
␣/4
␣/4
Fig. 1. Top view of binocular Listing’s planes during far (left) and near (right) viewing. Each Listing’s plane rotates temporally by a quarter of the vergence angle (␣).
Listing’s Law during Convergence
For the following considerations, eye positions need to be described threedimensionally with a horizontal, vertical, and torsional component. Since rotations are noncommutative, the most convenient conventions, such as rotation vectors or quaternion vectors, express every eye position as a single axis rotation from a reference position. Accordingly, vergence is then defined as the rotation that transforms the left eye position into the right eye position [37]. Rotation or quaternion vectors hold a specific 3-D orientation in the head. Listing’s law states that, in the absence of dynamic vestibular stimulation, these 3-D vectors all lie in one plane, so-called Listing’s plane. In the absence of convergence, the Listing’s planes of the two eyes are relatively parallel and oriented approximately frontal. With convergence the planes rotate outward [38–41], i.e. they ‘swing out like saloon doors’ [42]. In other words, the primary positions of the two eyes diverge during convergence [43]. Among the cited studies, the angle of the outward rotation of the Listing’s planes varies considerably and amounts roughly to about 1/4 (range: 0.16–0.43) of the convergence angle (fig. 1). An explanation of why the Listing’s planes rotate outward during convergence has to consider both visual and motor variables [44]. Tweed [45] proposed a most compelling hypothesis that is based on an optimal compromise between visual and motor variables: The visual variable is the maximal alignment of images in the visual plane on the two retinas irrespective of gaze direction; the motor variable is to keep rotation about the line of sight as close as possible to the zero vergence primary position. Since the amount of cyclovergence varies with gaze elevation when the Listing’s planes are rotated outward, stereograms that critically depend on the relative torsional orientation of the two retinas are only visible at a specific gaze elevation [46]. Hence, ocular motor control plays an important role in depth vision.
Disconjugate Eye Movements
93
MR images demonstrate that rectus pulleys in converging eyes are slightly extorted [47]. The outward rotation of Listing’s plane, however, cannot be explained by this change of the rectus pulleys and therefore must be due to variations of oblique muscle innervations. The convergence-induced outward rotation of Listing’s planes does not depend on whether convergence is induced by a stereogram, a horizontal prism, or an accommodative stimulus [48–50]. The orientation of Listing’s planes can, however, be modified by phoria adaptation (see below). Vergence movements with the eyes at various elevations lead to different torsional components that can be explained by the vergence-modulated orientation of Listing’s plane [41]. Accordingly, during pure vergence movements with gaze elevated or depressed, the eyes rotate about an axis which is orthogonal to the gaze direction [51]. This is different from the orientation of rotation axes during saccades, which tilt in the direction of gaze by only half the gaze angle [52]. During asymmetric vergence movements, e.g. when foveating a target moving along the line of sight of one eye, monocular torsion is less stable than cyclovergence and varies between convergence and divergence [53, 54]. Pitch head impulses while the eyes are converging on a near target in front of one eye lead to torsional movement components in both the adducting and the straight ahead viewing eye [55]. This effect corresponds to a modification of ocular rotation axes due to the convergence-induced outward rotation of Listing’s planes. The Listing’s planes in patients with acquired trochlear nerve palsy are not symmetric; the plane of the affected eye is rotated outward, as if this eye were converging [56]. In congenital trochlear nerve palsy, the orientation of Listing’s plane of the affected eye is normal; thus, congenital trochlear nerve palsy is not due to changed function of a single extraocular eye muscle [56]. In patients with acquired or congenital trochlear nerve palsy, Listing’s plane of the affected eye does not rotate temporally upon convergence. This finding suggests an important role of the SO in modifying the orientation of Listing’s plane as a function of vergence [57]. In patients with acute trochlear nerve palsy, Listing’s law is violated by the affected eye during downward saccades; this eye shows dynamic extorsion as a result of the missing agonistic action of the SO [58]. In patients with central abducens nerve palsy, Listing’s law is violated by both eyes, while in patients with peripheral abducens nerve palsy, Listing’s law is violated by the paretic eye and in the acute state only [59]. Compared to healthy subjects, patients with intermittent horizontal strabismus exhibit a similar, but more variable relation between vergence angle and angle between the Listing’s planes [60]. In patients with intermittent exotropia, vertical gaze-dependent cyclovergence is increased, possibly because additional convergence is required to cancel the exodeviation between the two eyes [61].
Straumann
94
Symmetric
Asymmetric
Fig. 2. Top view of both eyes during symmetric and asymmetric convergence movements. The visual target moves from far to near (arrow).
In a stereoblind patient with strabismus, the Listing’s planes of the two eyes were normal in shape, i.e. relatively planar, but changed their orientation depending on which eye was fixating [62]. This effect was most probably due to accommodation-induced vergence.
Asymmetric Vergence Movements and Hering’s Law
Hering’s law of equal innervation implies that equal version and vergence commands are sent to both eyes and that the binocular motor output represents the sum of the two signals. The analysis of asymmetric vergence movements (fig. 2) can give some indication whether Hering’s law holds [63, 64] or whether the two eyes are independently controlled, as advocated by Helmholtz [65, 66]. As we will see, there are arguments for both theories. During static convergence on a target in front of one eye, i.e. asymmetric convergence, only the inferior oblique muscle contracts in this eye, as demonstrated with MRI; contraction of the same muscle, apart from contractile changes in the lateral and medial rectus muscles, is also seen in the fellow eye, which is directed inward [47]. During rapid gaze shifts along the line of sight of one eye, which calls for asymmetric vergence, the horizontal peak accelerations of the two eyes are similar, despite different position trajectories [67]. This finding suggests equal saccadic pulses for each eye, according to Hering’s law, together with an additional vergence signal. After human subjects were trained to have a vertical vergence component during symmetric horizontal vergence, the vertical vergence component could also be demonstrated during smooth pursuit of targets in depth both along the line of sight of one eye [68]. Thus symmetric smooth pursuit seems to be combined with vergence to produce
Disconjugate Eye Movements
95
asymmetric slow eye movements, which speaks against monocular control of these movements. Some subjects are able to initiate smooth asymmetrical ‘saccade-free’ convergence movements when changing gaze from a far to a near target [69]. Thus, during binocular viewing, the ocular motor system is able to generate eye movements that do not adhere to Hering’s law of equal innervation. Similarly, the initial monocular smooth pursuit response to a target that moves in depth solely depends on target motion and is independent of the response of the other eye [70]. The firing rate of abducens motoneurons for a given eye position is higher with than without convergence, but, paradoxically, lateral rectus force (and similarly medial rectus force) is not increased [70a]. This finding still awaits an explanation. A reanalysis of single neuron recordings during eye movements that included vergence revealed that neural signals in abducens motoneurons, abducens interneurons, and medial rectus motoneurons encode the position of both eyes, not just one eye [71]. On the other hand, premotor neurons in the paramedian pontine reticular formation encode saccadic velocity signals for only one eye, not both [72]. These findings speak against a neural implementation of Hering’s law.
Saccade-Associated Vergence Movements
Peak vergence velocity increases when vergence is combined with a saccade, an effect that is more pronounced in divergence than convergence [73]. Vice versa, when saccades occur with vergence movements, the peak velocity of the saccades is reduced, more prominently so with convergence than divergence [74]. These findings suggest a nonlinear interaction between conjugate and disconjugate premotor systems; the omnipause neurons probably represent the crucial neural structure for gating saccade-related horizontal vergence [75]. This would also explain why saccadic oscillations occur, when saccades end during ongoing vergence [76–78]. Note that even horizontal and vertical saccades between far targets are associated with small transient vergence components, but these are probably related to mechanical differences between adducting and abducting muscles [75, 79]. Horizontal saccades also produce small torsional transients out of Listing’s plane, which are not equal in amplitude; hence, the eyes cycloverge somewhat shortly after the beginning of each saccade [80]. Saccades in patients with one deeply amblyopic eye are nonconjugate, i.e. Hering’s law seems to rely on intact binocular vision [81]. Subjects with anisometropic spectacles show saccades with different amplitudes in both eyes and
Straumann
96
asymmetric postsaccadic drift [82]. When saccades are made between targets at different distances, a presaccadic vergence movement along the isovergent line of the initial target appears [83]. This observation speaks for separate version and vergence channels contributing to fast eye displacements. A similarly strong coupling between version and vergence is found during incorrect saccades evoked by two targets appearing simultaneously in 3-D space [84]. Conversely, when targets are placed at closer distances from the eyes, no presaccadic convergence and only a small presaccadic divergence is observed, and postsaccadic vergence is usually asymmetric [85]. The latter finding speaks against a balanced interaction between the vergence and version systems during the saccade, and therefore against a Hering-type implementation of such movements. Such saccades are dominated by one eye, so that a least one of the two eyes is on target in time. Binocular vertical displacements between near targets in front of one eye require different vertical amplitudes of each eye to maintain binocular alignment. In downward movements, a major portion of the required disconjugacy takes place during the saccades, while in upward movements the intrasaccadic portion amounts to about half [86]. Dynamic dissociations between saccadic and vergence movements can also be observed during vertical saccades between targets in the midsagittal plane at different depth [87].
Binocular Adaptation
Phoria Adaptation Normal binocular fixation of a near target in a tertiary position requires a vertical vergence component, when eye positions are expressed in a head-fixed coordinate system. This component appears to be independent of whether subjects are viewing monocularly or binocularly [88]. Eight hours of monocular occlusion leads to excyclophoria and hyper- or hypophoria [89]. If an eye is covered and passively rotated away from the position of the fellow eye with a scleral suction lens during a few minutes, ocular misalignment persists up to 10 min or until binocular viewing is permitted [90]. When short-term phoria adaptation is performed with a vertical disparity at a single location, phoria becomes uniform for all gaze directions. Upon two vertical disparities at opposite gaze directions and with opposite sign, adapted phoria shows a gradient along the line between the two stimuli [91, 92]. Phoria adaptation to opposite vertical disparities is also effective along the depth axis [93] or to multiple vertical disparities at different near and far locations [94]. Human subjects are also able to adapt vertical phoria to different prism-induced vertical disparities that vary with head position [95] or with head and gaze
Disconjugate Eye Movements
97
position [96]. When monkeys are trained to synchronize vergence eye movements in synchrony with vestibularly evoked eye movements upon pitch oscillations, these oscillations evoked vergence eye movements even in the dark [97, 98]. Adaptation to discrete increments of refraction along a horizontal prism is also possible, but adapted vergence changes only gradually when crossing the prism edges [99]. After 30–150 s of cyclovergence evoked by incyclo- or excyclodisparity, the eyes do not tort back to their previous torsional positions, even in the presence of a visual stimulus [100]. Most likely, this torsional hysteresis is the result of fast phoria adaptation. Phoria adaptation with a vertical prism over one eye is often impaired in patients with cerebellar disease. Thus the cerebellum seems to be decisively involved in phoria adaptation [101]. Adaptation of Listing’s Plane Three days of vertical disparity with prisms induces, besides vertical phoria, reorientations of Listing’s planes; Listing’s plane of the higher eye is rotated up and Listing’s plane of the lower eye rotated down [102]. Phoria adaptation to different cyclodisparities along the vertical axis also modifies the orientation of Listing’s planes [103]. Binocular Saccade Adaptation Intrasaccadic displacement of a visual target leads to rapid binocular saccade adaptation. If the displacement is only presented to one eye, while the target is unchanged for the other eye, short-term adjustments are again conjugate, which suggests that there is no mechanism for fast disconjugate saccade adaptation [104]. Dichoptically presented random-dot patterns with local disparities representing a 3-D object lead to immediate position-dependent saccadic disconjugacies that persist during subsequent monocular viewing [105]. Similar immediate disconjugacies of saccades can be observed when disparities are introduced by dichoptical images that differ in size [106]. Subjects with anisometropic spectacles show saccades with different amplitudes and postsaccadic drifts between both eyes, even during monocular viewing [82, 107]. Already an image size inequality of 2% leads to disconjugate horizontal and vertical saccades, which persist after a short training period when tested in the absence of normal binocular visual targets [108]. Placing an afocal magnifier in front of one eye leads to disconjugate memory-guided saccades, which outlasts the removing of the magnifier after the training period, when subjects are viewing monocularly [109, 110]. Dichoptically presented patterns that are displaced at the end of each vertical saccade induce amplitude disconjugacy, but only little disconjugate postsaccadic drift [111]. Apparently, this effect does not require foveal fusion since microstrabismic patients adapt as
Straumann
98
well [112]. When vertical saccades are disconjugately adapted, smooth pursuit movements remain conjugate and vice versa [113]. Thus, the two classes of eye movements have separate mechanisms for binocular adaptation. In patients with trochlear nerve palsy, saccades become more conjugate after strabismus surgery, an effect that is more pronounced in patients with congenital than in patients with acquired trochlear nerve palsy [114]. In rhesus monkeys with one surgically weakened extraocular muscle, the paretic eye shows postsaccadic drift with the normal eye viewing. Deafferenting the paretic eye leaves postsaccadic drift unchanged; thus, proprioception from the paretic eye does not play a role in the adaptation of postsaccadic drift [115]. Proprioceptive deafferentation alone impairs ocular alignment and saccade conjugacy [116].
Disconjugate Eye Movements Evoked by Vestibular Stimulation
Vergence eye movements are elicited by linear motion in the dark with or without visual targets [117]. The gain of the translational vestibulo-ocular reflex (VOR) during heave ( ⫽ up-down) and sway ( ⫽ left-right) whole-body oscillation increases with increasing convergence [118, 119]. During surge ( ⫽ fore-aft) oscillation, the gain of the translational VOR increases with both increasing gaze eccentricity and increasing convergence, which is qualitatively accurate for foveal stabilization of both eyes [120–122]. Such vergence responses are enhanced by the presence of visual stimuli [123]. During visual fixation upon isovergence targets along the horizontal meridian and concurrent rapid oscillations in various directions in the horizontal plane, both eyes move in the geometrically correct direction needed to stabilize the targets on the two foveae; the gain of the version component (average velocity of both eyes divided target velocity), however, amounts to only around 0.5, while the gain of the vergence component (right eye velocity minus left eye velocity) ranges around unity [124]. This finding might reflect the fact that for visual acuity it is more important to stabilize the relative orientation of the lines of sight than binocular position. Vergence also modifies the gain of the angular VOR for gaze stabilization. For example, the gain of the VOR elicited on a horizontal turntable anticipates the vergence angle by about 50 ms [125]. Ocular counterroll elicited by head or whole-body roll interferes with stereopsis. This geometric incompatibility increases further with decreasing target distance. It is therefore advantageous that ocular counterroll decreases strongly during convergence [126, 127]. In the presence of ocular counterroll, binocular movements from a far to a near target show unequal torsion; the required torsion for the undermost eye is larger than for the uppermost eye, since convergence is associated with extorsion. Such torsional disconjugacy,
Disconjugate Eye Movements
99
however, cannot be demonstrated for divergent eye movements [128]. Static head roll also leads to excyclovergent eye positions [129]. This phenomenon can be explained by a static hysteresis that differs between the eyes contra- and ipsilateral to head roll [130]. Probably, ocular torsional hysteresis is introduced at the level of the otolith pathways because the direction-dependent torsional position lag of the eyes was related to head roll position, not eye position. Asymmetric binocular torsion evoked by hypo- or hypergravity may be a predictor for space sickness [131–133]. During position steps of head roll, the eyes show dynamic binocular counterrolling and skewing. While the gain of dynamic binocular torsion is larger in upright than in supine position, dynamic skewing is unaffected by the additional otolith input that appears in upright position [134]. Constant rotation about an off-vertical axis causes horizontal vergence movements [135]. During oscillatory head roll, the ocular rotation axes of the two eyes are convergent both in the dark and when fixating upon a far light dot; when subjects fix upon a near light dot, the convergence of binocular rotation axes exceeds the convergence of binocular positions [136]. The Bielschowsky head-tilt sign in unilateral trochlear nerve palsy, i.e. increased vertical and torsional divergence with the head tilted towards the affected eye, can be explained by inward tilt of the rotation axis of the covered eye during head oscillation about the naso-occipital axis [137]. This ‘convergence’ of ocular rotation axes is the result of decreased force by the SO of the covered paretic eye or, according to Hering’s law, increased force parallel to the paretic SO in the covered unaffected eye. The gain of the VOR in an eye with trochlear nerve palsy is reduced in all directions, but especially towards intorsion, depression and abduction, in accordance with the 3-D pulling direction of the SO [138]. In patients with peripheral abducens nerve palsy, the gain of the horizontal VOR in the affected eye is reduced in both directions, when tested in the dark. In the light, horizontal gains normalize in patients with mild or moderate palsy [139]. The gain of the torsional VOR is reduced in both the healthy and the affected eye [140]. The orientation of ocular rotation axes as a function of eye position depends on the gain of the torsional VOR; the lower the torsional gain, the more the axes tilt with eccentric gaze position [141]. As the torsional gain decreases further with increasing convergence, average 3-D eye positions scatter closely around the temporally rotated Listing’s plane, which is advantageous for binocular retinal stabilization [142]. Head roll in patients with peripheral abducens nerve palsy leads to a hyperdeviation of the ipsilateral eye, independent of which eye is affected. In patients with central abducens palsy, the same eye (healthy or affected) hyperdeviates when rolling the head to the left or the right side [143]. At low frequencies, the horizontal and vertical VOR can be cancelled by visually fixing upon head-fixed targets. During head oscillations about the
Straumann
100
naso-occipital axis visual suppression of the elicited torsional VOR is incomplete, but the lines of sight of the two eyes remain on target [144]. If subjects during head roll fix upon head-fixed eccentric horizontal targets at near distance, the eyes also show vertical movement components, even if one eye is covered [145]. These components are required to keep the lines of sight pointed to the targets. Thus, the vergence system correctly modifies the eye movements that are not visually cancelled to prevent horizontal and vertical retinal slip in either eye.
Disconjugate Eye Movements and Blinks
Initial eye movements during voluntary blinks are extorsional, downward, and inward, consistent with an early pulse-like innervation of the inferior rectus muscle [146]. Thus, during this early phase of blinking, the eyes converge and excyclodiverge. Blinks modify the kinematics and dynamics saccade-vergence and slow vergence eye movements [147, 148]. Besides mechanical factors of the eye plant, the found changes might reflect the blink-induced decrease in omnipause neuron activity.
Pathological Disconjugate Eye Movements
Normally, vergence eye movements in response to steps of a visual stimuli become slower with age, which has to be taken into account when evaluating patients with suspected vergence disorders [149]. Binocular positions in patients with cerebellar dysfunction are usually esophoric or even esotropic. In addition, there is a hypertropia that varies as a function of horizontal eye position, so-called alternating skew deviation with the abducting eye higher. The patients show both conjugate and disconjugate saccadic abnormalities that are also eye position dependent [150]. The mechanism of alternating skew deviation in patients with cerebellar disease could be due to a lost correction of changed eye muscle pulling directions, which is required when animals become frontal eyed. If, in addition, one assumes an imbalance of graviceptive-ocular pathways responding to head pitch, alternating skew deviation can be explained by this mechanism [151]. Dissociated vertical divergence (DVD) includes the following ocular motor phenomena [152]: Upon occlusion of either eye, a horizontal and cyclovertical latent nystagmus develops. This is quickly followed by cycloversion/vertical vergence, with the fixing eye intorting and tending to move downward and the covered eye extorting and moving up. Simultaneously, upward versions occur for the maintenance of fixation. This, in turn, leads to further
Disconjugate Eye Movements
101
upward movement of the covered eye and, at the same time, to a reduction of the cyclovertical component of the latent nystagmus. Thus, a possible ‘purpose’ of this cycloversion and vertical vergence is to damp the cyclovertical nystagmus that occurs when one eye is covered [153]. Brodsky hypothesized that DVD is a dorsal light reflex that occurs when binocular vision is impaired in infancy [154]. Since patients with DVD only transiently perceive a tilt of the subjective visual vertical when one eye is covered, it was speculated that the cancellation of SVV tilt in these patients is the main function of DVD [155]. Binocular eye movements in patients with convergent-divergent pendular nystagmus are conjugate in the vertical direction, but phase shifted by 180⬚ in the horizontal and torsional directions [156]. The lesion is usually localized within neural structures of the vergence system. If horizontal saccades or smooth pursuit eye movements are pathologically coupled with convergence, the abducting eye will appear paretic despite an intact abducens nerve. This socalled pseudo-abducens palsy is caused by lesions of convergence pathways near the midbrain-diencephalic junction and is frequently associated with upgaze palsy and convergence-retraction nystagmus [157]. Paramedian thalamic infarctions without involvement of the midbrain may lead to a selective bilateral pseudo-abducens palsy [158]. Convergence-retraction nystagmus, however, is due to a mesencephalic lesion [159] and represents a disorder of the vergence system [160]. Pathologically disconjugate eye movements with the vergence system intact, is typical of internuclear ophthalmoparesis [161]. Mild internuclear ophthalmoparesis, in which the adducting eye is only slightly slower than the abducting eye, is often missed by clinicians, as demonstrated by infrared oculography [162]. Ocular bobbing, which rarely appears after infratentorial lesions, but otherwise has no localizing value, may be disconjugate [163]. Disconjugate vertical and torsional ocular movements, resembling seesaw nystagmus, have been observed in a patient with locked-in syndrome after large infarction of the pons [164]. Smaller lesions in the ventral pons involving the nucleus reticularis tegmenti pontis lead to impairment of slow vergence movements to ramp targets [165]. On the other hand, fast vergence movements to step targets are affected by lesions of upper pontine nuclei [166]. References 1 2 3
Sheliga BM, Miles FA: Perception can influence the vergence responses associated with openloop gaze shifts in 3D. J Vis 2003;3:654–676. Cornell ED, MacDougall HG, Predebon J, Curthoys IS: Errors of binocular fixation are common in normal subjects during natural conditions. Optom Vis Sci 2003;80:764–771. Francis EL, Jiang BC, Owens DA, Tyrrell RA: Accommodation and vergence require effort-tosee. Optom Vis Sci 2003;80:467–473.
Straumann
102
4 5 6
7 8 9 10 11 12
13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29
Stevenson SB, Lott LA, Yang J: The influence of subject instruction on horizontal and vertical vergence tracking. Vision Res 1997;37:2891–2898. Semmlow JL, Yuan W, Alvarez TL: Evidence for separate control of slow version and vergence eye movements: support for Hering’s Law. Vision Res 1998;38:1145–1152. van Leeuwen AF, Collewijn H, Erkelens CJ: Dynamics of horizontal vergence movements: interaction with horizontal and vertical saccades and relation with monocular preferences. Vision Res 1998;38:3943–3954. Hung GK, Zhu H, Ciuffreda KJ: Convergence and divergence exhibit different response characteristics to symmetric stimuli. Vision Res 1997;37:1197–1205. Alvarez TL, Semmlow JL, Pedrono C: Divergence eye movements are dependent on initial stimulus position. Vision Res 2005;45:1847–1855. Semmlow JL, Hung GK, Horng JL, Ciuffreda K: Initial control component in disparity vergence eye movements. Ophthalmic Physiol Opt 1993;13:48–55. Semmlow JL, Hung GK, Horng JL, Ciuffreda KJ: Disparity vergence eye movements exhibit preprogrammed motor control. Vision Res 1994;34:1335–1343. Semmlow JL, Yuan W: Adaptive modification of disparity vergence components: an independent component analysis study. Invest Ophthalmol Vis Sci 2002;43:2189–2195. Masson GS, Yang DS, Miles FA: Version and vergence eye movements in humans: open-loop dynamics determined by monocular rather than binocular image speed. Vision Res 2002;42: 2853–2867. Horng JL, Semmlow JL, Hung GK, Ciuffreda KJ: Dynamic asymmetries in disparity convergence eye movements. Vision Res 1998;38:2761–2768. Horng JL, Semmlow JL, Hung GK, Ciuffreda KJ: Initial component control in disparity vergence: a model-based study. IEEE Trans Biomed Eng 1998;45:249–257. Alvarez TL, Semmlow JL, Yuan W: Closely spaced, fast dynamic movements in disparity vergence. J Neurophysiol 1998;79:37–44. Alvarez TL, Semmlow JL, Yuan W, Munoz P: Disparity vergence double responses processed by internal error. Vision Res 2000;40:341–347. Howard IP, Fang X, Allison RS, Zacher JE: Effects of stimulus size and eccentricity on horizontal and vertical vergence. Exp Brain Res 2000;130:124–132. Busettini C, Miles FA, Krauzlis RJ: Short-latency disparity vergence responses and their dependence on a prior saccadic eye movement. J Neurophysiol 1996;75:1392–1410. Busettini C, FitzGibbon EJ, Miles FA: Short-latency disparity vergence in humans. J Neurophysiol 2001;85:1129–1152. Masson GS, Busettini C, Miles FA: Vergence eye movements in response to binocular disparity without depth perception. Nature 1997;389:283–286. Busettini C, Masson GS, Miles FA: Radial optic flow induces vergence eye movements with ultrashort latencies. Nature 1997;390:512–515. Coubard O, Daunys G, Kapoula Z: Gap effects on saccade and vergence latency. Exp Brain Res 2004;154:368–381. Luu CD, Abel L: The plasticity of vertical motor and sensory fusion in normal subjects. Strabismus 2003;11:109–118. Hara N, Steffen H, Roberts DC, Zee DS: Effect of horizontal vergence on the motor and sensory components of vertical fusion. Invest Ophthalmol Vis Sci 1998;39:2268–2276. Betts GA, Curthoys U, Todd MJ: The effect of roll-tilt on ocular skew deviation. Acta Otolaryngol Suppl 1995;520:304–306. Enright JT: Unexpected role of the oblique muscles in the human vertical fusional reflex. J Physiol 1992;451:279–293. Cheeseman EW Jr, Guyton DL: Vertical fusional vergence: the key to dissociated vertical deviation. Arch Ophthalmol 1999;117:1188–1191. van Rijn LJ, Collewijn H: Eye torsion associated with disparity-induced vertical vergence in humans. Vision Res 1994;34:2307–2316. Mudgil AV, Walker M, Steffen H, Guyton DL, Zee DS: Motor mechanisms of vertical fusion in individuals with superior oblique paresis. J AAPOS 2002;6:145–153.
Disconjugate Eye Movements
103
30 31 32 33 34 35 36 37
38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55
56
Howard IP, Allison RS, Zacher JE: The dynamics of vertical vergence. Exp Brain Res 1997;116: 153–159. Howard IP, Fang X, Allison RS, Zacher JE: Effects of stimulus size and eccentricity on horizontal and vertical vergence. Exp Brain Res 2000;130:124–132. van Rijn LJ, Vandersteen J, Collewijn H: Instability of ocular torsion during fixation – cyclovergence is more stable than cycloversion. Vision Res 1994;34:1077–1087. Hooge IT, van den Berg AV: Visually evoked cyclovergence and extended Listing’s law. J Neurophysiol 2000;83:2757–2775. van Rijn LJ, Vandersteen J, Collewijn H: Visually induced cycloversion and cyclovergence. Vision Res 1992;32:1875–1883. Howard IP, Zacher JE: Human cyclovergence as a function of stimulus frequency and amplitude. Exp Brain Res 1991;85:445–450. Howard IP, Sun L, Shen X: Cycloversion and cyclovergence: the effects of the area and position of the visual display. Exp Brain Res 1994;100:509–514. Minken AW, Gielen CC, van Gisbergen JA: An alternative three-dimensional interpretation of Hering’s equal-innervation law for version and vergence eye movements. Vision Res 1995;35: 93–102. Mok D, Ro A, Cadera W, Crawford JD, Vilis T: Rotation of Listing’s plane during vergence. Vision Res 1992;32:2055–2064. van Rijn LJ, van den Berg AV: Binocular eye orientation during fixations: Listing’s law extended to include eye vergence. Vision Res 1993;33:691–708. Somani RA, DeSouza JF, Tweed D, Vilis T: Visual test of Listing’s law during vergence. Vision Res 1998;38:911–923. Minken AW, van Gisbergen JA: A three-dimensional analysis of vergence movements at various levels of elevation. Exp Brain Res 1994;101:331–345. Tweed D: Visual-motor optimization in binocular control. Vision Res 1997;37:1939–1951. Bruno P, van den Berg AV: Relative orientation of primary positions of the two eyes. Vision Res 1997;37:935–947. Hepp K: Theoretical explanations of Listing’s law and their implication for binocular vision. Vision Res 1995;35:3237–3241. Tweed D: Visual-motor optimization in binocular control. Vision Res 1997;37:1939–1951. Schreiber K, Crawford JD, Fetter M, Tweed D: The motor side of depth vision. Nature 2001;410: 819–822. Demer JL, Kono R, Wright W: Magnetic resonance imaging of human extraocular muscles in convergence. J Neurophysiol 2003;89:2072–2085. Steffen H, Walker MF, Zee DS: Rotation of Listing’s plane with convergence: independence from eye position. Invest Ophthalmol Vis Sci 2000;41:715–721. Kapoula Z, Bernotas M, Haslwanter T: Listing’s plane rotation with convergence: role of disparity, accommodation, and depth perception. Exp Brain Res 1999;126:175–186. Mikhael S, Nicolle D, Vilis T: Rotation of Listing’s plane by horizontal, vertical and oblique prism-induced vergence. Vision Res 1995;35:3243–3254. Minken AW, van Gisbergen JA: Dynamical version-vergence interactions for a binocular implementation of Donders’ law. Vision Res 1996;36:853–867. Tweed D, Vilis T: Geometric relations of eye position and velocity vectors during saccades. Vision Res 1990;30:111–127. Porrill J, Ivins JP, Frisby JP: The variation of torsion with vergence and elevation. Vision Res 1999;39:3934–3950. Ivins JP, Porrill J, Frisby JP: Instability of torsion during smooth asymmetric vergence. Vision Res 1999;39:993–1009. Migliaccio AA, Cremer PD, Aw ST, Halmagyi GM, Curthoys IS, Minor LB, Todd MJ: Vergencemediated changes in the axis of eye rotation during the human vestibulo-ocular reflex can occur independent of eye position. Exp Brain Res 2003;151:238–248. Straumann D, Steffen H, Landau K, Bergamin O, Mudgil AV, Walker MF, Guyton DL, Zee DS: Primary position and Listing’s law is acquired and congenital trochlear nerve palsy. Invest Ophthalmol Vis Sci 2003;44:4282–4292.
Straumann
104
57 Migliaccio AA, Cremer PD, Aw ST, Halmagyi GM: Vergence-mediated changes in Listing’s plane do not occur in an eye with superior oblique palsy. Invest Ophthalmol Vis Sci 2004;45:3043–3047. 58 Wong AMF, Sharpe JA, Tweed D: Adaptive neural mechanism for Listing’s law revealed in patients with fourth nerve palsy. Invest Ophthalmol Vis Sci 2002;43:1796–1803. 59 Wong AMF, Tweed D, Sharpe JA: Adaptive neural mechanism for Listing’s law revealed in patients with sixth nerve palsy. Invest Ophthalmol Vis Sci 2002;43:112–119. 60 Somani RA, Hutnik C, DeSouza JF, Tweed D, Nicolle D, Vilis T: Using a synoptophore to test Listing’s law during vergence in normal subjects and strabismic patients. Vision Res 1998;38: 3621–3631. 61 van den Berg AV, van Rijn LJ, de Faber JT: Excess cyclovergence in patients with intermittent exotropia. Vision Res 1995;35:3265–3278. 62 Melis BJ, Cruysberg JR, van Gisbergen JA: Listing’s plane dependence on alternating fixation in a strabismus patient. Vision Res 1997;37:1355–1366. 63 Moschovakis AK: Are laws that govern behavior embedded in the structure of the CNS? The case of Hering’s law. Vision Res 1995;35:3207–3216. 64 Mays L: Has Hering been hooked? Nat Med 1998;4:889–890. 65 King WM, Zhou W: Neural basis of disjunctive eye movements. Ann N Y Acad Sci 2002;956: 273–283. 66 Dell’Osso LF: Evidence suggesting individual ocular motor control of each eye (muscle). J Vestib Res 1994;4:335–345. 67 Ramat S, Das VE, Somers JT, Leigh RJ: Tests of two hypotheses to account for different-sized saccades during disjunctive gaze shifts. Exp Brain Res 1999;129:500–510. 68 Maxwell JS, Schor CM: Symmetrical horizontal vergence contributes to the asymmetrical pursuit of targets in depth. Vision Res 2004;44:3015–3024. 69 Enright JT: Slow-velocity asymmetrical convergence: a decisive failure of ‘Hering’s law’. Vision Res 1996;36:3667–3684. 70 King WM, Zhou W: Initiation of disjunctive smooth pursuit in monkeys: evidence that Hering’s law of equal innervation is not obeyed by the smooth pursuit system. Vision Res 1995;35:3389–3400. 70a Miller JM, Bockisch CJ, Pavlovski DS: Missing lateral rectus force and absence of medial rectus co-contraction in ocular convergence. J Neurophysiol 2002;8:2421–2433. 71 King WM, Zhou W, Tomlinson RD, McConville KM, Page WK, Paige GD, Maxwell JS: Eye position signals in the abducens and oculomotor nuclei of monkeys during ocular convergence. J Vestib Res 1994;4:401–408. 72 Zhou W, King WM: Premotor commands encode monocular eye movements. Nature 1998;393: 692–695. 73 Maxwell JS, King WM: Dynamics and efficacy of saccade-facilitated vergence eye movements in monkeys. J Neurophysiol 1992;68:1248–1260. 74 Collewijn H, Erkelens CJ, Steinman RM: Voluntary binocular gaze-shifts in the plane of regard: dynamics of version and vergence. Vision Res 1995;35:3335–3358. 75 Zee DS, FitzGibbon EJ, Optican LM: Saccade-Vergence interactions in humans. J Neurophysiol 1992;68:1624–1641. 76 Ramat S, Somers JT, Das VE, Leigh RJ: Conjugate ocular oscillations during shifts of the direction and depth of visual fixation. Invest Ophthalmol Vis Sci 1999;40:1681–1686. 77 Bhidayasiri R, Somers JT, Kim JI, Ramat S, Nayak S, Bokil HS, Leigh RJ: Ocular oscillations induced by shifts of the direction and depth of visual fixation. Ann Neurol 2001;49:24–28. 78 Ramat S, Leigh RJ, Zee DS, Optican LM: Ocular oscillations generated by coupling of brainstem excitatory and inhibitory saccadic burst neurons. Exp Brain Res 2005;160:89–106. 79 Collewijn H, Erkelens CJ, Steinman RM: Trajectories of the human binocular fixation point during conjugate and non-conjugate gaze-shifts. Vision Res 1997;37:1049–1069. 80 Straumann D, Zee DS, Solomon D, Lasker AG, Roberts DC: Transient torsion during and after saccades. Vision Res 1995;35:3321–3334. 81 Maxwell GF, Lemij HG, Collewijn H: Conjugacy of saccades in deep amblyopia. Invest Ophthalmol Vis Sci 1995;36:2514–2522. 82 Lemij HG, Collewijn H: Long-term nonconjugate adaptation of human saccades to anisometropic spectacles. Vision Res 1991;31:1939–1954.
Disconjugate Eye Movements
105
83 Collewijn H, Erkelens CJ, Steinman RM: Trajectories of the human binocular fixation point during conjugate and non-conjugate gaze-shifts. Vision Res 1997;37:1049–1069. 84 Chaturvedi V, van Gisbergen JA: Specificity of saccadic adaptation in three-dimensional space. Vision Res 1997;37:1367–1382. 85 Enright JT: Monocularly programmed human saccades during vergence changes? J Physiol 1998; 512:235–250. 86 Ygge J, Zee DS: Control of vertical eye alignment in three-dimensional space. Vision Res 1995;35:3169–3181. 87 Kumar AN, Han Y, Dell’Osso LF, Durand DM, Leigh RJ: Directional asymmetry during combined saccade-vergence movements. J Neurophysiol 2005;93:2797–2808. 88 Schor CM, Maxwell JS, Stevenson SB: Isovergence surfaces: the conjugacy of vertical eye movements in tertiary positions of gaze. Ophthalmic Physiol Opt 1994;14:279–286. 89 Graf EW, Maxwell JS, Schor CM: Changes in cyclotorsion and vertical eye alignment during prolonged monocular occlusion. Vision Res 2002;42:1185–1194. 90 Gauthier GM, Vercher JL, Zee DS: Changes in ocular alignment and pointing accuracy after sustained passive rotation of one eye. Vision Res 1994;34:2613–2627. 91 Maxwell JS, Schor CM: Mechanisms of vertical phoria adaptation revealed by time-course and 2-dimensional spatiotopic maps. Vision Res 1994;34:241–251. 92 Schor CM, Gleason G, Maxwell J, Lunn R: Spatial aspects of vertical phoria adaptation. Vision Res 1993;33:73–84. 93 Schor CM, McCandless JW: An adaptable association between vertical and horizontal vergence. Vision Res 1995;35:3519–3527. 94 Schor CM, McCandless JW: Context-specific adaptation of vertical vergence to correlates of eye position. Vision Res 1997;37:1929–1937. 95 Maxwell JS, Schor CM: Adaptation of vertical eye alignment in relation to head tilt. Vision Res 1996;36:1195–1205. 96 Maxwell JS, Schor CM: Head-position-dependent adaptation of nonconcomitant vertical skew. Vision Res 1997;37:441–446. 97 Akao T, Kurkin S, Fukushima K: Latency of adaptive vergence eye movements induced by vergence-vestibular interaction training in monkeys. Exp Brain Res 2004;158:129–132. 98 Sato F, Akao T, Kurkin S, Fukushima J, Fukushima K: Adaptive changes in vergence eye movements induced by vergence-vestibular interaction training in monkeys. Exp Brain Res 2004;156: 164–173. 99 Oohira A, Zee DS: Disconjugate ocular motor adaptation in rhesus monkey. Vision Res 1992;32: 489–497. 100 Taylor MJ, Roberts DC, Zee DS: Effect of sustained cyclovergence on eye alignment: rapid torsional phoria adaptation. Invest Ophthalmol Vis Sci 2000;41:1076–1083. 101 Kono R, Hasebe S, Ohtsuki H, Kashihara K, Shiro Y: Impaired vertical phoria adaptation in patients with cerebellar dysfunction. Invest Ophthalmol Vis Sci 2002;43:673–678. 102 Steffen H, Walker M, Zee DS: Changes in Listing’s plane after sustained vertical fusion. Invest Ophthalmol Vis Sci 2002;43:668–672. 103 Schor CM, Maxwell JS, Graf EW: Plasticity of convergence-dependent variations of cyclovergence with vertical gaze. Vision Res 2001;41:3353–3369. 104 Albano JE, Marrero JA: Binocular interactions in rapid saccadic adaptation. Vision Res 1995;35: 3439–3450. 105 Eggert T, Kapoula Z: Position dependency of rapidly induced saccade disconjugacy. Vision Res 1995;35:3493–3503. 106 Kapoula Z, Eggert T, Bucci MP: Immediate saccade amplitude disconjugacy induced by unequal images. Vision Res 1995;35:3505–3518. 107 Oohira A, Zee DS, Guyton DL: Disconjugate adaptation to long-standing, large-amplitude, spectacle-corrected anisometropia. Invest Ophthalmol Vis Sci 1991;32:1693–1703. 108 Bucci MP, Gomes M, Paris S, Kapoula Z: Disconjugate oculomotor earning caused by feeble image-size inequality: differences between secondary and tertiary positions. Vision Res 2001;41: 625–637.
Straumann
106
109 Paris S, Bucci MP, Kapoula Z: Disconjugate vertical memory-guided saccades to disparate targets. Exp Brain Res 2000;135:267–274. 110 Donnet SP, Kapoula Z, Bucci MP, Daunys G: Vertical memory-based disconjugate learning for downward saccades at a viewing distance of 70 cm: relation to horizontal vergence and to vertical phoria. Exp Brain Res 2002;146:474–480. 111 Kapoula Z, Eggert T, Bucci MP: Disconjugate adaptation of the vertical oculomotor system. Vision Res 1996;36:2735–2745. 112 Kapoula Z, Bucci MP, Eggert T, Zamfirescu F: Fast disconjugate adaptations of saccades in microstrabismic subjects. Vision Res 1996;36:103–104. 113 Schor CM, Gleason J, Horner D: Selective nonconjugate binocular adaptation of vertical saccades and pursuits. Vision Res 1990;30:1827–1844. 114 Lewis RF, Zee DS, Repka MX, Guyton DL, Miller NR: Regulation of static and dynamic ocular alignment in patients with trochlear nerve pareses. Vision Res 1995;35:3255–3264. 115 Lewis RF, Zee DS, Goldstein HP, Guthrie BL: Proprioceptive and retinal afference modify postsaccadic ocular drift. J Neurophysiol 1999;82:551–563. 116 Lewis RF, Zee DS, Gaymard BM, Guthrie BL: Extraocular muscle proprioception functions in the control of ocular alignment and eye movement conjugacy. J Neurophysiol 1994;72:1028–1031. 117 Paige GD, Tomko DL: Eye movement responses to linear head motion in the squirrel monkey. II. Visual-vestibular interactions and kinematic considerations. J Neurophysiol 1991;65:1183–1196. 118 Schwarz U, Miles FA: Ocular responses to translation and their dependence on viewing distance. I. Motion of the observer. J Neurophysiol 1991;66:851–864. 119 Paige GD, Tomko DL: Eye movement responses to linear head motion in the squirrel monkey. II. Visual-vestibular interactions and kinematic considerations. J Neurophysiol 1991;65:1183–1196. 120 Paige GD, Tomko DL: Eye movement responses to linear head motion in the squirrel monkey. II. Visual-vestibular interactions and kinematic considerations. J Neurophysiol 1991;65:1183–1196. 121 McHenry MQ, Angelaki DE: Primate translational vestibuloocular reflexes. II. Version and vergence responses to fore-aft motion. J Neurophysiol 2000;83:1648–1661. 122 Ramat S, Zee DS: Binocular coordination in fore/aft motion. Ann N Y Acad Sci 2005;1039:36–53. 123 Kodaka Y, Wada Y, Kawano K: Vergence responses to forward motion in monkeys: visual modulation at ultra-short latencies. Exp Brain Res 2003;148:541–544. 124 Angelaki DE, Hess BJM: Direction of heading and vestibular control of binocular eye movements. Vision Res 2001;41:3215–3228. 125 Snyder LH, Lawrence DM, King WM: Changes in vestibulo-ocular reflex (VOR) anticipate changes in vergence angle in monkey. Vision Res 1992;32:569–575. 126 Misslisch H, Tweed D, Hess BJ: Stereopsis outweighs gravity in the control of the eyes. J Neurosci 2001;21:RC126. 127 Ooi D, Cornell ED, Curthoys IS, Burgess AM, MacDougall HG: Convergence reduces ocular counterroll (OCR) during static roll-tilt. Vision Res 2004;44:2825–2833. 128 Mandelli MJ, Misslisch H, Hess BJ: Static and dynamic properties of vergence-induced reduction of ocular counter-roll in near vision. Eur J Neurosci 2005;21:549–555. 129 Pansell T, Ygge J, Schworm HD: Conjugacy of torsional eye movements in response to a head tilt paradigm. Invest Ophthalmol Vis Sci 2003;44:2557–2564. 130 Palla A, Bockisch CJ, Bergamin O, Straumann D: Dissociated hysteresis of static ocular counterroll in humans. J Neurophysiol 2006;95:2222–2232. 131 Diamond SG, Markham CH: Ocular torsion as a test of the asymmetry hypothesis of space motion sickness. Acta Astronaut 1992;27:11–17. 132 Markham CH, Diamond SG: Further evidence to support disconjugate eye torsion as a predictor of space motion sickness. Aviat Space Environ Med 1992;63:118–121. 133 Diamond SG, Markham CH: Prediction of space motion sickness susceptibility by disconjugate eye torsion in parabolic flight. Aviat Space Environ Med 1991;62:201–205. 134 Kori AA, Schmid-Priscoveanu A, Straumann D: Vertical divergence and counterroll eye movements evoked by whole-body position steps about the roll axis of the head in humans. J Neurophysiol 2001;85:671–678.
Disconjugate Eye Movements
107
135 Dai M, Raphan T, Kozlovskaya I, Cohen B: Modulation of vergence by off-vertical yaw axis rotation in the monkey: normal characteristics and effects of space flight. Exp Brain Res 1996;111: 21–29. 136 Jauregui-Renaud K, Faldon ME, Gresty MA, Bronstein AM: Horizontal ocular vergence and the three-dimensional response to whole-body roll motion. Exp Brain Res 2001;136:79–92. 137 Weber KP, Landau K, Palla A, Haslwanter T, Straumann D: Ocular rotation axes during dynamic Bielschowsky head-tilt testing in unilateral trochlear nerve palsy. Invest Ophthalmol Vis Sci 2004;45:455–465. 138 Wong AMF, Sharpe JA, Tweed D: The vestibulo-ocular reflex in fourth nerve palsy: deficits and adaptation. Vision Res 2002;42:2205–2218. 139 Wong AM, Tweed D, Sharpe JA: Adaptations and deficits in the vestibulo-ocular reflex after sixth nerve palsy. Invest Ophthalmol Vis Sci 2002;43:99–111. 140 Wong AM, Tweed D, Sharpe JA: Adaptations and deficits in the vestibulo-ocular reflex after sixth nerve palsy. Invest Ophthalmol Vis Sci 2002;43:99–111. 141 Misslisch H, Tweed D: Neural and mechanical factors in eye control. J Neurophysiol 2001;86: 1877–1883. 142 Misslisch H, Hess BJ: Combined influence of vergence and eye position on three-dimensional vestibulo-ocular reflex in the monkey. J Neurophysiol 2002;88:2368–2376. 143 Wong AMF, Tweed D, Sharpe JA: Vertical misalignment in unilateral sixth nerve palsy. Ophthalmology 2002;109:1315–1325. 144 Misslisch H, Tweed D, Fetter M, Dichgans J, Vilis T: Interaction of smooth pursuit and the vestibuloocular reflex in three dimensions. J Neurophysiol 1996;75:2520–2532. 145 Bergamin O, Straumann D: Three-dimensional binocular kinematics of torsional vestibular nystagmus during convergence on head-fixed targets in humans. J Neurophysiol 2001;86:113–122. 146 Bergamin O, Bizzarri S, Straumann D: Ocular torsion during voluntary blinks in humans. Invest Ophthalmol Vis Sci 2002;43:3438–3443. 147 Rambold H, Sprenger A, Helmchen C: Effects of voluntary blinks on saccades, vergence eye movements, and saccade-vergence interactions in humans. J Neurophysiol 2002;88:1220–1233. 148 Rambold H, Neumann G, Sprenger A, Helmchen C: Blink effect on slow vergence. Neuroreport 2002;13:2041–2044. 149 Rambold H, Neumann G, Sander T, Helmchen C: Age-related changes of vergence under natural viewing conditions. Neurobiol Aging 2006;27:163–172. 150 Versino M, Hurko O, Zee DS: Disorders of binocular control of eye movements in patients with cerebellar dysfunction. Brain 1996;119:1933–1950. 151 Zee DS: Considerations on the mechanisms of alternating skew deviation in patients with cerebellar lesions. J Vestib Res 1996;6:395–401. 152 Guyton DL: Dissociated vertical deviation: etiology, mechanism, and associated phenomena. Costenbader Lecture. J AAPOS 2000;4:131–144. 153 Guyton DL, Cheeseman EW Jr, Ellis FJ, Straumann D, Zee DS: Dissociated vertical deviation: an exaggerated normal eye movement used to damp cyclovertical latent nystagmus. Trans Am Ophthalmol Soc 1998;96:389–424; discussion 424–429. 154 Brodsky MC: Dissociated vertical divergence: a righting reflex gone wrong. Arch Ophthalmol 1999;117:1216–1222. 155 Brodsky MC: Dissociated vertical divergence: perceptual correlates of the human dorsal light reflex. Arch Ophthalmol 2002;120:1174–1178. 156 Averbuch-Heller L, Zivotofsky AZ, Remler BF, Das VE, Dell’Osso LF, Leigh RJ: Convergentdivergent pendular nystagmus: possible role of the vergence system. Neurology 1995;45:509–515. 157 Pullicino P, Lincoff N, Truax BT: Abnormal vergence with upper brainstem infarcts: pseudoabducens palsy. Neurology 2000;55:352–358. 158 Wiest G: Abnormal vergence with upper brainstem infarcts: pseudoabducens palsy. Neurology 2001;56:424–425. 159 Pullicino P, Lincoff N, Truax BT: Abnormal vergence with upper brainstem infarcts: pseudoabducens palsy. Neurology 2000;55:352–358. 160 Rambold H, Kömpf D, Helmchen C: Convergence retraction nystagmus: a disorder of vergence? Ann Neurol 2001;50:677–681.
Straumann
108
161 Zee DS: Internuclear ophthalmoplegia: pathophysiology and diagnosis. Baillieres Clin Neurol 1992;1:455–470. 162 Frohman TC, Frohman EM, O’Suilleabhain P, Salter A, Dewey RB Jr, Hogan N, Galetta S, Lee AG, Straumann D, Noseworthy J, Zee D, Corbett J, Corboy J, Rivera VM, Kramer PD: Accuracy of clinical detection of INO in MS: corroboration with quantitative infrared oculography. Neurology 2003;61:848–850. 163 Gaymard B: Disconjugate ocular bobbing. Neurology 1993;43:2151. 164 Park SH, Na DL, Kim M: Disconjugate vertical ocular movement in a patient with locked-in syndrome. Br J Ophthalmol 2001;85:497–498. 165 Rambold H, Neumann G, Helmchen C: Vergence deficits in pontine lesions. Neurology 2004;62: 1850–1853. 166 Rambold H, Sander T, Neumann G, Helmchen C: Palsy of ‘fast’ and ‘slow’ vergence by pontine lesions. Neurology 2005;64:338–340.
Dominik Straumann Neurology Department Zurich University Hospital CH–8091 Zurich (Switzerland) Tel. ⫹41 44 255 4407, Fax ⫹41 44 255 5564, E-Mail
[email protected]
Disconjugate Eye Movements
109
Straube A, Büttner U (eds): Neuro-Ophthalmology. Dev Ophthalmol. Basel, Karger, 2007, vol 40, pp 110–131
The Eyelid and Its Contribution to Eye Movements C. Helmchen, H. Rambold Department of Neurology, University of Lübeck, Lübeck, Germany
Abstract Lid and electromyographic recordings have contributed significantly to our understanding of clinical lid disorders. Tonic lid disorders (e.g. ptosis, blepharospasm, lid retraction, blepharocolysis) can be distinguished from dynamic lid disorders (lid lag) and from specific deficits of eye-lid coordination (e.g. lid nystagmus). Electromyographic recordings allow the identification of specific lid disorders that benefit from effective therapeutic interventions, e.g., botulinum toxin injections. Rapid lid closure (blink), which exerts substantial neural influence on oculomotor systems without obscuring vision, can be used for the diagnosis of brainstem disease. Copyright © 2007 S. Karger AG, Basel
Whereas clinicians often use peripheral eyelid disorders for a topologic diagnosis, supranuclear eyelid disorders have received little attention. Over the past 15 years, considerable progress has been made in our understanding of the supranuclear control of eyelid function. Moreover, several lines of evidence indicate a strong interaction between the neural control of eyelid and eye movements. Therefore, this chapter has three aims. First, the current knowledge of the anatomic and physiologic basis of eyelid movements will be reviewed, with particular emphasis on the supranuclear control of eyelid movements and eyelid coordination. Subsequently, the recent evidence for substantial interaction between eyelid and eye movements will be given (e.g. saccades and smooth pursuit eye movements) and the clinical implications. Finally, a variety of clinical eyelid disorders will be discussed.
Neural Control of the Eyelid
Although the position of the upper eyelid is actively controlled by several muscles, eyelid closure (blink) is itself a passive movement of the eyelid. It occurs when innervation of the levator palpebrae muscle (LPM) ceases [1]. In addition to the LPM inhibition, connective tissue (canthal tendons, superior transverse ligament) serves as an elastic force that is stretched during upgaze and released during downgaze. Voluntary firm closure of the eyelid is supplied by the orbicularis oculi (OO) muscles, which are innervated by the facial nerve [2]. The OO muscle is, however, not active during lid movements that accompany vertical eye movements [2, 3]. Eyelid opening is largely controlled by the strong LPM, which is innervated by the superior branch of the third cranial (oculomotor) nerve. In contrast, the superior tarsal (Müller) muscle is supplied by sympathetic efferents and regulates the width of the palpebral fissure. The LPM contains singly (but not multiply) innervated fibers that enable tonic activity [4]. Both fast-twitch and slow-twitch fibers of the LPM are rich in mitochondria and help to resist fatigue. In addition, the frontal muscle helps to retract the lid in maximal upgaze. The motoneurons of the LPM lie in the central caudal nucleus (CCN) of the oculomotor nucleus complex in the midbrain. This uniquely unpaired nucleus is located midline between the caudal pole of the oculomotor nucleus and the rostral pole of the trochlear nucleus [5]. Since motoneurons of both LPMs intermingle within the CCN, any lesion of the CCN affects both eyelids. Lid-Eye Coordination Eyelid and vertical eye movements are tightly coupled to avoid visual disturbances on upward gaze and to protect the eye on downward gaze. Accordingly, the neuronal activity of LP and superior rectus motoneurons [6] and also the dynamic properties of lid and eye saccades are very similar in their temporal profile, which is also reflected in electromyographic (EMG) recordings. The gain and phase shift of the eye and lid movement are similar during sinusoidal smooth pursuit. In contrast, during saccades the lid starts about 5 ms later than the eye but reaches the peak velocity at about the same time as the eye [7]. Lid movements that accompany saccadic eye movements between the straight ahead position and the lower visual field are larger than lid movements that accompany saccadic eye movements between the straight ahead position and the upper visual field [7]. Lid saccades are not as conjugate as saccades [8]. During fixation periods, lid position is quite unstable; the lids perform idiosyncratic eye movements that can amount to up to 5⬚ [7]. The tight coupling of lideye coordination may be changed by additional factors. The magnitude of OO-EMG activity is reduced, when a saccade is made to a previously cued
The Eyelid and Its Contribution to Eye Movements
111
spatial location. Thus, the modulation of gaze-evoked OO-EMG activity does not appear to depend on the presence of visual information per se, but results from an extraretinal signal [9]. Moreover, the tonic lid position and the tonic activity of the LPM depend on the state of alertness. The lid involuntarily lowers with increasing fatigue [10]. Levator motoneurons discharge at a steady rate. This increases linearly with the elevating lid position. Upward lid saccades are caused by a burst of activity in the LP motoneurons. Lid velocity increases with amplitude, saturating at about 450⬚/s [11]. LPM pause in firing during downward lid saccades, which are entirely due to the elastic forces. The eye and lid movement dissociate during a blink, and eye-lid coupling is discontinued. In contrast to superior rectus motoneurons, LP motoneurons cease firing [6]. Additional inhibition of the basal tonic LPM activity is required. This inhibition is presumably received from the nucleus of the posterior commissure (nPC) [12]. Physiologically, the inhibition of LPM precedes and outlasts the OO activation by about 10 ms [7]. Only during forced voluntary eye closure does OO activity precede LPM inhibition [13]. Due to the tight coupling of eye-lid coordination, the supranuclear areas for vertical eye movements are likely to also be involved, e.g. the interstitial nucleus of Cajal (iC) and the rostral interstitial nucleus of the medial longitudinal fascicle (riMLF). A small region, the M group, has been identified to be a supranuclear center of eye-lid coordination, at least for saccades. It is caudal and medial from the riMLF in the cat [14], monkey, and human [15]; from there, it projects to the superior rectus and the inferior oblique subnuclei. For this reason, the M group is thought to control the eyelids and eyes bilaterally [15], thus allowing close synchronicity of both eyelids. The CCN receives input from the nPC, the riMLF, and the superior colliculus (SC). Accordingly, disorders of eye-lid coordination in the absence of LPM or superior rectus paresis are likely to be caused by lesions of the M group or the nPC (see below). The nPC is located bilaterally adjacent to the posterior commissure [16]. Experimental and clinical nPC lesions elicit vertical upward gaze palsy and lid disorders [17]. Lid retraction is the most frequent sign [18–21]. Single vertical saccade-related neurons have been identified in the nPC [22], but their relation to lid movements has not yet been investigated. The nPC receives afferents from the frontal eye field (FEF) and SC, and projects to the neural integrator for vertical and torsional eye movements (iC) [23, 24], the riMLF, SC, and the paramedian pontine reticular formation (PPRF) [16]. It has reciprocal connections with the M group [25] and lesions involving the nPC [21] or the M group [26] may impair supranuclear inhibition of the CCN, leading to lid retraction and discoupling of eye-lid coordination.
Helmchen/Rambold
112
The saccade-related medium-lead burst neurons in the riMLF represent the neural substrate for vertical saccades [27]. They receive input from the omnipause neurons (OPNs) in the pontine reticular formation (nucleus raphe interpositus), which control their activity [28], and the SC. The rostral SC in turn exerts tonic excitation of the OPNs to suppress unwanted saccades, whereas the caudal SC provides the motor command to the pontine saccade-related burst neurons. The activity of SC neurons is reduced during blinks [29], but it remains unknown whether their activity is related to lid movements. Lesion experiments have not yet described lid disorders or deficits in lid-eye coordination [30]. The SC underlies the cortical control of the FEF, the parietal fields, and the subcortical control of the basal ganglia, e.g. the caudate nucleus and the substantia nigra (pars reticulata). Accordingly, disorders of eyelid movements are found in (right-sided) cortical lesions involving the FEF [31–34] and parkinsonian syndromes (see below). The cortical control of voluntary blinking involving the OO muscles has recently been identified by retrograde tracing experiments in the monkey [12]. Cortical afferents in OO motoneurons were obtained from multiple motor and sensory areas, e.g. the motor cortex (M1), FEF, supplementary motor area, cingulate motor area, and lateral prefrontal areas. Functional imaging techniques have demonstrated activation in the FEF, the supplementary eye field, the dorsolateral prefrontal cortex, and the posterior parietal eye field during voluntary blinking [35, 36]. Cortical efferents might use anatomic projections to the pontine and mesencephalic brainstem [37–39], but the precise efferent pathways of the cortical control of the supranuclear centers of lid and eye-lid coordination in the brainstem remain largely unknown.
Physiology of the Interaction between Eyelid and Eye Movements
The quantitative recording of eyelid movements with the search coil system in a magnetic field [11, 40–42] allows a precise analysis of lid-eye coordination. Eyelid movements are classified as spontaneous, passive (following eye saccades), reflectory (elicited by tone, air puff, visual signals), and acquired, for example when they are learned during classic conditioning procedures [40]. Thus, apart from lid-eye coordination, the eyelid motor system has become an excellent experimental tool for investigating learned motor behavior in experimental [43, 44] and clinical studies [43, 44]. Reflexive blink responses have a slightly shorter duration (200 ms) than spontaneous or voluntary blinks [2, 45]. They have a latency of 9–16 ms in the cat [3, 46] and 12 ms in humans [47]; their amplitude is smaller, and they only cover the pupil by a smaller degree than voluntary blinks. During voluntary blinks, only the pretarsal portion of the
The Eyelid and Its Contribution to Eye Movements
113
OO is involved [48]. Several blink-related aspects have to be considered in experimental studies: (a) voluntary blinks are distinctly different from reflectory blinks [2, 3, 49], (b) blinks interfere to some degree with visual perception, and (c) blinks elicit small amplitude eye movements. They will be discussed in more detail. Visual Consequences of Blinks While blinks can interrupt vision for a considerable amount of time, one is unaware of this type of blanking [49–54]. Visual sensitivity is reduced during blinks [53]. This reduction in sensitivity was found to be closely related to the duration of pupil occlusion during the blink [53]. Visual suppression during blinks is incomplete compared to that of saccades [51, 52, 55]. Blinks applied during saccades did not cause blanking of the target. Recent functional magnetic resonance imaging demonstrated a change in blink-related activity in the visual cortex and in areas of parietal and prefrontal cortex [56, 57]. This indicates active top-down modulation of visual processing during blinking, suggesting a possible mechanism by which blinks go unnoticed. Blink-Associated Eye Movements Long-lasting eye closure causes an upward eye drift known as Bell’s phenomenon [58, 59]; short eye closure with blinks induces distinctly different eye movements in humans (fig. 1) [2, 42, 45, 47, 59, 60]. During a blink, there is an early inward, downward, [45, 59, 61] and ex-torsional movement of the eyes [62]. The amplitude and direction of these eye movements depend on the initial eye position [45, 59]. During adduction and downward gaze, the amplitudes of the blink-associated eye movement components are minimal. The horizontal amplitude increases during abduction, and the vertical amplitude during upward gaze [45]. The horizontal, vertical, and torsional components of the blink-associated eye movement start before lid movement onset [53, 60, 62], and the movement is completed before blink termination [47, 59]. Blinkassociated eye movements are slower than saccades; they do not obey the saccadic main sequence [59] and Listing’s law [63]. Blink-associated eye movements are caused by cocontraction of all eye muscles [1, 13, 62, 64]. Bergamin et al. [62] showed in humans that during the early phase of eyelid closure of voluntary blinks the eye moves in a 3-D direction that can best be explained by a pulselike activation of the inferior rectus muscle. Blink-associated eye movements reflect an active process, i.e. they are not caused by mechanical eye-lid interaction [59], and they are important for the protection of the cornea [2, 40, 45]. Blink-associated eye movements are not only found during fixation but are superimposed on all kinds of eye movements, e.g. smooth pursuit, saccades, and vergence eye movements [41, 65–68].
Helmchen/Rambold
114
Verg
200º/s
con
div
VeIH
200º/s
left
right
VeIV
200º/s
up
down 100 ms 0
close
1
Lid
open
Fig. 1. Effect of blinks on eye velocity components at gaze straight ahead in a normal subject. Mean eye vergence velocity (Verg), horizontal (VelH) and vertical (VelV) version velocity, as well as relative eyelid position (Lid) are averaged (5 blinks) and aligned to blink onset. Note that the blink duration exceeds the eye movement duration; modified after Rambold et al. [42], with permission.
Effect of Blinks on Eye Movements Blinks affect eye movements in at least two ways: (1) by superimposing blink-associated eye movements and (2) by modifying the neuronal premotor activity in brainstem circuits, which change their dynamic properties. This second aspect will be discussed in more detail below. Blinks and Saccades Voluntary and reflexive blinks influence horizontal and vertical visually guided saccades in monkeys and in humans [30, 42, 47, 69]. Blinks reduce horizontal saccade velocity, acceleration, deceleration, and increase saccade duration, but they do not change saccade amplitude (fig. 2) [42, 47]. The effect of the blink on the saccade is time dependent. The maximum effect is observed with blinks elicited about 150 ms before saccade onset [42, 69]. If blinks are elicited later during the saccade, dynamic overshoots may occur [47]. Blinks reduce saccade latency [69] when they are elicited shortly after but not before [67] stimulus onset. This influence of blinks can be explained by the blink-induced changes of the neuronal oculomotor circuits in the brainstem [29, 30, 42, 47]. Medium-lead burst neurons of the PPRF and the riMLF provide the premotor saccadic command to the extraocular motoneurons [70]. Several lines of evidence indicate that OPNs in the nucleus raphe interpositus [71] control saccadic burst neurons [72]. OPNs, which discharge spontaneously, cease firing during saccades [70,
The Eyelid and Its Contribution to Eye Movements
115
left
15
0 ⫺15 ⫺25
a
Velocity (degrees/s)
right
left
500
⫺15
300 100 ⫺100
⫺300 down ⫺500
e
open 0 Lid
0
Lid close
⫺25
500
up
⫺100
open
0
d
100
⫺500
b
15
down
300
⫺300
25
up Position (degrees)
25
Velocity (degrees/s)
Position (degrees)
right
1
c
close
f
1 100 ms
Fig. 2. Eye movement traces for one normal subject are aligned with respect to saccade begin. Horizontal (a–c) and vertical (d–f) saccades are displayed separately as eye position (a, d), eye velocity (b, e), and lid position (c, f). Saccade duration is increased and peak velocity decreased for both horizontal (a, b) and vertical (d, e) saccades in the blink condition (solid line), in contrast to the control condition (dotted line). The shift of the dotted lines (f) indicates the accompanying lid movement with vertical eye movements; modified after Rambold et al. [42], with permission.
73–75]. Ibotenic acid injections in the OPN region of the monkey decrease saccadic peak velocity and increase saccade duration without changing saccade amplitude [76]. Blinks decrease OPN discharge even without eye movements [77–79]; the discharge during saccades in medium-lead burst neurons of the PPRF [80] and in saccade-related long-lead burst neurons in the intermediate layer of the SC is decreased [29]. Accordingly, the inhibitory effect of blinks on the OPNs might
Helmchen/Rambold
116
10º Vergence (degree)
a
b
Lid
open
phase 2
phase 2
close phase 1
c
phase 1
d
200 ms
Fig. 3. The vergence eye movements are shown separately for the convergence (a, b) and divergence (c, d) components of the vergence position (a, c) and the relative lid position (b, d). Eye movements during the blink condition (black solid traces) are compared with those during the no blink condition (dotted trace). All traces are aligned to vergence onset. For better illustration, the onset of two phases of the vergence components is indicated by vertical dotted lines. In phase 1, a convergence-divergence movement is found in the convergence (a) and in the divergence (c) paradigms. Note that vergence duration exceeds blink duration; modified after Rambold et al. 2002 [42], with permission.
explain the outlined behavioral effects. Further evidence comes from a saccadic brainstem model that incorporates rebound inhibition firing of the mediumlead burst neurons [81]. Blinks and Vergence Eye Movements Vergence may be divided into two subsystems: a transient and a sustained vergence system [82, 83]. The transient vergence system is elicited by large retinal disparity errors, which cannot be fused on the retina; the sustained vergence is largely elicited by similar images, small disparity errors, or velocities of less than 4⬚/s [83, 84]. Blinks affect both subsystems of vergence. Following blink-associated eye movements, the subsequent transient vergence is increased in duration and decreased in velocity when a voluntary blink is elicited (fig. 3).
The Eyelid and Its Contribution to Eye Movements
117
4º
Everg (degrees)
Everg (degrees)
conv
div
a
b 0 Lid
Lid
open 500 ms
close
1
c
d
div
5º/s
Vverg (degrees/s)
con
100 ms
e
f
Fig. 4. Eye position traces are shown for vergence position (a, b) and lid position (c, d) in one healthy subject. The two different vergence directions, convergence (a, c), and divergence (b, d) are shown separately. a–d Thick solid lines indicate the mean of the control condition (without blinks), while the dashed lines show recordings during the blink condition. The long dashed line indicates the end of the blink. The gray inset (a, b) represents the part shown below at higher resolution and as vergence velocity in e, f . e, f Thick solid lines indicate the vergence velocity in the control condition (dotted lines ⫾ 1 standard deviation), and thin solid lines vergence velocity in the blink condition. The arrows mark the late peak vergence velocity. All traces are aligned to blink onset and shifted for better comparison; modified after Rambold et al. [68], with permission.
This effect is also time dependent; the earlier blinks start before the vergence onset, the more their duration is increased and peak velocity decreased [42]. The blink effect on transient vergence movements may be related to changes in the brainstem premotor circuit, including the OPNs [68], since OPNs also control vergence burst neurons [85]. Accordingly, stimulation of the OPN area slows vergence movements [85]. The peak of vergence velocity depends on the stimulus direction when a reflexive blink is elicited during sustained vergence [68] (fig. 4). This velocity peak shows oscillations (1.7–3.3 Hz) similar to vergence oscillations [25, 83]. These oscillations may be caused by the inhibition of OPNs leading to a disinhibition of the vergence systems. Blinks and Saccade-Vergence Interaction To perform saccades in space, conjugate and vergence eye movements are elicited together [86]. Blinks also exert a distinct influence on combined
Helmchen/Rambold
118
a
0
500 ms
10 deg/s 10 deg/s
100 deg/s
0
Delta velocity
100 deg/s 0
0
Leftward 0
Lid position
Lid position
Eye velocity
Rightward
0
b
100 ms
Fig. 5. Eye velocity responses of step-ramp smooth pursuit (target: thin, solid line) are shown for the blink paradigm (gray lines) in rightward (1st trace) and leftward (2nd trace) directions. The mean desaccaded control pursuit velocity (control paradigm; bold solid line) is superimposed. Below each plot, the lid position is shown (3rd trace). Blink-associated eye movements are marked by asterisks. The other fast peaks in eye velocity reflect saccades that occur with some pause before or after the blink, but not during the blink. After the blinkassociated eye movements, there is a velocity decrease compared to control for both directions and subjects. b The pursuit velocity (mean: solid black line; individual data: thin gray lines) in the blink and control paradigms are subtracted for rightward (1st trace) and leftward (2nd trace) pursuit directions for the interval indicated by the dashed rectangle in a. All data are aligned to maximal lid closure during the blink. Negative velocity indicates a decrease compared to that of the control; modified after Rambold et al. [65], with permission.
saccade-vergence eye movements: both components are decreased in peak velocity, acceleration, deceleration, and increased in duration [42]. This effect might be related to the inhibitory effect of blinks on the OPNs [79, 80, 87]. Blinks and Smooth Pursuit Eye Movements Introducing a blink just before target onset in a step-ramp smooth pursuit paradigm causes a decrease in pursuit latency of about 10 ms. This effect is on the average less than the gap effect of 35 ms in a gap paradigm (extinguishing the visual stimulus before target onset) when using a comparable gap and blink duration [41]. Saccades are suppressed during the blink but not during the gap [65]. When a reflexive blink is introduced during ongoing smooth pursuit there are blink-associated eye movements, which are followed by a decrease in pursuit velocity (fig. 5). This decrease is independent of the direction and the blink
The Eyelid and Its Contribution to Eye Movements
119
amplitude, i.e. regardless of whether it covers or does not cover the pupil. Immediately before and during the blinks, correcting saccades are suppressed. These effects are probably not related to blanking the visual target but rather to changes of the activity of OPNs or to visual suppression [65]. The activity of 50% of the OPNs is decreased during ongoing smooth pursuit [88]. Electrical stimulation of the OPN area during ongoing smooth pursuit decelerates smooth pursuit eye movements [88].
Clinical Disorders of the Eyelid and Its Interaction with Saccades
Disorders of Blink Frequency The spontaneous blink frequency shows a high interindividual variability (10–30/min; on average, 24 blinks/min) [89]. The mean amplitude and peak velocity of spontaneous blinks decrease with age. This is also true of voluntary blinks, but to a less extent [90, 91]. Here, the narrowing of the palpebral fissure width probably plays a role. Alternatively, the reduction in the blink main sequence could reflect a reduction in OO motoneuron activity, which compensates for age-related increases in blink reflex excitability. In contrast, blink frequency and blink conjugacy do not change with age [90, 92]. Blink frequency is strongly modulated by attentional mechanisms under normal and pathological conditions, e.g., in schizophrenic patients [93]. In contrast to reflexive blinks, voluntary blinks may crucially depend on internal vs. external commands, e.g. in parkinsonian syndromes. Special forms of increased blink frequency are lid nystagmus and eyelid tremor. Lid nystagmus is usually associated with eye movements, is gaze dependent, and modulated by vergence eye movements [94, 95]. It reflects a slow downward drift of the lids with correcting upward jerks of the upper eyelid. Due to the tight lid-eye coupling, vertical nystagmus may be associated with lid nystagmus. While it may be benign [96], it is usually associated with lateral medullary infarction [97] or cerebellar or midbrain disease, e.g. lowgrade astrocytoma compressing the CCN [98]. Lid nystagmus may outlast vertical nystagmus [99]. Lid nystagmus may also occur without eye nystagmus due to midbrain lesions [25, 98, 100]. Vestibular stimulation in midbrain-lesioned monkeys causes an upward lid nystagmus, although upbeating nystagmus was abolished [101]. Lid nystagmus with a horizontal nystagmus is found in lateral medullary lesion (Wallenberg’s syndrome), which may be inhibited by convergence [97]. In contrast, eyelid nystagmus may also be elicited by convergence in medullary and cerebellar lesions (Pick’s sign) [94, 102, 103]. Eyelid tremor is defined as regular eyelid twitches of 7 Hz and is usually not gaze dependent. In contrast, blepharoclonus consists of repetitive eyelid
Helmchen/Rambold
120
jerks at a slower frequency (2–4 Hz) and may be induced by eye closure [104]. Eyelid tremor may be associated with parkinsonian syndromes [105], but also paramedian thalamic lesions [106]. It is still not known whether the presumed disinhibition of LPM and OO muscle activity is related to the thalamus, the extension of the lesion into the midbrain, or disconnecting cortical areas involved in voluntary lid control. Pathophysiologically, inappropriate contractions of LPM and OO with disturbed reciprocal inhibition have been proposed [19]. In animal experiments, blink rates significantly and positively correlated with the concentration of dopamine in the caudate nucleus, and the severity of experimentally induced parkinsonism was inversely correlated with the blink rate [107]. Accordingly, since spontaneous blink frequency probably reflects central dopamine activity, it is characteristically decreased in parkinsonian syndromes (17 blinks per minute) [108], although it may vary in the ‘off’ and ‘on’ periods of patients with fluctuating Parkinson’s disease (PD) [109]. Blink rate decreases as PD advances [110], but also de novo PD patients who have not been exposed to dopaminergic therapy show decreased blink rates [108]. The blink rate in patients with levodopa-induced dyskinesias has been shown to be higher than that in optimally treated PD patients and normal individuals [111]. It is consistently found to be decreased in progressive supranuclear palsy (PSP) [112], patients with PD [89], and those patients who receive dopaminergic medication [113], whereas it is not changed in Huntington’s disease and dystonia. The strongest decrease is found in PSP patients (4 blinks per minute) [89]. In addition, dopaminergic basal ganglia circuits play a role in the inhibition of LPM during blinks and eye closure [19]. As a major adverse effect, decreased blink rate in PD leads to ocular surface irritation (blepharitis), the most common ocular complaint of PD patients [108]. Apart from recording changes in blink rate, the blink reflex has been established to be a reliable diagnostic tool for assessing the site of brainstem lesions, in particular lesions in the dopaminergic circuit, which controls eyelid blink. The blink reflex is known to be hyperexcitable in PD [92, 114–116]. Pathophysiologically, the loss of dopamine in the substantia nigra pars compacta may lead to increased reflex blink excitability. Descending inhibitory pathways from the basal ganglia modulate the excitability via tectoreticular projections. Decreasing the basal ganglia inhibitory output to the SC and electrical stimulation of the SC reduce blink hyperexcitability and blink amplitude [114]. According to the latter model, the substantia nigra pars reticulata inhibits SC neurons, which excite tonically active neurons of the raphe magnus nucleus. The latter inhibits spinal trigeminal neurons involved in reflex blink circuits [115]. Thus, changes in reflex blink excitability and blink amplitude may help to detect early or preclinical signs in PD. Since a reflex blink inhibits subsequent blinks,
The Eyelid and Its Contribution to Eye Movements
121
the magnitude of a blink reflects a balance between inhibitory and facilitatory processes [117]. Disorders of Tonic Eyelid Position The eyelid position is greatly influenced by cortical and brainstem mechanisms. Thus, ptosis may result from midbrain and cortical lesions. Midbrain lesions involving the caudal third nerve nucleus (CCN) elicit complete bilateral ptosis since the LPMs are deficient [118–123]. Nuclear third nerve lesions with CCN involvement may elicit bilateral ptosis with contralateral superior rectus paresis [124]. Isolated CCN lesions are rare but may preserve ocular motility [125, 126]. In contrast to the complete ptosis in lesions of the LPM, sympathetic lesions elicit a slight upper lid depression, e.g. in Horner’s syndrome, which may be caused by carotid artery occlusion or dissection (peripheral) or lateral medullary infarctions (central Horner’s syndrome) [120]. Unilateral ptosis may result from fascicular or peripheral third nerve palsy [127] or large hemispheric lesions, probably related to descending corticonuclear pathways of eyelid control [120]. Weber’s syndrome and Claude’s syndrome reflect unilateral fascicular third nerve lesion with contralateral hemiataxia or hemiparesis. Cortical bifrontal or unilateral, predominantly right-hemispheric, lesions may elicit bilateral ptosis [31, 32, 128, 129]. Controversial data exist as to which side is more strongly affected: the contralateral [120] or ipsilateral eye [32]. Fourteen of 24 patients with hemispheric strokes had predominantly ipsilateral ptosis, which is probably related to an associated facial weakness superimposed on the asymmetry of the palpebral fissures of bilateral partial ptosis [32]. Otherwise, the common concept of a single motor nucleus innervating both levators would have to be challenged. Two additional conditions with involuntary eyelid closure or the inability to open the eyelids are blepharospasm and blepharocolysis. Pathological involuntary eyelid closure may result from a deficient excitation, a prolonged inhibition of the LPM (blepharocolysis), or involuntary excitation of the OO muscles, e.g. focal dystonia (blepharospasm). Blepharospasm is an excessive involuntary focal dystonic unilateral or bilateral contraction of the OO muscles with LP muscle cocontraction. It is characterized by frequent and prolonged blinks, clonic bursts, and prolonged tonic OO contraction [130]. Clinically, the brows are lowered below the superior orbital rim (Charcot’s sign). Accordingly, EMG recordings of the LPM and OO muscles simultaneously show impaired timing of the reciprocal inhibition, which may lead clinically to dystonic blinks [48] and electrophysiologically facilitate the R2 component of the blink reflex [131]. Cases of unilateral lid spasm may occur in conjunction with unilateral or hemifacial spasm. The most common cause of hemifacial spasm is irritation of the seventh nerve roots by a dilated or tortuous vascular structure. Blepharospasm has also
Helmchen/Rambold
122
been reported to occur with thalamic [132, 133], subthalamic [132, 134], and brainstem [135, 136] lesions, but it is often associated with PD or PSP [137]. Benign essential blepharospasm may be caused by an overexcitatory drive of the basal ganglia. As initial treatment, artificial tear drops are recommended, since ocular surface irritation (due to decreased blink rate) may also contribute to increased OO tone [108]. Blepharospasm may also be secondary to Bell’s palsy and may be relieved by passive eyelid lowering [138]. Otherwise, injections of botulinum toxin to weaken the affected muscles, in particular the pretarsal portion of the upper eyelid, are the appropriate treatment [139–141]. Blepharospasm may be restricted to dystonic contraction of only the pretarsal portion of the OO without concomitant contraction of the OO (pretarsal LP inhibition, pretarsal blepharospasm) [142]. In contrast to the typical blepharospasm, the eyes appear to be nearly closed, and there is a concomitant contraction of the frontal muscles and elevation of the brows. Moreover, the blink frequency is reduced. Patients usually suffer from PD or PSP. Tactile sensory stimulation (eyelash touching or glabellar tapping) may help to release the dystonic position. Blepharocolysis is a similar – possibly identical – condition characterized by an excessive involuntary closure of the eyelids due to involuntary LPM inhibition. The inappropriate, synonymous term ‘apraxia of eyelid opening,’ previously widely used, describes the inability of voluntary eyelid opening [143] and of sustained lid elevation [139] caused by an involuntary LPM inhibition. In contrast to blepharospasm, blepharocolysis is due to an involuntary overinhibition of the levator palpebrae superioris muscles with no evidence of ongoing OO activity; it coexists with a coinhibition of these muscles [130], as confirmed by simultaneous EMG recordings of the LP and OO muscles [139]. EMG recordings help to separate pretarsal blepharospasm from blepharocolysis and to make adequate therapeutic decisions. Since reflectory blinks remain largely unaffected, it is likely to be a disorder of the supranuclear LP control. However, the mechanism is only partly understood. Blepharocolysis is associated with PD, PSP, motor neuron disease, and putaminal [144] and subthalamic lesions [134]. Its prevalence is about 10% in patients with dystonia, and about 2% in patients with parkinsonian syndromes (PD, 0.7%; PSP, 33.3%) [145]. Finally, under certain circumstances, the activity in the OO may only persist on voluntary eyelid opening but not when the eyes are open. This form of pretarsal motor persistence [139] does not reveal any lid depression and is therefore distinctly different from blepharocolysis. It also responds positively to botulinum toxin. Although lid retraction also reflects a tonic eyelid disorder, it leads to impaired eyelid-eye coordination and will be discussed below.
The Eyelid and Its Contribution to Eye Movements
123
Disorders of Eyelid-Eye Coordination Lid-eye coordination is preserved in most pathological eye movements. For example, in vertical nystagmus the lid usually accompanies the eye movement [146]. Disorders of eyelid-eye coordination occur when lid saccades are impaired but eye saccades preserved. Involuntary lid movement without accompanying vertical eye movement, e.g. in lid nystagmus, is less frequent. Lid nystagmus without vertical nystagmus may be elicited on horizontal gaze, e.g. reported in a case of midbrain astrocytoma [98]. In midbrain lesions in the monkey, vestibular stimulation caused an upward lid nystagmus, although the upbeat nystagmus was abolished [101]. In accordance with the anatomical connections outlined above, lid nystagmus may imply lesions of the M group, the nPC, or their reciprocal connections. Lid lag and lid retraction are the most common disorders of impaired eyelid-eye coordination [147]. Whereas lid lag is a dynamic sign, which can be observed on downgaze, lid retraction is a static phenomenon. Lid retraction is diagnosed when the sclera is seen above the corneal limbus during steady fixation. It indicates inappropriate LP muscle activity, presumably related to neurogenic disinhibition of LP [19], but EMG evidence is still missing. The basal tonic LPM activity is likely to be under the inhibitory control of the nPC [12]. Deficient inhibition would result in lid retraction on gaze straight ahead or lid lag with downgaze [147]. A clinicopathological retrospective correlation study based on animal [18, 148] and human [149] case studies delineated the nPC as the most likely lesion site for lid retraction [19]. This is consistent with very few eyelidand vertical saccade-related burst neurons that have been recorded in nPC [150]. Although lid lag and lid retraction may occur together [151], a feasible pathomechanism has to account for lesions that cause only either lid lag or lid retraction. A single case report showing a patient with slow vertical saccades and lid lag but no lid retraction [152] suggests separate pathways for both clinical signs. This lesion spared the nPC but probably affected the M group. It remains open whether dynamic and static lid-eye coordination is controlled by separate pathways. Lid retraction is seen in ischemic midbrain lesions, e.g. Parinaud’s syndrome, and extrapyramidal syndromes, e.g. PD and PSP [153, 154]. The prevalence of lid retraction/lid lag in PD patients is not exactly known, but preliminary data indicate up to 37% of patients [147]. In incomplete vertical gaze palsy caused by midbrain lesions, the lid appears to follow the eye, but it may also cause a lid saccade [19, 155]. In the case of upward gaze palsy, the lids may retain the ability to elevate during attempted vertical upgaze, i.e. so-called ‘pseudoretraction’. In turn, the lid may lower during attempted downgaze in downgaze saccade palsy, leading to ‘pseudoptosis’ [19]. Eye-lid coordination in mesencephalic lesions has not yet been systematically examined in detail.
Helmchen/Rambold
124
Clinical Application of Lid Movements
Blinks and the Initiation of Eye Movements Under certain circumstances, blinks might slow eye movements down, speed them up, or elicit specific eye movements. Patients with posterior fossa lesions, for example, were found to have saccades of normal velocity, but only if a blink was simultaneously elicited [156]. In patients with ocular flutter and opsoclonus, eye movement oscillations are often elicited by blinks [157, 158]. Peli and McCormack [159] reported on a patient with uncorrected antimetropia (one eye is myopic, the fellow eye hyperopic) who achieved motor fusion by blinking. Although this patient could have used saccadic vergence and slow fusional vergence, he usually relied on blink vergence. These observations might also be explained by the inhibition of OPNs. Blinks may also be used to initiate saccades in ocular motor apraxia [160]. Ocular motor apraxia is characterized by the loss of voluntary control of saccades but by preserved reflectory saccades of the optokinetic reflex and the vestibulo-ocular reflex. Most of these clinical observations have been attributed to the inhibition of OPNs, which facilitates the execution of saccades. Blinks Unmasking Vestibular Imbalance Blinks may exhibit blink-related torsional quick-phase-like eye movements in patients with acute or persisting vestibular tone imbalance, e.g. in vestibular neuritis or a circumscribed brainstem infarction in the vestibular nuclei [161]. These blinks were followed by slow drifts with a time constant of 1–2 s, suggesting an unmasking of a vestibular tone imbalance. It has therefore been proposed that blinks might be another useful clinical test for identifying a persistent vestibular failure once spontaneous nystagmus has resolved. References 1 2 3 4 5
6
Evinger C, Shaw MD, Peck CK, Manning KA, Baker R: Blinking and associated eye movements in humans, guinea pigs, and rabbits. J Neurophysiol 1984;52:323–339. Evinger C, Manning KA, Sibony PA: Eyelid movements. Mechanisms and normal data. Invest Ophthalmol Vis Sci 1991;32:387–400. Gruart A, Blazquez P, Delgado-Garcia JM: Kinematics of spontaneous, reflex, and conditioned eyelid movements in the alert cat. J Neurophysiol 1995;74:226–248. Spencer RF, Porter JD: Structural organization of the extraocular muscles. Rev Oculomot Res 1988;2:33–79. Porter JD, Burns LA, May PJ: Morphological substrate for eyelid movements: innervation and structure of primate levator palpebrae superioris and orbicularis oculi muscles. J Comp Neurol 1989;287:64–81. Fuchs AF, Becker W, Ling L, Langer TP, Kaneko CR: Discharge patterns of levator palpebrae superioris motoneurons during vertical lid and eye movements in the monkey. J Neurophysiol 1992;68:233–243.
The Eyelid and Its Contribution to Eye Movements
125
7 8 9 10 11 12 13 14
15
16 17 18 19 20 21 22 23 24 25 26
27 28 29 30 31 32 33
Becker W, Fuchs AF: Lid-eye coordination during vertical gaze changes in man and monkey. J Neurophysiol 1988;60:1227–1252. Wouters RJ, van den Bosch WA, Stijnen T, Bubberman AC, Collewijn H, Lemij HG: Conjugacy of eyelid movements in vertical eye saccades. Invest Ophthalmol Vis Sci 1995;36:2686–2694. Williamson SS, Zivotofsky AZ, Basso MA: Modulation of gaze-evoked blinks depends primarily on extraretinal factors. J Neurophysiol 2005;93:627–632. Kennard D, Glaser G: An analysis of eyelid movements. J Nerv Ment Dis 1964;139:31–48. Guitton D, Simard R, Codere F: Upper eyelid movements measured with a search coil during blinks and vertical saccades. Invest Ophthalmol Vis Sci 1991;32:3298–3305. Gong S, DeCuypere M, Zhao Y, LeDoux MS: Cerebral cortical control of orbicularis oculi motoneurons. Brain Res 2005;1047:177–193. Esteban A, Salinero E: Reciprocal reflex activity in ocular muscles: implications in spontaneous blinking and Bell’s phenomenon. Eur Neurol 1979;18:157–165. Chen B, May PJ: Premotor circuits controlling eyelid movements in conjunction with vertical saccades in the cat: I. the rostral interstitial nucleus of the medial longitudinal fasciculus. J Comp Neurol 2002;450:183–202. Horn AK, Büttner-Ennever JA, Gayde M, Messoudi A: Neuroanatomical identification of mesencephalic premotor neurons coordinating eyelid with upgaze in the monkey and man. J Comp Neurol 2000;420:19–34. Büttner-Ennever JA, Buttner U: Neuroanatomy of the oculomotor system. The reticular formation. Rev Oculomot Res 1988;2:119–176. Christoff N: A clinicopathologic study of vertical eye movements. Arch Neurol 1974;31:1–8. Carpenter MB, Harbison JW, Peter P: Accessory oculomotor nuclei in the monkey: projections and effects of discrete lesions. J Comp Neurol 1970;140:131–154. Schmidtke K, Buttner-Ennever JA: Nervous control of eyelid function. A review of clinical, experimental and pathological data. Brain 1992;115(pt 1):227–247. Pasik T, Pasik P: Experimental models of oculomotor dysfunction in the rhesus monkey. Adv Neurol 1975;10:77–89. Galetta SL, Gray LG, Raps EC, Schatz NJ: Pretectal eyelid retraction and lag. Ann Neurol 1993;33:554–557. Moschovakis AK, Scudder CA, Highstein SM: Structure of the primate oculomotor burst generator. I. Medium-lead burst neurons with upward on-directions. J Neurophysiol 1991;65:203–217. Crawford JD, Cadera W, Vilis T: Generation of torsional and vertical eye position signals by the interstitial nucleus of Cajal. Science 1991;252:1551–1553. Fukushima K: The interstitial nucleus of Cajal in the midbrain reticular formation and vertical eye movement. Neurosci Res 1991;10:159–187. Leigh RJ, Zee DS: The Neurology of Eye Movements, ed 3. New York, Oxford University Press, 1999. Büttner-Ennever JA, Jenkins C, Armin-Parsa H, Horn AK, Elston JS: A neuroanatomical analysis of lid-eye coordination in cases of ptosis and downgaze paralysis. Clin Neuropathol 1996;15:313–318. Bhidayasiri R, Plant GT, Leigh RJ: A hypothetical scheme for the brainstem control of vertical gaze. Neurology 2000;54:1985–1993. Horn AK, Buttner-Ennever JA, Wahle P, Reichenberger I: Neurotransmitter profile of saccadic omnipause neurons in nucleus raphe interpositus. J Neurosci 1994;14:2032–2046. Goossens HH, Van Opstal AJ: Blink-perturbed saccades in monkey. II. Superior colliculus activity. J Neurophysiol 2000;83:3430–3452. Goossens HH, Van Opstal AJ: Blink-perturbed saccades in monkey. I. Behavioral analysis. J Neurophysiol 2000;83:3411–3429. Averbuch-Heller L, Stahl JS, Remler BF, Leigh RJ: Bilateral ptosis and upgaze palsy with right hemispheric lesions. Ann Neurol 1996;40:465–468. Averbuch-Heller L, Leigh RJ, Mermelstein V, Zagalsky L, Streifler JY: Ptosis in patients with hemispheric strokes. Neurology 2002;58:620–624. Afifi AK, Corbett JJ, Thompson HS, Wells KK: Seizure-induced miosis and ptosis: association with temporal lobe magnetic resonance imaging abnormalities. J Child Neurol 1990;5:142–146.
Helmchen/Rambold
126
34 35 36
37 38
39
40 41 42
43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59
Benbadis SR, Kotagal P, Klem GH: Unilateral blinking: a lateralizing sign in partial seizures. Neurology 1996;46:45–48. Bodis-Wollner I, Bucher SF, Seelos KC: Cortical activation patterns during voluntary blinks and voluntary saccades. Neurology 1999;53:1800–1805. van Eimeren T, Boecker H, Konkiewitz EC, Schwaiger M, Conrad B, Ceballos-Baumann AO: Right lateralized motor cortex activation during volitional blinking. Ann Neurol 2001;49: 813–816. Leichnetz GR, Hardy SG, Carruth MK: Frontal projections to the region of the oculomotor complex in the rat: a retrograde and anterograde HRP study. J Comp Neurol 1987;263:387–399. Leichnetz GR, Spencer RF, Smith DJ: Cortical projections to nuclei adjacent to the oculomotor complex in the medial dien-mesencephalic tegmentum in the monkey. J Comp Neurol 1984;228: 359–387. Leichnetz GR, Gonzalo-Ruiz A: Prearcuate cortex in the Cebus monkey has cortical and subcortical connections like the macaque frontal eye field and projects to fastigial-recipient oculomotorrelated brainstem nuclei. Brain Res Bull 1996;41:1–29. Delgado-Garcia JM, Gruart A, Trigo JA: Physiology of the eyelid motor system. Ann N Y Acad Sci 2003;1004:1–9. Rambold H, El Baz I, Helmchen C: Differential effects of blinks on horizontal saccade and smooth pursuit initiation in humans. Exp Brain Res 2004;156:314–324. Rambold H, Sprenger A, Helmchen C: Effects of voluntary blinks on saccades, vergence eye movements, and saccade-vergence interactions in humans. J Neurophysiol 2002;88: 1220–1233. Gerwig M, Dimitrova A, Kolb FP, et al: Comparison of eyeblink conditioning in patients with superior and posterior inferior cerebellar lesions. Brain 2003;126(pt 1):71–94. Timmann D, Gerwig M, Frings M, Maschke M, Kolb FP: Eyeblink conditioning in patients with hereditary ataxia: a one-year follow-up study. Exp Brain Res 2005;162:332–345. Bour LJ, Aramideh M, de Visser BW: Neurophysiological aspects of eye and eyelid movements during blinking in humans. J Neurophysiol 2000;83:166–176. Gruart A, Schreurs BG, del Toro ED, Delgado-Garcia JM: Kinetic and frequency-domain properties of reflex and conditioned eyelid responses in the rabbit. J Neurophysiol 2000;83:836–852. Rottach KG, Das VE, Wohlgemuth W, Zivotofsky AZ, Leigh RJ: Properties of horizontal saccades accompanied by blinks. J Neurophysiol 1998;79:2895–2902. Esteban A, Traba A, Prieto J: Eyelid movements in health and disease. The supranuclear impairment of the palpebral motility. Neurophysiol Clin 2004;34:3–15. Manning KA, Riggs LA, Komenda JK: Reflex eyeblinks and visual suppression. PerceptPsychophys 1983;34:250–256. Ridder WH, Tomlinson A: Spectral characteristics of blink suppression in normal observers. Vision Res 1995;35:2569–2578. Ridder WH, Tomlinson A: A comparison of saccadic and blink suppression in normal observers. Vision Res 1997;37:3171–3179. Stevenson SB, Volkmann FC, Kelly JP, Riggs LA: Dependence of visual suppression on the amplitudes of saccades and blinks. Vision Res 1986;26:1815–1824. Volkmann FC, Riggs LA, Moore RK: Eyeblinks and visual suppression. Science 1980;207: 900–902. Volkmann FC, Riggs LA, White KD, Moore RK: Contrast sensitivity during saccadic eye movements. Vision Res 1978;18:1193–1199. Ridder WH, Tomlinson A: Suppression of contrast sensitivity during eyelid blinks. Vision Res 1993;33:1795–1802. Bristow D, Haynes JD, Sylvester R, Frith CD, Rees G: Blinking suppresses the neural response to unchanging retinal stimulation. Curr Biol 2005;15:1296–1300. Bristow D, Frith C, Rees G: Two distinct neural effects of blinking on human visual processing. Neuroimage 2005;27:136–145. Wilkins RH, Brody IA: Bell’s palsy and Bell’s phenomenon. Arch Neurol 1969;21:661–662. Collewijn H, van der Steen J, Steinman RM: Human eye movements associated with blinks and prolonged eyelid closure. J Neurophysiol 1985;54:11–27.
The Eyelid and Its Contribution to Eye Movements
127
60 61 62 63 64 65 66 67 68 69 70
71 72 73 74 75 76 77 78 79 80 81 82 83 84 85
86
Riggs LA, Kelly JP, Manning KA, Moore RK: Blink-related eye movements. Invest Ophthalmol Vis Sci 1987;28:334–342. Rambold H, El Baz I, Helmchen C: Effect of blinks on saccades before smooth-pursuit eyemovement initiation. Ann NY Acad Sci 2005;1039:563–566. Bergamin O, Bizzarri S, Straumann D: Ocular torsion during voluntary blinks in humans. Invest Ophthalmol Vis Sci 2002;43:3438–3443. Straumann D, Zee DS, Solomon D, Kramer PD: Validity of Listing’s law during fixations, saccades, smooth pursuit eye movements, and blinks. Exp Brain Res 1996;112:135–146. Evinger C, Manning KA: Pattern of extraocular muscle activation during reflex blinking. Exp Brain Res 1993;92:502–506. Rambold H, El Baz I, Helmchen C: Blink effects on ongoing smooth pursuit eye movements in humans. Exp Brain Res 2005;161:11–26. Rambold H, El B, I, Helmchen C: Effect of Blinks on Saccades before Smooth-Pursuit EyeMovement Initiation. Ann NY Acad Sci 2005;1039:563–566. Rambold H, El Baz I, Helmchen C: Differential effects of blinks on horizontal saccade and smooth pursuit initiation in humans. Exp Brain Res 2004;156:314–324. Rambold H, Neumann G, Sprenger A, Helmchen C: Blink effect on slow vergence. Neuroreport 2002;13:2041–2044. Gandhi NJ, Bonadonna DK: Temporal interactions of air-puff-evoked blinks and saccadic eye movements: insights into motor preparation. J Neurophysiol 2005;93:1718–1729. Hepp K, Henn V, Vilis T, Cohen B. Brainstem regions related to saccade generation; in Wurtz RH, Goldberg ME (eds): The Neurobiology of Saccadic Eye Movements. Amsterdam, Elsevier, 1989, pp 105–212. Büttner-Ennever J, Büttner U. The reticualr formation; in Büttner-Ennever J (ed): Neuroanatomy of the Oculomotor System. Amsterdam, Elsevier, 1988. Zee DS, Fitzgibbon EJ, Optican LM: Saccade-vergence interactions in humans. J Neurophysiol 1992;68:1624–1641. Evinger C, Kaneko CR, Fuchs AF: Activity of omnipause neurons in alert cats during saccadic eye movements and visual stimuli. J Neurophysiol 1982;47:827–844. Keller EL: Control of saccadic eye movements by midline brainstem neurons; in Baker R, Berthoz A (eds): Control of Gaze by Brainstem Neurons. Amsterdam, Elsevier, 1977. Busettini C, Mays LE: Pontine omnipause activity during conjugate and disconjugate eye movements in macaques. J Neurophysiol 2003;90:3838–3853. Kaneko CR: Effect of ibotenic acid lesions of the omnipause neurons on saccadic eye movements in rhesus macaques. J Neurophysiol 1996;75:2229–2242. Cohen B, Henn V: Unit activity in the pontine reticular formation associated with eye movements. Brain Res 1972;46:403–410. Fuchs AF, Ling L, Kaneko CRS, King W, Usher SD: The timing of the response of brainstem omnipause neurons relative to saccadic eye movements in the rhesus monkey. 1991;17:462. Mays LE, Morrisse EJ: Activity of omnipause neurons during blinks. Soc Neurosci 1993;19:1404. Mays LE, Morrisse DW: Electrical stimulation of the pontine omnipause area inhibits eye blink. J Am Optom Assoc 1995;66:419–422. Miura K, Optican LM: Saccadic slowing after inactivation of omnipause neuron may be caused by the membrane characteristics of brainstem burst neurons. 2002;716.8. Rambold H, Sander T, Neumann G, Helmchen C: Palsy of ‘fast’ and ‘slow’ vergence by pontine lesions. Neurology 2005;64:338–340. Semmlow JL, Yuan W, Alvarez TL: Evidence for separate control of slow version and vergence eye movements: support for Hering’s Law. Vision Res 1998;38:1145–1152. Erkelens CJ: Adaptation of ocular vergence to stimulation with large disparities. Exp Brain Res 1987;66:507–516. Mays LE, Gamlin PDR. A neuronal mechanism subserving saccade-vergence interactions; in Findlay JM, Walker R, Kentridge RW (eds): Eye Movement Research: Mechanism, Processes, Applications. Amsterdam, Elsevier, 1995, pp 215–223. Kumar AN, Han Y, Dell’osso LF, Durand DM, Leigh RJ: Directional asymmetry during combined saccade-vergence movements. J Neurophysiol 2005;93:2797–2808.
Helmchen/Rambold
128
87 Busettini C, Mays LE: Saccade-vergence interaction in macaques. II. Vergence eenhancement as the product of a local feedback vergence motor error and a weighted saccadic burst. J Neurophysiol 2005;in press. 88 Missal M, Keller EL: Common inhibitory mechanism for saccades and smooth-pursuit eye movements. J Neurophysiol 2002;88:1880–1892. 89 Karson CN, Burns RS, LeWitt PA, Foster NL, Newman RP: Blink rates and disorders of movement. Neurology 1984;34:677–678. 90 Sun WS, Baker RS, Chuke JC, et al: Age-related changes in human blinks. Passive and active changes in eyelid kinematics. Invest Ophthalmol Vis Sci 1997;38:92–99. 91 Wouters RJ, van den Bosch WA, Mulder PG, Lemij HG: Upper eyelid motility in blepharoptosis and in the aging eyelid. Invest Ophthalmol Vis Sci 2001;42:620–625. 92 Deuschl G, Goddemeier C: Spontaneous and reflex activity of facial muscles in dystonia, Parkinson’s disease, and in normal subjects. J Neurol Neurosurg Psychiatry 1998;64:320–324. 93 Karson CN, Dykman RA, Paige SR: Blink rates in schizophrenia. Schizophr Bull 1990;16: 345–354. 94 Sanders MD, Hoyt WF, Daroff RB: Lid nystagmus evoked by ocular convergence: an ocular electromyographic study. J Neurol Neurosurg Psychiatry 1968;31:368–371. 95 Safran AB, Berney J, Safran E: Convergence-evoked eyelid nystagmus. Am J Ophthalmol 1982;93:48–51. 96 Ticho U: Synkinesis of upper lid elevation occurring in horizontal eye movements. Acta Ophthalmol (Copenh) 1971;49:232–238. 97 Daroff RB, Hoyt WF, Sanders MD, Nelson LR: Gaze-evoked eyelid and ocular nystagmus inhibited by the near reflex: unusual ocular motor phenomena in a lateral medullary syndrome. J Neurol Neurosurg Psychiatry 1968;31:362–367. 98 Brodsky MC, Boop FA: Lid nystagmus as a sign of intrinsic midbrain disease. J Neuroophthalmol 1995;15:236–240. 99 Rohmer F, Conraux C, Collard M: Convergence nystagmus and palpebral nystagmus. Rev Otoneuroophtalmol 1972;44:89–94. 100 Brusa A, Massa S, Piccardo A, Stoehr R, Bronzini E: Palpebral nystagmus. Rev Neurol (Paris) 1984;140:288–292. 101 Pasik T, Pasik P, Bender MB: The pretectal syndrome in monkeys. II. Spontaneous and induced nystagmus, and ‘lightning’ eye movements. Brain 1969;92:871–884. 102 Howard RS: A case of convergence evoked eyelid nystagmus. J Clin Neuroophthalmol 1986;6: 169–171. 103 Safran AB, Berney J: Synchronism of reverse ocular bobbing and blinking. Am J Ophthalmol 1983;95:401–402. 104 Jacome DE: Synkinetic blepharoclonus. J Neuroophthalmol 2000;20:276–284. 105 Slatt B, Loeffler JD, Hoyt WF: Ocular motor disturbances in Parkinson’s disease electromyographic observations. Can J Ophthalmol 1966;1:267–273. 106 Jungehulsing GJ, Ploner CJ: Eyelid tremor in a patient with a unilateral paramedian thalamic lesion. J Neurol Neurosurg Psychiatry 2003;74:356–358. 107 Taylor JR, Elsworth JD, Lawrence MS, Sladek JR Jr, Roth RH, Redmond DE Jr: Spontaneous blink rates correlate with dopamine levels in the caudate nucleus of MPTP-treated monkeys. Exp Neurol 1999;158:214–220. 108 Biousse V, Skibell BC, Watts RL, Loupe DN, Drews-Botsch C, Newman NJ: Ophthalmologic features of Parkinson’s disease. Neurology 2004;62:177–180. 109 Kimber TE, Thompson PD: Increased blink rate in advanced Parkinson’s disease: a form of ‘off’period dystonia? Mov Disord 2000;15:982–985. 110 Karson CN, LeWitt PA, Calne DB, Wyatt RJ: Blink rates in parkinsonism. Ann Neurol 1982;12: 580–583. 111 Hallet M: Clinical physiology of dopa dyskinesia. Ann Neurol 2000;47:147–150. 112 Pfaffenbach DD, Layton DD Jr, Kearns TP: Ocular manifestations in progressive supranuclear palsy. Am J Ophthalmol 1972;74:1179–1184. 113 Karson CN: Spontaneous eye-blink rates and dopaminergic systems. Brain 1983;106(pt 3): 643–653.
The Eyelid and Its Contribution to Eye Movements
129
114 Basso MA, Powers AS, Evinger C: An explanation for reflex blink hyperexcitability in Parkinson’s disease. I. Superior colliculus. J Neurosci 1996;16:7308–7317. 115 Basso MA, Evinger C: An explanation for reflex blink hyperexcitability in Parkinson’s disease. II. Nucleus raphe magnus. J Neurosci 1996;16:7318–7330. 116 Basso MA, Strecker RE, Evinger C: Midbrain 6-hydroxydopamine lesions modulate blink reflex excitability. Exp Brain Res 1993;94:88–96. 117 Powers AS, Schicatano EJ, Basso MA, Evinger C: To blink or not to blink: inhibition and facilitation of reflex blinks. Exp Brain Res 1997;113:283–290. 118 Liu GT, Carrazana EJ, Charness ME: Unilateral oculomotor palsy and bilateral ptosis from paramedian midbrain infarction. Arch Neurol 1991;48:983–986. 119 Growdon JH, Winkler GF, Wray SH: Midbrain ptosis. A case with clinicopathologic correlation. Arch Neurol 1974;30:179–181. 120 Caplan LR: Ptosis. J Neurol Neurosurg Psychiatry 1974;37:1–7. 121 Zackon DH, Sharpe JA: Midbrain paresis of horizontal gaze. Ann Neurol 1984;16:495–504. 122 Dehaene I, Dom R, Marchau M, Geens K: Locked-in syndrome with bilateral ptosis: combination of bilateral horizontal pontine gaze paralysis and nuclear oculomotor nerve paralysis. J Neurol 1985;232:366–367. 123 Conway VH, Rozdilsky B, Schneider RJ, Sundaram M: Isolated bilateral complete ptosis. Can J Ophthalmol 1983;18:37–40. 124 Bogousslavsky J, Regli F, Ghika J, Hungerbuhler JP: Internuclear ophthalmoplegia, prenuclear paresis of contralateral superior rectus, and bilateral ptosis. J Neurol 1983;230:197–203. 125 Martin TJ, Corbett JJ, Babikian PV, Crawford SC, Currier RD: Bilateral ptosis due to mesencephalic lesions with relative preservation of ocular motility. J Neuroophthalmol 1996;16: 258–263. 126 Barton JJ, Kardon RH, Slagel D, Thompson HS: Bilateral central ptosis in acquired immunodeficiency syndrome. Can J Neurol Sci 1995;22:52–55. 127 Thomke F, Hopf HC: Acquired monocular elevation paresis. An asymmetric upgaze palsy. Brain 1992;115(pt 6):1901–1910. 128 Lepore FE: Bilateral cerebral ptosis. Neurology 1987;37:1043–1046. 129 Sibony P, Evinger C. Anatomy and physiology of normal and abnormal eyelid position and movements; in Miller N, Newman N (eds): Walsh and Hoyt’s Clinical Neuro-Ophthalmology, ed 5. Baltimore, Williams & Wilkins, 1998, pp 1537–1540. 130 Esteban-Garcia A: Blepharospasm and blepharocolysis. Different sides of the same coin. Rev Neurol 2005;40:298–302. 131 Berardelli A, Rothwell JC, Day BL, Marsden CD: Pathophysiology of blepharospasm and oromandibular dystonia. Brain 1985;108(pt 3):593–608. 132 Lee MS, Marsden CD: Movement disorders following lesions of the thalamus or subthalamic region. Mov Disord 1994;9:493–507. 133 Miranda M, Millar A: Blepharospasm associated with bilateral infarcts confined to the thalamus: case report. Mov Disord 1998;13:616–617. 134 Klostermann W, Vieregge P, Kompf D: Apraxia of eyelid opening after bilateral stereotaxic subthalamotomy. J Neuroophthalmol 1997;17:122–123. 135 Jankovic J, Patel SC: Blepharospasm associated with brainstem lesions. Neurology 1983;33: 1237–1240. 136 Aramideh M, Ongerboer de Visser BW, Holstege G, Majoie CB, Speelman JD: Blepharospasm in association with a lower pontine lesion. Neurology 1996;46:476–478. 137 Hallett M, Daroff RB: Blepharospasm: report of a workshop. Neurology 1996;46:1213–1218. 138 Cattaneo L, Chierici E, Pavesi G: Bell’s palsy-induced blepharospasm relieved by passive eyelid closure and responsive to apomorphine. Clin Neurophysiol 2005. 139 Aramideh M, Ongerboer de Visser BW, Brans JW, Koelman JH, Speelman JD: Pretarsal application of botulinum toxin for treatment of blepharospasm. J Neurol Neurosurg Psychiatry 1995;59:309–311. 140 Albanese A, Bentivoglio AR, Colosimo C, Galardi G, Maderna L, Tonali P: Pretarsal injections of botulinum toxin improve blepharospasm in previously unresponsive patients. J Neurol Neurosurg Psychiatry 1996;60:693–694.
Helmchen/Rambold
130
141 Kowal L: Pretarsal injections of botulinum toxin improve blephospasm in previously unresponsive patients. J Neurol Neurosurg Psychiatry 1997;63:556. 142 Elston JS: A new variant of blepharospasm. J Neurol Neurosurg Psychiatry 1992;55:369–371. 143 Lepore FE, Duvoisin RC: ‘Apraxia’ of eyelid opening: an involuntary levator inhibition. Neurology 1985;35:423–427. 144 Verghese J, Milling C, Rosenbaum DM: Ptosis, blepharospasm, and apraxia of eyelid opening secondary to putaminal hemorrhage. Neurology 1999;53:652. 145 Lamberti P, De Mari M, Zenzola A, Aniello MS, Defazio G: Frequency of apraxia of eyelid opening in the general population and in patients with extrapyramidal disorders. Neurol Sci 2002;23 (suppl 2):S81–S82. 146 Bjoerk L: Compulsive eye opening and associated phenomena. 1955;73 597–601. 147 Averbuch-Heller L: Neurology of the eyelids. Curr Opin Ophthalmol 1997;8:27–34. 148 Pasik P, Pasik T, Bender MB: The pretectal syndrome in monkeys. I. Disturbances of gaze and body posture. Brain 1969;92:521–534. 149 Nashold BS Jr, Gills JP, Wilson WP: Ocular signs of brain stimulation in the human. Confin Neurol 1967;29:169–174. 150 Scudder CA, Moschovakis AK, Karabelas AB, Highstein SM: Anatomy and physiology of saccadic long-lead burst neurons recorded in the alert squirrel monkey. I. Descending projections from the mesencephalon. J Neurophysiol 1996;76:332–352. 151 Galetta SL, Gray LG, Raps EC, Grossman RI, Schatz NJ: Unilateral ptosis and contralateral eyelid retraction from a thalamic-midbrain infarction. Magnetic resonance imaging correlation. J Clin Neuroophthalmol 1993;13:221–224. 152 Galetta SL, Raps EC, Liu GT, Saito NG, Kline LB: Eyelid lag without eyelid retraction in pretectal disease. J Neuroophthalmol 1996;16:96–98. 153 Grandas F, Esteban A: Eyelid motor abnormalities in progressive supranuclear palsy. J Neural Transm Suppl 1994;42:33–41. 154 Friedman DI, Jankovic J, McCrary JA 3rd: Neuro-ophthalmic findings in progressive supranuclear palsy. J Clin Neuroophthalmol 1992;12:104–109. 155 Pasik P, Pasik T, Bender MB: The pretectal syndrome in monkeys. I. Disturbances of gaze and body posture. Brain 1969;92:521–534. 156 Zee DS, Chu FC, Leigh RJ, et al: Blink-saccade synkinesis. Neurology 1983;33:1233–1236. 157 Hain TC, Zee DS, Mordes M: Blink-induced saccadic oscillations. Ann Neurol 1986;19:299–301. 158 Herishanu Y, Abarbanel JM, Frisher S: Blink induced ocular flutter. Neuro-ophthalmol 1987;7: 175–177. 159 Peli E, McCormack G: Blink vergence in an antimetropic patient. Am J Optom Physiol Opt 1986;63:981–984. 160 Cogan DG: A type of congenital ocular motor apraxia presenting jerky head movements. Am J Ophthalmol 1953;36:433–441. 161 Schneider E, Glasauer S, Dieterich M, Kalla R, Brandt T: Diagnosis of vestibular imbalance in the blink of an eye. Neurology 2004;63:1209–1216.
Prof. Dr. Christoph Helmchen Department of Neurology, University Hospitals Schleswig-Holstein, Campus Lübeck Ratzeburger Allee 160 DE–23538 Lübeck (Germany) Tel. ⫹49 451 500 2927, Fax ⫹49 451 500 2489 E-Mail
[email protected]
The Eyelid and Its Contribution to Eye Movements
131
Straube A, Büttner U (eds): Neuro-Ophthalmology. Dev Ophthalmol. Basel, Karger, 2007, vol 40, pp 132–157
Mechanics of the Orbita Joseph L. Demer Jules Stein Eye Institute, Departments of Ophthalmology and Neurology, Neuroscience Bioengineering Interdepartmental Programs, David Geffen Medical School at the University of California, Los Angeles, Calif., USA
Abstract The oculomotor periphery was formerly regarded as a simple mechanism executing complex behaviors explicitly specified by innervation. It is now recognized that several fundamental aspects of ocular motility are properties of the extraocular muscles (EOMs) and their associated connective tissue pulleys. The Active Pulley Hypothesis proposes that rectus and inferior oblique EOMs have connective tissue soft pulleys that are actively controlled by the action of the EOMs’ orbital layers. Functional imaging and histology have suggested that the rectus pulley array constitutes an inner mechanism, similar to a gimbal, that is rotated torsionally around the orbital axis by an outer mechanism driven by the oblique EOMs. This arrangement may mechanically account for several commutative aspects of ocular motor control, including Listing’s law, yet permits implementation of noncommutative motility as during the vestibulo-ocular reflex. Recent human behavioral studies, as well neurophysiology in monkeys, are consistent with mechanical rather than central neural implementation of Listing’s law. Pathology of the pulley system is associated with predictable patterns of strabismus that are surgically treatable when the pathologic anatomy is characterized by imaging. This mechanical determination may imply limited possibilities for neural adaptation to some ocular motor pathologies, but indicates greater potential for surgical treatments. Copyright © 2007 S. Karger AG, Basel
Ophthalmologists routinely interpret the ocular motility examination to assess the status of cranial nerves and central ocular motor processing. While normal motility is easily interpreted, the interpretation of abnormal motility can be quite complex, since it is founded on an understanding of the anatomy of the extraocular muscles (EOMs), the orbital connective tissues, and general principles of motor innervation that ordinarily coordinate binocular movements. Our understanding of even fundamental gross EOM anatomy has been clarified by imaging methods developed in the late 20th century. These insights have in turn
motivated investigations that have altered fundamental understanding of ocular motility.
Classical Anatomy
There are six striated oculorotary EOMs, configured as antagonist pairs [1, 2]. The medial (MR) and lateral rectus (LR) EOMs rotate the eye horizontally, with the MR accomplishing adduction and the LR accomplishing abduction. The superior (SR) and inferior rectus (IR) EOMs form a vertical antagonist pair, with the SR supraducting and the IR infraducting the globe. However, the vertical rectus EOMs have additional actions not strictly antagonistic. The superior (SO) and inferior oblique (IO) EOMs form an antagonist pair implementing torsion around the line of sight. The SO intorts, while the IO extorts. The oblique EOMs have additional actions that are not strictly antagonistic.
EOM Layers
The oculorotary EOMs, but not the lid-elevating levator palpebrae superioris muscle, are bilaminar [3]. The global layer (GL), containing in humans a maximum of approximately 10,000–15,000 fibers in the mid-length of the EOM, is located adjacent to the globe in rectus EOMs and in the central core of the oblique EOMs [4, 5]. In rectus EOMs and the SO, the GL anteriorly becomes continuous with the terminal tendon that inserts on the sclera [6]. Each rectus orbital layer (OL) contains 40–60% of all the EOM’s fibers. The OL terminates well posterior to the sclera, and at least some of its fibers insert on connective tissue pulleys [6, 7]. The OL is located on the orbital surface of rectus EOMs, sometimes C shaped, and constitutes the concentric peripheral layer of the oblique EOMs.
Gross Structure of EOMs
Rectus EOMs originate in the orbital apex from the fibrous annulus of Zinn. The SO muscle originates from the periorbita of the superonasal orbital wall. The rectus EOMs course anteriorly through loose lobules of fat and connective tissues that form sheathes as the EOMs penetrate posterior Tenon’s fascia. Despite common clinical terminology to the contrary, there exists no
Mechanics of the Orbita
133
‘muscle cone’ of connective tissue forming bridges among the adjacent rectus EOM bellies in the mid to deep orbit. The SO muscle remains tethered to the periorbita via connective tissues as it courses anteriorly, thins to become continuous with its long, thin tendon. The concentric OL of the SO terminates posterior on a peripherally located sheath [5]. Both the SO sheath and tendon pass through the trochlea, a cartilaginous rigid pulley attached to the superonasal orbital wall. After reflection in the trochlea, the SO tendon passes inferior to the SR, thins, and flattens as it spreads out to its broad scleral insertion posterolaterally on the globe [5]. The IO muscle originates much more anteriorly from the periorbita of the inferonasal orbital rim adjacent to the anterior lacrimal crest, continuing laterally to enter its connective tissue pulley inferior to the IR where the IO penetrates Tenon’s fascia [8]. Notwithstanding the implications of many textbooks, a recent fundamental insight is that rectus EOMs do not follow straight-line paths from their origins to their scleral insertions. In eccentric gaze, rectus EOM paths are inflected sharply at discrete points in the anterior orbit. Even in the 19th century, it was supposed that inflections in EOM paths might be due to orbital connective tissues acting as pulleys, although the archaic concept of early anatomists was largely concerned with bowing of rectus EOM paths away from the orbital center rather than prevention of muscle sideslip relative to the orbital wall [9, 10]. The modern concept of pulleys was first conceived by Joel M. Miller [11], and any eponym applied to rectus pulleys should be his. The ‘pulleys of Miller’ change the anterior paths of rectus EOMs, and thus their pulling directions, in an orderly way during duction. This is shown in the axial magnetic resonance images (MRI) in figure 1, illustrating that the anterior path of the IR muscle changes by half the change in the angle of duction. MRI has shown the same behavior for all the rectus EOMs. The anterior path angle of a rectus EOM changes by half the amount of duction [12].
Structure of Pulleys
Rectus EOM inflection points constitute the functional pulleys of Miller. Anterior to these, rectus EOM paths follow the scleral insertions in eccentric gazes. The pulleys thus act mechanically as rectus EOM origins. The EOM segment between the scleral insertion and pulley defines the direction of force applied to the globe. Pulleys consist of discrete rings of dense collagen encircling the EOM, transitioning gradually into less substantial but broader collagenous sleeves. Anteriorly, these sleeves thin to form slings convex to the orbital wall, and more posteriorly the sleeves thin to form slings convex toward the orbital center. The anterior pulley slings have also been called the ‘intermuscular
Demer
134
43º Abduction
30º Adduction
ON MR
LR
73º Gaze shift
47º
11º
IR 36º Inferior rectus path change
WJ
Fig. 1. Axial MRI images of a right orbit taken at the level of the lens, fovea, and optic nerve (top row), and simultaneously in an inferior plane along the IR muscle path (bottom row), in abduction (left) and adduction (right). Note the bisegmental IR path, with an inflection corresponding to the IR pulley. For this 73⬚ horizontal gaze shift, there was a corresponding 36⬚ shift in IR muscle path anterior to the inflection at its pulley. By permission from Demer [19].
septum’, a time-honored but not functionally specific term that may be eventually supplanted by more specific terminology. Electron microscopy demonstrates the fibrils of collagen in the pulleys to have an interlaced configuration suited to high internal rigidity [13]. There are bands of smooth muscle (SM) in
Mechanics of the Orbita
135
Pulley ring
Globa Orbit l layer al lay er
yer ital la yer Orblo la l a G b
Pulley sling
Smooth muscle Collagen Elastin Trochlea
LPS
SO SR
LR Pulley sling IO
Pulley ring
MR
IO
IR Orbital layer
Fig. 2. Diagram of the orbita. Coronal views are depicted at levels indicated on axial view. Functional pulleys are at level depicted at lower right. LG ⫽ Lacrimal gland; LPS ⫽ levator palpebrae superioris muscle; SOT ⫽ superior oblique tendon. By permission from Demer [31].
the pulley suspensions [14, 15], and particularly in a distribution called the inframedial peribulbar SM between the MR and IR pulleys [16]. The overall structure of the orbital connective tissues in schematized in figure 2. The IR pulley is coupled to the IO pulley in a bond forming part of Lockwood’s ligament, the connective tissue ‘hammock’ across the inferior orbit [8, 16]. The IR and IO pulleys are composed of a common collagenous sheath stiffened by dense elastin. The OL of the IR inserts on its pulley and does not continue anteriorly. The OL of the IO muscle inserts partly on the conjoined IO-IR pulleys, partly on the IO sheath temporally and partly on the inferior aspect of the LR pulley. Elastin and SM occur in the Lockwood’s ligament region of posterior Tenon’s fascia supporting the IR-IO pulley. The inframedial peribulbar SM originates on the nasal aspect of this conjoint pulley, and is positioned upon contraction to displace the pulley nasally. The SM retractors of
Demer
136
the lower eyelid (‘Muller’s inferior tarsal muscle’) and connective tissues extending to the inferior tarsal plate are also coupled to the conjoint IR-IO pulley, coordinating lower eyelid position with vertical eye position during vertical gaze shift. The SM of the pulley system has autonomic innervation, including three likely pathways: (1) sympathetic with a norepinephrine projection from the superior cervical ganglion; (2) cholinergic parasympathetic, probably from the ciliary ganglion, and (3) nitroxidergic, probably from the pterygopalatine ganglion [15]. Although the rigid SO pulley – the trochlea – has been known since antiquity [17, 18], its immobility is exceptional, and also unique that the SO’s OL inserts via the SO sheath on the SR pulley’s medial aspect [5]. Net SO pulling direction probably changes half as much as duction despite an immobile pulley, because of the uniquely thin, broad SO tendon wrapping over the globe [19]. Most of these anatomical relationships are evident in gross dissections and surgical exposures. After surgical transposition of a rectus tendon (for the treatment of, e.g., strabismus due to LR palsy), the path of the transposed EOM continues to be obliquely toward the original pulley location. The effect of rectus EOM transposition can be improved by suture fixation from a posterior point on the transposed EOM belly to the sclera adjacent to the palsied EOM [20], a maneuver shown by MRI to displace the pulley further in the transposed direction [21].
Functional Anatomy of Pulleys
The insertion of each rectus EOM’s OL on its pulley appears to be the main driving force translating (linearly moving) that pulley posteriorly during EOM contraction. There is consensus that, in both humans and monkeys, fibers on the orbital surface of each rectus EOM insert into the dense encircling tissue [4, 6] in a distributed manner over an anteroposterior region in which successive bundles of fibers extend up to 1 mm into the surrounding connective tissue1 [7].
1 While they may properly be said to have dual insertions, the OL and GL insertions are not widely displaced. The OLs and GLs of EOMs do not bifurcate widely before inserting as might have been misunderstood from the diagrammatic implications of some authors who intended to emphasize the differing neural control and possible proprioception of the two layers [22]. The concept of dual insertions does not necessarily imply that every fiber in each layer terminates in that layer’s insertion, since fibers may terminate on one another short of the insertion in myomyous junctions [23].
Mechanics of the Orbita
137
Imaging by MRI suggests that these enveloping tissues move in coordination with the insertion and underlying sclera, although histological examinations show the absence of direct connections between these tissues. The connective tissue sleeves themselves have a substantial anteroposterior extent along which connective tissue thickness varies [14], and it has not been possible to histologically identify the precise sites causing EOM path inflections. Consequently, actual pulley locations have been determined from functional imaging by MRI in vivo, rather than by histological examination of dead tissues not subjected to physiological striated and smooth EOM forces. Since the EOMs must pass through their pulleys, and since pulleys encircle the EOMs, pulley locations may be inferred from EOM paths even if pulley connective tissues cannot be imaged directly. Quantitative determinations of pulley locations and shifts during ocular rotation have been obtained from coronal MRIs in secondary and tertiary gazes associated with EOM path inflection at the pulleys. Imaging in tertiary (combined horizontal and vertical) gaze positions is particularly informative, since such images show changes in the anteroposterior position of the EOM path inflections [12]. These data have confirmed that all four rectus pulleys move anteroposteriorly in coordination with their scleral insertions, by the same anteroposterior amounts. Being partially coupled to the mobile IR pulley, the IO pulley shifts anteriorly in supraduction, and posteriorly in infraduction. Quantitative MRI shows that the IO pulley moves anteroposteriorly by half as much as the IR insertion [8]. To date, the MRI studies in living subjects have been consistent with histological examinations of the same regions in cadavers that were also examined by MRI prior to embedding and sectioning [16]. Although MRI indicates that rectus pulleys are mobile along the axes of their respective EOMs, pulleys are located stably and stereotypically in the planes transverse to the EOM axes. The 95% confidence intervals for the horizontal and vertical coordinates of normal rectus pulleys range over less than ⫾ 0.6 mm [22]. Precise placement of rectus pulleys is important since the pulleys act as the EOM’s functional mechanical origins. Pulley stability in the coronal plane implies a high degree of stiffness of the suspensory tissues of the pulleys. The Active Pulley Hypothesis (APH) supposes that the anteroposterior mobility of the pulleys is accomplished by application of substantial force by the OL of each EOM (fig. 2). Aging causes cause inferior sagging of horizontal rectus pulley positions, which shift downward by 1–2 mm from young adulthood to the seventh decade [23]. Vertical rectus pulley positions change little with aging [23]. The globe itself makes small translations – linear shifts – during ocular duction, as determined by high-resolution MRI in normal humans [23]. For example, the globe translates 0.8 mm inferiorly from 22⬚ downward gaze to 22⬚
Demer
138
upward gaze, and it also translates slightly nasally in both abduction and adduction. While small, these translations affect EOM force directions since the globe center is only 8 mm anterior to the plane of the rectus pulleys. Pulleys prevent EOM sideslip during globe rotations, but physiologic transverse shifts of rectus pulleys can also occur. Gaze-related changes in rectus pulley positions have been determined by tracing EOM paths with coronal MRI using a coordinate system relative to the center of the orbit [24]. The MR pulley translates 0.6 mm superiorly from 22⬚ infraduction to 22⬚ supraduction. The LR pulley translates 1.5 mm inferiorly from infraduction to supraduction. The IR pulley shifts 1.1 mm medially in supraduction, but moves 1.3 mm temporally in infraduction. The SR pulley is relatively stable in the mediolateral direction, but moves inferiorly in supraduction, and superiorly in infraduction. Gaze-related shifts in rectus pulley positions are uniform among normal people.
Kinematics of Pulleys
Joel M. Miller first suggested that orbitally fixed pulleys would make the eye’s rotational axis dependent on eye position [11]. Miller’s crucial insight has proved fundamental to ocular kinematics, the rotational properties of the eye. Sequential rotations are not mathematically commutative, so that final eye orientation depends on the order of rotations [25]. Each combination of horizontal and vertical orientations could be associated with infinitely many torsional positions [26], but the eye is constrained (when the head is upright and immobile) by Listing’s law (LL): ocular torsion in any gaze direction is that which the eye would have it if it had reached that gaze direction by a single rotation from primary eye position about an axis lying in Listing’s plane (LP) [27]. LL is satisfied if the ocular rotational velocity axis shifts by half of the shift in ocular duction [28]. For example, if the eye supraducts 20⬚, then the vertical velocity axis about which it rotates for subsequent horizontal movement should tip back by 10⬚. This is called the ‘half-angle rule’, or the velocity domain formulation of LL. Conformity to the half angle rule makes the sequence of ocular rotations appear commutative to the brain [29]. Commutativity is the critical feature of the pulley system. The APH explains how rectus pulley position can implement the half angle kinematics required by LL [2, 6, 12, 19]. The EOMs rotate the globe about axes perpendicular to the tendon paths near the insertion. In figure 3a, b, it is seen from simple small angle trigonometry that a horizontal rectus EOM’s pulling direction tilts posteriorly by half the angle of supraduction if the pulley is located as far posterior to globe center as the insertion is anterior to globe center. If all rectus EOMs and their pulleys are arranged similarly, this configuration
Mechanics of the Orbita
139
Rotational axis
Rotational axis Straight ahead LR
Insert.
LR
Pulley
a
D1 ⫽ D2
Primary position Nasal r laye ital Orb r laye bal Glo
Glo
bal
Orb
ital
sion
en
Susp
Temporal
Nasal
Suspension
d
ital
er
laye
Temporal
Primary position
e
c
nsion
Suspe
Primary position 10 D1 D2
Suspension
Gaze
n
nsion
Suspe r laye ital r Orb bal laye lo g R S
D1
D2
f
␣
␣/2
Supraduction
10 IR glo bal la Orbityer al lay er Inferior
10 axis ␣/2
LR global layer
r
Suspension Adduction
10 axis
LR axis
er
al lay
r
IR g Orb lobal laye r ital laye r
ensio
Glob Orb
␣
l lay
ba Glo
r
r laye yer ital la Orb lobal g R S LR global layer
2
Susp
yer
bi Or
laye
␣/2 D1 D
Supraduction
la tal
D1 D2
laye
b
Superior
␣/2
D3/2
D2 D1
D3
Fig. 3. Diagram of EOM and pulley behavior for half angle kinematics conforming to LL. a Lateral view. Rotational velocity axis of the EOM is perpendicular to the segment from pulley to scleral insertion. The velocity axis for the LR is vertical in primary position. b Lateral view. In supraduction to angle alpha, the LR velocity axis tilts posteriorly by angle alpha/2 if distance D1 from pulley to globe center is equal to distance D2 from globe center to insertion. c Lateral view. In primary position, terminal segment of the IO muscle lies in the plane containing the LR and IR pulleys into which the IO’s orbital layer inserts. The IO velocity axis parallels primary gaze. d Superior view of rectus EOMs and pulleys in primary position, corresponding to a. e Superior view. In order for adduction to maintain D1 ⫽ D2 in an oculocentric reference, the MR pulley must shift posteriorly in the orbit, and the LR pulley anteriorly. This is proposed to be implemented by the orbital layers of these EOMs, working against elastic pulley suspensions. f Lateral view similar to c. In supraduction to angle alpha, the IR pulley shifts anteriorly by distance D3, as required by the relationship shown in e. The IO pulley shifts anteriorly by D3/2, shifting the IO velocity axis superiorly by alpha/2. By permission from Demer [19].
mechanically enforces LL since all the rectus forces rotating the globe observe half angle kinematics. If only primary and secondary gaze positions were required, rectus pulleys could be rigidly fixed to the orbit. However, it has been proven mathematically that perfect agonist-antagonist EOM alignment is possible only if pulley locations move in the orbit [30]. Tertiary gazes such as adducted supraduction require the rectus pulleys actively to shift anteroposteriorly in the orbit along
Demer
140
the EOM’s length, maintaining a fixed oculocentric relationship (fig. 3d, e). The APH proposes that pulley shifts are generated by the contraction of the OLs acting against the elasticity of the pulley suspensions [1, 6, 12, 31]. This behavior could not be due to attachment of rectus pulleys to the sclera. Not only does serial section histology show no such attachment, but also the sclera moves freely relative to pulleys transverse to the EOM axes. Anteroposterior rectus pulley movements persist even after enucleation [32], when the MR path inflection at its pulley continues to shift anteroposteriorly with horizontal versions, but the angle of inflection sharpens to as much as 90⬚ at the pulley [32]. Despite coordinated movements, however, it is supposed that ocular rotation by the OL and pulley translation by the GL require different EOM actions and neural commands. The mechanical load on the GL is predominantly the viscosity of the relaxing antagonist EOM, proportional to rotational speed [33]. The load on the OL, however, is due to the pulley suspension elasticity, which is independent of rotational speed, but proportional to the angle of eccentric gaze. Laminar electromyography in humans shows high, phasic activity in the GL during saccades, with only a small maintained change in activity in eccentric gaze [33]. In the OL, electromyography shows sustained, high activity in eccentric gaze, but no phasic activity during saccades. In cat, the most powerful and fatigue-resistant LR motor units, comprising 27% of all units, innervate both the OL and GL [34]. These ‘bilayer’ motor units would command similar tonic contraction in the two layers, an arrangement convenient to maintain pulley position relative to the EOM insertion. Other motor units project selectively to either the OL or GL [34], as might be appropriate for control of differing viscous loads. While the rectus EOMs by themselves seem capable of implementing LL [35], some important eye movements do not conform to LL. Violations of LL occur during the vestibulo-ocular reflex (VOR) [36, 37] and during convergence [38, 39]. These violations may be due to the action of the oblique EOMs. The IO muscle’s functional anatomy also appears suited to half angle kinematics. The IO pulley shifts anteroposteriorly by half of vertical ocular duction [8], shifting the IO’s rotational axis by half of vertical duction (fig. 3d, f) [8]. The broad, thin SO insertion on the sclera resists sideslip by virtue of its shape. The SO approximates half angle kinematics because the distance from trochlea to globe center is approximately equal to the distance from globe center to insertion, the SO rotational axis shifts by half the horizontal duction [19]. Optimal stereopsis requires torsional cyclovergence to align corresponding retinal meridia [40]. In central gaze, excyclotorsion occurs in convergence that violates LL [41]. During asymmetrical convergence to a target aligned to one eye, this extorsion occurs in both eyes, interpretable as temporal tilting of LP for each eye [38]. A form of Herring’s law of equal innervation probably exists
Mechanics of the Orbita
141
for the vergence system, such that both eyes receive symmetric version commands for remote targets, and mirror symmetric vergence commands for near targets [42]. MRI during convergence to a target aligned to one eye has been performed using mirrors and has allowed the effect of convergence to be distinguished from that of adduction [43]. In the aligned orbit, there was a 0.3–0.4 mm extorsional shift of most rectus pulleys corresponding to about 1.9⬚ [43], similar to globe extorsion [44]. It appears that during convergence, the rectus pulley array rotates about the long axis of the orbit in coordination with ocular torsion, changing the torsional pulling directions of all rectus EOMs but maintaining half angle dependence on horizontal and vertical duction. This would cause a parallel, torsional offset in LP. While it is possible that globe torsion might passively rotate the rectus pulley array, the high stiffness of the rectus pulley suspensions necessary to stabilize them against sideslip would severely limit such passive torsional shifts, always to less than ocular torsion [43]. An active mechanism has been suggested for the torsional pulley shifts in convergence that equal ocular torsion. The OL of the IO muscle inserts on the IR pulley and, at least in younger specimens, also on the LR pulley [8]. Contraction of the IO OL would directly extorsionally shift the LR and IR pulleys. Contractile IO thickening has been directly demonstrated by MRI during convergence [43]. Inferior LR pulley shift could be coupled to lateral SR pulley shift via the dense connective tissue band between them [45]. The OL of the SO muscle inserts on the SO sheath posterior to the trochlea, with both tendon and sheath reflected at that rigid pulley [5]. Anterior to the trochlea, the SO sheath inserts on the SR pulley’s nasal border. Relaxation of the SO OL during convergence is consistent with single unit recordings in the monkey trochlear nucleus [46], and could contribute to extorsion of the pulley array. The inframedial peribulbar SM might also contribute to rectus pulley extorsion in convergence [16].
Controversy Concerning Pulleys
Because of their distributed nature, some doubt the existence of EOM pulleys of Miller, with the alternative suppositions being that the penetrations of the rectus EOMs through Tenon’s fascia are unimportant, or that the connective tissues serve only to limit the range of ductions [47]. Histological evidence has previously been presented suggesting the presence of EOM pulleys in rodents [48]. Ruskell et al. [7] have proposed that OL insertion into connective tissue sleeves may be a general feature of all mammals. They studied isolated human and monkey rectus EOMs near their pulleys, reporting tendons leaving the
Demer
142
orbital surface of the EOMs to insert in sleeves or other surrounding connective tissues. Ruskell et al. [7] considered their results to confirm and extend the observation that the OL fibers separate from the GL fibers and insert in the sheath, and that OL fibers are unlikely to contribute much to duction. Histological study in rat, including 3-D reconstruction, suggested insertion of the OL of the IR on a pulley [49], consistent with the APH. Dimitrova et al. [50] electrically stimulated eye movements from central to secondary gazes in anesthetized cats and monkeys before and after removal of the LR pulley. Although this surgery predictably increased the amplitude and velocity of horizontal eye movements, there was no significant effect on vertical eye movements [50]. Dimitrova et al. [50] interpreted the increase in eye movement size to transmission of OL force to the tendon, although they also noted that reduction in elastic load associated with pulley removal would also increase eye movement. Their experiment was not a test of the APH’s implications for LL, which would have required investigation of tertiary gazes.
Listing’s Law (LL) Is Mechanical
Long regarded as an organizing principle of ocular motility, LL reduces ocular rotational freedom from three (horizontal, vertical, and torsional) to only two degrees (horizontal and vertical) during visually guided eye movements with the head upright and stationary [28]. The classic formulation of LL states that, with the head upright and immobile, any eye position can be reached from primary position by rotation about one axis lying in LP. Conformity with LL can be demonstrated by expressing ocular rotational axes as ‘quaternions’ that can be directly plotted to form LP [25]. Unlike 1-D velocity that is the time derivative of position, 3-D eye velocity is a mathematical function both of eye position and its derivative. The time derivative of each component of 3-D eye position is called coordinate velocity, but this differs from 3-D velocity in a way critical to neural control of saccades [29, 51–53]. Tweed et al. [54] have pointed out that the ocular position axis will be constrained to a plane if, in the velocity domain, the ocular velocity axis changes by half the amount of duction. This can be expressed as a tilt angle ratio of one half. Since in most situations the eye begins in LP, a tilt angle ratio of one half constrains the eye to remain in LP, and so satisfies LL. However, if eye position were somehow to begin outside LP at the onset of an eye movement that subsequently conforms to the velocity domain formulation of LL, eye position would remain in a plane parallel to but displaced from LP. Violation of LL during the VOR occurs since the VOR compensates for head rotation about any arbitrary axis [37, 55, 56]. The VOR does not violate
Mechanics of the Orbita
143
LL ideally, but has a non-half angle dependency of rotational velocity axis on eye position. The ideal tilt angle ratio for the VOR would be zero. However, ocular torsion during the VOR does depend on eye position in the orbit; the VOR axis shifts by about one quarter of duction relative to the head, and thus a tilt angle ratio near 0.25 [37, 55, 56]. During well-controlled, whole-body transient yaw rotation at high acceleration, the VOR exhibits quarter angle behavior beginning at a time indistinguishable for the earliest VOR response [57, 58]. Such kinematics would be consistent with neural drive to a mechanical implementation of quarter angle VOR kinematics as part of the minimum latency reflex, and a different mechanical specification of saccadic half angle behavior. Neural and mechanical roles in determination of ocular kinematics have been controversial. Before modern descriptions of the orbita, it seemed obvious that LL was implemented neurally in premotor circuits as an intrinsic feature of central ocular motor control [59–63]. The APH then proposed to account for LL mechanically, but physiologic violations of LL continued to suggest a role for central neural control [64]. A neural role in LL appeared tenable given the observation of ocular extorsion and temporal tilting of LP during convergence [39, 65] associated with torsional repositioning of the rectus EOM pulley array [43] and alteration in discharge of trochlear motoneurons [46]. Crane et al. [66] studied the transition between the angular VOR’s quarter angle strategy and saccades’ half-angle behavior. These investigators used the yaw angular VOR to drive ocular torsion out of LP, and then used a visual target to evoke a vertical saccade. This is an unusual situation in which the velocity and position domain formulations of LL are no longer equivalent. To return the saccade’s position domain rotational axis to LP would require that the saccade’s velocity axis violate the half angle rule in the process of canceling the initial non-LP torsion. If instead the saccade’s velocity axis conformed to the half angle rule, the saccade would begin and end with the non-LP torsion induced by the VOR. Crane et al. [66] showed that saccades observed half angle kinematics in the velocity domain, and maintained any non-LL initial torsion. This result suggests that the half angle velocity relationship is the fundamental principle underlying LL, as would be expected from coordinated APH behavior of the rectus pulleys. However, torsion returning the eye to LP has been observed during both horizontal and vertical saccades after torsional optokinetic nystagmus had driven the eye out of LP [67], a difference perhaps related to the entrainment of quick phases during nystagmus, and seemingly impossible to implement with a purely mechanical system [67]. Reconciliation of these findings would require differences in neural control of visual saccades vs. vestibular quick phases, a possibility [66] given the known ability of the vestibular system to drive saccades [68].
Demer
144
Contralateral to head tilt
Upright Rotational axis Lateral view
Rotational axis MR
Insert.
MR Pulley
Pulley
Insert. Extorsion
SR
SR Frontal view
LR
LR MR
MR
Extorsion IR
IR
Fig. 4. Diagram of effects of head tilt on rectus pulleys in lateral (top row) and frontal (bottom row) views. With head upright, the IR, LR, MR, and SR pulleys are arrayed in frontal view in a cruciate pattern. The MR passes through its pulley, represented as a ring, to its scleral insertion. The rotational velocity axis imparted by the MR is perpendicular to the segment from pulley to insertion. The pulley array extorts during contralateral head tilt. Since during head tilt the MR pulley shifts superiorly by the half the distance the insertion shifts, the MR’s velocity axis changes by one fourth the ocular torsion. By permission from Demer and Clark [69].
The functional anatomy of human EOMs has been examined by MRI during ocular counterrolling (OCR), a static torsional VOR mediated by the otoliths [69]. The coronal plane positions of the rectus EOMs shifted torsionally in the same direction as OCR. While OCR was not measured, the torsion of the rectus pulley array was roughly half of OCR reported by other eye movement studies. The torsional shift of the rectus pulley array half of OCR would change rectus EOM pulling directions by one quarter of OCR (fig. 4), ideal for quarter angle VOR kinematics. During OCR, oblique EOMs exhibited changes in cross section consistent with their possible roles in torsional positioning of rectus pulleys [69]. This finding, considered in the context of saccade kinematics during the VOR [66], suggests that the array of the four rectus pulleys constitute a kind of ‘inner gimbal’ that conforms to Listing’s half angle kinematics for visually guided movements such as fixations and saccades, but which is rotated by the oblique EOMs to implement eye movements such as the slow and quick phases of the VOR.
Mechanics of the Orbita
145
Older recordings of trochlear motoneuron discharge suggest that ocular extorsion during convergence is neurally commanded [46]. If the ocular torsion specified by LL were similarly neurally commanded, torsional commands should be reflected in discharge patterns of neurons innervating the oblique and vertical rectus EOMs. Ghasia and Angelaki [70] recorded activities of motoneurons and nerve fibers innervating the vertical rectus and oblique EOMs in monkeys during smooth pursuit conforming to LL. There were no neural commands for LL torsion in motor units innervating the cyclovertical EOMs [51]. This evidence for a mechanical basis of LL was also supported by the experiment of Klier et al. [71] in which electrical stimulation was delivered to the abducens nerve (CN6) of alert monkeys to evoke saccade-like movements. Klier et al. [71] demonstrated that the evoked saccades had half angle kinematics conforming to LL. The decisive conclusion from these two experiments is that LL has a mechanical basis, and is not specified by the instantaneous neural commands. These two results were predicted by the APH [6], while the neural theory of LL predicted opposite results in both cases [62]. However, the neurons driving the cyclovertical EOMs not only did not command half angle LL torsion, but also did not command quarter angle kinematics for the VOR [70]. This suggests that quarter angle VOR kinematics are also mechanical, rather than neural. An early suggestion had been made than quarter angle behavior could be implemented mechanically by retraction of rectus pulleys [6], but subsequent recognition that this idea would be unrealistic [61] led to abandonment of the concept of pulley retraction [2, 43]. Furthermore, uncoordinated anteroposterior shift in pulley location would be inconsistent with the recent experiments of Crane et al. [66] demonstrating transition between quarter angle VOR, and half angle saccade behavior without measurable latency. The foregoing results seemingly require that quarter angle VOR behavior arise from mechanical phenomena not previously considered.
Implications for Neural Control
Some tentative conclusions can now be reached concerning neural control of eye movements generally, and some older data probably should be reinterpreted. Central neural signals correlated with all types of eye movements would be expected to reflect effects of torsional reconfiguration of rectus pulleys during the VOR. Recordings from burst neurons in monkeys appear compatible with the torsional shift of rectus pulleys transverse to the EOM axes in the direction of OCR induced by head tilt [72]. In monkeys, the displacement plane for 3-D eye positions during pursuit and saccades shifts opposite to changes in head orientation relative to gravity [73], and such shifts may be
Demer
146
dynamic during semicircular canal stimulation [74, 75]. Hess and Angelaki have suggested that shift in LP is mediated by the otolith input to the 3-D neural integrator [73], but the finding may be reconciled with the observation that lesion of the integrator in the rostral interstitial nucleus of the medial longitudinal fasciculus also abolishes the torsional shift in LP associated with OCR [76] if the torsional shift of pulleys is mediated by the 3-D neural integrator. If so, it would be predicted that integrator lesion would abolish counterroll of the pulleys during vestibular stimulation, by blocking polysynaptic vestibular input to the oblique EOMs whose tonic activity presumably maintains torsional pulley array orientation. In monkeys, the preferred directions of saccadic neurons in the superior colliculus shift in the opposite direction, and by slightly more than half the amount, of head tilt [77]. Based on simultaneous measurements of OCR and preferred directions of superior collicular neurons, Frens et al. [77] concluded that the changes in EOM pulling directions are probably about two thirds of ocular torsion. Regardless of the ocular motor subsystem involved, torsional rectus pulley shifts during the VOR would preserve the advantage of apparent commutativity of the peripheral ocular motor apparatus for concurrent saccades and pursuit. This commutativity would be valuable even though higher-level sensorimotor transformations must account for 3-D geometrical effects of eye and head orientation [64, 77–79], and is incorporated in some modern models of ocular motor control [29, 52, 76, 78, 80]. Neural processing for the VOR must be generated in 3-D, based on transduction of head motion in three degrees of freedom, and on 3-D eye orientation in the head. Some low level visuomotor processing may be simpler than previously believed. In saccade programming, retinal error could be mapped onto corresponding zero-torsion motor error commands within LP as modeled by the ‘displacement-feedback’ model of Crawford and Guitton [81]. This model, with a downstream mechanism for half angle behavior, can simulate the visuomotor transformations necessary for accurate and kinematically correct saccades within a reasonable oculomotor range, but had been rejected by Crawford and Guitton who supposed that saccades from non-LL torsional starting positions return to LP [81]. Recent demonstration by Crane et al. [66] that such saccades maintain their initial non-LL torsion while nevertheless conforming to half angle kinematics suggests that the ‘displacement-feedback’ model, lacking in a neural representation of LL, is plausible for control of visual saccades. In the context of realistic mechanical properties of EOM pulleys, sensorimotor integration of saccades does not require explicit neural computation of ocular torsion. This simplification solves some complexity, but merely moves other kinematic problems to a higher level. When head movements are involved,
Mechanics of the Orbita
147
neural consideration of torsion is geometrically unavoidable for accurate localization of visual targets [78, 81]. Several aspects of ocular kinematics are thus implemented by an intricate mechanical arrangement, rather than by complex neural commands to a simpler mechanical arrangement. This insight alters the interpretation of common situations, and offers hope of mechanical (i.e., surgical) solutions to clinical disorders that might earlier have been believed to have neural origins. If the APH were correct, oblique EOM function would not be critical for LL [35], although oblique tone might set initial LP orientation. This is supported by the finding in chronic SO paralysis that LL is observed, albeit with temporal tilting of LP [82, 83], and that this temporally tilted LP is not changed by vergence as is normally the case [84]. The orientation of LP varies considerably both among individuals, and between eyes of the same individuals, making it unlikely that absolute LP orientation is very important to either vision of ocular motor control [58]. Although oblique EOMs do not actively participate in generation of LL, elastic tensions arising from stretching and relaxation or oblique EOMs would create torques violating LL unless their innervations were adjusted to compensate [51]. Consequently, recordings of small changes in oblique EOM innervations during pursuit movements conforming to LL [70, 85] do not negate a pulley contribution, nor do dynamic violations of LL during saccades in SO palsy [82].
Implications for Strabismus
Thinking about cyclovertical strabismus has been dominated by the historical concept of EOM weakness, typified by the terms ‘paresis’ and ‘paralysis’ [86]. This is likely because cranial nerves innervating EOMs are susceptible to damage by trauma and compression, and because when the concept of EOM weakness became dominant, neuroscience was too primitive to offer alternative explanations [86]. Deeply engrained clinical concepts require modification. Prototypic for cyclovertical strabismus is SO palsy. Theoretical, experimental, and much clinical evidence supports the idea that acute, unilateral SO palsy produces a small ipsilateral hypertropia that increases with contralateral gaze, and with head tilt to the ipsilateral shoulder [87, 88]. The basis of this ‘3step test’ is traditionally believed related to OCR, so that the eye ipsilateral to head tilt is normally intorted by the SO and SR EOMs whose vertical actions cancel [89]. However, ipsilateral to a palsied SO, unopposed SR elevating action is supposed to create hypertropia. The 3-step test has been the cornerstone of diagnosis and classification of cyclovertical strabismus for generations of clinicians [90, 91]. When the 3-step test is positive, strabismologists infer SO
Demer
148
weakness and attribute the large amount of interindividual alignment variability to secondary changes [83] such as ‘IO overaction’ and ‘SR contracture’. The 3step test’s mechanism is generally misunderstood. Kushner [92] has pointed out that were traditional teaching true, then IO weakening, the most common surgery for SO palsy, should increase the head tilt-dependent change in hypertropia; the opposite is observed. Among numerous inconsistencies with common clinical observations [92], bilateral SO palsy should cause greater head tilt-dependent change in hypertropia than unilateral SO palsy; however, the opposite is found [93]. Modeling and simulation of putative effects of head tilt in SO palsy suggest that SO weakness alone cannot account for typical 3-step test findings [94, 95]. High-resolution MRI has quantified normal changes in SO cross-section with vertical gaze, and SO atrophy and loss of gaze-related contractility typical of SO palsy [96–99]. Neurosurgical SO denervation rapidly produces neurogenic atrophy and ablates contractile thickening normally observed in infraduction. A striking and consistent MRI finding has been the nonspecificity of the 3-step test for structural abnormalities of the SO belly, tendon, and trochlea, found in only in ⬃50% of patients [100]. Even in patients selected because MRI demonstrated profound SO atrophy, there was no correlation between clinical motility and IO size or contractility [99]. A possible explanation for some of this discrepancy might be putative SO tendon laxity, assessed intraoperatively by a qualitative and perhaps unreliable judgment made during application of traction with forceps [101–103]. Multiple conditions can simulate the ‘SO palsy’ pattern of incomitant hypertropia [104]. Vestibular lesions cause head-tilt dependent hypertropia, also known as skew deviation [105] that can mimic SO palsy by the 3-step test [106]. Pulley heterotopy can simulate SO palsy [107], and is probably not its result, since SO atrophy is not associated with significant alterations in pulley position in central gaze [108]. Craniosynostosis is a congenital disorder in which skull shape is distorted by premature fusion of the sutures among cranial bones. While various eponyms have been attached based on variable expressivity (e.g. Crouzon, Pfeiffer), these are largely due to known gene mutations affecting bone formation [109]. Strabismus is prevalent in craniosynostosis, particularly large V and A patterns [110, 111], yet responds poorly to oblique EOM surgery [112]. Rectus EOM paths may be markedly abnormal in craniosynostosis [107, 113], imparting abnormal pulling directions. It has been proposed that because the EOM pulley array is anchored to the bony orbit at discrete points [45], bony abnormality alters EOM pulling directions by malpositioning pulleys. Typically, the heterotopic array of rectus pulleys is extorted or intorted, not necessarily symmetrically. Computer simulations suggest rectus pulley malpositioning as in craniosynostosis can produce incomitant strabismus [114, 115].
Mechanics of the Orbita
149
Extorsion of the pulley array is associated with V patterns, and intorsion associated with A patterns [116].
Surgical Treatment of Pulley Pathology
Surgery for pulley disorders has recently emerged for treatment of three types of pathologies [19]. Pulley Heterotopy Milder pulley heterotopy not apparently associated with craniosynostosis may involve the stable malpositioning of one or several rectus pulleys [114, 115]. Initial efforts to treat heterotopy involved transpositions of the scleral insertions of EOMs whose pulleys were heterotopic [19], later augmented by fixations of EOM bellies to the underlying sclera ⬃8 mm posteriorly [113]. While MRI has demonstrated that this does shift the involved rectus pulley in the desired direction [21, 117], because the pulley does not shift as far as the insertion, the operation introduces undesirable ocular torsion opposite the direction of transposition. Since normal pulleys are not fixed to sclera, posterior fixation also compromises normal pulley kinematics and introduces abnormal globe translation during duction [117]. Newer approaches to pulley heterotopy involve surgery on connective tissues suspending the pulleys. A technically convenient approach to treatment of inferior displacement of the LR pulley is to shorten and stiffen the ligament coupling the LR and SR pulleys. Extreme pulley heterotopy is associated with esotropia and hypotropia in axial high myopia [118, 119]. In this condition, historically misnamed the ‘heavy eye syndrome,’ the LR pulley shifts inferiorly to approach the IR, and the globe correspondingly shifts superotemporally out of the rectus pulley array. It has been recently reported that surgical anastomosis of the lateral margin of the IR belly with the superior margin of the LR belly is highly effective in correcting esotropia associated with the ‘heavy eye syndrome,’ since the procedure normalizes EOM paths relative to the globe in a manner impossible for more conventional strabismus surgery [120]. Pulley Instability Normal pulleys shift only slightly in the coronal plane even during large ductions [24]. Large gaze-related shifts or one or more pulleys are associated with incomitant strabismus [19, 121]. Pulley instability has also been termed ‘gaze-related pulley shift’ [122]. Inferior LR pulley shift in adduction produces restrictive hypotropia closely resembling Brown syndrome caused by hindrance of SO travel in the trochlea [123], or ‘X’ pattern exotropia characterized by
Demer
150
greater deviation in both up and down than in central gaze [121]. Early efforts to treat pulley instability consisted of posterior fixation of the involved EOM to the underlying sclera, and were intended to prevent posterior sideslip of the EOM belly. More recent physiologically driven approaches involve pulley suspensions directly, tightening lax connective tissue bands that presumably permitted the pulley shift. Pulley Hindrance The third recognized pathology is pulley hindrance, in which normal posterior shift with EOM contraction is mechanically impeded [124], often inducing abnormal globe translation. Intentionally created hindrance can be therapeutic, as long known for posterior fixation (also known as ‘retroequatorial myopexy’ and ‘fadenoperation’) of an EOM to the underlying sclera. An operation intended to reduce an EOM’s effect in its field of action, posterior fixation was originally supposed to work by reduction in the EOM’s arc of contact, reducing its rotational lever arm [125]. Imaging by MRI demonstrates this mechanism incorrect, but several lines of evidence indicate that posterior fixation actually works by hindering posterior shift of the contracting EOM’s pulley, mechanically restricting EOM action [126]. A technically simpler and safer modification of posterior fixation has recently been introduced by us in which the MR pulley suspension is placed under tension and the MR pulley sutured to the EOM belly; this operation is at least as effective as posterior fixation with scleral suturing in treatment of accommodative esotropia with excessive accommodative convergence [127]. Central to the initial recognition of pulleys was the stability of rectus EOM paths after large surgical transpositions of the scleral insertions. Only slight shifts of pulleys are observed by MRI after transposition [21, 117]. Posterior suture fixation of the transposed EOMs as described by Foster [20] shifts the pulley farther into the direction of the transposed insertion. This changes the pulling direction to mimic more closely that of the paralyzed EOM, increasing the effectiveness of transposition [117].
Conclusion
The fundamental anatomy of the ocular motor effector apparatus fundamentally differs from traditional teaching. The following encapsulates this author’s broad concept of the orbita, simplified here for heuristic purposes. Rather than consisting of mechanically simple EOMs rotating the eye under explicit neural control of every kinematic nuance, the ocular motor system consists of a rather intricate mechanical arrangement comprised of a trampoline-like
Mechanics of the Orbita
151
suspension supported by the rectus EOMs and their associated connective tissues, which in turn is circumferentially controlled by the obliques. Rectus EOMs and their pulleys constitute the inner suspension that implements kinematics in 2-D corresponding largely to the 2-D organization of the retina and subcortical visual system, and so mechanically implements LL without additional neural specification. The inner suspension has effectively commutative properties. Analogous to a gimbal arrangement (but importantly different from a gimbal in some respects), the outer suspension moves the inner under the drive from the oblique EOMs to generate torsion not conforming to LL, and noncommutatively influences the inner suspension. The degree to which neural adaptations can compensate for ocular kinematics that normally are mechanically determined is a crucial question, since the answer will inform us about the clinical significance of many disorders of ocular motility, and the degree to which they may be amenable to surgical treatment. Acknowledgement This work was supported by US Public Health Service grants EY08313, EY00331, and DC005224. J. Demer received an award from Research to Prevent Blindness and is Leonard Apt Professor of Ophthalmology.
References 1 2 3 4 5 6 7 8 9 10 11 12
Demer JL: Extraocular muscles; in Jaeger EA, Tasman PR (eds): Duane’s Clinical Ophthalmology. Philadelphia, Lippincott, 2000, vol 1, chapter 1, pp 1–23. Demer JL: Anatomy of strabismus; in Taylor D, Hoyt C (eds): Pediatric Ophthalmology and Strabismus, ed 3. London, Elsevier, 2005, pp 849–861. Porter JD, Baker RS, Ragusa RJ, Brueckner JK: Extraocular muscles: basic and clinical aspects of structure and function. Surv Ophthalmol 1995;39:451–484. Oh SY, Poukens V, Demer JL: Quantitative analysis of rectus extraocular muscle layers in monkey and humans. Invest Ophthalmol Vis Sci 2001;42:10–16. Kono R, Poukens V, Demer JL: Superior oblique muscle layers in monkeys and humans. Invest Ophthalmol Vis Sci 2005;46:2790–2799. Demer JL, Oh SY, Poukens V: Evidence for active control of rectus extraocular muscle pulleys. Invest Ophthalmol Vis Sci 2000;41:1280–1290. Ruskell GL, Kjellevold Haugen IB, Bruenech JR, van der Werf F: Double insertions of extraocular rectus muscles in humans and the pulley theory. J Anat 2005;206:295–306. Demer JL, Oh SY, Clark RA, Poukens V: Evidence for a pulley of the inferior oblique muscle. Invest Ophthalmol Vis Sci 2003;44:3856–3865. Sappey PC: Traite D’Anatomie Descriptive Avec Figures Intercalees Dans Le Texte.Paris, Delahaye et Lecrosnier, 1888. Sappey PC: The motor muscles of the eyeball [translation from the French]. Strabismus 2001;9: 243–253. Miller JM: Functional anatomy of normal human rectus muscles. Vision Res 1989;29:223–240. Kono R, Clark RA, Demer JL: Active pulleys: magnetic resonance imaging of rectus muscle paths in tertiary gazes. Invest Ophthalmol Vis Sci 2002;43:2179–2188.
Demer
152
13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
33
34 35 36 37 38 39 40 41
Porter JD, Poukens V, Baker RS, Demer JL: Cytoarchitectural organization of the medial rectus muscle pulley in man. Invest Ophthalmol Vis Sci 1995;36:S960. Demer JL, Miller JM, Poukens V, Vinters HV, Glasgow BJ: Evidence for fibromuscular pulleys of the recti extraocular muscles. Invest Ophthalmol Vis Sci 1995;36:1125–1136. Demer JL, Poukens V, Miller JM, Micevych P: Innervation of extraocular pulley smooth muscle in monkeys and humans. Invest Ophthalmol Vis Sci 1997;38:1774–1785. Miller JM, Demer JL, Poukens V, Pavlowski DS, Nguyen HN, Rossi EA: Extraocular connective tissue architecture. J Vis 2003;3:240–251. Fink WH. Surgery of the Vertical Muscles of the Eye. Springfield (IL), Thomas, 1962, pp 37–121. Helveston EM, Merriam WW, Ellis FD, Shellhamer RH, Gosling CG: The trochlea: a study of the anatomy and physiology. Ophthalmology 1992;80:124–133. Demer JL: Pivotal role of orbital connective tissues in binocular alignment and strabismus. The Friedenwald lecture. Invest Ophthalmol Vis Sci 2004;45:729–738. Foster RS: Vertical muscle transposition augmented with lateral fixation. J AAPOS 1997;1:20–30. Clark RA, Rosenbaum AL, Demer JL: Magnetic resonance imaging after surgical transposition defines the anteroposterior location of the rectus muscle pulleys. J AAPOS 1999;3:9–14. Clark RA, Miller JM, Demer JL: Three-dimensional location of human rectus pulleys by path inflections in secondary gaze positions. Invest Ophthalmol Vis Sci 2000;41:3787–3797. Clark RA, Demer JL: Effect of aging on human rectus extraocular muscle paths demonstrated by magnetic resonance imaging. Am J Ophthalmol 2002;134:872–878. Clark RA, Miller JM, Demer JL: Location and stability of rectus muscle pulleys inferred from muscle paths. Invest Ophthalmol Vis Sci 1997;38:227–240. Haslwanter T: Mathematics of three-dimensional eye rotations. Vision Res 1995;35:1727–1739. van den Berg AV: Kinematics of eye movement control. Proc R Soc Lond 1995;260:191–197. Ruete CGT: Ocular physiology. Strabismus 1999;7:43–60. Tweed D, Vilis T: Geometric relations of eye position and velocity vectors during saccades. Vision Res 1990;30:111–127. Quaia C, Optican LM: Commutative saccadic generator is sufficient to control a 3-D ocular plant with pulleys. J Neurophysiol 1998;79:3197–3215. Koene AR, Erklens CJ: Properties of 3D rotations and their relation to eye movement control. Biol Cybern 2004;90:410–417. Demer JL: The orbital pulley system: a revolution in concepts of orbital anatomy. Ann N Y Acad Sci 2002;956:17–32. Detorakis ET, Engstrom RE, Straatsma BR, Demer JL: Functional anatomy of the anophthalmic socket: insights from magnetic resonance imaging. Invest Ophthalmol Vis Sci 2003;44: 4307–4313. Collins CC: The human oculomotor control system; in Lennerstrand G, Bach-y-Rita P (ed): Basic Mechanisms of Ocular Motility and Their Clinical Implications. New York, Pergamon, 1975, pp 145–180. Shall MS, Goldberg SJ: Lateral rectus EMG and contractile responses elicited by cat abducens motoneurons. Muscle Nerve 1995;18:948–955. Porrill J, Warren PA, Dean P: A simple control laws generates Listing’s positions in a detailed model of the extraocular muscle system. Vision Res 2000;40:3743–3758. Smith MA, Crawford JD: Neural control of rotational kinematics within realistic vestibuloocular coordinate systems. J Neurophysiol 1998;80:2295–2315. Crane BT, Tian J, Demer JL: Human angular vestibulo-ocular reflex initiation: relationship to Listing’s law. Ann NY Acad Sci 2005;1039:1–10. Steffen H, Walker MF, Zee DS: Rotation of Listing’s plane with convergence: Independence from eye position. Invest Ophthalmol Vis Sci 2000;41:715–721. Kapoula Z, Bernotas M, Haslwanter T: Listing’s plane rotation with convergence: role of disparity, accommodation, and depth perception. Exp Brain Res 1999;126:175–186. Schreiber K, Crawford JD, Fetter M, Tweed D: The motor side of depth vision. Nature 2001;410:819–822. Bruno P, van den Berg AV: Relative orientation of primary positions of the two eyes. Vision Res 1997;37:935–947.
Mechanics of the Orbita
153
42 43 44 45 46 47 48 49
50 51 52 53
54 55 56
57 58 59 60 61 62 63 64 65 66 67
van Rijn LJ, van den Berg AV: Binocular eye orientation during fixations: Listing’s law extended to include eye vergence. Vision Res 1993;33:691–708. Demer JL, Kono R, Wright W: Magnetic resonance imaging of human extraocular muscles in convergence. J Neurophysiol 2003;89:2072–2085. Allen MJ, Carter JH: The torsional component of the near reflex. Am J Optom Arch Am Acad Optom 1967;44:343–349. Kono R, Poukens V, Demer JL: Quantitative analysis of the structure of the human extraocular muscle pulley system. Invest Ophthalmol Vis Sci 2002;43:2923–2932. Mays LE, Zhang Y, Thorstad MH, Gamlin PD: Trochlear unit activity during ocular convergence. J Neurophysiol 1991;65:1484–1491. van den Bedem SPW, Schutte S, van der Helm FCT, Simonsz HJ: Mechanical properties and functional importance of pulley bands or ‘faisseaux tendineux’. Vis Res 2005;45:2710–2714. Khanna S, Porter JD: Evidence for rectus extraocular muscle pulleys in rodents. Invest Ophthalmol Vis Sci 2001;42:1986–1992. Felder E, Bogdanovich S, Rubinstein NA, Khana TS: Structural details of rat extraocular muscles andd three-dimensional reconstruction of the rat inferior rectus muscle and muscle-pulley interface. Vision Res 2005;45:1945–1955. Dimitrova DM, Shall MS, Goldberg SJ: Stimulation-evoked eye movements with and without the lateral rectus muscle pulley. J Neurophysiol 2003;90:3809–3815. Quaia C, Optican LM: Dynamic eye plant models and the control of eye movements. Strabismus 2003;11:17–31. Raphan T: Modeling control of eye orientation in three dimensions. I. Role of muscle pulleys in determining saccadic trajectory. J Neurophysiol 1998;79:2653–2667. Raphan T: Modeling control of eye orientation in three dimensions; in Fetter M, Haslwanter T, Misslisch H, Tweed D (eds): Three-dimensional Kinematics of Eye, Head, and Limb Movements. Amsterdam, Harwood, 1997, pp 359–374. Tweed D, Cadera W, Vilis T: Computing three-dimensional eye position quaternions and eye velocity from search coil signals. Vision Res 1990;30:97–110. Misslisch H, Tweed D, Fetter M, Sievering D, Koenig E: Rotational kinematics of the human vestibuloocular reflex. III. Listing’s law. J Neurophysiol 1994;72:2490–2502. Thurtell MJ, Black RA, Halmagyi GM, Curthoys IA, Aw ST: Vertical eye position-dependence of the human vestibuloocular reflex during passive and active yaw head rotations. J Neurophysiol 1999;81:2415–2428. Crane BT, Tian JR, Demer JL: Temporal dynamics of ocular position dependence of the initial human vestibulo-ocular reflex. Invest Ophthalmol Vis Sci 2005 (in revision). Crane BT, Tian JR, Demer JL: Human angular vestibulo-ocular reflex initiation: relationship to Listing’s law. Ann N Y Acad Sci 2005;1039:26–35. Crawford JD, Vilis T: Symmetry of oculomotor burst neuron coordinates about Listing’s plane. J Neurophysiol 1992;68:432–448. Tweed D: Visual-motor optimization in binocular control. Vision Res 1997;37:1939–1951. Misslisch H, Tweed D: Neural and mechanical factors in eye control. J Neurophysiol 2001;86: 1877–1883. Angelaki DE, Hess BJ: Control of eye orientation: where does the brain’s role end and the muscle’s begin? Eur J Neurosci 2004;19:1–10. Angelaki DE: Three-dimensional ocular kinematics during eccentric rotations: evidence for functional rather than mechanical constraints. J Neurophysiol 2003;89:2685–2696. Klier EM, Crawford JD: Human oculomotor system acounts for 3-D eye orientation in the visualmotor transformation for saccades. J Neurophysiol 1998;80:2274–2294. Mok D, Ro A, Cadera W, Crawford JD, Vilis T: Rotation of Listing’s plane during vergence. Vision Res 1992;32:2055–2064. Crane BT, Tian J, Demer JL: Kinematics of vertical saccades during the yaw vestibulo-ocular reflex in humans. Invest Ophthalmol Vis Sci 2005;46:2800–2809. Lee C, Zee DS, Straumann D: Saccades from torsional offset positions back to Listing’s plane. J Neurophysiol 2000;83:3141–3253.
Demer
154
68 Tian JR, Crane BT, Demer JL: Vestibular catch-up saccades in labyrinthine deficiency. Exp Brain Res 2000;131:448–457. 69 Demer JL, Clark RA: Magnetic resonance imaging of human extraocular muscles during static ocular counter-rolling. J Neurophysiol 2005;94:3292–3302. 70 Ghasia FF, Angelaki DE: Do motoneurons encode the noncommutativity of ocular rotations? Neuron 2005;47:281–293. 71 Klier EM, Meng H, Angelaki DE: Abducens nerve/nucleus stimulation produces kinematically correct three-dimensional eye movements. Soc Neurosci Abstr 2005:abstract #475.4. 72 Scherberger H, Cabungcal J-H, Hepp K, Suzuki Y, Straumann D, Henn V: Ocular counterroll modulates the preferred direction of saccade-related pontine burst neurons in the monkey. J Neurophysiol 2001;86:935–949. 73 Hess BJM, Angelaki DE: Gravity modulates Listing’s plane orientation during both pursuit and saccades. J Neurophysiol 2003;90:1340–1345. 74 Hess BJM, Angelaki DE: Kinematic principles of primate rotational vestibulo-ocular reflex II. Gravity-dependent modulation of primary eye position. J Neurophysiol 1997;78:2203–2216. 75 Hess BJM, Angelaki DE: Kinematic principles of primate rotational vestibulo-ocular reflex. I. Spatial organization of fast phase velocity axes. J Neurophysiol 1997;78:2193–2202. 76 Crawford JD, Tweed DB, Vilis T: Static ocular counterroll is implemented through the 3-D neural integrator. J Neurophysiol 2003;90:2777–2784. 77 Frens MA, Suzuki Y, Scherberger H, Hepp K, Henn V: The collicular code of saccade direction depends on the roll orientation of the head relative to gravity. Exp Brain Res 1998;120:283–290. 78 Crawford JD, Martinez-Trujillo JC, Kleier EM: Neural control of three-dimensional eye and head movements. Cur Opin Neurosci 2003;13:655–662. 79 Van Opstal AJ, Hepp K, Hess BJ, Straumann D, Henn V: Two- rather than three-dimensional representation of saccades in monkey superior colliculus. Science 1991;252:1313–1315. 80 Glasauer S, Dieterich M, Brandt T: Central positional nystagmus simulated by a mathematical ocular motor model of otolith-dependent modification of Listing’s plane. J Neurophysiol 2001;86:1456–1554. 81 Crawford JD, Guitton D: Visual-motor transformations required for accurate and kinematically correct saccades. J Neurophysiol 1997;78:1447–1467. 82 Wong AMF, Sharpe JA, Tweed D: Adaptive neural mechanism for Listing’s law revealed in patients with fourth nerve palsy. Invest Ophthalmol Vis Sci 2002;43:1796–1803. 83 Straumann D, Steffen H, Landau K, et al: Primary position and Listing’s law in acquired and congenital trochlear nerve palsy. Invest Ophthalmol Vis Sci 2003;44:4282–4292. 84 Migliaccio AA, Cremer PD, Sw ST, Halmagyi GM: Vergence-mediated changes in Listing’s plane do not occur in an eye with superior oblique palsy. Invest Ophthalmol Vis Sci 2004;45:3043–3047. 85 Angelaki DE, Dickman DJ: Premotor neurons encode torsional eye velocity during smooth-pursuit eye movements. J Neurosci 2003;23:2971–2979. 86 Demer JL: Clarity of words and thoughts about strabismus. Am J Ophthalmol 2001;132:757–759. 87 Bielschowsky A: Lectures on motor anomalies. XI. Etiology, prognosis, and treatment of ocular paralyses. Am J Ophthalmol 1939;22:723–734. 88 von Noorden GK, Murray E, Wong SY: Superior oblique paralysis. A review of 270 cases. Arch Ophthalmol 1986;104:1771–1776. 89 Adler FE: Physiologic factors in differential diagnosis of paralysis of superior rectus and superior oblique muscles. Arch Ophthalmol 1946;36:661–673. 90 Scott WE, Kraft SP: Classification and treatment of superior oblique palsies: II. Bilateral superior oblique palsies; in Caldwell D (ed): Pediaric Ophthalmology and Strabismus: Transactions of the New Orleans Academy of Ophthalmology. New York, Raven Press, 1986, pp 265–291. 91 Scott WE, Parks MM: Differential diagnosis of vertical muscle palsies; in von Noorden GK (ed): Symposium on Strabismus: Transactions of the New Orleans Academy of Ophthalmology. St. Louis, Mosby, 1978, pp 118–134. 92 Kushner BJ: Ocular torsion: rotations around the ‘WHY’ axis. J AAPOS 2004;8:1–12. 93 Kushner BJ: The diagnosis and treatment of bilateral masked superior oblique palsy. Am J Ophthalmol 1988;105:186–194.
Mechanics of the Orbita
155
94 Robinson DA: Bielschowsky head-tilt test – II. Quantitative mechanics of the Bielschowsky headtilt test. Vision Res 1985;25:1983–1988. 95 Simonsz HJ, Crone RA, van der Meer J, Merckel-Timmer CF, van Mourik-Noordenbos AM: Bielschowsky head-tilt test I – ocular counterrolling and Bielschowsky head-tilt test in 23 cases of superior oblique palsy. Vision Res 1985;25:1977–1982. 96 Demer JL, Miller JM: Magnetic resonance imaging of the functional anatomy of the superior oblique muscle. Invest Ophthalmol Vis Sci 1995;36:906–913. 97 Chan TK, Demer JL: Clinical features of congenital absence of the superior oblique muscle as demonstrated by orbital imaging. J AAPOS 1999;3:143–150. 98 Velez FG, Clark RA, Demer JL: Facial asymmetry in superior oblique palsy and pulley heterotopy. J AAPOS 2000;4:233–239. 99 Kono R, Demer JL: Magnetic resonance imaging of the functional anatomy of the inferior oblique muscle in superior oblique palsy. Ophthalmology 2003;110:1219–1229. 100 Demer JL, Miller MJ, Koo EY, Rosenbaum AL, Bateman JB: True versus masquerading superior oblique palsies: muscle mechanisms revealed by magnetic resonance imaging; in Lennerstrand G (ed): Update on Strabismus and Pediatric Ophthalmology. Boca Raton (FL), CRC Press, 1995, pp 303–306. 101 Plager DA: Traction testing in superior oblique palsy. J Pediatr Ophthalmol Strabismus 1990;27: 136–140. 102 Plager DA: Tendon laxity in superior oblique palsy. Ophthalmology 1992;99:1032–1038. 103 Plager DA, Helveston EM, Fahad B: Superior oblique muscle atrophy/hypodevelopment in superior oblque palsy. Abstr of 22nd Annual AAPOS Mtg. 1996:papers 10. 104 Kushner BJ: Errors in the three-step test in the diagnosis of vertical strabismus. Ophthalmology 1987;96:127–132. 105 Brodsky ME: Three dimensions of skew deviation. Br J Ophthalmol 2003;87:1440–1441. 106 Donahue SP, Lavin PJ, Hamed LM: Tonic ocular tilt reaction simulating a superior oblique palsy: diagnostic confusion with the 3-step test. Arch Ophthalmol 1999;117:347–352. 107 Clark RA, Miller JM, Rosenbaum AL, Demer JL: Heterotopic muscle pulleys or oblique muscle dysfunction? J AAPOS 1998;2:17–25. 108 Clark RA, Miller JM, Demer JL: Displacement of the medial rectus pulley in superior oblique palsy. Invest Ophthalmol Vis Sci 1998;39:207–212. 109 Lajeunie E, Catala M, Renier D. Craniosynostosis: from a clinical description to an understanding of bone formation of the skull. Childs Nerv Syst 1999;15:276–280. 110 Limon de Brown E, Monasterio FO, Feldman MS: Strabismus in plagiocephaly. J Pediatr Ophthalmol Strabismus 1998;25:180–190. 111 Khan SH, Nischal KK, Dean F, Hayward RD, Walker J: Visual outcomes and amblyogenic risk factors in craniosynostotic syndromes: a review of 141 cases. Br J Ophthalmol 2003;87: 999–1003. 112 Coats DK, Paysse EA, Stager DR: Surgical management of V-pattern strabismus and oblique dysfunction in craniofacial dysostosis. J AAPOS 2000;4:338–342. 113 Velez FG, Thacker N, Britt MT, Rosenbaum AL: Cause of V pattern strabismus in craniosynostosis: a case report. Br J Ophthalmol 2004;88:1598–1599. 114 Clark RA, Demer JL, Miller JM, Rosenbaum AL: Heterotopic rectus extraocular muscle pulleys simulate oblique muscle dysfunction. Abstracts of the American Association for Pediatric Ophthalmology and Strabismus. 1997, p 39. 115 Demer JL, Clark RA, Miller JM: Heterotopy of extraocular muscle pulleys causes incomitant strabismus; in Lennerstrand G (ed). Advances in Strabismology. Buren (Netherlands), Aeolus Press, 1999, pp 91–94. 116 Demer JL: A 12 year, prospective study of extraocular muscle imaging in complex strabismus. J AAPOS 2003;6:337–347. 117 Clark RA, Demer JL: Rectus extraocular muscle pulley displacement after surgical transposition and posterior fixation for treatment of paralytic strabismus. Am J Ophthalmol 2002;133:119–128. 118 Krzizok TH, Schroeder BU: Measurement of recti eye muscle paths by magnetic resonance imaging in highly myopic and normal subjects. Invest Ophthalmol Vis Sci 1999;40:2554–2560.
Demer
156
119 Demer JL, Miller JM: Orbital imaging in strabismus surgery; in Rosenbaum AL, Santiago AP (eds): Clinical Strabismus Management: Principles and Techniques. Philadelphia, WB Saunders, 1999, pp 84–98. 120 Wong IBY, Leo SW, Khoo BK: Surgical correction of myopia strabismus fixus. Abstracts of 31th Annual Meeting of the American Association for Pediatric Ophthalmology and Strabismus. 2005, p 50. 121 Oh SY, Clark RA, Velez F, Rosenbaum AL, Demer JL: Incomitant strabismus associated with instability of rectus pulleys. Invest Ophthalmol Vis Sci 2002;43:2169–2178. 122 Demer JL, Kono R, Wright W, Oh SY, Clark RA: Gaze-related orbital pulley shift: A novel cause of incomitant strabismus; in de Faber JT (ed): Progress in Strabismology. Lisse, Swets and Zeitlinger, 2002, pp 207–210. 123 Bhola R, Rosenbaum AL, Ortube MC, Demer JL: High resolution magnetic resonance imaging demonstrates varied anatomic abnormalities in Brown’s syndrome. J AAPOS 2004 (in revision). 124 Piruzian A, Goldberg RA, Demer JL: Inferior rectus pulley hindrance: orbital imaging mechanism of restrictive hypertropia following lower lid surgery. J AAPOS 2004;8:338–344. 125 Scott AB: The faden operation: mechanical effects. Am Orthoptic J 1977;27:44–47. 126 Clark RA, Isenberg SJ, Rosenbaum SJ, Demer JL: Posterior fixation sutures: a revised mechanical explanation for the fadenoperation based on rectus extraocular muscle pulleys. Am J Ophthalmol 1999;128:702–714. 127 Clark RA, Ariyasu R, Demer JL: Medial rectus pulley posterior fixation is as effective as scleral posterior fixation for acquired esotropia with a high AC/A ratio. Am J Ophthalmol 2004;137: 1026–1033.
Joseph L. Demer, MD, PhD Jules Stein Eye Institute, Departments of Ophthalmology and Neurology, David Geffen Medical School at the University of California 100 Stein Plaza, UCLA Los Angeles, CA 90095-7002 (USA) Tel. ⫹1 310 825 5931, Fax ⫹1 310 206 7826, E-Mail
[email protected]
Mechanics of the Orbita
157
Straube A, Büttner U (eds): Neuro-Ophthalmology. Dev Ophthalmol. Basel, Karger, 2007, vol 40, pp 158–174
Current Models of the Ocular Motor System Stefan Glasauer Center for Sensorimotor Research, Department of Neurology, Ludwig-Maximilian University Munich, Munich, Germany
Abstract This chapter gives a brief overview of current models of the ocular motor system. Beginning with models of the final ocular pathway consisting of eye plant and the neural velocity-to-position integrator for gaze holding, models of the motor part of the saccadic system, models of the vestibulo-ocular reflexes (VORs), and of the smooth pursuit system are reviewed. As an example, a simple model of the 3-D VOR is developed which shows why the eyes rotate around head-fixed axes during rapid VOR responses such as head impulses, but follow a compromise between head-fixed axes and Listing’s law for slow VOR responses. Copyright © 2007 S. Karger AG, Basel
The ocular motor system is one of the best examined motor systems. Not only are there numerous studies on behavioral data, but also the neurophysiology and anatomy of the ocular motor system is well documented. This knowledge makes the ocular motor system a perfect candidate for modeling. Models of the ocular motor system span the range from models at the systems level to detailed neural networks using firing rate neurons. Spiking neuron models are, at present, rare. The main reason is that the ocular motor system is composed of a wealth of neuronal structures which makes a detailed implementation using spiking neuron models computationally difficult. Moreover, the impressive explanatory power of models at the systems level has not yet raised the need for more detailed modeling at the level of single neurons except for restricted subsets of the ocular motor circuitry. The present chapter attempts to give an overview of the most recent models related to the ocular motor system, without trying to compile a complete bibliography or referring to the whole seminal work by D.A. Robinson, starting
in the 1960s, which still is the basis for models of the ocular motor system. The focus is on the motor system, therefore, models of visual cortical mechanisms such as computation of motion from retinal sensory inputs will only briefly be touched upon. However, one should not forget that the question of how retinal input represented on retinotopic maps is neurally transformed by the brain to finally result in a motor command for an eye movement is an important aspect which should not be neglected. In the following, the various models will be presented in the reverse order, that is, the chapter begins with models focused on the biomechanics of the eye. Subsequently, models of the neural velocity-toposition integrator, which is common to all types of eye movements, are considered. Finally, models of the various types of eye movements and their neural control are presented.
Eye Plant
The term ‘eye plant’ covers the kinematic and dynamic behavior of the eye. Thus, models of the eye plant (for review, see also [1]) focus on the relationship between a motor command generated in the ocular motor nuclei of the brainstem and the resulting eye movement. Evidently, this transformation from motor command to eye movement is determined by the biomechanics of the eye globe, the extraocular eye muscles, the muscle pulleys (connective tissue pulleys that serve as the functional mechanical origin of the muscles), and the orbital tissues [see Demer, this vol, pp 132–157]. Most models focusing on the eye plant explicitly deal with the 3-D geometry and kinematics of the eye, and with specific properties of the plant such as the force-length relationship of the muscles or the placement of the pulleys. In contrast, models dealing with the neural control implemented in brainstem structures and above very often treat the eye plant as a lumped element. Two types of eye plant models can be distinguished: static models, concerned with the anatomy of the eye plant, and dynamic models, also considering the temporal properties involved (e.g. time constants of the eye plant). Static models, derived from Robinson’s work [2, 3] have resulted in software packages, i.e. Orbit [4], SEE [5], designed to help the ophthalmologist, for example, in strabismus surgery. Other authors have designed static models to evaluate the role of the eye plant in Listing’s law [6–9]. For a review on Listing’s law, see Wong [10]. This question is closely related to the problem of noncommutativity of 3-D rotations. From these theoretical studies, especially after the existence of muscle pulleys was established [see Demer, this vol, pp 132–157], it was concluded that, given specific pulley configurations, Listing’s law (i.e. if eye orientation is expressed as rotation vectors or quaternions,
Ocular Motor Models
159
torsion depends linearly on gaze direction) may be implemented by the eye plant. In other words, a 2-D innervation of the six extraocular eye muscles would be sufficient to achieve the torsional eye orientations required by Listing’s law (see also below) in tertiary positions (off the horizontal and vertical meridians). This view has recently been supported by recordings from the motoneurons during smooth pursuit [11]. This does not mean that the eye plant constricts eye movements to obey Listing’s law, but it simplifies its implementation to a great extent. Dynamics have been implemented mostly in simplified, lumped eye plant models [12–16], since detailed experimental studies of the 3-D dynamics have been missing. Recently, the dynamics of the eye plant have been re-evaluated [17], suggesting that in contrast to previous assumptions of a dominant time constant of 200 ms, the dynamics have to be described by a wide range of time constants ranging from about 10 ms to 10 s. A possibly more severe shortcoming of the lumped eye plant models is that they do not account for the fact that muscle force is a function of innervation and length. According to a more realistic model of 3-D dynamics [1], this leads to passive eye position-dependent torque that has to be compensated for by additional innervation. Thus, while models using simplified eye plant approximations are useful and valid in many cases, a more adequate implementation of the eye plant will be necessary to fully understand the neural mechanisms controlling eye movements.
The Neural Velocity-to-Position Integrator
Together with the ocular motor nuclei in the brainstem, the neural velocityto-position integrator [for review, see 18] forms the final neural structure common to all types of eye movements. The neural commands for eye movements, which are also sent to the ocular motor nuclei, consist of phasic signals coding eye velocity (e.g. the saccadic burst command). However, if this were the only signal sent to the muscles, the eye would not remain in an eccentric position, but drift back to the equilibrium position determined by the eye plant. Therefore, an additional signal is necessary to generate the tonic muscle force to hold the eye. This signal comes from the neural velocity-to-position integrators located in the brainstem (nucleus prepositus hypoglossi and medial vestibular nucleus) for horizontal eye movements and the midbrain (interstitial nucleus of Cajal) for vertical eye movements. Additionally, the cerebellar flocculus plays an important role in neural integration in mammals, as shown by lesion experiments in different species such as rats, cats, and nonhuman primates [19]. As for the eye plant, many models consider the neural integrator as lumped element, which is described by a so-called leaky integrator with a time constant of more than 2 s
Glasauer
160
for primates, which determines the residual centripetal drift. This lumped description is useful and valid for models interested in other aspects of the ocular motor system. However, it does not allude as to how the integrator is implemented neurally, or which additional properties it may need. Specifically when considering 3-D eye movements, it has been shown that simply using three leaky integrators (as an extension to 1-D models) may not suffice depending on the coding of velocity information to be integrated, because 3-D rotations do not commute. This poses a problem especially for the vestibulo-ocular reflex (VOR): the semicircular canal afferent signal codes angular velocity, but the integral of angular velocity does not yield orientation [15]. This problem can, however, be circumvented if the signal to be integrated is first converted to the derivative of eye orientation (which is not angular velocity). Thus, in such case, a commutative integrator composed of three parallel 1-D integrators can be used [13, 15, 16], and will produce a correct tonic signal to hold the eye eccentrically, given that the eye plant has the property of converting this neural command to actual eye orientation. Such a configuration will also maintain the eye orientation in Listing’s plane if the command is 2-D. Notably, as mentioned above, eye movements violating Listing’s law (e.g. during the VOR, or during active eye-head gaze shifts) are still possible, but necessarily require a full 3-D neural command. Additionally, Listing’s law is modified by vergence and head tilt. Such a modification requires changes in the central nervous commands, either by altering the pulley configuration or the commands sent to the extraocular muscles. Therefore, an extension to the neural integrator scheme has been proposed which incorporates additional input from the otoliths to achieve accurate fixations during head tilt [20, 21]. The neural implementation of the integration is the topic of a considerable number of studies. It has been suggested that a network of reciprocal inhibition forms a positive feedback loop which effectively prolongs the short time constants of single neurons to the desired long time constant of the integrating network [18, 22, 23]. Other related models proposed that the positive feedback loop forming the integrator is excitatory and contains an internal model of the eye plant dynamics [24, 25]. One of the problems of the original reciprocal feedback hypothesis was that fine tuning of the synaptic strength is implausible given that membrane time constants of about 5 ms have to be extended to the 20 s of the network [26]. A possible solution [27] is that the intrinsic time constant of processing is determined by synaptic time constants with values around 100 ms (corresponding to NMDA receptors). Alternative models suggest that single cell properties determine integration [28, 29]. While the models above mostly assume that the known integrator brainstem regions exclusively perform the integration, it has been shown by several studies that, in mammals, lesions of the cerebellar floccular lobe or the parts of
Ocular Motor Models
161
the inferior olive projecting to it decrease the integrator time constant to less than 2 s. This means that the brainstem integrator alone only needs to achieve weak integration, the remainder is done by the cerebellum. Models of how the cerebellum may contribute to the integrator function are relatively sparse, but suggest that recurrent feedback loops are responsible for this function [19, 30–33].
Saccadic Eye Movements
Saccades rapidly redirect gaze, for example in response to a visual stimulus [see Thier, this vol, pp 52–75]. The function of the saccadic burst generator in the brainstem (horizontal: paramedian pontine reticular formation; vertical: rostral interstitial nucleus of the medial longitudinal fasciculus) and its input structures are the focus of numerous modeling studies. While the first models by Robinson focused on how the burst generator and the neural integrator cooperate to achieve an inverse dynamic model of the eye plant to produce rapid and accurate saccades without postsaccadic drift, later studies concentrated, for example, on how saccadic accuracy is achieved by local feedback loops (e.g. [34]). Such feedback loops have been proposed since, during an ongoing saccade, visual feedback for fine endpoint corrections is not available due to the long latency of visual processing. Subsequently, these 1-D models have been extended to three dimensions [35, 16, 20] to explain how the 2-D visual input, the retinal error, is converted to an accurate 3-D motor command, which obeys Listing’s law [10]. Neural network models of the saccadic burst generator, inspired by Robinson’s work, have shown how the various cell types in the brainstem, such as omnipause neurons and burst neurons, may interact to generate the saccadic burst command [36–39]. Another problem tackled by modelers is how the transformation necessary to generate a temporal, vector-coded command (the saccadic burst) from a spatial representation of retinal error coded in a retinotopic map (e.g. the superior colliculus) is achieved [40]. Since the exact mechanism of this spatiotemporal transformation is unknown to date, these models provide important testable hypotheses [37]. Detailed modeling of map-like structures such as the superior colliculus necessitates the use of neural network models to represent the spatial distribution of neural activity. For the superior colliculus, this has been done in various ways, e.g. as 1-D simplification [41], to complex networks which represent the collicular map, propose feedback mechanism [42], and also implement the above-mentioned visuomotor transformation [43]. Even more complex models of the superior colliculus and saccade generation, such as the ones by Grossberg et al. [44], incorporate aspects such as multimodality, model cortical
Glasauer
162
regions such as the frontal eye fields (FEFs), and have been proposed to formulated hypotheses about how the brain may allow for reactive vs. planned saccades, how target selection may work, and how the behavioral differences in common saccade paradigms, such as gap, overlap, or delayed saccades may be explained [45]. Another important region implicated in saccade generation, the oculomotor vermis and the fastigial nucleus of the cerebellum, are the focus of only a few models so far. Their focus is either mainly on the functional role of the cerebellum [46, 47], or on explaining the possible interaction of superior colliculus and cerebellum for saccade generation [32, 48–50]. One of the tests for the realism of these models is simulation of the profound effects of cerebellar lesions on saccade execution, thereby providing and testing hypotheses on cerebellar function for on-line motor control of rapid movements. The most recent of these models [50] proposes that the role of the cerebellum goes beyond controlling eye movement in that the cerebellum is considered to control gaze, that is, the combined action of eye and head in achieving accurate gaze shifts. While lesion studies have demonstrated the importance of these cerebellar structures for adaptive modification of saccadic amplitude, even less modeling studies have touched upon this issue [51–53]. However, since recent experimental studies [54] on saccade adaptation challenge the prevailing theories of the adaptive function of the cerebellum and inferior olive [55, 56], an increasing interest in modeling of these structures can be expected. Perceptual aspects of the saccadic system, which are further upstream from motor processing, are also a topic of current models. To name one example, Niemeier et al. [57] explained the saccadic suppression of displacement by Bayesian integration of sensory and motor information, thus suggesting that an apparent flaw in trans-saccadic processing of visual information is, in fact, an optimal solution. For readers with deeper interest in computational modeling of the saccadic system from cortical structures to brainstem, a recent review article [58] providing a comprehensive overview is recommended.
Vestibulo-Ocular Reflexes
The VOR is the phylogenetically oldest eye movement system and serves to stabilize the eye in space, and thus the visual image on the retina [see Fetter, this vol, pp 35–51]. There are two distinct VOR systems, the angular VOR driven by the semicircular canals stabilizing the retinal image during head rotation, and the translational VOR which gets input from the otolith systems and compensates for translations. Additionally, the so-called static VOR, which is
Ocular Motor Models
163
also driven by the otoliths, compensates for head tilt with respect to gravity and results in static ocular counterroll and a compensatory tilt of Listing’s plane. The static VOR plays a minor role in primates due to its weak gain (only about 5 of counterroll for a 90 head tilt in roll), but is of interest for the clinicians, since peripheral and central vestibular imbalance causes ocular counterroll. It has thus been of interest not only to model the static VOR, but also to formalize hypotheses about possible lesion sites causing pathological counterroll [59, 60]. Another study of interest for clinicians is concerned with the angular VOR after unilateral or bilateral vestibular lesions [61]. Practically all ocular motor models are based on a firing rate description of the underlying neural structure. However, there is one exception, a model of the horizontal angular VOR in the guinea pig which uses realistic spiking neurons [62]. The model consists of separate brainstem circuits for generation of slow and quick phases, and thus allows simulation of nystagmus. Due to the bilateral layout of the network, a simulation of unilateral peripheral vestibular lesions was also possible. While the three-neuron arc of the angular VOR and its indirect pathway via the neural integrator, first modeled by Robinson, has been an excellent example of an inverse internal model, modeling it regained interest only after considering the 3-D properties of the VOR [12, 15] (see also the modeling example below). In parallel to these attempts, models of canal-otolith interaction considered how the VOR response is influenced by gravity [63, 64], e.g. why there are differences in pitch VOR if performed in upright vs. supine positions. This question is closely related to the more general question of how the brain resolves the ambiguity of otolith signals which do not differentiate between linear acceleration and gravity, a problem for which various solutions based on canal-otolith senory fusion have been offered so far [63–67]. While these models focused on the necessary underlying computations of the proposed interaction of semicircular canal and otolith information for VOR responses, others investigated how these signals could interact at the brainstem level [68–70]. Some of these models also included visual-vestibular interaction [64, 67], which played a major role in early models of the angular VOR [71–73], since the dynamics of the semicircular canals are insufficient to generate the ongoing nystagmus observed in light in response to continuous whole-body rotation. This response, called optokinetic nystagmus [see Büttner, this vol, pp 76–89], and its intimate link to the VOR via the so-called velocity-storage mechanism have been treated by various models [64, 74, 75]. Of ongoing interest is another feature of the VOR, its adaptability [76]. The gain of the VOR in darkness can be adapted by changing the visual input during training, for example, rotating a visual scene with the subject will decrease the VOR gain. Since adaptability depends on the cerebellum [77], several models
Glasauer
164
have been proposed which explain gain adaptation by assuming synaptic plasticity at the level of the cerebellar flocculus [78]. Other models suggest on the basis of experimental evidence that plasticity also occurs at the level of the vestibular nuclei [75, 79, 80]. Recent papers suggest that VOR adaptation may, in fact, be ‘plant adaptation’, since the experimental modification is applied to the visual rather than the vestibular input [30, 33]. Consequently, in those models the adaptation takes place in a floccular feedback loop carrying an efference copy of the motor command rather than changing the weights of the vestibular input.
A Modeling Example: A 3-D Model of the Angular VOR
As an example of how a model is formulated in mathematical terms, I shall now develop a model of the 3-D rotational VOR. 3-D eye position can be expressed by rotation vectors [6]. The rotation vector expresses the rotation of the eye with respect to a reference direction, e.g. straight ahead. The direction of the rotation vector corresponds to the rotation axis, and its length is approximately proportional to half the angle of the rotation. Since the VOR is driven by the afferent signal from the semicircular canals, which is proportional to angular head velocity, we need a relation between rotational position and angular velocity. This relation is given by a differential equation which expresses the temporal derivative of a rotation vector r· dr/dt by angular velocity and the rotation vector r [81]: r ( ( 䊊 r) r r)/2
(1)
From this differential equation, angular position is obtained by integration. The model developed below is based on work by Tweed [15], who originally used quaternions to describe rotations. Note that, for our purpose, both methods are equivalent. According to the linear plant hypothesis (see above), the extraocular motor neurons code a weighted combination of eye position, the output of the neural integrator, and its temporal derivative (rather than angular velocity). The brain has thus to convert the angular velocity vector supplied by the semicircular canal system to the temporal derivative of eye position. This conversion can be performed by equation 1. Tweed [15] suggested a simplified version of quaternion multiplication, which, expressed in rotation vectors, leads to the following formulation: r 艐 ( r)/2 艐 R : ½ [1 rx ry; rz 1 0; ry 0 1]
(2)
with r being an eye position in Listing’s plane, i.e. rx ⬇ 0. The latter prerequisite is fulfilled for real VOR eye movements, since frequent vestibular
Ocular Motor Models
165
quick phases keep the eye close to Listing’s plane [82, 83]. Equation 2 also shows that using this relation there is no longer a difference between Tweed’s 3-component quaternions [15] and the rotation vector computation. Even though this formula is sufficient for most purposes, it does not capture a main feature of the VOR, the quarter-angle rule [84]. Therefore, instead of equation 2, the following relationship is proposed r j [½ 0 0; 0 1 0; 0 0 1] R
(3)
which sets the gain of the torsional component of the derivative of eye position to 0.5. R is the eye position-dependent matrix defined in equation 2. Note that this is not equivalent to setting the gain of the torsional angular velocity to 0.5. This equation already reproduces both the low gain of the torsional VOR and the quarter-angle rule (on close inspection, this is exactly what is proposed by Tweed [15] in the simulation source code in his appendix A). However, it was shown that the rapid VOR, for example in response to head impulses, does not follow the quarter-angle rule but remains head fixed [85]. This finding, which is not explained by Tweed’s model, can easily be accounted for by the combination of a direct pathway carrying an accurate derivative of eye position (equation 2) and the integrator pathway following equation 3. This results in the following motor command m: m R r r j
(4)
with r being computed according to equation 3, and being the dominant time constant of the eye plant (200 ms). The so-called linear plant can be expressed by e· (m – e)/
(5)
with e being true eye position (in contrast to r, which signifies an internal estimate of eye position). Equations 2–5 thus constitute a simple dynamical model, which captures the main features of the 3-D VOR: low torsional VOR gain, quarter-angle rule for low frequencies, and head-fixed rotation axes for high frequencies. The model necessarily requires feedback connections from the neural integrators to vestibular nuclei to achieve the conversion from angular velocity to the derivative of eye position (fig. 1). Indeed, feedback connections to the vestibular nuclei have been shown anatomically from both the nucleus prepositus hypoglossi and the interstitial nucleus of Cajal. For a numerical simulation of the model comparing responses to slow and fast head movements, see figure 2. This modeling example not only demonstrates the importance of taking into account that eye movements are 3-D, but also that models based on eye velocity as model output are often not sufficient.
Glasauer
166
rI
Semicircular canals
Vestibular nuclei
Head rotation
Ocular motor nuclei
. rI
Neural integrator
r
I
m
+
Eye plant
+
. ·R·r
e Eye rotation
Direct pathway
Fig. 1. Block diagram of the model of the VOR described in the main text. The symbols correspond to the variables used in the mathematical description (equations 1–5); the boxes contain the differential equations or other mathematical relations translating input to output.
Straight ahead
250
30˚ down 30˚ up
6
5 Horizontal (degrees/s)
Horizontal (degrees/s)
200
150
100
4
3
2
50 1
0 50
a
0 0 Torsional (degrees/s)
1
50
b
0
1
Torsional (degrees/s)
Fig. 2. Simulation of VOR responses to purely horizontal head rotations (amplitude 5) with a model of the 3-D VOR (see text). a Rapid VOR, duration 50 ms. b Slow VOR, duration 2 s. Solid lines: horizontal angular eye velocity plotted over torsional angular eye velocity. Note the difference in velocity scales. Black: gaze straight ahead; dark grey: gaze 30° down; light grey: gaze 30° up. Dashed lines: quarter-angle rule prediction for relation between torsional and horizontal eye velocity at the respective gaze elevation. The model thus simulates how rapid VOR responses can be purely head fixed, while slow VOR follows the quarterangle rule, as demonstrated experimentally [85].
Ocular Motor Models
167
Retina
Target motion
Retinal slip
Afferent pathways
Efferent pathways Pursuit command Motor pathways
a
Internal model Retina
Target motion
Retinal slip
Afferent pathways
Reconstructed target motion
Efferent pathways
Efference copy
Pursuit command Motor pathways
b
Fig. 3. Two basic hypotheses for the processing of retinal slip information for smooth pursuit [after 89]. a The pursuit command is generated in a simple feedback loop. b An internal model of motor pathways and afferent pathways driven by an efference copy of the pursuit command generates a signal suited to reconstruct target motion. This signal is used to generate the pursuit command.
Smooth Pursuit Eye Movements
The smooth pursuit system [for overview, see Büttner, this vol, pp 76–89] has received considerable interest by modelers. In contrast to saccadic eye movements, it has to be modeled as a closed-loop system, since the pursuit eye movement changes the visual input by attempting to stabilize the target on the retina. Even though it shares some pathways and properties with the saccadic system (for review, see [86]), most of its structure can be regarded as implementing a separate stream of processing [review: 87]. Most importantly, smooth pursuit relies on an intact cerebellum (flocculus, paraflocculus, and dorsal vermis), while saccades are possible even without it. One group of models assumes that the eye movement response is based on a combination of eye acceleration, eye velocity, and sometimes eye position signals, which are combined to drive the pursuit controller (e.g. [88]). Alternatively, a positive feedback loop within the visual cortex is proposed (fig. 3) which has a similar effect as using combined retinal velocity and acceleration signals [90]. Another group building on the earliest modeling attempts [91, 92] assumes an internal reconstruction of target velocity from retinal slip and an efference
Glasauer
168
copy of eye velocity, which then drives pursuit (e.g. [93]). The latter approach has some advantages, especially regarding the problem of the long latency of visual processing, which makes the use of a simple high-gain feedback loop problematic. It is also supported by recent experimental evidence: it has been shown that the cortical middle superior temporal area (MST) contains neurons which code target motion in space (for review, see [87]), and that thalamic neurons carry smooth pursuit signals which are suited to convey an efference copy to the cortex [94]. While figure 2 shows the basic information processing of the two hypotheses, the various boxes in this processing scheme may contain mathematical descriptions of the underlying processing from simple gain elements, delays or linear differential equations, as in [91], to more complex systems of nonlinear differential equations which are used to model neural networks. It is worth to note that all dynamic computational models, whether on a systems level or describing in detail the dynamics of ion channels of single neurons, rely on the same basic building blocks, coupled differential equations. All pathways for pursuit pass through the cerebellum; therefore, most models have concentrated on the role of the cerebellar pathways, especially those passing through the floccular lobe. The role of the cortical structures (pursuit region of the FEFs and MST), their downstream pathways (dorsolateral pontine nuclei and nucleus reticularis tegmenti pontis), and their specific contribution has received less attention so far. Neurophysiology suggests that the FEF pathway is more related to signals on eye acceleration, i.e. changes in pursuit velocity, while MST is thought to convey signals related to ongoing pursuit [95]. FEF has also been implicated in pursuit gain control [96]: rapid variations in target velocity have a greater effect if pursuit velocity is high. Similarly, pursuit onset is slower than pursuit offset. While earlier models assumed a switch in pursuit pathways [97], one pathway for pursuit onset, and one for offset, a continuous gain control is now discussed [98, 99]. Gain control may also be related to another relevant feature of smooth pursuit, its predictive nature. Despite the visual latency, pursuit tracking of simple motions, such as ramp-like or sinusoidal target movement, can reach unity gain with zero latency. Thus, some form of predictive control must take place. Current models propose memory-based mechanisms [100] or adaptive control implementing a predictive model of target dynamics [101] to explain the experimental findings. It is also not clear whether the predictive aspects of pursuit control are implemented in cortical areas [101], or in the cerebellum [102], or in both. Since pursuit movements are almost always accompanied by saccadic eye movements, a recent model proposes how switching between both modes can be achieved together with predictive aspects of saccades and pursuit [103].
Ocular Motor Models
169
Combined Eye-Head Movements
Combined eye-head movements occur when the head is passively perturbed and the eyes compensate by the VOR. However, under natural circumstances saccadic gaze shifts and smooth pursuit consist of a combination of eye and head movements, especially when the target eccentricity is too large to be reached with the eye alone. Active combined eye-head movements raise several questions [104], for example whether the VOR is active during the gaze shift, or whether the local feedback loops in the saccadic system operate on gaze (eye plus head) or eye-in-head signals. While it is usually accepted that the VOR is shut off during the gaze shift, models on combined eye-head gaze shifts reached different conclusions concerning the feedback loops: while most models assume that gaze is the controlled variable [105–107], others propose that eye and head movements are controlled separately with the head controller influencing the saccadic burst generator for the eye [108]. The 3-D behavior of eye and head during gaze shifts has successfully been explained by an elegant model [109] which shows how the eye may anticipate the final head position. Finally, a recent neural network model showed how superior colliculus and cerebellum may interact for combined eye-head gaze shifts [50]. Conclusions
Basically for all aspects of eye movement control, computational models do exist. The vast majority of these models are based on a systems level approach or use neural networks with firing rate neurons. While most models concentrate on specific aspects of eye movements, there are some attempts to provide models putting together several of the ocular motor subsystems. To be useful, future models need to pursue such a holistic approach to eye movements, and at the same time try to link the systems level approach to the underlying neural mechanisms.
References 1 2 3 4 5
Quaia C, Optican LM: Dynamic eye plant models and the control of eye movements. Strabismus 2003;11:17–31. Robinson DA: A quantitative analysis of extraocular muscle cooperation and squint. Invest Ophthalmol Vis Sci 1975;14:801–825. Miller JM, Robinson DA: A model of the mechanics of binocular alignment. Comput Biomed Res 1984;17:436–470. Miller JM, Pavlovski DS, Shamaeva I: OrbitTM 1.8 Gaze Mechanics Simulation. Eidactics, Suite 404, 1450 Greenwich St., San Francisco, CA 94109, USA, 1999. Haslwanter T, Buchberger M, Kaltofen T, Hoerantner R, Priglinger S: SEE: a biomechanical model of the oculomotor plant. Ann N Y Acad Sci 2005;1039:9–14.
Glasauer
170
6 7 8 9 10 11 12 13 14
15
16 17 18 19 20
21 22
23
24 25 26 27 28 29 30 31
Haustein W: Considerations on listing’s law and the primary position by means of amatrix description of eye position control. Biol Cybern 1989;60:411–420. Porrill J, Warren PA, Dean P: A simple control law generates Listing’s positions in a detailed model of the extraocular muscle system. Vision Res 2000;40:3743–3758. Koene AR, Erkelens CJ: Properties of 3D rotations and their relation to eye movement control. Biol Cybern 2004;90:410–417. Warren PA, Porrill J, Dean P: Consistency of Listing’s law and reciprocal innervation with pseudoinverse control of eye position in 3-D. Biol Cybern 2004;91:1–9. Wong AM: Listing’s law: clinical significance and implications for neural control. Surv Ophthalmol 2004;49:563–575. Ghasia FF, Angelaki DE: Do motoneurons encode the noncommutativity of ocular rotations? Neuron 2005;47:281–293. Schnabolk C, Raphan T: Modeling three-dimensional velocity-to position transformation in oculomotor control. J Neurophysiol 1994;71:623–638. Tweed D, Misslisch H, Fetter M: Testing models of the oculomotor velocity-to-position transformation. J Neurophysiol 1994;72:1425–1429. Raphan T: Modeling control of eye orientation in three dimensions; in Fetter M, Haslwanter T, Misslisch H, Tweed D (eds): Three-Dimensional Kinematics of Eye, Head, and Limb Movements. The Netherlands, Harwood Academic Publishing, 1997, pp 359–374. Tweed D: Velocity-to-position transformation in the VOR and the saccadic system; in Fetter M, Haslwanter T, Misslisch H, Tweed D (eds): Three-Dimensional Kinematics of Eye, Head, and Limb Movements. The Netherlands, Harwood Academic Publishing, 1997, pp 375–386. Quaia C, Optican LM: Commutative saccadic generator is sufficient to control a 3-D ocular plant with pulleys. J Neurophysiol 1998;79:3197–3215. Sklavos S, Porrill J, Kaneko CR, Dean P: Evidence for wide range of time scales in oculomotor plant dynamics: implications for models of eye-movement control. Vision Res 2005;45:1525–1542. Robinson DA: Integrating with neurons. Annu Rev Neurosci 1989;12:33–45. Zee D, Yamazaki A, Butler PH, Gücer G: Effects of ablation of flocculus and paraflocculus on eye movements in primate. J Neurophysiol 1981;46:878–899. Glasauer S, Dieterich M, Brandt T: Central positional nystagmus simulated by a mathematical ocular motor model of otolith-dependent modification of Listing’s plane. J Neurophysiol 2001;86: 1546–1554. Crawford JD, Tweed DB, Vilis T: Static ocular counterroll is implemented through the 3-D neural integrator. J Neurophysiol 2003;90:2777–2784. Anastasio TJ: Nonuniformity in the linear network model of the oculomotor integrator produces approximately fractional-order dynamics and more realistic neuron behavior. Biol Cybern 1998; 79:377–391. Sklavos SG, Moschovakis AK: Neural network simulations of the primate oculomotor system IV. A distributed bilateral stochastic model of the neural integrator of the vertical saccadic system. Biol Cybern 2002;86:97–109. Galiana HL, Outerbridge JS: A bilateral model for central neural pathways in vestibuloocular reflex. J Neurophysiol 1984;51:210–241. Green AM, Galiana HL: Hypothesis for shared central processing of canal and otolith signals. J Neurophysiol 1998;80:2222–2228. Seung HS: How the brain keeps the eyes still. Proc Natl Acad Sci USA 1996;93:13339–13344. Seung HS, Lee DD, Reis BY, Tank DW: Stability of the memory of eye position in a recurrent network of conductance-based model neurons. Neuron 2000;26:259–271. Koulakov AA, Raghavachari S, Kepecs A, Lisman JE: Model for a robust neural integrator. Nat Neurosci 2002;5:775–782. Loewenstein Y, Sompolinsky H: Temporal integration by calcium dynamics in a model neuron. Nat Neurosci 2003;6:961–967. Dean P, Porrill J, Stone JV: Decorrelation control by the cerebellum achieves oculomotor plant compensation in simulated vestibulo-ocular reflex. Proc Biol Sci 2002;269:1895–1904. Ebadzadeh M, Darlot C: Cerebellar learning of bio-mechanical functions of extra-ocular muscles: modeling by artificial neural networks. Neuroscience 2003;122:941–966.
Ocular Motor Models
171
32 33 34
35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59
Glasauer S: Cerebellar contribution to saccades and gaze holding: a modeling approach. Ann NY Acad Sci 2003;1004:206–219. Porrill J, Dean P, Stone JV: Recurrent cerebellar architecture solves the motor-error problem. Proc Biol Sci 2004;271:789–796. Jürgens R, Becker W, Kornhuber HH: Natural and drug-induced variations of velocity and duration of human saccadic eye movements: evidence for a control of the neural pulse generator by local feedback. Biol Cybern 1981;39:87–96. Crawford JD, Guitton D: Visual-motor transformations required for accurate and kinematically correct saccades. J Neurophysiol 1997;78:1447–1467. Scudder CA: A new local feedback model of the saccadic burst generator. J Neurophysiol 1988;59:1455–1475. Moschovakis AK: Neural network simulations of the primate oculomotor system. II. Frames of reference. Brain Res Bull 1996;40:337–345. Gancarz G, Grossberg S: A neural model of the saccade generator in the reticular formation. Neural Netw 1998;11:1159–1174. Jackson ME, Litvak O, Gnadt JW: Analysis of the frequency response of the saccadic circuit: numerical simulations. Neural Netw 2001;14:1357–1376. Moschovakis AK, Highstein SM: The anatomy and physiology of primate neurons that control rapid eye movements. Annu Rev Neurosci 1994;17:465–488. Bozis A, Moschovakis AK: Neural network simulations of the primate oculomotor system. III. An one-dimensional, one-directional model of the superior colliculus. Biol Cybern 1998;79:215–230. Arai K, Das S, Keller EL, Aiyoshi E: A distributed model of the saccade system: simulations of temporally perturbed saccades using position and velocity feedback. Neural Netw 1999;12:1359–1375. Smith MA, Crawford JD: Distributed population mechanism for the 3-D oculomotor reference frame transformation. J Neurophysiol 2005;93:1742–1761. Grossberg S, Roberts K, Aguilar M, Bullock D: A neural model of multimodal adaptive saccadic eye movement control by superior colliculus. J Neurosci 1997;17:9706–9725. Brown JW, Bullock D, Grossberg S: How laminar frontal cortex and basal ganglia circuits interact to control planned and reactive saccades. Neural Netw 2004;17:471–510. Dean P: Modelling the role of the cerebellar fastigial nuclei in producing accurate saccades: the importance of burst timing. Neuroscience 1995;68:1059–1077. Enderle JD, Engelken EJ: Effects of cerebellar lesions on saccade simulations. Biomed Sci Instrum 1996;32:13–21. Lefevre P, Quaia C, Optican LM: Distributed model of control of saccades by superior colliculus and cerebellum. Neural Netw 1998;11:1175–1190. Quaia C, Lefèvre P, Optican LM: Model of the control of saccades by superior colliculus and cerebellum. J Neurophysiol 1999;82:999–1018. Wang X, Jin J, Jabri M: Neural network models for the gaze shift system in the superior colliculus and cerebellum. Neural Netw 2002;15:811–832. Schweighofer N, Arbib MA, Dominey PF: A model of the cerebellum in adaptive control of saccadic gain. I. The model and its biological substrate. Biol Cybern 1996;75:19–28. Schweighofer N, Arbib MA, Dominey PF: A model of the cerebellum in adaptive control of saccadic gain. II. Simulation results. Biol Cybern 1996;75:29–36. Ebadzadeh M, Darlot C: Cerebellar learning of bio-mechanical functions of extra-ocular muscles: modeling by artificial neural networks. Neuroscience 2003;122:941–966. Catz N, Dicke PW, Thier P: Cerebellar complex spike firing is suitable to induce as well as to stabilize motor learning. Curr Biol 2005;15:2179–2189. Marr D: A theory of cerebellar cortex. J Physiol 1969;202:437–470. Albus JS: A theory of cerebellar function. Math Biosci 1971;10:5–61. Niemeier M, Crawford JD, Tweed DB: Optimal transsaccadic integration explains distorted spatial perception. Nature 2003;422:76–80. Girard B, Berthoz A: From brainstem to cortex: computational models of saccade generation circuitry. Prog Neurobiol 2005;77:215–251. Glasauer S, Dieterich M, Brandt T: Three-dimensional modeling of static vestibulo-ocular brainstem syndromes. Neuroreport 1998;9:3841–3845.
Glasauer
172
60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87
Glasauer S, Dieterich M, Brandt T: Simulation of pathological ocular counterroll and skew-torsion by a 3-D mathematical model. Neuroreport 1999;10:1843–1848. Galiana HL, Smith HL, Katsarkas A: Modelling non-linearities in the vestibulo-ocular reflex (VOR) after unilateral or bilateral loss of peripheral vestibular function. Exp Brain Res 2001;137:369–386. Cartwright AD, Gilchrist DP, Burgess AM, Curthoys IS: A realistic neural-network simulation of both slow and quick phase components of the guinea pig VOR. Exp Brain Res 2003;149:299–311. Merfeld DM, Young LR: The vestibulo-ocular reflex of the squirrel monkey during eccentric rotation and roll tilt. Exp Brain Res 1995;106:111–122. Zupan LH, Merfeld DM, Darlot C: Using sensory weighting to model the influence of canal, otolith and visual cues on spatial orientation and eye movements. Biol Cybern 2002;86:209–230. Glasauer S: Interaction of semicircular canals and otoliths in the processing structure of the subjective zenith. Ann NY Acad Sci 1992;656:847–849. Mergner T, Glasauer S: A simple model of vestibular canal-otolith signal fusion. Ann NY Acad Sci 1999;871:430–434. Reymond G, Droulez J, Kemeny A: Visuovestibular perception of self-motion modeled as a dynamic optimization process. Biol Cybern 2002;87:301–314. Green AM, Galiana HL: Hypothesis for shared central processing of canal and otolith signals. J Neurophysiol 1998;80:2222–2228. Green AM, Angelaki DE: Resolution of sensory ambiguities for gaze stabilization requires a second neural integrator. J Neurosci 2003;23:9265–9275. Green AM, Angelaki DE: An integrative neural network for detecting inertial motion and head orientation. J Neurophysiol 2004;92:905–925. Robinson DA: Vestibular and optokinetic symbiosis: an example of explaining by modeling; in Baker R, Berthoz A (eds): Control of Gaze by Brain Stem Neurons. Elsevier, Amsterdam, 1977, pp 49–58. Furman JM, Hain TC, Paige GD: Central adaptation models of the vestibulo-ocular and optokinetic systems. Biol Cybern 1989;61:255–264. Raphan T, Sturm D: Modeling the spatiotemporal organization of velocity storage in the vestibuloocular reflex by optokinetic studies. J Neurophysiol 1991;66:1410–1421. Schweigart G, Mergner T, Barnes G: Eye movements during combined pursuit, optokinetic and vestibular stimulation in macaque monkey. Exp Brain Res 1999;127:54–66. Hirata Y, Takeuchi I, Highstein SM: A dynamical model for the vertical vestibuloocular reflex and optokinetic response in primate. Neurocomputing 2003;52–54:531–540. Miles FA, Lisberger SG: Plasticity in the vestibulo-ocular reflex: a new hypothesis. Annu Rev Neurosci 1981;4:273–299. Blazquez PM, Hirata Y, Highstein SM: The vestibulo-ocular reflex as a model system for motor learning: what is the role of the cerebellum? Cerebellum 2004;3:188–192. Gomi H, Kawato M: Adaptive feedback control models of the vestibulocerebellum and spinocerebellum. Biol Cybern 1992;68:105–114. Lisberger SG: Neural basis for motor learning in the vestibuloocular reflex of primates. III. Computational and behavioral analysis of the sites of learning. J Neurophysiol 1994;72:974–998. Galiana HL, Green AM: Vestibular adaptation: how models can affect data interpretations. Otolaryngol Head Neck Surg 1998;119:231–243. Hepp K: Oculomotor control: Listing’s law and all that. Curr Opin Neurobiol 1994;4:862–868. Lee C, Zee DS, Straumann D: Saccades from torsional offset positions back to listing’s plane. J Neurophysiol 2000;83:3241–3253. Schneider E, Glasauer S, Dieterich M, Kalla R, Brandt T: Diagnosis of vestibular imbalance in the blink of an eye. Neurology 2004;63:1209–1216. Misslisch H, Tweed D, Fetter M, Sievering D, Koenig E: Rotational kinematics of the human vestibulo-ocular reflex III. Listing’s law. J Neurophysiol 1994;72:2490–2502. Palla A, Straumann D, Obzina H: Eye-position dependence of three-dimensional ocular rotationaxis orientation during head impulses in humans. Exp Brain Res 1999;129:127–133. Krauzlis RJ: The control of voluntary eye movements: new perspectives. Neuroscientist 2005;11: 124–137. Thier P, Ilg U: The neural basis of smooth-pursuit eye movements. Curr Opin Neurobiol 2005;15: 645–652.
Ocular Motor Models
173
88 Krauzlis RJ, Lisberger SG: A model of visually-guided smooth pursuit eye movements based on behavioral observations. J Comput Neurosci 1994;1:265–283. 89 Lisberger SG, Morris EJ, Tychsen L: Visual motion processing and sensory-motor integration for smooth pursuit eye movements. Annu Rev Neurosci 1987;10:97–129. 90 Tabata H, Yamamoto K, Kawato M: Computational study on monkey VOR adaptation and smooth pursuit based on the parallel control-pathway theory. J Neurophysiol 2002;87:2176–2189. 91 Robinson DA, Gordon JL, Gordon SE: A model of the smooth pursuit eye movement system. Biol Cybern 1986;55:43–57. 92 Yasui S, Young LR: Perceived visual motion as effective stimulus to pursuit eye movement system. Science 1975;190:906–908. 93 Marti S, Straumann D, Glasauer S: The origin of downbeat nystagmus: an asymmetry in the distribution of on-directions of vertical gaze-velocity Purkinje cells. Ann N Y Acad Sci 2005;1039: 548–553. 94 Tanaka M: Involvement of the central thalamus in the control of smooth pursuit eye movements. J Neurosci 2005;25:5866–5876. 95 Ono S, Das VE, Economides JR, Mustari MJ: Modeling of smooth pursuit-related neuronal responses in the DLPN and NRTP of the rhesus macaque. J Neurophysiol 2005;93:108–116. 96 Chou IH, Lisberger SG: The role of the frontal pursuit area in learning in smooth pursuit eye movements. J Neurosci 2004;24:4124–4133. 97 Huebner WP, Saidel GM, Leigh RJ: Nonlinear parameter estimation applied to a model of smooth pursuit eye movements. Biol Cybern 1990;62:265–273. 98 Keating EG, Pierre A: Architecture of a gain controller in the pursuit system. Behav Brain Res 1996;81:173–181. 99 Nuding U, Glasauer S, Büttner U: Nonlinear Systems Analysis of the Smooth-Pursuit Gain-Control Mechanism. Abstract for the Japan-Germany Symposium on Computational Neuroscience, Tokio, 2006 100 Barnes G, Grealy M: Modelling prediction in ocular pursuit; in Becker W, Deubel H, Mergner T (eds): Current Oculomotor Research. New York, Plenum Press, 1999, pp 97–107. 101 Shibata T, Tabata H, Schaal S, Kawato M: A model of smooth pursuit in primates based on learning the target dynamics. Neural Netw 2005;18:213–224. 102 Kettner RE, Suh M, Davis D, Leung HC: Modeling cerebellar flocculus and paraflocculus involvement in complex predictive smooth eye pursuit in monkeys. Ann N Y Acad Sci 2002;978: 455–467. 103 Lee WJ, Galiana HL: An internally switched model of ocular tracking with prediction. IEEE Trans Neural Syst Rehabil Eng 2005;13:186–193. 104 Crawford JD, Martinez-Trujillo JC, Klier EM: Neural control of three-dimensional eye and head movements. Curr Opin Neurobiol 2003;13:655–662. 105 Galiana HL, Guitton D: Central organization and modeling of eye-head coordination during orienting gaze shifts. Ann N Y Acad Sci 1992;656:452–471. 106 Goossens HH, Van Opstal AJ: Human eye-head coordination in two dimensions under different sensorimotor conditions. Exp Brain Res 1997;114:542–560. 107 Wagner R, Galiana HL: Hybrid gaze control: ffusing visual/vestibular senses, slow/fast processes, and eye/head coordination. Proc 31st Int Symp Robotics ISR 2000;220–225. 108 Freedman EG: Interactions between eye and head control signals can account for movement kinematics. Biol Cybern 2001;84:453–462. 109 Tweed D: Three-dimensional model of the human eye-head saccadic system. J Neurophysiol 1997;77:654–666.
Stefan Glasauer Department of Neurology Klinikum Grosshadern Marchioninistrasse 15 DE–81377 Munich (Germany) Tel. 49 89 7095 4835, Fax 49 89 7095 4801, E-Mail
[email protected]
Glasauer
174
Straube A, Büttner U (eds): Neuro-Ophthalmology. Dev Ophthalmol. Basel, Karger, 2007, vol 40, pp 175–192
Therapeutic Considerations for Eye Movement Disorders A. Straube Department of Neurology, University of Munich, Munich, Germany
Abstract Advances made in understanding the pathophysiology of eye movement disorders have only recently with the publication of the first well-planned studies been translated into better treatment strategies. The following chapter summarizes the pharmacological treatment options for a variety of oculomotor syndromes. Cortisone is useful, for example, for acute vestibular neuritis to improve the restitution of the labyrinthine function. For the widespread benign paroxysmal positioning nystagmus, a series of liberatory movements that free the semicircular canal from the causative otoconia is now a well-established therapy. Treatment for the central vestibular syndrome of up- and downbeat nystagmus consists of drugs like the potassium canal blocker 4-aminopyridine, which influence the cerebellar circuits involved in the disorder’s pathophysiology. Acquired pendular nystagmus, one of the oculomotor syndromes often caused by multiple sclerosis, results in the severe impairment of reduced visual acuity. Memantine, a weak NMDA antagonist, has now been proven effective here. Finally, anticonvulsants like carbamazepine are the drugs of choice for disorders involving a nerve-blood vessel contact that induces symptoms of vestibular paroxysmia or superior oblique myokymia. Copyright © 2007 S. Karger AG, Basel
The common goal of voluntary as well as most reflexive eye movements is to stabilize images on the retina (especially the central fovea, the area of the highest resolution) in order to prevent retinal slip. Abnormal involuntary eye movements may cause excessive motion of images on the retina, leading to blurred vision and to the illusion that the perceived world is moving (oscillopsia). Clinical examination of such pathological eye movements often allows the topological diagnosis of the lesion causing the abnormalities. Despite our extensive knowledge of the anatomy and physiology of eye movements, very little is known about pharmacological aspects of the ocular motor system. Thus, our treatment options for abnormal eye movements remain fairly limited. Most drug treatments are based on case reports. Only recently have a few controlled trials
Table 1. Practical treatment of oculomotor signs/syndromes Ocular sign/disorder
Substance
Dosage
Contraindications
Vestibular neuritis
Acute: dimenhydrinate Prednisolone
50–100 mg 1 mg/kg body weight per day for 5 days, or starting with 100 mg
General contraindications for cortisone and dimenhydrinate
Menière’s disease
Acute: dimenhydrinate Prophylaxis: betahistine Gentamicin
50–100 mg 8/16–32 mg/day Locally in the middle ear
General contraindications for dimenhydrinate and betahistine Ototoxic (hearing loss)
Vestibular paroxysmia
Carbamazepine
2 ⫻ 200–600 mg slowrelease formulation 3–4 ⫻ 300–600 mg
Drowsiness, ataxia Vertigo, dry mouth Enzyme induction
Superior oblique myokymia
Carbamazepine Gabapentin
2 ⫻ 200–600 mg slowrelease formulation 3–4 ⫻ 300–600 mg
Drowsiness, ataxia Vertigo, dry mouth Enzyme induction
Downbeat nystagmus
Clonazepam Baclofen 4-aminopyridine
2 ⫻ 0.5–1 mg daily 3 ⫻ 5–10 mg daily 3 ⫻ 10 mg
Sedation Ataxia, weakness Seizures
Upbeat nystagmus
Baclofen 4-aminopyridine
3 ⫻ 5–10 mg
Sedation; weakness Seizures
Periodic alternating nystagmus
Baclofen
3 ⫻ 5–10 mg
Sedation Ataxia, weakness
Acquired pendular nystagmus
Memantine Gabapentin
3–4 ⫻ 10 mg 3–4 ⫻ 300–600 mg
Somnolence, confusion, dry mouth, edema
Gabapentin
been published (overview in [1–5]). Several drugs can themselves cause nystagmus, for example, anticonvulsants, sedatives, and antihistaminergic drugs induce gaze-evoked nystagmus; nicotinergic substances induce a nystagmus that can disclose an underlying vestibular tone imbalance; and intoxication due to lithium or phenytoin can lead to downbeat nystagmus as well as opsoclonus. This chapter summarizes the most recent publications on pharmacological treatment options for the different eye movement syndromes and also gives a short overview of the clinical aspects and pathophysiology of these syndromes. Eye movement syndromes are generally differentiated into those characterized by a pathological jerk nystagmus, pendular nystagmus, atypical nystagmus, or saccadic oscillations. All interfere with the normal foveal fixation of a target.
Straube
176
Peripheral and Central Vestibular Disorders
Pathophysiology The vestibulo-ocular reflex (VOR) is one of the most basic reflexes. It can even be observed in fish. After a short latency, the VOR generates eye rotations in the same plane as the head rotation that elicits them [6]. To do this, the oculomotor system uses information provided by the three pairs of orthogonally oriented semicircular canals. The right and left sides work together in a tradeoff manner (i.e. when one labyrinth increases the neuronal activity, the other decreases it) [6]. Disorders of the vestibular periphery cause nystagmus in a direction that is determined by the pattern of labyrinthine semicircular canals involved [6]. The complete, unilateral loss of one labyrinth causes a mixed horizontal-torsional nystagmus that is suppressed by visual fixation. Another consequence of peripheral vestibular lesions is a change in the size (gain) of the overall dynamic VOR response, i.e. the gain of the VOR for head movements toward the affected ear becomes smaller, and the subject has to refixate the object after the head movement by a saccade. The head-impulse test uses this feature clinically. As a result, patients may complain of oscillopsia during rapid head movements. Central vestibular disorders are caused by lesions of pathways or areas involved in the adjustment of the VOR (e.g. the cerebellar connections to the vestibular nuclei) [2, 6]. These lesions result in upbeat, downbeat, torsional nystagmus or central positional vertigo. Vestibular Neuritis Clinical Aspects The presenting sign of vestibular neuritis is an acute onset of severe rotatory vertigo that lasts for hours to days [7]. Hearing loss is normally not a sign of vestibular neuritis [7]. The horizontal contraversive beating spontaneous nystagmus has a torsional component and causes postural instability with a tendency to fall to the ipsiversive side. Etiology Recent findings support the view that an inflammation of parts of the vestibular nerve is the cause of vestibular neuritis and acute labyrinthitis. Most studies have shown the presence of latent herpes simplex virus type 1 in human vestibular ganglia [8, 9]. The imaging of 2 patients with vestibular neuritis using 3-tesla MRI and high-dose contrast medium revealed isolated enhancement of
Treatment of Oculomotor Disorders
177
the vestibular nerve only on the affected side [10], a sign of a disturbed bloodbrain barrier due to the inflammation. Treatment Treatment options consist primarily of vestibular sedatives (e.g. dimenhydrinate, 50–100 mg) [11] in the first 3 days administered in combination with steroids. Kitahara et al. [12] examined 36 patients who were treated for up to 2 years after onset either with or without steroids. Although the treatment onset was rather late, the group on steroids showed a tendency for more improvement. A more detailed study published in 2004 [13] reported on a total of 141 patients who were randomized within 3 days after onset of symptoms to one of four treatment options – placebo, methylprednisolone (starting with 100 mg daily), valacyclovir , or a combination of valacyclovir and methylprednisolone. The main finding of this study was that the groups receiving methylprednisolone had a better final outcome (caloric testing showed about 60% recovery of peripheral vestibular function) after 12 months than the placebo/ valacyclovir groups (36–39%). The combination of valacyclovir and methylprednisolone provided no additional benefit. It has also been reported that patients should be mobilized early to accelerate the recovery of vestibulospinal function [14].
Menière’s Disease Clinical Aspects Menière’s disease is characterized by spontaneous attacks of vertigo, fluctuating sensorineural hearing loss, aural fullness, and tinnitus that lasts for hours to a few days [11, 15]. Key symptoms of such an attack are a horizontal rotatory nystagmus, postural instability, and nausea/vomiting. The symptoms only rarely include the opposite ear. Only 5 of 101 patients in a 2-year followup developed symptoms in the contralateral ear [16]. In addition to a typical history, the finding of a unilateral hearing deficit on the audiogram and a reduced reaction to caloric vestibular testing also support the diagnosis [15]. Etiology The cause of Menière’s disease is still not known. It has been shown histopathologically that endolymphatic hydrops and concomitant distortion of the membranous labyrinth can cause Menière’s disease [15]. Other candidates include immunological causes and inflammation. An increased prevalence of migraine has also been described in patients with Menière’s disease [17]. The pathophysiological link between both diseases may be allergic mechanisms [17].
Straube
178
Treatment In the daily practice it is useful to administer vestibular sedatives such as dimenhydrinate during acute self-limiting attacks [11, 15, 18]. One popular prophylactic treatment regimen tries to reduce the endolymph by low-salt diet or diuretics; another option is to administer betahistine (8–16 mg/day). Higher dosages (up to 3 ⫻ 48 mg) seem to be more effective than lower ones [15], although the efficacy of betahistine has not been proven [18]. No randomized studies on these treatment options have yet been conducted. A retrospective survey of the outcome of 22 patients revealed that intratympanic steroid perfusion was only of short-term benefit [19]. A systematic review of published uncontrolled studies found that gentamicin reduced vestibular function in the treated ear and achieved overall vertigo control (complete or substantial control) in 89% of the patients (range 73–100%); hearing worsened in 26% (0–90%) [20]. A meta-analysis examined the application of gentamicin, which poses the lowest risk of hearing loss [21]. The titration technique with daily or weekly doses until onset of vestibular symptoms, change in vertigo, or hearing loss showed the best rate of vertigo control. Complete ablation of the vestibular function is not typically required for such control [21], as this is also not achieved for a long time with gentamicin instillation [22].
Superior Canal Dehiscence Syndrome Clinical Aspects Patients with a so-called superior canal dehiscence syndrome [23, 24] complain of vertigo and oscillopsia, which are induced by intense sound stimuli, a Valsalva maneuver, or in some cases even the heart beat, when nystagmus beats synchronously with the pulse in the plane of the involved vestibular canal [25]. The accompanying jerk nystagmus has vertical and torsional components [23, 24]. Etiology The superior canal dehiscence syndrome is a special form of inner-ear perilymph fistula [23]. High-resolution computed tomography has shown that the cause is a missing bone coverage between the superior canal and the middle cranial fossa. This results in increased pressure on the superior canal when the intracranial pressure increases. In some patients, the dehiscence may be bilateral [23]. Treatment Surgical plugging of the canal or resurfacing of the dehiscence can prevent the pressure-induced oscillopsia [23]. Aftereffects are not long lasting.
Treatment of Oculomotor Disorders
179
Vestibular Paroxysmia Clinical Aspects If patients complain of short, repeated, paroxysmal attacks of vertigo lasting for seconds to minutes, which can sometimes be provoked by particular head positions, a vestibular paroxysmia is suspected. Spontaneous nystagmus is observed during the attack [26]. Other possible symptoms include unilateral tinnitus, hyperacusis, or facial contractions. Clinical examination in the attackfree intervals may in some patients reveal slight signs of permanent vestibular deficit, hypoacusis, or facial paresis on the affected side [26, 27]. Etiology High-resolution MR imaging may show the compression of the 8th nerve by an artery (most often AICA) or more rarely by a vein in the region of the root entry zone of the vestibular nerve. However, such a result does not prove the diagnosis of paroxysmia, since such contacts can also be found in healthy subjects. The proposed mechanism is similar to that of nerve-blood vessel contact in trigeminal neuralgia. Treatment As in other neurovascular compression syndromes, an anticonvulsant (carbamazepine, slow-release formulation, 2 ⫻ 200 to 2 ⫻ 800 mg p.o. daily; phenytoin 1 ⫻ 250 to 1 ⫻ 400 mg p.o. daily; lamotrigine 100–400 mg p.o. daily) should be given initially [26, 27]. All drugs should be first administered in the lowest recommended dose and only gradually increased in order to prevent side effects. In general, a positive response to antiepileptic drugs can be achieved with low dosages and after a few days. If the symptoms do not resolve, a surgical approach may be considered [28]. There are no satisfactory follow-up studies on any of these treatment options, and the diagnostic criteria have not yet been fully established.
Downbeat Nystagmus Clinical Aspects Downbeat nystagmus is a central nystagmus that occurs during fixation and increases on downward gaze, especially on lateral gaze [6, 29, 30]. The head position relative to the earth’s vertical may play a role in some patients [31]. Convergence may suppress or enhance the nystagmus or even change its nystagmus toward an upbeat nystagmus in certain patients. Most patients also have vestibulocerebellar ataxia. Lesions that cause downbeat nystagmus occur in the vestibular cerebellum bilaterally and rarely in the underlying medulla [6].
Straube
180
Etiology The main pathophysiological mechanism of downbeat nystagmus is a central imbalance of the vertical VOR [28] in combination with an abnormality of the vertical-torsional gaze-holding mechanism – the ‘neural integrator for eye movements’ [32]. The neural integrator is a network consisting of the medial vestibular complex and its connection to the cerebellum. The most common cause of downbeat nystagmus is cerebellar degeneration (hereditary, sporadic, or paraneoplastic). Recently, a report was published on a patient with glutamic-acid decarboxylase antibodies and a downbeat nystagmus in addition to signs of a stiff person syndrome [33]. Other important causes are Arnold-Chiari malformation and drug intoxication (especially anticonvulsants and lithium). In everyday practice, cerebellar atrophy, Arnold-Chiari malformation, various cerebellar lesions (multiple sclerosis, vascular, tumors), and idiopathic causes account for approximately one fourth each of cases of downbeat nystagmus [30, 34]. Treatment Since a loss of inhibitory cerebellar influence on the vestibular nuclei is one of the main pathophysiological mechanisms of downbeat nystagmus, it seems expedient to investigate substances that may help re-establish such cerebellar influence on the brainstem. The vestibulocerebellar efferences to the vestibular nuclei are gabaergic; thus, most drugs investigated were GABA-A agonists. The GABA-A agonist clonazepam (2 ⫻ 1 mg daily) was recently reported to have a positive effect on so-called idiopathic downbeat nystagmus (e.g. no pathological findings on MRI) [35]. This supports older observations that clonazepam (0.5 mg p.o. three times daily) and the GABA-B agonist baclofen (10 mg p.o. three times daily) [36, 37] reduce the velocity in downbeat nystagmus. Gabapentin (an alpha2-delta calcium channel antagonist) [38] might also have weak positive effects and reduces in some patients downbeat nystagmus. A placebo-controlled, doubleblind study with a crossover design investigated the effect of the potassium channel blocker 3,4-diaminopyridine in 17 patients with downbeat nystagmus [39]. Potassium channel blockers can increase the spontaneous firing rate of the cerebellar Purkinje cells and therefore the inhibitory effect on the vestibular nuclei. On average, the potassium channel blocker reduced the slow-phase velocity of the nystagmus by more than 50% [39]. The same group reported a similar effect of 4aminopyridine (10 mg orally) in a single patient [40]. This substance penetrates the blood-brain barrier better than 3,4-diaminopyridine and may therefore be more effective. The potassium channel blockers also seem to have a specific influence on the gravity-dependent component of the vertical velocity bias of downbeat nystagmus [41]. This might explain why patients who do not show such a vertical velocity bias and have more offset in the null position (e.g. the position at which the nystagmus velocity is minimal) do not seem to benefit in the same
Treatment of Oculomotor Disorders
181
way from the treatment. The patients in whom the influence of the gravity-dependent component is more pronounced also seem to benefit more from a supine head position [41]. In isolated patients with a craniocervical anomaly, a surgical decompression involving the removal of part of the occipital bone in the region of the foramen magnum was beneficial [42, 43]. As a practical rule, treatment should be started by trying clonazepam. If this option does not improve the nystagmus satisfactorily, 4-aminopyridine (10 mg three times daily) should be tried.
Upbeat Nystagmus Clinical Aspects Upbeat nystagmus occurs when the eyes are close to the central position and usually increases during upgaze [44]. The nystagmus usually disrupts vertical smooth pursuit. In some patients, the upbeat nystagmus changes to downbeat nystagmus during convergence. An upbeat nystagmus has in general a better prognosis than a downbeat nystagmus and is often only a temporary problem [11]. Etiology A central vestibular imbalance is involved in upbeat nystagmus as in downbeat nystagmus. The most frequently seen lesions are medullary lesions [44]. Probable causes of upbeat nystagmus are lesions in the ascending pathways from the anterior canals (and/or the otoliths) at the pontomesencephalic or pontomedullary junction, near the perihypoglossal nuclei [44, 45]. The main causes are multiple sclerosis, tumors of the brainstem, Wernicke’s encephalopathy, intoxication (e.g. nicotine), and seldom cerebellar degeneration. Treatment Treatment with baclofen (5–10 mg p.o. three times daily) caused an improvement in several patients [37]. Probably 4-aminopyridine will also improve the upbeat nystagmus in some patients [46].
Seesaw Nystagmus Clinical Aspects Seesaw nystagmus is a rare pendular or jerk oscillation around the line of gaze. A half-cycle consists of elevation and intorsion of one eye with synchronous
Straube
182
depression and extorsion of the other eye [6, 47]. During the next half-cycle, there is a reversal of the vertical and torsional movements. The frequency is lower in the pendular (2–4 Hz) than in the jerk variety. Etiology Jerk hemi-seesaw nystagmus has been attributed to unilateral mesodiencephalic lesions [48], which affect the interstitial nucleus of Cajal and its vestibular afferents from the vertical semicircular canals [49]. The pendular form is associated with lesions that affect the optic chiasm; it can be congenital. Loss of crossed visual input seems to be the crucial element in the pathophysiology of pendular seesaw nystagmus [50]. Therapeutic Recommendations Alcohol was reported to have a beneficial effect (1.2 g/kg body weight) in 2 patients [51, 52], as does clonazepam [1]. More recently, Averbuch-Heller reported on 3 patients with a seesaw component to their pendular nystagmus, who improved with gabapentin [53].
Periodic Alternating Nystagmus Clinical Aspects Periodic alternating nystagmus is a spontaneous horizontal beating nystagmus which periodically changes direction after 100–240 s [6]. Consequently, the patients complain of increasing/decreasing oscillopsia. When the nystagmus amplitude gradually decreases, the nystagmus reverses its direction, and then the amplitude increases again. Periodic alternating nystagmus also disrupts visual fixation. During the nystagmus, patients often complain of increasing/ decreasing oscillopsia [11]. Etiology Animal and human experiments show that the disinhibition of the GABAergic velocity-storage mechanism, which is mediated by the vestibular nuclei, is responsible for the nystagmus [54, 55]. Patients with periodic alternating nystagmus commonly have vestibulocerebellar lesions or, very rarely, intoxications [56, 57]. The underlying etiologies are craniocervical anomalies, multiple sclerosis, cerebellar degenerations or tumors, anticonvulsant therapy, and bilateral visual loss. Recently, autoantibodies directed against glutamic acid decarboxylase were described in a patient with progressive cerebellar ataxia and periodic alternating nystagmus, suggesting an autoimmune mechanism [58].
Treatment of Oculomotor Disorders
183
Therapeutic Recommendations In general, periodic alternating nystagmus does not improve spontaneously. Several case reports describe a positive effect of baclofen, a GABA-B agonist, in a dose of 5–10 mg p.o. three times daily [1, 57, 59, 60].
Other Supranuclear Oculomotor Disorders
Acquired Pendular Nystagmus Clinical Aspects Acquired pendular nystagmus is a visually distressing form of nystagmus, in which oscillopsia and impaired vision are common. Acquired pendular nystagmus is a quasi-sinusoidal oscillation that may have a predominantly horizontal, vertical, or mixed trajectory (i.e. circular, elliptical, or diagonal); it can be either predominantly monocular or predominantly binocular [6, 61, 62]. The frequency of this type of nystagmus is 2–7 Hz [63]. It is often associated with head titubation (a kind of head tremor with small amplitude and not synchronized with the nystagmus), trunk and limb ataxia, or visual impairment. The amplitude is small and can often be only seen with an ophthalmoscope. Etiology Acquired pendular nystagmus occurs with several myelin disorders (e.g. multiple sclerosis, toluene abuse, Pelizaeus-Merzbacher disease). It is also a component of the syndrome of oculopalatal tremor (myoclonus) and is observed in Whipple’s disease [6, 62]. Common etiologies in adults are multiple sclerosis and brainstem stroke [62, 64]. On the basis of observations that the nystagmus is often dissociated and that eye movements other than optokinetic nystagmus and voluntary saccades are also disturbed, it has been suggested that a lesion in the brainstem near the oculomotor nuclei is the cause [61]. Alternative candidates such as an inhibition of the inferior olive due to lesions of the ‘Mollaret triangle’ or an instability of the gazeholding network (neural integrator) have also been proposed [64]. Treatment The first reported treatment option was anticholinergic treatment with trihexyphenidyl (20–40 mg p.o. daily) [65, 66]; however, Leigh et al. [67] reported in a double-blind study that only 1 of 6 patients improved during this oral treatment. Starck et al. [68] reported that nystagmus improved with memantine, a glutamate antagonist, in all 9 tested patients (15–60 mg p.o. daily). Gabapentin, an alpha-2-delta calcium channel antagonist, substantially improved the nystagmus (and visual acuity) in 10 of 15 patients (3 ⫻ 300–400 mg daily) [53]. Gabapentin
Straube
184
was superior to vigabatrin in a small series of patients [69]; others have also reported an improvement due to gabapentin [70, 71]. Cannabis, which acts as a retrograde presynaptic inhibitory transmitter and in this way is similar to gabapentin, which also acts presynaptically, was recently reported to be equally effective [72, 73]. A bilateral retrobulbar botulinum toxin injection was successfully used in some patients to induce a complete external ophthalmoplegia, thereby diminishing the acquired pendular nystagmus [74, 75]; however, it proved unsatisfactory in other patients [76]. Opsoclonus and Ocular Flutter Clinical Aspects Opsoclonus consists of repetitive bursts of conjugate saccadic oscillations, which have horizontal, vertical, and torsional components. During each burst of these high-frequency oscillations, the movement is continuous, without any intersaccadic interval. These oscillations are often triggered by eye closure, convergence, pursuit, and saccades; amplitudes range up to 2–15⬚ [6]. The same pattern is restricted in ocular flutter to the horizontal plane. The ocular symptoms are often accompanied by cerebellar signs, such as gait and limb myoclonus (the ‘dancing feet, dancing eyes syndrome’). Most of the patients complain of very disturbing oscillopsias during these saccadic oscillations [6, 77]. Etiology A functional disturbance of active saccadic suppression by the pontine omnipause neurons is the most probable pathophysiological mechanism. Since histological abnormalities of these neurons have not been shown [78], a functional lesion of the glutaminergic cerebellar projections from the fastigial nuclei to the omnipause cells is the likely cause of their disinhibition. Opsoclonus can be observed in benign cerebellar encephalitis (postviral, e.g. Coxsackie B37; postvaccinal) or as a paraneoplastic symptom (infants, neuroblastoma; adults, carcinoma of the lung, breast, ovary, or uterus) [77]. Treatment In addition to therapy for any underlying process such as tumor or encephalitis, treatment with immunoglobulins or prednisolone may occasionally be effective [79]. Four of 5 patients with square-wave oscillations, probably a related fixation disturbance, showed an improvement on therapy with valproic acid [80]. In single cases, an improvement has been observed during treatment with propranolol (40–80 mg p.o. three times daily), nitrazepam (15–30 mg p.o. daily), and clonazepam (0.5–2.0 mg p.o. three times daily) [1, 77, 81].
Treatment of Oculomotor Disorders
185
Infranuclear Oculomotor Disorders
Superior Oblique Myokymia Clinical Aspects Superior oblique myokymia is characterized by paroxysmal monocular high-frequency oscillations [6, 82, 83]. These oscillations are mainly torsional in the primary gaze position and in abduction, but when the eyes are in adduction the oscillations have a vertical component [83]. The patients usually complain of oscillopsia during these paroxysmal attacks. Etiology The pathophysiology of this condition is not totally clear, but vascular compression of the 4th nerve [84, 85] may be responsible. The same mechanism is suspected in vestibular paroxysmia. Alternative causes may include spontaneous discharges in the 4th nerve nucleus or of the superior oblique muscle. Treatment Like trigeminal neuralgia (another putative neurovascular compression disorder), superior oblique myokymia frequently remits spontaneously for periods of a few months to years. If it does not, a number of drugs have been reported to be beneficial, including the anticonvulsants carbamazepine [82] and gabapentin [86, 87]. In chronic cases that did not improve with anticonvulsants, tenotomy of the superior oblique muscle has been performed, but usually it necessitates inferior oblique surgery as well. Surgical decompression of the 4th nerve has also been reported to help, but this treatment should be reserved for the most vexing cases, as it may result in superior oblique palsy [88, 89] and bears a risk of suboccipital craniotomy. Treatment should always be started with one of the anticonvulsants. Benign Paroxysmal Positional Vertigo Clinical Aspects One of the most frequent types of vertigo as well as oculomotor syndromes is benign paroxysmal positional vertigo (BPPV) [11, 90]. BPPV occurs when particles in one of the semicircular canals move freely when the head is turned in the plane of the affected canal. Theoretically, all three canals can be affected, but in practice the posterior vertical canal (p-BPPV) is affected most often [11, 90]. The positioning of the head towards the affected canal plane induces a rotatory nystagmus that beats to the undermost ear with a crescendo-decrescendo
Straube
186
time course. Horizontal BPPV (h-BPPV) is characterized by a nonfatiguable bilateral horizontal beating nystagmus that occurs while the patient lies supine and turns his/her head to the side of the affected canal [11, 91]. h-BPPV was reported to occur in about 12% of a series of 300 patients [91]. BPPV of the anterior vertical canal probably occurs much more seldom than that of the posterior or horizontal canal. The associated nystagmus characteristically has less of a torsional component than in p-BPPV [92]. Etiology BPPV is caused by the displacement of calcium-rich particles from the utricle into one of the canals [11, 90]. These particles change the function of the canal, which normally only detects angular acceleration. If the head is positioned in the plane of the affected canal, the particles move within the semicircular canal according to the gravitational force, causing an endolymph flow that is followed by a displacement of the cupula of the canal. Predisposing conditions are older age, head trauma, labyrinthitis, Menière’s disease, migraine, or longer periods of immobilization. A differential diagnosis of positional vertigo is migrainous vertigo; it may mimic BPPV. Several groups recently reported an association of migraine and vertigo. A study published this year classified 10 patients of 362 consecutive patients who had positional vertigo as well as migrainous. Diagnostic factors that distinguish the migrainous form from idiopathic positional vertigo are short duration of the attacks, frequent recurrences, early manifestation in life, other migrainous symptoms like photo-/phonophobia and headache during the vertigo episodes, and atypical nystagmus [93]. Central positional vertigo due to lesions of the vestibular cerebellum can mimic peripheral positional vertigo sometimes, but normally the nystagmus is less pronounced and does not show habituation [94]. Treatment Treatment consists of so-called liberatory maneuvers. The rationale is to redirect the particles out of the affected canal. There are two repositioning treatments for p-BPPV: Epley’s and Semont’s maneuvers. Both require active movements by the patients; this may be difficult for older patients. Another possibly effective therapeutic procedure is the so-called prolonged forced position. It requires the patient to maintain a position in which the affected ear remains uppermost for several hours. This is thought to allow the floating particles to slip out of the canal into labyrinthine recesses, where they no longer have any impact on the cupula [95]. The question as to which liberatory maneuver is superior for benign positional paroxysmal vertigo of the posterior canal was recently addressed in
Treatment of Oculomotor Disorders
187
several published studies and meta-analyses. Updating the Cochrane database, Hilton and Pinder [96] reanalyzed randomized trials of adult patients with p-BPPV to determine the extent of improvement of the vertigo after the Epley maneuver, no treatment, or other repositioning maneuvers. Using only 3 of 15 trials for the final analysis, the authors concluded that there is some evidence that the Epley maneuver is a safe and effective treatment option, but the available data were insufficient to compare the Epley maneuver with other repositioning maneuvers [96]. Another study on the best liberatory maneuver compared the self-applied Semont maneuver with the self-applied Epley procedure. Patients who performed the Epley maneuver had a significantly higher success rate than the group using the Semont maneuver (95 vs. 58%). Thus, the Epley procedure, as a home-based self-applied liberatory maneuver, seems to be the better choice [97]. For h-BPPV, the maneuver involves a 360⬚ horizontal head and body (‘barbecue’) rotation (e.g. rotation about the longitudinal body axis in a supine position) [91]. A small group of patients who were followed for 60 months had a recurrence rate of 26% for posterior canal and 50% for horizontal canal BPPV [98]. Patients with trauma or labyrinthitis had lower initial success rates of the repositioning maneuver, whereas patients with endolymphatic hydrops were predicted to have higher recurrence rates [99, 100]. References 1 2 3 4 5 6 7 8 9 10 11 12
Carlow TJ: Medical treatment of nystagmus and ocular motor disorders. Int Ophthalmol Clin 1986;26:251–264. Straube A, Leigh RJ, Bronstein A, Heide W, Riordan-Eva P, Tijssen CC, Dehaene I, Straumann D: EFNS task force – therapy of nystagmus and oscillopsia. Eur J Neurol 2004;11:83–89. Leigh RJ, Tomsak RL: Drug treatments for eye movement disorders. J Neurol Neurosurg Psychiatry 2003;74:1–4. Rucker JC: Current treatment of nystagmus. Curr Treat Options Neurol 2005;7:69–77. Büttner U, Fuhry L: Drug therapy of nystagmus and saccadic intrusions; in Büttner U (ed): Vestibular Dysfunction and Its Therapy. Adv Otorhinolaryngol. Basel, Karger, 1999, pp 195–227. Leigh RJ, Zee DS: The Neurology of Eye Movements, ed 3. New York, Oxford University Press, 1999. Straube A: Nystagmus: an update on treatment in adults. Expert Opin Pharmacother 2005;6: 583–590. Furuta Y, Takasu T, Fukuda S, Inuyama Y, Sato KC, Nagashima K: Latent herpes simplex virus type 1 in human vestibular ganglia. Acta Otolaryngol Suppl 1993;503:85–89. Arbusow V, Theil D, Strupp M, Mascolo A, Brandt T: HSV-1 not only in human vestibular ganglia but also in the vestibular labyrinth. Audiol Neurootol 2001;6:259–262. Karlberg M, Annertz M, Magnusson M: Acute vestibular neuritis visualized by 3-T magnetic resonance imaging with high-dose gadolinium. Arch Otolaryngol Head Neck Surg 2004;130:229–232. Brandt T: Vertigo. Its Multisensory Syndromes, ed 2. London, Springer Verlag, 1999. Kitahara T, Kondoh K, Morihana T, Okumura S, Horii A, Takeda N, Kubo T: Steroid effects on vestibular compensation in human. Neurol Res 2003;25:287–289.
Straube
188
13
14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33
34 35 36 37
38
Strupp M, Zingler VC, Arbusow V, Niklas D, Maag KP, Dieterich M, Bense S, Theil D, Jahn K, Brandt T: Methylprednisolone, valacyclovir, or the combination for vestibular neuritis. N Engl J Med 2004;351:354–361. Strupp M, Arbusow V, Maag KP, Gall C, Brandt T: Vestibular exercises improve central vestibulospinal compensation after vestibular neuritis. Neurology 1998;51:838–844. Minor LB, Schessel DA, Carey JP: Meniere’s disease. Curr Opin Neurol 2004;17:9–16. Perez R, Chen JM, Nedzelski JM: The status of the contralateral ear in established unilateral Meniere’s disease. Laryngoscope 2004;114:1373–1376. Sen P, Georgalas C, Papesch M: Co-morbidity of migraine and Meniere’s disease – is allergy the link? J Laryngol Otol 2005;119:455–460. James AL, Burton MJ: Betahistine for Meniere’s disease or syndrome. Cochrane Database Syst Rev 2001;CD001873. Dodson KM, Woodson E, Sismanis A: Intratympanic steroid perfusion for the treatment of Meniere’s disease: a retrospective study. Ear Nose Throat J 2004;83:394–398. Diamond C, O’Connell DA, Hornig JD, Liu R: Systematic review of intratympanic gentamicin in Meniere’s disease. J Otolaryngol 2003;32:351–361. Chia SH, Gamst AC, Anderson JP, Harris JP: Intratympanic gentamicin therapy for Meniere’s disease: a meta-analysis. Otol Neurotol 2004;25:544–552. Atlas J, Parnes LS: Intratympanic gentamicin for intractable Meniere’s disease: 5-year follow-up. J Otolaryngol 2003;32:288–293. Minor LB: Superior canal dehiscence syndrome. Am J Otol 2000;21:9–19. Banerjee A, Whyte A, Atlas MD: Superior canal dehiscence: review of a new condition. Clin Otolaryngol 2005;30:9–15 (review). Tilikete C, Krolak-Salmon P, Truy E, Vighetto A: Pulse-synchronous eye oscillations revealing bone superior canal dehiscence. Ann Neurol 2004;56:556–560. Straube A, Büttner U, Brandt T: Recurrent attacks with skew deviation, torsional nystagmus and contraction of the left frontalis muscle. Neurology 1994;44:177–178. Brandt T, Dieterich M: Vestibular paroxysmia: vascular compression of the eighth nerve? Lancet 1994;343:798–799. Jannetta PJ, Møller MB, Møller AR: Disabling positional vertigo. N Engl J Med 1984;310: 1700–1705. Baloh RW, Spooner JW: Downbeat nystagmus. A type of central vestibular nystagmus. Neurology 1981;31:304–310. Bronstein AM, Miller DH, Rudge P, Kendall BE: Down beating nystagmus: magnetic resonance imaging and neuro-otological findings. J Neurol Sci 1987;81:173–184. Marti S, Palla A, Straumann D: Gravity dependence of ocular drift in patients with cerebellar downbeat nystagmus. Ann Neurol 2002;52:712–721. Glasauer S, Hoshi M, Kempermann U, Eggert T, Büttner U: Three-dimensional eye position and slow phase velocity in humans with downbeat nystagmus. J Neurophysiol 2003;89:338–354. Ances BM, Dalmau JO, Tsai J, Hasbani MJ, Galetta SL: Downbeating nystagmus and muscle spasms in a patient with glutamic-acid decarboxylase antibodies. Am J Ophthalmol 2005;140: 142–144. Halmagyi MG, Rudge P, Gresty MA, Sanders MD: Downbeating nystagmus. A review of 62 cases. Arch Neurol 1983;40:777–784. Young YH, Huang TW: Role of clonazepam in the treatment of idiopathic downbeat nystagmus. Laryngoscope 2001;111:1490–1493. Currie J, Matsuo V: The use of clonazepam in the treatment of nystagmus induced oscillopsia. Ophthalmology 1986;93:924–932. Dieterich M, Straube A, Brandt T, Paulus W, Büttner U: The effects of baclofen and cholinergic drugs on upbeat and downbeat nystagmus. J Neurol Neurosurg Psychiatry 1991;54: 627–632. Averbuch-Heller L, Tusa RJ, Fuhry L, Rottach KG, Ganser GL, Heide W, Büttner U, Leigh RJ: A double-blind controlled study of gabapentin and baclofen as treatment for acquired nystagmus. Ann Neurol 1997;41:818–825.
Treatment of Oculomotor Disorders
189
39
40 41
42 43 44 45 46 47 48 49
50 51 52 53
54 55 56 57 58 59 60 61 62 63 64 65
Strupp M, Schuler O, Krafczyk S, Jahn K, Schautzer F, Büttner U, Brandt T: Treatment of downbeat nystagmus with 3,4-diaminopyridine: a placebo-controlled study. Neurology 2003;61: 165–170. Kalla R, Glasauer S, Schautzer F, Lehnen N, Büttner U, Strupp M, Brandt T: 4-aminopyridine improves downbeat nystagmus, smooth pursuit, and VOR gain. Neurology 2004;62:1228–1229. Helmchen C, Sprenger A, Rambold H, Sander T, Kömpf D, Straumann D: Effect of 3,4diaminopyridine on the gravity dependence of ocular drift in downbeat nystagmus. Neurology 2004;63:752–753. Pedersen RA, Troost BT, Abel LA, Zorub D: Intermittent down beat nystagmus and oscillopsia reversed by suboccipital craniectomy. Neurology 1980;30:1232–1242. Spooner JW, Baloh RW: Arnold-Chiari malformation. Improvement in eye movements after surgical treatment. Brain 1981;104:51–60. Stahl JS, Averbuch-Heller L, Leigh RJ: Acquired nystagmus. Arch Ophthalmol 2000;118: 544–549. Fisher A, Gresty M, Chambers B, Rudge P: Primary position upbeating nystagmus: a variety of central positional nystagmus. Brain 1983;106:949–964. Glasauer S, Kalla R, Büttner U, Strupp M, Brandt T: 4-aminopyridine restores visual ocular motor function in upbeat nystagmus. J Neurol Neurosurg Psychiatry 2005;76:451–453. Endres M, Heide W, Kömpf D: See-saw nystagmus. Clinical aspects, diagnosis, pathophysiology: observations in 2 patients. Nervenarzt 1996;67:484–489. Halmagyi GM, Aw ST, Dehaene I, Curthoys IS, Todd MJ: Jerk-waveform see-saw nystagmus due to unilateral meso-diencephalic lesion. Brain 1994;117:775–788. Rambold H, Helmchen C, Büttner U: Unilateral muscimol inactivations of the interstitial nucleus of Cajal in the alert rhesus monkey do not elicit seesaw nystagmus. Neurosci Lett 1999;272: 75–78. Stahl JS, Averbuch-Heller L, Leigh RJ: Acquired nystagmus. Arch Ophthalmol 2000;118: 544–549. Frisèn L, Wikkelso C: Posttraumatic seesaw nystagmus abolished by ethanol ingestion. Neurology 1986;36:841–844. Lepore FE: Ethanol-induced resolution of pathologic nystagmus. Neurology 1987;37:877. Averbuch-Heller L, Tusa RJ, Fuhry L, Rottach K, Ganser GL, Heide W, Büttner U, Leigh RJ: A double-blind controlled study of gabapentin and baclofen as treatment for acquired nystagmus. Ann Neurol 1997;41:818–825. Waespe W, Cohen B, Raphan T: Dynamic modification of the vestibuloocular reflex by the nodulus and uvula. Science 1985;228:199–202. Furman JMR, Wall C, Pang D: Vestibular function in periodic alternating nystagmus. Brain 1990;113:1425–1439. Lee MS, Lessell S: Lithium-induced periodic alternating nystagmus. Neurology 2003;60:344. Halmagyi MG, Rudge P, Gresty MA: Treatment of periodic alternating nystagmus. Ann Neurol 1980;8:609–611. Tilikete C, Vighetto A, Trouillas P, Honnorat J: Anti-GAD antibodies and periodic alternating nystagmus. Arch Neurol 2005;62:1300–1303. Isago H, Tsuboya R, Kataura A: A case of periodic alternating nystagmus: with special reference to the efficacy of baclofen treatment. Auris Nasus Larynx 1985;12:15–21. Nuti D, Ciacci G, Giannini F, Rossi A, Frederico A: Aperiodic alternating nystagmus: report of two cases and treatment by baclofen. Ital J Neurol Sci 1986;7:453–459. Gresty M, Ell JJ, Findley LJ: Acquired pendular nystagmus: its characteristics, localising value and pathophysiology. J Neurol Neurosurg Psychiatry 1982;45:431–439. Leigh RJ: Clinical features and pathogenesis of acquired forms of nystagmus. Baillieres Clin Neurol 1992;1:393–416. Zee DS: Mechanisms of nystagmus. Am J Otolaryngol (Suppl) 1985;30–34. Lopez LI, Bronstein AM, Gresty MA, Du Boulay EP, Rudge P: Clinical and MRI correlates in 27 patients with acquired pendular nystagmus. Brain 1996;119:465–472. Herishanu Y, Louzoun Z: Trihexyphenidyl treatment of vertical pendular nystagmus. Neurology 1986;36:82–84.
Straube
190
66
67
68 69
70 71 72 73
74 75
76
77 78
79 80
81 82 83 84
85 86 87 88 89
Jabbari B, Rosenberg M, Scherokman B, Gunderson CH, McBurney JW, McClintock W: Effectiveness of trihexyphenidyl against pendular nystagmus and palatal myoclonus: evidence of cholinergic dysfunction. Mov Disord 1987;2:93–98. Leigh RJ, Burnstine TH, Ruff RL, Kasmer RJ: The effect of anticholinergic agents upon acquired nystagmus: a double-blind study of trihexyphenidyl and tridihexethyl chloride. Neurology 1991;41:1737–1741. Starck M, Albrecht H, Pöllmann W, Straube A, Dieterich M: Drug therapy of acquired nystagmus in multiple sclerosis. J Neurol 1997;244:9–16. Bandini F, Castello E, Mazzella L, Mancardi GL, Solaro C: Gabapentin but not vigabatrin is effective in the treatment of acquired nystagmus in multiple sclerosis: how valid is the GABAergic hypothesis? J Neurol Neurosurg Psychiatry 2001;71:107–110. Stahl JS, Rottach KG, Averbuch-Heller L, von Maydell RD, Collins SD, Leigh RJ: A pilot study of gabapentin as treatment for acquired nystagmus. Neuro-ophthalmology 1996;16:107–113. Fabre K, Smet-Dieleman H, Zeyen T: Improvement of acquired pendular nystagmus by gabapentin: case report. Bull Soc Belge Ophtalmol 2001;282:43–46. Dell’Osso LF: Suppression of pendular nystagmus by smoking cannabis in a patient with multiple sclerosis. Neurology 2000;13:2190–2191. Schon F, Hart PE, Hodgson TL, Pambakian AL, Ruprah M, Williamson EM, Kennard C: Suppression of pendular nystagmus by smoking cannabis in a patient with multiple sclerosis. Neurology 1999;53:2209–2210. Menon GJ, Thaller VT: Therapeutic external ophthalmoplegia with bilateral retrobulbar botulinum toxin – an effective treatment for acquired nystagmus with oscillopsia. Eye 2002;16:804–806. Leigh RJ, Tomsak RL, Grant MP, Remler BF, Yaniglos SS, Lystad L, Dell’Osso LF: Effectiveness of botulinum toxin administered to abolish acquired nystagmus. Ann Neurol 1992;32: 633–642. Tomsak RL, Remler BF, Averbuch-Heller L, Chandran M, Leigh RJ: Unsatisfactory treatment of acquired nystagmus with retrobulbar injection of botulinum toxin. Am J Ophthalmol 1995;119: 489–496. Büttner U, Straube A, Handke V: Opsoclonus und Okular flutter. Nervenarzt 1997;68:633–637. Ridley A, Kennard C, Scholtz CL, Büttner-Ennever JA, Summers B, Turnbull A: Omnipause neurons in two cases of opsoclonus associated with oat cell carcinoma of the lung. Brain 1987;110: 1699–1709. Pless M, Ronthal M: Treatment of opsoclonus-myoclonus with high-dose intravenous immunoglobulin. Neurology 1996;46:583–584. Traccis S, Marras MA, Puliga MV, Ruiu MC, Masala PG, Carboni A, Aiello I, Pugliatti M, Rosati G: Square-wave jerks and square-wave oscillations: treatment with valproic acid. Neuro-ophthal Mol 1997;18:51–58. Leopold HC: Opsoklonus- und Myoklonie-Syndrom. Klinische und elektronystagmographische Befunde mit Verlaufsstudien. Fortschr Neurol Psychiatr 1985;53:42–54. Rosenberg MI, Glaser JS: Superior oblique myokymia. Ann Neurol 1983;13:667–669. Leigh RJ, Tomsak RL, Seidman SH, Dell’Osso LF: Superior oblique myokymia. Quantitative characteristics of the eye movements in three patients. Arch Ophthalmol 1991;109:1710–1713. Yousry I, Dieterich M, Naidich TP, Schmid UD, Yousry TA: Superior oblique myokymia: magnetic resonance imaging support for the neurovascular compression hypothesis. Ann Neurol 2002;51: 361–368. Hashimoto M, Ohtsuka K, Suzuki Y, Minamida Y, Houkin K: Superior oblique myokymia caused by vascular compression. J Neuroophthalmol 2004;24:237–239. Tomsak RL, Kosmorsky GA, Leigh RJ: Gabapentin attenuates superior oblique myokymia. Am J Ophthalmol 2002;133:721–723. Deokule S, Burdon M, Matthews T: Superior oblique myokymia improved with gabapentin. J Neuroophthalmol 2004;24:95–96. Samii M, Rosahl SK, Carvalho GA, Krzizok T: Microvascular decompression for superior oblique myokymia: first experience. J Neurosurg 1998;89:1020–1024. Scharwey K, Krzizok T, Samii M, Rosahl SK, Kaufmann H: Remission of superior oblique myokymia after microvascular decompression. Ophthalmologica 2000;214:426–428.
Treatment of Oculomotor Disorders
191
90 Bronstein A: Benign paroxysmal positional vertigo (BPPV): Diagnosis and physical treatment. Adv Clin Neurosci Rehabil 2005;5:13–15. 91 Hornibrook J: Horizontal canal benign positional vertigo. Ann Otol Rhinol Laryngol 2004;113:721–725. 92 Bertholon P, Bronstein AM, Davies RA, Rudge P, Thilo KV: Positional down beating nystagmus in 50 patients: cerebellar disorders and possible anterior semicircular canalithiasis. J Neurol Neurosurg Psychiatry 2002;72:366–367. 93 von Brevern M, Radtke A, Clarke AH, Lempert T: Migrainous vertigo presenting as episodic positional vertigo. Neurology 2004;62:469–472. 94 Büttner U, Helmchen C, Brandt T: Diagnostic criteria for central versus peripheral positioning nystagmus and vertigo: a review. Acta Otolaryngol 1999;119:1–5. 95 Crevits L: Treatment of anterior canal benign paroxysmal positional vertigo by a prolonged forced position procedure. J Neurol Neurosurg Psychiatry 2004;75:779–781. 96 Hilton M, Pinder D: The Epley (canalith repositioning) manoeuvre for benign paroxysmal positional vertigo. Cochrane Database Syst Rev 2004;CD003162. 97 Radtke A, von Brevern M, Tiel-Wilck K, Mainz-Perchalla A, Neuhauser H, Lempert T: Self-treatment of benign paroxysmal positional vertigo: semont maneuver vs Epley procedure. Neurology 2004;63:150–152. 98 Sakaida M, Takeuchi K, Ishinaga H, Adachi M, Majima Y: Long-term outcome of benign paroxysmal positional vertigo. Neurology 2003;60:1532–1534. 99 Del Rio M, Arriaga MA: Benign positional vertigo: prognostic factors. Otolaryngol Head Neck Surg 2004;130:426–429. 100 Gordon CR, Levite R, Joffe V, Gadoth N: Is posttraumatic benign paroxysmal positional vertigo different from the idiopathic form? Arch Neurol 2004;61:1590–1593.
A. Straube Department of Neurology, Klinikum Grosshadern Marchioninistrasse 15 DE–81377 Munich (Germany) Tel. ⫹49 89 7095 3900, Fax ⫹49 89 7095 3677, E-Mail
[email protected]
Straube
192
Subject Index
Alcohol, seesaw nystagmus management 183 4-Aminopyridine downbeat nystagmus management 181, 182 upbeat nystagmus management 182 Baclofen periodic alternating nystagmus management 184 upbeat nystagmus management 182 Basal ganglia, saccadic eye movement control 62 Benign paroxysmal positional vertigo (BPPV) clinical features 186, 187 etiology 187 treatment 187, 188 Betahistine, Ménière’s disease management 179 Binocular adaptation Listing’s plane 98 phoria adaptation 97, 98 saccade adaptation 98, 99 Blinking clinical applications 125 eye movements and effects blink-associated 114 blink effects 115 disconjugate eye movements 101, 117, 118 saccade-vergence interactions 118, 119 saccadic eye movement 115–117
smooth pursuit eye movements 119, 120 frequency disorders 120, 122 visual consequences 114 Botulinum toxin, acquired pendular nystagmus management 185 Brainstem saccadic generator excitatory burst neurons 55, 56 inhibitory burst neurons 56, 57 midbrain reticular formation 55 omnipause neurons 57 paramedian pontine reticular formation 55 tonic neurons 57–60 Caloric testing, vestibulo-ocular reflex function 45, 46 Carbamazepine superior oblique myokymia management 186 vestibular paroxysmia management 180 Central caudal nucleus (CCN), eyelid control 111 Cerebellum central processing of vestibular signals 39, 40 saccadic eye movement control 66–70 smooth pursuit eye movement role 80–82 Click-evoked myogenic potential, vestibular function testing 48, 49 Clonazepam downbeat nystagmus management 181, 182 opsoclonus management 185 seesaw nystagmus management 183
193
Craniosynostosis, strabismus 149 Cyclovergence 92 Dimenhydrimnate Ménière’s disease management 179 vestibular neuritis management 178 Disconjugate eye movements binocular adaptation Listing’s plane 98 phoria adaptation 97, 98 saccade adaptation 98, 99 blinking 101, 117, 118 cyclovergence 92 Hering’s law and asymmetric vergence movements 95, 96 horizontal vergence movements 91 Listing’s law during convergence 93–95 overview 90, 91 pathology 101, 102 saccade-associated vergence movements 96, 97 vertical vergence movements 92 vestibular stimulation 99–101 Double Purkinje image (DPI) eye tracker, historical perspective 17 Downbeat nystagmus, see Nystagmus Electro-oculogram (EOG) comparison with other eye movement recording techniques 31, 32 historical perspective 17 infrared reflection device comparison 20, 21 noise and resolution 20 principles 19, 20 single-eye measurement 21 vestibulo-ocular reflex function 45 Epley maneuver, benign paroxysmal positional vertigo management 187, 188 Extraocular muscles, see Eye muscles Eye-head movement, ocular motor system modeling 170 Eyelid, see also Blinking disorders blink frequency 120–122 eyelid-eye coordination 124 tonic eyelid position 122, 123
Subject Index
neural control levator palpebrae muscle innervation 111 lid-eye coordination 111–113 supranuclear disorders 110 Eye movement recordings comparison of techniques 31, 32 double Purkinje image eye tracker 17 electro-oculogram infrared reflection device comparison 20, 21 noise and resolution 20 overview 17 principles 19, 20 single-eye measurement 21 historical perspective 16–18 infrared reflection device calibration 23, 24 overview 17 principles 22, 23 magnetic search coil accuracy 26 disadvantages 26, 27 error sources 25, 26 noise 26 overview 18 principles 24, 25 video-oculography calibration 28, 29 noise 30 ocular torsion measurements 30 overview 18, 19 principles 27, 28 Eye muscles fibers 2–4, 8–11 innervation central pathways 7 motoneurons 7, 8 premotor circuits 8–10 Listing’s law 139, 140, 143–146, 152 magnetic resonance imaging 134, 138, 139, 142, 145, 149 morphology 2, 133, 134 ocular counterrolling 145 proprioception 10, 11 pulleys animal studies 142, 143
194
functional anatomy 137–139 kinematics 139–142, 152 neural control 146–148 structure 134–137 surgery pulley heterotopy 150 pulley hindrance 151 pulley instability 150, 151 sensory receptors Golgi tendon organs 6 palisade endings 5, 6 spindles 4, 5 skeletal muscle comparison 2 strabismus 148–150 types 133 Eye plant, ocular motor system model 159, 160 Frontal eye field (FEF) eyelid control 112, 113 smooth pursuit eye movement role 80, 169 Gabapentin acquired pendular nystagmus management 184, 185 downbeat nystagmus management 181 seesaw nystagmus management 183 superior oblique myokymia management 186 Golgi tendon organs, eye muscles 6 Hering’s law, asymmetric vergence movements 95, 96 Infrared reflection device (IRD) calibration 23, 24 comparison with other eye movement recording techniques 31, 32 historical perspective 17 principles 22, 23 Lamotrigine, vestibular paroxysmia management 180 Levator palpebrae muscle, see Eyelid Listing’s law Convergence 93–95 mechanical basis 143–146
Subject Index
ocular motor system modeling 162 pulley kinematics 139, 140, 152 violation during vestibulo-ocular reflex 143, 144 Magnetic resonance imaging (MRI), eye muscles 134, 138, 139, 142, 145, 149 Magnetic search coil accuracy 26 comparison with other eye movement recording techniques 31, 32 disadvantages 26, 27 error sources 25, 26 historical perspective 18 noise 26 principles 24, 25 Medulla, smooth pursuit eye movement pathology 84 Ménière’s disease clinical features 178 etiology 178, 179 treatment 179 Methylprednisolone, vestibular neuritis management 178 Neural velocity-to-position integrator, ocular motor system model 160–162 Nitrazepam, opsoclonus management 185 Nucleus reticularis tegmenti pontis (NRTP), saccadic eye movement control 62, 64, 65, 66 Nystagmus, see also Optokinetic nystagmus acquired pendular nystagmus clinical features 184 etiology 184 treatment 184, 185 bedside clinical evaluation dynamic disturbances 42, 43 positional testing 43, 44 static imbalance 41, 42 Valsalva- and hyperventilation-induced nystagmus 44, 45 downbeat nystagmus clinical features 180 etiology 181 treatment 181, 182
195
Nystagmus (continued) pathology 177 periodic alternating nystagmus clinical features 183 etiology 183 treatment 184 seesaw nystagmus clinical features 182, 183 etiology 183 treatment 183 upbeat nystagmus clinical features 182 etiology 182 treatment 182 vestibulo-ocular reflex pathology 40, 41 Ocular flutter clinical features 185 etiology 185 treatment 185 Ocular following response (OFR) anatomy and physiology 78, 81 features 78 Ocular motor nerve, eye muscle sensory afferents 7 Oculomotor nucleus, motoneurons 7 Opsoclonus clinical features 185 etiology 185 treatment 185 Optokinetic nystagmus (OKN) anatomy and physiology 81 components 77, 78 definition 77 pathology 84 velocities 78 vertical versus horizontal 78 Otoliths, function testing 48 Palisade endings, eye muscles 5, 6 Paramedian pontine reticular formation, see Brainstem saccadic generator Parkinson’s disease (PD), eyelid disorders 121, 123, 124 Periodic alternating nystagmus, see Nystagmus
Subject Index
Phenytoin, vestibular paroxysmia management 180 Pontine nuclei, saccadic eye movement control 62, 64, 65 Propranolol, opsoclonus management 185 Pulleys, see Eye muscles Robinson, D.A., ocular motor system models 158–160 Rotational testing, vestibulo-ocular reflex function 45, 46 Saccadic eye movement antisaccades 53 binocular saccade adaptation 98 blinking effects 115–117 vergence interactions 118, 119 features 53 latency 53 memory-guided saccades 53 neurocircuitry basal ganglia 62 brainstem saccadic generator excitatory burst neurons 55, 56 inhibitory burst neurons 56, 57 midbrain reticular formation 55 omnipause neurons 57 paramedian pontine reticular formation 55 tonic neurons 57–60 cerebellum 66–70 monkey studies 146, 147 nucleus reticularis tegmenti ponti 62, 64–66 overview 53–55 pontine nuclei 62, 64, 65 superior colliculus 60–62 ocular motor system modeling 162, 163 orienting cascade 53 resting saccades 52 spontaneous saccades 53 target-directed saccades 53 vergence movements 96, 97 Search coil, see Magnetic search coil
196
Seesaw nystagmus, see Nystagmus Semicircular canal (SCC) vestibular testing 47, 48 vestibulo-ocular reflex 36 Smooth pursuit eye movements (SPEM) anatomy and physiology 79–81 blinking effects 119, 120 features 76 latency 76 ocular motor system modeling 168, 169 pathology cerebellum 82, 84 cortex 82 medulla 84 pontine structures 82 testing 77 Spindles, eye muscles 4, 5 Strabismus craniosynostosis 149 muscle weakness 148 superior oblique palsy 148, 149 Subjective visual vertical (SVV), otolith function testing 48 Superior canal dehiscence syndrome clinical features 179 etiology 179 treatment 179 Superior colliculus eyelid control 112, 113 saccadic eye movement control 60–62 Superior oblique myokymia clinical features 186 etiology 186 treatment 186 Supplementary eye field (SEF), smooth pursuit eye movement role 80 Trigeminal nerve, eye muscle sensory afferents 7 Trihexyphenidyl, acquired pendular nystagmus management 184 Upbeat nystagmus, see Nystagmus Valacyclovir, vestibular neuritis management 178
Subject Index
Valproic acid, opsoclonus management 185 Vergence eye movements, see Disconjugate eye movements Vertigo benign paroxysmal positional vertigo, see Benign paroxysmal positional vertigo vestibulo-ocular reflex pathology 40, 41 Vestibular neuritis clinical features 177 etiology 177, 178 treatment 178 Vestibular nuclear complex, central processing of vestibular signals 39, 40 Vestibular paroxysmia clinical features 180 etiology 180 treatment 180 Vestibulo-ocular reflex (VOR) angular reflex 35, 36, 183 bedside clinical evaluation dynamic disturbances 42, 43 positional testing 43, 44 static imbalance 41, 42 Valsalva- and hyperventilation-induced nystagmus 44, 45 click-evoked myogenic potential testing 48, 49 components central processing of vestibular signals 37, 39, 40 motor output 40 overview 36 peripheral sensory apparatus 36, 37 function 35, 77 laboratory testing caloric testing 45, 46 electro-oculography 45 rotational testing 45, 46 linear reflex 36 ocular motor system modeling adaptation 164, 165 angular reflex three-dimensional model 165, 166 overview 163–165 otolith function testing 48
197
Vestibulo-ocular reflex (continued) pathology 40, 41, 177 semicircular canal function testing 47, 48 Video-oculography (VOG) calibration 28, 29
Subject Index
comparison with other eye movement recording techniques 31, 32 historical perspective 18, 19 noise 30 ocular torsion measurements 30 principles 27, 28
198