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Vertigo and Imbalance: Clinical Neurophysiology of the Vestibular System

Name: Vertigo and Imbalance: Clinical Neurophysiology of the Vestibular System
Author: S. D. Eggers, D. Zee

Handbook of Clinical Neurophysiology

S. D. Eggers, D. Zee

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Vertigo and Imbalance: Clinical Neurophysiology of the Vestibular System

Handbook of Clinical Neurophysiology

S. D. Eggers, D. Zee

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Vertigo and Imbalance: Clinical Neurophysiology of the Vestibular System

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Informations

Éditeur

Elsevier

Année

2009

ISBN

9780444534781

Sujet

Medizin

Sous-sujet

Neurologie

Chapter 1

Overview of vestibular and balance disorders

Scott D.Z. Eggers^a* and David S. Zee^b, ^aDepartment of Neurology, Mayo Clinic College of Medicine, 200 First St. SW, Rochester, MN 55905, USA; ^bDepartment of Neurology, The Johns Hopkins Hospital, Path 2-210, 600 N. Wolfe St., Baltimore, MD 21287, USA. E-mail address: [email protected]

^*Correspondence to: Dr. Scott D.Z. Eggers, Department of Neurology, Mayo Clinic College of Medicine, 200 First St. SW, Rochester, MN 55905, USA. (S.D.Z. Eggers)

Publisher Summary

This chapter reviews the basic vestibular and ocular motor anatomy, and physiology relevant to patients with balance disorders. Then with a foundation of physiological and anatomical principles in mind, the historical features and special bedside examination techniques for evaluating the dizzy patient are discussed. It explores that great advances have been made in the past half century in the ability to study and quantify the characteristics of eye movements, and the influence of the vestibular and optokinetic systems on ocular motor control. This, combined with careful clinical observation of patients, has led to the discovery of new disorders, such as superior canal dehiscence and treatments like the canalith repositioning procedure. The chapter also reviews that rational model of the neural basis for vestibular and ocular motor control can be created, and tested experimentally with great precision.

This volume of the Clinical Neurophysiology Handbook Series is devoted to the clinical neurophysiology of vestibular and balance disorders. This large subject is covered by 40 chapters written by experts from around the world. As Editors of the volume, we are indebted to these authors for their unselfish dedication and far-reaching contributions.

Clinicians and scientists involved in the research and care of patients with dizziness are defined not by an anatomic specialty or disease, but rather by the nature of their patients’ presenting complaints: vertigo, disequilibrium, imbalance, and related symptoms. Thus, the target audience for this volume is reflected in the diverse backgrounds of its authors — neurologists, otolaryngologists, neuro-ophthalmologists, audiologists, physical therapists, psychiatrists, and bioengineers. Indeed a multidisciplinary approach is essential for the optimal diagnosis and treatment of patients with vestibular disorders. The goal of this volume is to review each topic with enough background to be accessible to the non-specialist, while at the same time providing depth and completeness for the specialist and methodological detail for the clinician, technician, or investigator.

This volume has been divided into four major sections:

(1) The Overview section reviews basic vestibular and ocular motor anatomy and physiology relevant to patients with balance disorders. Then with a foundation of physiological and anatomical principles in mind, the historical features and special bedside examination techniques for evaluating the dizzy patient are discussed.

(2) The Methodological Techniques section reviews in depth the great breadth of techniques now available to evaluate the function of the vestibular system. Beginning with the various techniques of recording eye movements, this section covers standard methods such as rotary chair testing and caloric testing, as well as recently developed or specialized tests such as head impulse testing, translational vestibulo-ocular reflex testing, vestibular evoked potentials, electrocochleography, and provocative maneuvers. Many of these emerging techniques have not been previously reviewed systematically. Many have not reached widespread clinical use but are in development or are useful research tools. Methodological descriptions are not repeated later in the chapters covering specific diseases, so the reader will need to refer back to these chapters for description of techniques and normal values.

(3) Chapters in the Diseases and Treatments section address the most common conditions and important issues relevant to care of patients with vestibular and balance disorders. Topics range from peripheral vestibular disorders to neurological disorders, with additional discussion of psychological issues, visual symptoms, and the elderly. Both “new” diagnoses (e.g., migrainous vertigo and superior canal dehiscence) and more traditional causes of vestibular dysfunction (e.g., Ménière’s disease and vestibular neuritis) are discussed. Given the focus of this volume and series, special attention is paid to the role of available testing techniques in the diagnosis and management of patients.

(4) A final chapter looks back at the historical roots of the study of vestibular and ocular motor function. Based upon our expanding fundamental understanding and computational modeling of these systems, the authors look ahead to the next decade for methodological approaches and advances, such as use of artificial neural networks to aid diagnosis, development of vestibular prostheses, study of the perceptual disturbances often reported by patients with vestibular dysfunction, and finally treatment approaches based upon the molecular biology and genetics of vestibular disease.

Evaluating dizzy patients with vertigo and other “spells” of symptoms requires some knowledge in several areas, including cardiovascular and autonomic disorders, psychiatry, and areas within neurology such as cerebrovascular disease, epilepsy, and migraine. Readers may need to consult other textbooks for further details on cardiovascular diseases, autonomic disorders, and epilepsy, all of which can sometimes lead to dizziness and falls.

Great advances have been made in the past half century in the ability to study and quantify the characteristics of eye movements and the influence of the vestibular and optokinetic systems on ocular motor control. This, combined with careful clinical observation of patients, has led to the discovery of new disorders such as superior canal dehiscence and treatments such as the canalith repositioning procedure. Rational models of the neural basis for vestibular and ocular motor control can be created and tested experimentally with great precision. Yet clinical care of patients with dizziness and vertigo is still often empiric and messy. Many important basic and clinical questions remain unanswered. What is the underlying pathophysiological basis for Ménière’s syndrome and migrainous vertigo, and how are they related? How can we promote regeneration or engineer alternatives in the setting of vestibular damage? Can pharmacogenetics be applied for the rational treatment of vestibular disorders?

The field is ripe for further research. Collaboration is needed among clinicians, basic scientists, engineers, radiologists, molecular biologists, and geneticists. We hope that this book will provide a framework for basic knowledge and inspiration for further study.

Chapter 2

Overview of anatomy and physiology of the vestibular system

Terry D. Fife*, Department of Neurology, University of Arizona College of Medicine, and Arizona Balance Center, Barrow Neurological Institute, Phoenix, AZ 85013, USA. E-mail address: [email protected]

^*Correspondence to: Terry D. Fife, Arizona Balance Center, Barrow Neurological Institute, 222 W. Thomas Road, Suite 110A, Phoenix, AZ 85013, USA. Tel.: +1-602-406-6338; fax: +1-602-406-6339.

Publisher Summary

This chapter reviews that the vestibular system helps to maintain spatial orientation and stabilize vision for the purpose of maintaining balance, especially during movement. Vestibular end organs sense angular and linear acceleration, and transduce these forces to electrochemical signals that can be used by the central nervous system. It discusses that the central nervous system integrates the information from the vestibular system to stabilize gaze during head motion by means of the vestibulo-ocular reflex (VOR) and to modulate muscle tone by the vestibulocollic and vestibulospinal reflexes. The vestibular system detects angular and linear acceleration through five end organs of the membranous labyrinth on each side: the saccule; the utricle; and the anterior, posterior, and lateral semicircular canals. The saccule and the utricle, the otolith organs, transduce linear accelerations, be they from the pull of gravity or from translation of the head. Each of the semicircular canals has a different spatial orientation; the summation of signals from the semicircular canals allows one to detect rotation of the head in any direction.

2.1 Introduction

The vestibular system helps to maintain spatial orientation and stabilize vision for the purpose of maintaining balance, especially during movement. Vestibular end organs sense angular and linear acceleration and transduce these forces to electrochemical signals that can be used by the central nervous system. The central nervous system integrates the information from the vestibular system to stabilize gaze during head motion by means of the vestibulo-ocular reflex (VOR) and to modulate muscle tone by the vestibulocollic and vestibulospinal reflexes (Fig. 1).

Fig. 1 Overview of the vestibular system showing its influence on ipsilateral muscle tone, cerebellar responses and ocular motility. Lateral canal signals synapse in the ipsilateral vestibular nuclear complex and project to the contralateral abducens nucleus innervating the lateral rectus. Abducens interneurons cross back and ascend in the ipsilateral medial longitudinal fasciculus to reach the oculomotor nucleus and innervate the medial rectus. Vestibular signals from various labyrinthine structures also synapse in the lateral vestibular nucleus and travel down the vestibulospinal pathways in the spinal cord to modulate ispilateral muscle tone. Tonic signals from muscle feed back to the vestibular nucleus, interacting with the cerebellum to regulate muscle tone. Vestibular signals also relay through the thalamus to the cerebral cortex for cortical perception. Also illustrated in simplified form are numerous vesibulocerebellar interconnecting pathways, VPL: ventral posterolateral and VPM: ventral posteromedial nucleus of the thalamus.

The vestibular system detects angular and linear acceleration through five end organs of the membranous labyrinth on each side: the saccule, the utricle, and the anterior, posterior and lateral semicircular canals (Fig. 2). The saccule and utricle, the otolith organs, transduce linear accelerations, be they from the pull of gravity or from translation of the head. Each of the semicircular canals has a different spatial orientation; the summation of signals from the semicircular canals allows one to detect rotation of the h...