Anatomy and Physiology of Vestibular System

DeckerMed Otolaryngology Pub Date : 2022-02-07 DOI:10.2310/ot.7027

Gary Chi, Matthew G. Crowson

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Abstract

A comprehensive understanding of vestibular anatomy and physiology is essential to interpreting and treating vestibular disorders. The otolithic organs and semicircular canals are the major components of the vestibular system. Each contains hair cells, mechanosensory cells responsible for converting mechanical signals produced by the body into electrical signals. Each hair cell produces a resting discharge rate. This rate can be increased or decreased as a result of head motion, with the magnitude of change dependent on the direction and strength of the motion. These signals are sent to the vestibulocochlear nerve which interprets and integrates the information with input from other sensory organs. The main role of the vestibular system is to maintain balance and detect angular and linear acceleration. Angular acceleration is detected by the semicircular canal via interpretation of endolymph flow caused by head movement. Linear acceleration is detected by the otolith organs through gravity-dependent otoconia movement. This article serves as a review for the structure and function of the major vestibular organs. This review contains, 9 figures, 1 table, and 8 references Keywords: Vestibular physiology, Hair cells, Otolith organs, Macule, Semicircular canals, Ampulla, Crista, Vestibulocochlear nerve, Angular acceleration, Linear acceleration

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前庭系统的解剖学和生理学

全面了解前庭解剖学和生理学对于解释和治疗前庭疾病是必不可少的。耳石器官和半规管是前庭系统的主要组成部分。每个都包含毛细胞，负责将身体产生的机械信号转化为电信号的机械感觉细胞。每个毛细胞产生一个静息放电率。这个速率可以随着头部运动而增加或减少，变化的幅度取决于运动的方向和强度。这些信号被发送到前庭耳蜗神经，该神经将这些信息与其他感觉器官的输入信息进行解释和整合。前庭系统的主要作用是维持平衡和检测角加速度和线加速度。角加速度由半规管通过头部运动引起的内淋巴流来检测。耳石器官通过依赖重力的耳石运动来检测线性加速度。本文就前庭主要器官的结构和功能作一综述。关键词:前庭生理学，毛细胞，耳石器官，黄斑，半规管，壶腹，嵴，前庭耳蜗神经，角加速度，线加速度

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DeckerMed Otolaryngology

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