A Model of the Nystagmus Induced by off Vertical Axis Rotation

Overview

Journal Biol Cybern

Specialties Neurology
Physiology

Date 1986 Jan 1

PMID 3741902

Citations 25

Authors

T C Hain

Affiliations

Soon will be listed here.

Abstract

A three-dimensional model is proposed that accounts for a number of phenomena attributed to the otoliths. It is constructed by extending and modifying a model of vestibular velocity storage. It is proposed that the otolith information about the orientation of the head to gravity changes the time constant of vestibular responses by modulating the gain of the velocity storage feedback loop. It is further proposed that the otolith signals, such as those that generate L-nystagmus (linear acceleration induced nystagmus), are partially coupled to the vestibular system via the velocity storage integrator. The combination of these two hypotheses suggests that a vestibular neural mechanism exists that performs correlation in the mathematical sense which is multiplication followed by integration. The multiplication is performed by the otolith modulation of the velocity storage feedback loop gain and the integration is performed by the velocity storage mechanism itself. Correlation allows calculation of the degree to which two signals are related and in this context provides a simple method of determining head angular velocity from the components of linear acceleration induced by off-vertical axis rotation. Correlation accounts for the otolith supplementation of the VOR and the sustained nystagmus generated by off-vertical axis rotation. The model also predicts the cross-coupling of horizontal and vertical optokinetic after nystagmus that occurs in head-lateral positions and the reported effects of tilt on vestibular responses.

Citing Articles

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The role of GABAB receptors in the vestibular oculomotor system in mice.

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Direction of balance and perception of the upright are perceptually dissociable.

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Dynamic characteristics of otolith ocular response during counter rotation about dual yaw axes in mice.

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Otolith signals contribute to inter-individual differences in the perception of gravity-centered space.

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