The Journal of Neurophysiology Vol. 88 No. 2 August 2002, pp. 914-928
Copyright ©2002 by the American Physiological Society

Spatial Orientation of Caloric Nystagmus in Semicircular Canal-Plugged Monkeys

 ¹Department of Otolaryngology, Tokyo Women's Medical University Daini Hospital, Tokyo 116-8567, Japan;  ²Department of Neurology, Mount Sinai School of Medicine, New York, New York 10029-6574;  ³Department of Otolaryngology, Teikyo University School of Medicine, Tokyo 173-8605, Japan; and  ⁴Department of Computer and Information Science, Brooklyn College, City University of New York, Brooklyn, New York 11210

Arai, Yasuko, Sergei B. Yakushin, Bernard Cohen, Jun-Ichi Suzuki, and Theodore Raphan. Spatial Orientation of Caloric Nystagmus in Semicircular Canal-Plugged Monkeys. J. Neurophysiol. 88: 914-928, 2002. We studied caloric nystagmus before and after plugging all six semicircular canals to determine whether velocity storage contributed to the spatial orientation of caloric nystagmus. Monkeys were stimulated unilaterally with cold (20°C) water while upright, supine, prone, right-side down, and left-side down. The decline in the slow phase velocity vector was determined over the last 37% of the nystagmus, at a time when the response was largely due to activation of velocity storage. Before plugging, yaw components varied with the convective flow of endolymph in the lateral canals in all head orientations. Plugging blocked endolymph flow, eliminating convection currents. Despite this, caloric nystagmus was readily elicited, but the horizontal component was always toward the stimulated (ipsilateral) side, regardless of head position relative to gravity. When upright, the slow phase velocity vector was close to the yaw and spatial vertical axes. Roll components became stronger in supine and prone positions, and vertical components were enhanced in side down positions. In each case, this brought the velocity vectors toward alignment with the spatial vertical. Consistent with principles governing the orientation of velocity storage, when the yaw component of the velocity vector was positive, the cross-coupled pitch or roll components brought the vector upward in space. Conversely, when yaw eye velocity vector was downward in the head coordinate frame, i.e., negative, pitch and roll were downward in space. The data could not be modeled simply by a reduction in activity in the ipsilateral vestibular nerve, which would direct the velocity vector along the roll direction. Since there is no cross coupling from roll to yaw, velocity storage alone could not rotate the vector to fit the data. We postulated, therefore, that cooling had caused contraction of the endolymph in the plugged canals. This contraction would deflect the cupula toward the plug, simulating ampullofugal flow of endolymph. Inhibition and excitation induced by such cupula deflection fit the data well in the upright position but not in lateral or prone/supine conditions. Data fits in these positions required the addition of a spatially orientated, velocity storage component. We conclude, therefore, that three factors produce cold caloric nystagmus after canal plugging: inhibition of activity in ampullary nerves, contraction of endolymph in the stimulated canals, and orientation of eye velocity to gravity through velocity storage. Although the response to convection currents dominates the normal response to caloric stimulation, velocity storage probably also contributes to the orientation of eye velocity.