Short-Term Adaptation of the VOR: Non-Retinal-Slip Error Signals and Saccade Substitution

doi:10.1196/annals.1303.010

We studied short-term (30 min) adaptation of the vestibulo-ocularreflex (VOR) in five normal humans using a "position error"stimulus without retinal image motion. Both before and afteradaptation a velocity gain (peak slow-phase eye velocity/peakhead velocity) and a position gain (total eye movement duringchair rotation/amplitude of chair motion) were measured in darknessusing search coils. The vestibular stimulus was a brief ( $~$ 700ms), 15° chair rotation in darkness (peak velocity 43°/s).To elicit adaptation, a straight-ahead fixation target disappearedduring chair movement and when the chair stopped the targetreappeared at a new location in front of the subject for gain-decrease(x0) adaptation, or 10° opposite to chair motion for gain-increase(x1.67) adaptation. This position-error stimulus was effectiveat inducing VOR adaptation, though for gain-increase adaptationthe primary strategy was to substitute augmenting saccades duringrotation while for gain-decrease adaptation both correctivesaccades and a decrease in slow-phase velocity occurred. Finally,the presence of the position-error signal alone, at the endof head rotation, without any attempt to fix upon it, was notsufficient to induce adaptation. Adaptation did occur, however,if the subject did make a saccade to the target after head rotation,or even if the subject paid attention to the new location ofthe target without actually looking at it.

				R. R. Kimpo, E. S. Boyden, A. Katoh, M. C. Ke, and J. L. Raymond Distinct Patterns of Stimulus Generalization of Increases and Decreases in VOR Gain J Neurophysiol, November 1, 2005; 94(5): 3092 - 3100. [Abstract] [Full Text] [PDF]

				G. C.Y. PENG, L. B. MINOR, and D. S. ZEE Gaze Position Corrective Eye Movements in Normal Subjects and in Patients with Vestibular Deficits Ann. N.Y. Acad. Sci., April 1, 2005; 1039(1): 337 - 348. [Abstract] [Full Text] [PDF]