The horizontal vestibulo-ocular reflex in the hemilabyrinthectomized guinea-pig.

The horizontal vestibulo-ocular reflex (HVOR) in the alert guinea-pig elicited by sinusoidal rotations and by velocity steps was studied with scleral search coil measurement between 3 and 7 days (short term) and between 35 and 160 days (long term) after hemilabyrinthectomy. Animals of the short-term group were always tested after spontaneous nystagmus in darkness had disappeared. The HVOR gain in response to sinusoidal rotations (peak angular velocity: 40 deg/s) in the short-term group was bilaterally depressed compared to normal animals. The HVOR phase showed a shift towards larger phase leads over the whole frequency range tested (from 0.05 to 3 Hz). In addition, both the mean number of fast phases per half-cycle of sinusoidal rotation and the mean amplitude were reduced. HVOR responses to velocity steps at a constant acceleration of 300 deg/s2 up to final velocity (0 to 100 deg/s) and of 1000 deg/s2 up to final velocity (0 to 300 deg/s) were depressed bilaterally and asymmetrically such that the gain for rotation towards the intact side greatly exceeded that obtained for rotation towards the lesioned side. Finally, the latency of the vestibular responses was increased and the time constant reduced for both sides of rotation. The HVOR gain values for sinusoidal rotations in the long-term group were lower than normal but higher than in the short-term group: they were asymmetric as a result of a greater compensation for rotation towards the intact side. Neither the phase lead nor the HVOR latency and time constant recovered values close to normal. Finally, the mean number of fast phases per half-cycle remained depressed although the mean amplitude recovered. These results demonstrate that in the guinea-pig, the dynamic deficits show a certain degree of recovery after unilateral labyrinthectomy. However, compared to the compensation of the static deficits previously quantified, the rate of recovery is much lower. This suggests that different processes may be involved in the compensation of the static and dynamic deficits.