Paige G D, Sargent E W
Department of Otolaryngology, Washington University School of Medicine, St. Louis, MO 63110.
Exp Brain Res. 1991;84(1):25-34. doi: 10.1007/BF00231759.
The vestibulo-ocular reflex (VOR) is under adaptive control which corrects VOR performance when visual-vestibular mismatch arises during head movements. However, the dynamic characteristics of VOR adaptive plasticity remain controversial. In this study, eye movements (coil technique) were recorded from normal human subjects during sinusoidal rotations in darkness before and after 8 h. of adaptation to 2X binocular lenses. The VOR was studied at 7 frequencies between 0.025 and 4.0 Hz at 50 degrees/s peak head velocity (less for 2.5-4 Hz). For 0.025 and 0.25 Hz, the VOR was tested at 4 peak head velocities between 50 and 300 degrees/s. Before 2X lens adaptation, VOR gain was around 0.9 at 2.5-4.0 Hz and dropped gradually with decreasing frequency to under 0.6 at 0.025 Hz. Phase showed a small lead at the highest frequencies which declined to 0 degree as frequency decreased to 0.5-0.25 Hz, but then rose to 14 degrees by 0.025 Hz. VOR gain was independent of head velocity in the range 50-300 degrees/s at both 0.025 and 0.25 Hz. However, Phase lead rose with increasing head velocity, more so at 0.025 than at 0.25 Hz. After 2X lens adaptation, gain rose across the frequency bandwidth. However, the proportional gain enhancement was frequency dependent; it was greatest at 0.025 Hz (44%), and declined with increasing frequency to reach a minimum at 4 Hz (19%). Phase lead increased after 2X lens adaptation at lower frequencies, but decreased at higher frequencies. New velocity-dependent gain nonlinearities also developed which were not present prior to adaptation; gain declined as peak head velocity increased from 50 to 300 degrees/s at both 0.025 (23% drop) and 0.25 Hz (15% drop). This may suggest an amplitude-dependent limitation in VOR adaptive plasticity. Results indicate both frequency and amplitude dependent nonlinearities in human VOR response dynamics before and after adaptive gain recalibration.
前庭眼反射(VOR)受适应性控制,当头部运动过程中出现视觉 - 前庭不匹配时,该控制会纠正VOR的表现。然而,VOR适应性可塑性的动态特征仍存在争议。在本研究中,在8小时适应2倍双眼透镜前后,于黑暗中对正常人类受试者进行正弦旋转时记录眼动(线圈技术)。在50度/秒的峰值头部速度下(2.5 - 4Hz时较低),以0.025至4.0Hz之间的7个频率研究VOR。对于0.025和0.25Hz,在50至300度/秒之间的4个峰值头部速度下测试VOR。在适应2倍透镜之前,2.5 - 4.0Hz时VOR增益约为0.9,并随着频率降低逐渐下降,在0.025Hz时降至0.6以下。相位在最高频率时显示出小的超前,随着频率降至0.5 - 0.25Hz时降至0度,但在0.025Hz时又升至14度。在0.025和0.25Hz时,50 - 300度/秒范围内的VOR增益与头部速度无关。然而,相位超前随着头部速度增加而增加,在0.025Hz时比在0.25Hz时更明显。适应2倍透镜后,增益在整个频率带宽内上升。然而,增益增强的比例与频率有关;在0.025Hz时最大(44%),并随着频率增加而下降,在4Hz时达到最小值(19%)。在较低频率下,适应2倍透镜后相位超前增加,但在较高频率下减少。还出现了新的与速度相关的增益非线性,这在适应之前并不存在;在0.025Hz(下降23%)和0.25Hz(下降15%)时,随着峰值头部速度从50度/秒增加到300度/秒,增益均下降。这可能表明VOR适应性可塑性存在幅度依赖性限制。结果表明,在适应性增益重新校准前后,人类VOR反应动力学中存在频率和幅度依赖性非线性。
