Correia M J, Perachio A A, Eden A R
J Neurophysiol. 1985 Sep;54(3):532-48. doi: 10.1152/jn.1985.54.3.532.
We studied the vertical vestibuloocular response (VVOR) in seven cynomolgus monkeys. Eye movements were measured by the search coil method. We tested the monkeys by rotating them about their interaural axis, which was colinear with gravity. Each monkey was tested by using a standard rotational paradigm that consisted of discrete sinusoidal oscillations at three frequencies (0.01, 0.1, and 1.0 Hz) and six peak velocities (5, 10, 30, 60, 100, and 150 degrees/S). The standard rotational paradigm was applied twice for each of two conditions. The first condition (EOD) consisted of rotations with the animal's vision occluded; the second condition (EOL) consisted of rotations during which the animal was allowed to view a well-lighted room. Using various statistics, we tested the linearity of the sinusoidal slow-phase velocity component of the VVOR. The largest nonlinearity found was a skewness of approximately 14% in the waveform of f = 0.01 Hz. We did not find an amplitude asymmetry between slow-phase eye velocity upward (SPVU) and slow-phase eye velocity downward (SPVD) greater than 6% for any oscillation. Nonlinearities present in the VVOR during testing with vision occluded (EOD condition) disappeared with the addition of vision (EOL condition). Intensity function plots [peak slow-phase eye velocity vs. peak rotator (head) velocity] revealed that at f = 0.01, 0.1, and 1.0 Hz over the intensity range from +/-30 degrees/s to +/-150 degrees/s, the VVOR is highly linear. The lowest correlation coefficient associated with linear regressions of the intensity function data at each frequency was 0.99. Analyses of frequency response functions for the bandwidth f = 0.01 to 1.0 Hz, revealed the following: 1) mean amplitude ratio (AR) and phase overlap for four different stimulus intensities (30, 60, 100, and 150 degrees/s); 2) no significant differences (Mann-Whitney U test, P greater than 0.05) between any AR or phase value for mean peak SPVU and mean peak SPVD re appropriately directed head velocity; 3) no significant differences (Mann-Whitney U test, P greater than 0.05) between AR and phase values for animals tested and then retested 1 mo later with five intervening standard rotational paradigms; 4) a large effect of vision in producing a VVOR with near-unity gain and near-perfect phase compensation.(ABSTRACT TRUNCATED AT 400 WORDS)
我们研究了7只食蟹猴的垂直前庭眼反射(VVOR)。通过搜索线圈法测量眼动。我们通过绕与重力共线的双耳轴旋转猴子来对其进行测试。每只猴子都采用一种标准旋转范式进行测试,该范式由三个频率(0.01、0.1和1.0赫兹)和六个峰值速度(5、10、30、60、100和150度/秒)的离散正弦振荡组成。标准旋转范式在两种条件下各应用两次。第一种条件(EOD)包括在动物视觉被遮挡的情况下旋转;第二种条件(EOL)包括在动物能够看到光线充足的房间的情况下旋转。我们使用各种统计方法测试了VVOR正弦慢相速度分量的线性度。发现的最大非线性是在f = 0.01赫兹的波形中约14%的偏度。对于任何振荡,我们都未发现慢相眼速度向上(SPVU)和慢相眼速度向下(SPVD)之间的幅度不对称大于6%。在视觉被遮挡的测试(EOD条件)期间VVOR中存在的非线性在增加视觉(EOL条件)后消失。强度函数图[峰值慢相眼速度与峰值旋转器(头部)速度]显示,在f = 0.01、0.1和1.0赫兹时,在+/-30度/秒至+/-150度/秒的强度范围内,VVOR高度线性。每个频率下强度函数数据线性回归的最低相关系数为0.99。对带宽f = 0.01至1.0赫兹的频率响应函数分析显示如下:1)四种不同刺激强度(30、60、100和150度/秒)的平均幅度比(AR)和相位重叠;2)对于适当定向的头部速度,平均峰值SPVU和平均峰值SPVD的任何AR或相位值之间无显著差异(曼-惠特尼U检验,P大于0.05);3)在测试动物然后在1个月后用五个中间标准旋转范式重新测试时,AR和相位值之间无显著差异(曼-惠特尼U检验,P大于0.05);4)视觉在产生具有接近单位增益和接近完美相位补偿的VVOR方面有很大影响。(摘要截断于400字)
