自由活动家兔的眼球和头部运动
Eye- and head movements in freely moving rabbits.
作者信息
Collewijn H
出版信息
J Physiol. 1977 Apr;266(2):471-98. doi: 10.1113/jphysiol.1977.sp011778.
Abstract
- Eye- and head movements were recorded in unrestrained, spontaneously behaving rabbits with a new technique, based upon phase detection of signals induced in implanted coils by a rotating magnetic field. 2. Movements of the eye in space were exclusively saccadic. In the intersaccadic intervals the eyes were stabilized in space, even during vigorous head movements. Most of this stability was maintained in darkness, except for the occurrence of slow drift. 3. Many saccades were initiated while the head was stationary. They were accompanied by a similar, but slower head rotation with approximately the same amplitude. The displacement of the eye in space was a pure step without appreciable under- or over-shoot. The deviation of the eye in the head was mostly transient. 4. Other saccades were started while the head was moving and were possibly fast phases of a vestibulo-ocular reflex. The time course of the eye movement in space was identical for all saccades, whether the head was moving prior to the saccade or not. Eye movements without any head movement were not observed. 5. Saccades were mostly large (average 20-6 +/- 12-4 degrees S.D.) and never smaller than 1 degree. The relations of maximal velocity and duration to amplitude were similar to those reported for man. 6. Visual pursuit of moving objects, when elicited, was only saccadic and never smooth. 7. It is concluded that the co-ordination and dynamics of the rabbit's head- and eye movements are similar to those of primates. In the absence of foveal specilization, the eye movements are restricted to a rather global redirection of the visual field, possibly in particular of the binocular area.
摘要
- 采用一种新技术,在自由活动、自发行为的家兔身上记录眼动和头部运动,该技术基于对旋转磁场在植入线圈中感应信号的相位检测。2. 眼球在空间中的运动完全是跳跃式的。在两次跳跃之间的间隔期,眼球在空间中保持稳定,即使在剧烈的头部运动时也是如此。除了出现缓慢漂移外,这种稳定性在黑暗中大多得以维持。3. 许多跳跃是在头部静止时启动的。它们伴随着类似但较慢的头部旋转,幅度大致相同。眼球在空间中的位移是一个纯粹的阶跃,没有明显的 undershoot 或 overshoot。眼球在头部内的偏差大多是短暂的。4. 其他跳跃是在头部运动时开始的,可能是前庭眼反射的快相。无论跳跃前头部是否运动,所有跳跃时眼球在空间中的运动时间进程都是相同的。未观察到无任何头部运动的眼动。5. 跳跃大多幅度较大(平均20 - 6±12 - 4度标准差),且从不小于1度。最大速度和持续时间与幅度的关系与人类报道的相似。6. 当引发对移动物体的视觉追踪时,仅为跳跃式,从不平滑。7. 得出的结论是,家兔头部和眼动的协调与动力学与灵长类动物相似。在没有中央凹特化的情况下,眼动仅限于视野的相当全面的重新定向,可能特别是双眼区域。
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