Psychology Department, University of Florence, 50135 Florence, Italy.
Curr Biol. 2011 Aug 23;21(16):1380-4. doi: 10.1016/j.cub.2011.06.014. Epub 2011 Jul 28.
Saccadic adaptation [1] is a powerful experimental paradigm to probe the mechanisms of eye movement control and spatial vision, in which saccadic amplitudes change in response to false visual feedback. The adaptation occurs primarily in the motor system [2, 3], but there is also evidence for visual adaptation, depending on the size and the permanence of the postsaccadic error [4-7]. Here we confirm that adaptation has a strong visual component and show that the visual component of the adaptation is spatially selective in external, not retinal coordinates. Subjects performed a memory-guided, double-saccade, outward-adaptation task designed to maximize visual adaptation and to dissociate the visual and motor corrections. When the memorized saccadic target was in the same position (in external space) as that used in the adaptation training, saccade targeting was strongly influenced by adaptation (even if not matched in retinal or cranial position), but when in the same retinal or cranial but different external spatial position, targeting was unaffected by adaptation, demonstrating unequivocal spatiotopic selectivity. These results point to the existence of a spatiotopic neural representation for eye movement control that adapts in response to saccade error signals.
扫视适应[1]是一种强大的实验范式,可以探究眼球运动控制和空间视觉的机制,其中扫视幅度会根据虚假视觉反馈而发生变化。适应主要发生在运动系统[2,3]中,但也有证据表明存在视觉适应,这取决于扫视后误差的大小和持续时间[4-7]。在这里,我们证实适应具有很强的视觉成分,并表明适应的视觉成分在外层空间坐标而不是视网膜坐标上具有空间选择性。受试者执行了一个记忆引导的、双扫视、向外适应任务,旨在最大限度地提高视觉适应,并区分视觉和运动修正。当记忆中的扫视目标与适应训练中使用的位置相同时(在外层空间中),扫视目标会受到适应的强烈影响(即使在视网膜或颅位置上不匹配),但当在相同的视网膜或颅但不同的外部空间位置时,适应不会影响目标,明确证明了空间选择性。这些结果表明,存在一种用于眼球运动控制的空间拓扑神经表示,它会根据扫视误差信号进行适应。
