Lateral interactions in the superior colliculus, not an extended fixation zone, can account for the remote distractor effect

E. Olivier; M. C. Dorris; D. P. Munoz

doi:10.1017/S0140525X99432157

Abstract

Recordings of neuronal activity in the monkey superior colliculus (SC) suggest that the two apparently independent effects of a visual distractor on both temporal (latency) and spatial (metrics) saccade parameters may be the result of lateral interactions between subpopulations of saccade-related neurons located at different sites on the motor map of the superior colliculus. One subpopulation is activated during the planing and initiation of a saccade; the other is activated by the appearance of a distractor. The inhibitory or facilitative nature of this interaction depends on the distance between the distractor and the target and is consistent with the complex pattern of intrinsic and commissural collicular connections.

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Lateral interactions in the superior colliculus, not an extended fixation zone, can account for the remote distractor effect

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Lateral interactions in the superior colliculus, not an extended fixation zone, can account for the remote distractor effect

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