Competition between saccade goals in the superior colliculus produces saccade curvature

doi:10.1152/jn.00657.2002

Competition between saccade goals in the superior colliculus produces saccade curvature

Robert M. McPeek¹^*, Jae H. Han¹, and Edward L. Keller¹

¹ The Smith-Kettlewell Eye Research Institute, San Francisco, CA, USA

^* To whom correspondence should be addressed. E-mail: rmm{at}ski.org.

When saccadic eye movements are made in a search task that requiresselecting a target from distractors, the movements show greatercurvature in their trajectories than similar saccades made tosingle stimuli. To test the hypothesis that this increase incurvature arises from competitive interactions between saccadegoals occurring near the time of movement onset, we performedsingle-unit recording and microstimulation experiments in thesuperior colliculus (SC). We found that saccades which endednear the target but curved toward a distractor were accompaniedby increased pre-saccadic activity of SC neurons coding thedistractor site. This increased activity occurred ~30 ms beforesaccade onset and was abruptly quenched upon saccade initiation.The magnitude of increased activity at the distractor site wascorrelated with the amount of curvature toward the distractor.In contrast, neurons coding the target location did not showany significant difference in discharge for curved vs. straightsaccades. To determine whether this pattern of SC dischargeis causally related to saccade curvature, we performed a secondseries of experiments using electrical microstimulation. Monkeysmade saccades to single visual stimuli presented without distractors,and we stimulated sites in the SC that would have correspondedto distractor sites in the search task. The stimulation wassub-threshold for evoking saccades, but when its temporal structuremimicked the activity recorded for curved saccades in search,the subsequent saccades to the visual target showed curvaturetoward the location coded by the stimulation site. The effectwas larger for higher stimulation frequencies and when the stimulationsite was in the same colliculus as the representation of thevisual target. These results support the hypothesis that theincreased saccade curvature observed in search arises from rivalrybetween target and distractor goals, and are consistent withthe idea that the SC is involved in the competitive neural interactionsunderlying saccade target selection.

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				D. L. Kimmel and T. Moore Temporal Patterning of Saccadic Eye Movement Signals J. Neurosci., July 18, 2007; 27(29): 7619 - 7630. [Abstract] [Full Text] [PDF]

				J. O'Shea, N. G. Muggleton, A. Cowey, and V. Walsh Human Frontal Eye Fields and Spatial Priming of Pop-out. J. Cogn. Neurosci., July 1, 2007; 19(7): 1140 - 1151. [Abstract] [Full Text] [PDF]

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				R. M. McPeek Incomplete Suppression of Distractor-Related Activity in the Frontal Eye Field Results in Curved Saccades J Neurophysiol, November 1, 2006; 96(5): 2699 - 2711. [Abstract] [Full Text] [PDF]

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				S. Ito, V. Stuphorn, J. W. Brown, and J. D. Schall Performance Monitoring by the Anterior Cingulate Cortex During Saccade Countermanding Science, October 3, 2003; 302(5642): 120 - 122. [Abstract] [Full Text] [PDF]