Visual Tracking Neurons in Primate Area MST Are Activated by Smooth-Pursuit Eye Movements of an "Imaginary" Target

doi:10.1152/jn.00272.2003

Visual Tracking Neurons in Primate Area MST Are Activated by Smooth-Pursuit Eye Movements of an "Imaginary" Target

Uwe J. Ilg and Peter Thier

Abteilung Kognitive Neurologie, Neurologische Universitätsklinik, Hoppe-Seyler-Str. 3, D-72076 Tübingen, Germany

Submitted 20 March 2003; accepted in final form 6 May 2003

Because smooth-pursuit eye movements (SPEM) can be executedonly in the presence of a moving target, it has been difficultto attribute the neuronal activity observed during the executionof these eye movements to either sensory processing or to motorpreparation or execution. Previously, we showed that rhesusmonkeys can be trained to perform SPEM directed toward an "imaginary"target defined by visual cues confined to the periphery of thevisual field. The pursuit of an "imaginary" target providesthe opportunity to elicit SPEM without stimulating visual receptivefields confined to the center of the visual field. Here, wereport that a subset of neurons [85 "imaginary" visual tracking(iVT)-neurons] in area MST of 3 rhesus monkeys were identicallyactivated during pursuit of a conventional, foveal dot targetand the "imaginary" target. Because iVT-neurons did not respondto the presentation of a moving "imaginary" target during fixationof a stationary dot, we are able to exclude that responses topursuit of the "imaginary" target were artifacts of stimulationof the visual field periphery. Neurons recorded from the representationof the central parts of the visual field in neighboring areaMT, usually vigorously discharging during pursuit of fovealtargets, in no case responded to pursuit of the "imaginary"target. This dissociation between MT and MST neurons supportsthe view that pursuit responses of MT neurons are the resultof target image motion, whereas those of iVT-neurons in areaMST reflect an eye movement–related signal that is nonretinalin origin. iVT-neurons fell into two groups, depending on theproperties of the eye movement–related signal. Whereasmost of them (71%) encoded eye velocity, a minority showed responsesdetermined by eye position, irrespective of whether eye positionwas changed by smooth pursuit or by saccades. Only the formergroup exhibited responses that led the eye movement, which isa prerequisite for a causal role in the generation of SPEM.

Address for reprint requests: U. Ilg, Abteilung Kognitive Neurologie, Neurologischen Universitätsklinik, Hoppe-Seyler Str 3, D-72076 Tübingen, Germany (E-mail: uwe.ilg{at}uni-tuebingen.de).

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