Neuronal Clusters in the Primate Motor Cortex During Interception of Moving Targets

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Neuronal Clusters in the Primate Motor Cortex During Interception of Moving Targets

Daeyeol Lee, Nicholas L. Port, Wolfgang Kruse and Apostolos P. Georgopoulos

Veteran Affairs Medical Center, Minneapolis

Two rhesus monkeys were trained to intercept a moving targetat a fixed location with a feedback cursor controlled by a 2-Dmanipulandum. The direction from which the target appeared,the time from the target onset to its arrival at the interceptionpoint, and the target acceleration were randomized for eachtrial, thus requiring the animal to adjust its movement accordingto the visual input on a trial-by-trial basis. The two animalsadopted different strategies, similar to those identified previouslyin human subjects. Single-cell activity was recorded from thearm area of the primary motor cortex in these two animals, andthe neurons were classified based on the temporal patterns intheir activity, using a nonhierarchical cluster analysis. Resultsof this analysis revealed differences in the complexity anddiversity of motor cortical activity between the two animalsthat paralleled those of behavioral strategies. Most clustersdisplayed activity closely related to the kinematics of handmovements. In addition, some clusters displayed patterns ofactivation that conveyed additional information necessary forsuccessful performance of the task, such as the initial targetvelocity and the interval between successive submovements, suggestingthat such information is represented in selective subpopulationsof neurons in the primary motor cortex. These results also suggestthat conversion of information about target motion into movement-relatedsignals takes place in a broad network of cortical areas includingthe primary motor cortex.

Key Words: Cluster analysis • Monkey • Submovements • Target acceleration

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				W. Kruse, S. Dannenberg, R. Kleiser, and K.-P. Hoffmann Temporal Relation of Population Activity in Visual Areas MT/MST and in Primary Motor Cortex during Visually Guided Tracking Movements Cereb Cortex, May 1, 2002; 12(5): 466 - 476. [Abstract] [Full Text] [PDF]