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Experimental Brain Research

, Volume 51, Issue 2, pp 247–260 | Cite as

Cortical mechanisms related to the direction of two-dimensional arm movements: relations in parietal area 5 and comparison with motor cortex

  • J. F. Kalaska
  • R. Caminiti
  • A. P. Georgopoulos
Article

Summary

The relations between the direction of two-dimensional arm movements and single cell discharge in area 5 were investigated during 49 penetrations into the superior parietal lobule of 3 monkeys. A significant variation of cell discharge with the direction of movement was observed in 182 of 212 cells that were related to arm movements. In 151/182 of these cells the frequency of discharge was highest during movements in a preferred direction, and decreased in an orderly fashion with movements made in directions farther and farther away from the preferred one; in 112/151 cells this variation in discharge was a sinusoidal function of the direction of movement. Preferred directions differed for different cells so that directional tuning curves overlapped partially. These results are similar to those described for cells in the motor cortex (Georgopoulos et al. 1982): this suggests that directional information may be processed in a similar way in these structures.

Many cells in area 5 changed activity before the onset of movement, and several did so before the earliest electromyographic changes (63% and 35%, respectively, of the cells that showed an increase in activity with movements in the preferred direction). However, the distribution of onset times of the parietal cells lagged the corresponding one of the motor cortical cells by about 60 ms. This suggests that the early changes observed in the parietal cortex might represent a corollary discharge from the pre-central motor fields, whereas later activity might reflect peripheral as well as central events.

Key words

Parietal Motor Cortex Direction Movement 

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Copyright information

© Springer-Verlag 1983

Authors and Affiliations

  • J. F. Kalaska
    • 1
  • R. Caminiti
    • 1
  • A. P. Georgopoulos
    • 1
  1. 1.The Philip Bard Laboratories of Neurophysiology, Department of Neuroscience, and Department of PhysiologyThe Johns Hopkins University, School of MedicineBaltimoreUSA

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