Decoding M1 Neurons During Multiple Finger Movements

doi:10.1152/jn.00760.2006

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J Neurophysiol 98: 327-333, 2007. First published April 11, 2007; doi:10.1152/jn.00760.2006
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Decoding M1 Neurons During Multiple Finger Movements

S. Ben Hamed¹, M. H. Schieber¹^,2 and A. Pouget¹

¹Department of Brain and Cognitive Science and the Center for Visual Science, University of Rochester; and ²Departments of Neurology and Neurobiology, University of Rochester, School of Medicine and Dentistry, Rochester, New York

Submitted 21 July 2006; accepted in final form 5 April 2007

We tested several techniques for decoding the activity of primarymotor cortex (M1) neurons during movements of single fingersor pairs of fingers. We report that single finger movementscan be decoded with >99% accuracy using as few as 30 neuronsrandomly selected from populations of task-related neurons recordedfrom the M1 hand representation. This number was reduced to20 neurons or less when the neurons were not picked randomlybut selected on the basis of their information content. We extendedtechniques for decoding single finger movements to the problemof decoding the simultaneous movement of two fingers. Movementsof pairs of fingers were decoded with 90.9% accuracy from 100neurons. The techniques we used to obtain these results canbe applied, not only to movements of single fingers and pairsof fingers as reported here, but also to movements of arbitrarycombinations of fingers. The remarkably small number of neuronsneeded to decode a relatively large repertoire of movementsinvolving either one or two effectors is encouraging for thedevelopment of neural prosthetics that will control hand movements.

Address for reprint requests and other correspondence: A. Pouget, Brain and Cognitive Science Dept., Meliora Hall, Univ. of Rochester, Rochester, NY 14627 (E-mail: alex{at}bcs.rochester.edu)

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