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The Journal of Neurophysiology Vol. 82 No. 4 October 1999, pp. 1832-1842
Copyright ©1999 by the American Physiological Society
Department of Anatomy and Neurobiology, University of Tennessee, Memphis, Tennessee 38163
Lebedev, M. A. and
R. J. Nelson.
Rhythmically Firing Neostriatal Neurons in Monkey: Activity
Patterns During Reaction-Time Hand Movements. J. Neurophysiol. 82: 1832-1842, 1999. While previous studies
have identified rhythmically firing neurons (RFNs) in monkey
neostriatum and these rhythmic firing patterns have been shown to
evolve in neostriatal tonically active neurons (TANs) after dopamine
input depletion, the activity patterns of RFNs during motor behavior
are still far from completely understood. We examined the single-unit
activity patterns of neostriatal neurons, recorded in awake behaving
monkeys during a wrist movement task, for evidence of rhythmic
activity. Monkeys made ballistic wrist flexion and extension movements
in response to vibrotactile cues. Animals held a steady wrist position
for 0.5 to 2.0 s while awaiting the onset of the go-cues (hold
period). Although the majority of neostriatal neurons (274/306) did not
fire rhythmically, approximately 10% of the neurons (32/306) fired
rhythmically at 10-50 Hz during the hold period. Most RFNs (28/32)
showed significant activity changes during the time between go-cue
presentation and movement onset (premovement activity). One-half of
RFNs exhibited premovement activity that differed as a function of
movement direction. Only one RFN may have responded to the delivery of
a fruit juice reward. Neuronal firing was analyzed using interspike
interval distributions, autocorrelations, and serial correlation
techniques. These analyses showed that the activity patterns of most
RFNs were consistent with an integrate-and-fire model of neuronal
rhythm generation. Changes in RFN activity patterns during the
premovement interval and intertrial variations in firing frequency
could be explained by changes in the general level of excitatory input.
These observations are consistent with the firing properties reported
for neostriatal cholinergic interneurons. It has been suggested that
tonically active neurons may be cholinergic interneurons and that these neurons show changes in activity related to specific aspects of behavioral paradigms, such as rewards. RFNs may constitute a special class of TANs. The results presented here suggest that RFNs may have a
role in movement initiation. We speculate that RFNs may modulate the
propagation of cortical oscillations via basal
ganglia-thalamic-cortical loops.
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