The functional role of the cerebellum in voluntary movement was invest
igated by local cooling of the cerebellar nuclei in three Japanese mon
keys which performed hand movement tasks in response to visual stimuli
. We implanted electrodes in various areas of the cerebral hemispheres
to record field potentials in the cortex, and examined effects of the
cooling upon the movement and field potentials. Cooling of the dentat
e nucleus ipsilateral to the moving hand reversibly increased the reac
tion time and reduced the size of surface-negative, depth-positive (s-
N, d-P) field potential in the motor cortex contralateral to the hand.
The potential preceded the movement by an almost constant time of abo
ut 100 ms in the normal condition. The cooling remarkably prolonged an
d deviated the time. By shifting the cooling probe to different distan
ces from the nucleus, we noted various decreases of the cooling effect
. We also found a close correlation between the size of the s-N, d-P p
otential and the reaction time, i.e., when the potential was small, th
e reaction time was long. These findings support the following ideas;
the motor command for this task comes to the motor cortex through the
cerebello-thalamo-cortical pathway which includes the dentate nucleus,
and produces the s-N, d-P potential as EPSP currents in pyramidal neu
rons in the motor cortex. We also studied self-paced movement task. In
some cases, the cooling reduced the size of readiness potential in th
e motor cortex.