Cortical Control of a Whisking Central Pattern Generator

doi:10.1152/jn.00071.2006

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J Neurophysiol (April 26, 2006). doi:10.1152/jn.00071.2006

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Submitted on January 20, 2006
Accepted on April 13, 2006

Cortical Control of a Whisking Central Pattern Generator

Nathan P Cramer¹ and Asaf Keller¹^*

¹ Program in Neuroscience and the Department of Anatomy and Neurobiology, University of Maryland School of Medicine, Baltimore, Maryland, United States

^* To whom correspondence should be addressed. E-mail: akeller{at}umaryland.edu.

Whether the motor cortex regulates voluntary movements by generatingthe motor pattern directly, or by acting through subcorticalcentral pattern generators (CPGs) remains a central questionin motor control. Using the rat whisker system, an importantmodel system of mammalian motor control, we develop an anesthetizedpreparation to investigate the interaction between the motorcortex and a whisking CPG. Using this model we investigate theinvolvement of a serotonergic component of the whisking CPGin determining whisking kinematics, and the mechanisms throughwhich drive from the CPG is converted into movements by vibrissamotor units. Consistent with an action of the vibrissa motorcortex (vMCx) on a subcortical CPG, the frequency of whiskingevoked by intracortical microstimulation (ICMS) of vMCx differedsignificantly from the stimulation frequency, while whiskingonset latencies correlated negatively with stimulation intensity.Further, ICMS-evoked whisking was suppressed by a serotoninreceptor antagonist, supporting previous findings that the whiskingCPG contains a significant serotonergic component. The amplitudeof ICMS-evoked whisking was correlated with the number of activemotor units - isolated from vibrissal EMGs or recorded directlyfrom vibrissa motoneurons - and their activity level. In addition,whisking frequency was correlated with the firing rate of thesemotoneurons. These findings support the hypothesis that vMCxregulates whisking through its actions on a subcortical CPG.

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