Characteristic membrane potential trajectories in primate sensorimotor cortex neurons recorded in vivo

doi:10.1152/jn.00024.2005

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J Neurophysiol (June 29, 2005). doi:10.1152/jn.00024.2005

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Submitted on January 10, 2005
Accepted on June 26, 2005

Characteristic membrane potential trajectories in primate sensorimotor cortex neurons recorded in vivo

Daofen Chen¹^* and Eberhard E. Fetz¹

¹ Physiology and Biophysics, University of Washington, Seattle, WA, USA

^* To whom correspondence should be addressed. E-mail: daofen.chen{at}nih.gov.

We examined the membrane potentials and firing properties ofmotor cortical neurons recorded intracellularly in awake, behavingprimates. Three classes of neuron were distinguished by (a)the width of their spikes, (b) the shape of the afterhyperpolarization(AHP), and (c) the distribution of interspike intervals. TypeI neurons had wide spikes, exhibited scoop-shaped AHPs, andfired irregularly. Type II neurons had narrower spikes, showedbrief postspike afterdepolarizations prior to the AHP, and sometimesfired high-frequency doublets. Type III neurons had the narrowestspikes, showed a distinct post-AHP depolarization, or "reboundAHP" (rAHP) lasting ~30 ms, and tended to fire at 25-35 Hz. The evidence suggests that an intrinsic rAHP may confer onthese neurons a tendency to fire at a preferred frequency governedby the duration of the rAHP and may contribute to a "pacemaking"role in generating cortical oscillations.

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