Control of Locomotor Cycle Durations

doi:10.1152/jn.00991.2004

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Control of Locomotor Cycle Durations

S. Yakovenko¹, D. A. McCrea², K. Stecina² and A. Prochazka³

¹Department of Physiology, Universite de Montreal, Montreal, Quebec; ²Department of Physiology, University of Manitoba, Winnipeg, Manitoba; and ³Centre for Neuroscience, University of Alberta, Edmonton Alberta, Canada

Submitted 21 September 2004; accepted in final form 6 March 2005

In intact animals and humans, increases in locomotor speed areusually associated with decreases in step cycle duration. Mostdata indicate that the locomotor central pattern generator (CPG)shortens cycle duration mainly by shortening the durations ofextensor rather than flexor phases of the step cycle. Here wereport that in fictive locomotion elicited by electrical stimulationof the midbrain locomotor region (MLR) in the cat, spontaneousvariations in cycle duration were due more to changes in flexorrather than extensor phase durations in 22 of 31 experiments.The locomotor CPG is therefore not inherently extensor- or flexor-biased.We coined the term "dominant" to designate the phase (flexionor extension) showing the larger variation. In a simple half-centeroscillator model, experimental phase duration plots were fittedwell by adjusting two parameters that corresponded to backgrounddrive ("bias") and sensitivity ("gain") of the oscillator'stiming elements. By analogy we argue that variations in backgrounddrive to the neural timing elements of the CPG could producelarger variations in phase duration in the half-center receivingthe lower background drive, i.e., background drive may determinewhich half-center is dominant. The fact that data from normalcats were also fitted well by the model indicates that sensoryinput and central drive combine to determine locomotor phasedurations. We conclude that there is a considerable flexibilityin the control of phase durations in MLR-induced fictive locomotion.We posit that this may be explained by changes in backgroundexcitation of neural timing elements in the locomotor CPG.

Address for reprint requests and other correspondence: A. Prochazka, Centre for Neuroscience, 507 HMRC, University of Alberta, Edmonton, Alberta T6G 2S2, Canada (E-mail: arthur.prochazka{at}ualberta.ca)

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