Increases in Corticospinal Tract Function by Treadmill Training After Incomplete Spinal Cord Injury

doi:10.1152/jn.00532.2005

Increases in Corticospinal Tract Function by Treadmill Training After Incomplete Spinal Cord Injury

Sarah L. Thomas and Monica A. Gorassini

Department of Biomedical Engineering, Centre for Neuroscience, Faculty of Medicine and Dentistry, University of Alberta, Edmonton, Alberta, Canada

Submitted 23 May 2005; accepted in final form 1 July 2005

In this study, we examined if several months of intensive locomotortraining increases the function of spared corticospinal tractpathways after chronic spinal cord injury (SCI) in associationwith the recovery of locomotor function. Transcranial magneticstimulation (TMS) at incrementing levels of intensity was appliedover the motor cortex supplying either the tibialis anterioror vastus lateralis muscles, and the resulting peak-to-peakamplitude of the motor-evoked potentials (MEPs) were measuredto obtain a recruitment curve both before and after training.In the majority of subjects (7/8), 3–5 mo of daily intensivetraining increased the responses to TMS in at least one of theleg muscles tested (9/13). On average, across all muscles testedMEP_max, which was evoked at high stimulation intensities, increasedby 46% and MEP_h, which was evoked at intermediate stimulationintensities, increased by 45% (both significantly differentfrom 0), indicating an increase in corticospinal tract connectivityfrom training. The slope of the sigmoid function fit to therecruitment curve increased by 24% after training (significantlydifferent), indicating an expansion and/or increased excitabilityof corticospinal circuits supplying muscles to the lower leg.We also observed that the average duration of the silent periodmeasured at MEP_max increased after training from 130 to 178ms, suggesting that training had effects on cortical circuitsthought to mediate this long-lasting inhibition. The percentageincrease in MEP_max was positively and significantly correlatedto the degree of locomotor recovery as assessed by the WISCIII score, the distance a subject could walk in 6 min, and theamplitude of the locomotor EMG activity, suggesting that thecorticospinal tract, in part, mediated the functional locomotorrecovery produced from training.

Address for reprint requests and other correspondence: M. Gorassini, Centre for Neuroscience, 513 HMRC, University of Alberta, Edmonton, Alberta T6G 2S2, Canada (E-mail: monica.gorassini{at}ualberta.ca)

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