Origin of Facilitation of Motor-Evoked Potentials After Paired Magnetic Stimulation: Direct Recording of Epidural Activity in Conscious Humans

doi:10.1152/jn.00360.2006

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Origin of Facilitation of Motor-Evoked Potentials After Paired Magnetic Stimulation: Direct Recording of Epidural Activity in Conscious Humans

V. Di Lazzaro¹, F. Pilato¹, A. Oliviero¹^,2, M. Dileone¹, E. Saturno¹, P. Mazzone³, A. Insola⁴, P. Profice¹, F. Ranieri¹, F. Capone¹, P. A. Tonali¹^,5 and J. C. Rothwell⁶

¹Institute of Neurology, Università Cattolica, Rome, Italy; ²Unidad de Neurologia Funcional, Hospital Nacional de Paraplejicos, Finca la Peraleda, Toledo, Spain; ³Neurochirurgia CTO, and ⁴Neurofisiologia CTO, and ⁵Fondazione Don C Gnocchi, Rome, Italy; and ⁶Sobell Department of Neurophysiology, Institute of Neurology and The National Hospital for Neurology and Neurosurgery, London, United Kingdom

Submitted 6 April 2006; accepted in final form 22 May 2006

A magnetic transcranial conditioning stimulus given over themotor cortex at intensities below active threshold for obtainingmotor-evoked potentials (MEPs) facilitates EMG responses evokedat rest in hand muscles by a suprathreshold magnetic stimulusgiven 10–25 ms later. This is known as intracortical facilitation(ICF). We recorded descending volleys produced by single andpaired magnetic motor cortex stimulation through high cervicalepidural electrodes implanted for pain relief in six consciouspatients. At interstimulus intervals (ISIs) of 10 and 15 ms,although MEP was facilitated, there was no change in the amplitudeor number of descending volleys. An additional I wave sometimeswas observed at 25 ms ISI. In one subject, we also evaluatedthe effects of reversing the direction of the induced currentin the brain. At 10 ms ISI, the facilitation of the MEPs disappearedand was replaced by slight suppression; at 2 ms ISI, there wasa pronounced facilitation of epidural volleys. Subsequent experimentson healthy subjects showed that a conditioning stimulus capableof producing ICF of MEPs had no effect on the EMG response evokedby transmastoidal electrical stimulation of corticospinal tract.We conclude that ICF occurs because either 1) the conditioningstimulus has a (thus far undetected) effect on spinal cord excitabilitythat increases its response to the same amplitude test volleyor 2) that it can alter the composition (but not the amplitude)of the descending volleys set up by the test stimulus such thata larger proportion of the activity is destined for the targetmuscle.

Address for reprint requests and other correspondence: V. Di Lazzaro, Inst. of Neurology, Univ. Cattolica, L.go A. Gemelli 8, 00168 Rome, Italy (E-mail: vdilazzaro{at}rm.unicatt.it)

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