Grandjean, Julien
[UCL]
Derosiere, Gerard
[UCL]
Vassiliadis, Pierre
[UCL]
Quemener, Louise
Wilde, Ysaline de
Duque, Julie
[UCL]
For several decades, Transcranial magnetic stimulation (TMS) has been used to monitor corticospinal excitability (CSE) changes in various contexts. Habitually, single-coil TMS is applied over one primary motor cortex (M1), eliciting motor-evoked potentials (MEPs) in a contralateral limb muscle, usually a hand effector. However, in many situations, it would be useful to obtain MEPs in both hands simultaneously, to track CSE bilaterally. Such an approach requires stimulating both M1 concurrently while avoiding interference between the two descending stimuli. We examined MEPs obtained at rest using a double-coil TMS approach where the two M1 are stimulated with a 1ms inter-pulse interval (double-coil1ms). MEPs were acquired using double-coil1ms (MEPdouble) or single-coil (MEPsingle) TMS, at five different intensities of stimulation (100, 115, 130, 145 or 160% of the resting motor threshold, rMT). Given the 1ms inter-pulse interval in double-coil1ms trials, MEPdouble were either evoked by a 1st (MEPdouble-1) or a 2nd (MEPdouble-2) TMS pulse. All MEPTYPE (MEPTYPE=MEPsingle, MEPdouble-1 and MEPdouble-2) were equivalent, regardless of the hand within which they were elicited, the intensity of stimulation or the pulse order. This method allows one to observe state-related CSE changes for the two hands simultaneously on a trial-by-trial basis. These results infer the absence of any neural interactions between the two cortico-spinal volleys with double-coil1ms TMS. Hence, this technique can be reliably used to assess CSE bilaterally, opening new research perspectives for scientists interested in physiological markers of activity in the motor output system.
Bibliographic reference |
Grandjean, Julien ; Derosiere, Gerard ; Vassiliadis, Pierre ; Quemener, Louise ; Wilde, Ysaline de ; et. al. Towards assessing corticospinal excitability bilaterally: Validation of a double-coil TMS method.. In: Journal of Neuroscience Methods, Vol. 293, p. 162-168 (2018) |
Permanent URL |
http://hdl.handle.net/2078.1/192881 |