Evaluation of the effects of transcranial magnetic stimulation coil orientation on motor evoked potentials of abductor pollicis brevis by high density electromyography

Transcranial magnetic stimulation (TMS) pulses with different coil orientations causes changes in amplitudes and latencies of motor evoked potentials (MEP) in muscles of the hand. Nonetheless, the properties of MEP are also affected by the systems of detection, e.g. placement and size of acquisition electrodes; and by the target muscle anatomy, e.g. architecture of fat and muscles tissues. In this study, we assessed the effect of TMS coil orientation on MEP spatial distribution, peak-to-peak amplitude, latency, conduction velocity of muscle fiber and median frequency, from the abductor pollicis brevis (APB) muscle. A grid of electrodes (13 lines and 5 columns) was used to detect the surface electromyography (sEMG) signals from the APB at eight different TMS coil orientations in respect to the midsagital line, connecting the inium and nasium. Two distinct approaches were adopted to compare the amplitude according to the coil orientation: first, we calculated the mean amplitude of MEP in the electrodes of the matrix over an active region of the muscle. Second, we extracted the amplitude of MEP in a single differential signal from two groups of matrix electrodes simulating a conventional sEMG bipolar configuration, commonly used in TMS experiments. In both cases, the maximum MEP amplitudes were induced at coil orientations of 45° and 90°, confirming the past findings in literature. However, we could not identify significant differences in latency, median frequency and conduction velocity of MEP according to different stimulus orientation. Maps of spatial distribution showed a localized muscle activity at the distal portion of the APB muscle for all the coil orientations, indicating that conventional bipolar sEMG electrodes may not be rightly placed over the active portion of the muscle recruited by TMS. Finally, we considered that a neuronavigation system could facilitate the localization of brain internal structures to apply TMS stimulus and improve the accuracy of coil handling and positioning over the stimulation point. Thereafter, we developed a computational tool to the InVesalius Navigator, to track the TMS coil position and orientation in respect to the subjects midsagital line to be used in future experiments. (AU)