Neuroscience
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Randomized Controlled Trial
Fronto-Parietal Brain Areas Contribute to the Online Control of Posture during a Continuous Balance Task.
Neuroimaging studies have provided evidence for the involvement of frontal and parietal cortices in postural control. However, the specific role of these brain areas for postural control remains to be known. Here, we investigated the effects of disruptive transcranial magnetic stimulation (TMS) over supplementary motor areas (SMA) during challenging continuous balance task in healthy young adults. ⋯ Importantly, cTBS over SMA compared to sham stimulation altered EEG power within the identified fronto-parietal regions. These findings suggest that the changes in activation within distant fronto-parietal brain areas following cTBS over SMA contributed to the altered postural behavior. Our study confirms a critical role of AC, CG, and both PPC regions in calibrating online postural responses during a challenging continuous balance task.
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Randomized Controlled Trial
Effects of Transcranial Static Magnetic Stimulation on Motor Cortex Evaluated by Different TMS Waveforms and Current Directions.
Transcranial static magnetic stimulation (tSMS) modulates cortical excitability probably by interacting with the GABA-glutamate intracortical balance. Different transcranial magnetic stimulation (TMS) waveforms probe distinct GABA-mediated cortical inhibition networks. The goal of the present work is to further characterize tSMS-induced changes in motor cortex reactivity and inhibition-excitation (I/E) balance. ⋯ MEP amplitude increased compared to sham with monoAP TMS, with no clear changes in general intracortical I/E balance. Biphasic TMS was not able to capture any effects of tSMS. The results show that the effects of tSMS on cortical excitability and inhibition involve specific interneuron circuits that are selectively activated by monoPA TMS.
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Randomized Controlled Trial
Acute Exercise at Different Intensities Influences Corticomotor Excitability and Performance of a Ballistic Thumb Training Task.
The response to motor training is improved when preceded by a bout of aerobic exercise. However, the effect of exercise at different intensities on motor performance is not well understood. The aim of the current study was therefore to compare the neurophysiological and functional response to training with a ballistic abduction task following a single 30-min bout of low intensity continuous cycling exercise, high-intensity interval cycling exercise, or rest. ⋯ Finally, low-intensity exercise resulted in improved ballistic motor performance on both days. Our findings provide some evidence to suggest that low-intensity aerobic cycling is beneficial for performance during subsequent ballistic training. Furthermore, the effects of exercise intensity on motor training may depend on the type of task performed.