Abstract
ObjectiveThe impact of transcranial magnetic stimulation (TMS) has been shown to depend on the initial brain state of the stimulated cortical region. This observation has led to the development of paradigms that aim to enhance the specificity of TMS effects by using visual/luminance adaptation to modulate brain state prior to the application of TMS. However, the neural basis of interactions between TMS and adaptation is unknown. Here, we examined these interactions by using electroencephalography (EEG) to measure the impact of TMS over the visual cortex after luminance adaptation. MethodsSingle-pulses of neuronavigated TMS (nTMS) were applied at two different intensities over the left visual cortex after adaptation to either high or low luminance. We then analyzed the effects of adaptation on the global and local cortical excitability. ResultsThe analysis revealed a significant interaction between the TMS-evoked responses and the adaptation condition. In particular, when nTMS was applied with high intensity, the evoked responses were larger after adaptation to high than low luminance. ConclusionThis result provides the first neural evidence on the interaction between TMS with visual adaptation. SignificanceTMS can activate neurons differentially as a function of their adaptation state.
Highlights
The effects of transcranial magnetic stimulation (TMS) are modulated by the initial activation state of the stimulated region
The 2-way ANOVA analyses conducted on the individual global mean field power (GMFP) for the low and high TMS conditions revealed a main effect of adaptation in the global cortical excitability for low TMS intensity (F (1,6) = 7.98; p = 0. 030) but not for high intensity (F (1,10) = 0.718; p = 0.417)
The same results were obtained for the GMFP for the same 7 participants who completed both TMS conditions
Summary
The effects of transcranial magnetic stimulation (TMS) are modulated by the initial activation state of the stimulated region (statedependency). Suppression or facilitation of neural activity with transcranial direct current stimulation (tDCS) in the. TMS-evoked potentials (TEPs) depend on the state of neuronal activity in the stimulated area in the motor cortex and change in relation to preparation and execution of unilateral motor action (e.g., (Nikulin et al, 2003; Kicicet al., 2008)) with high reproducibility and sensitivity of TEPs (Lioumis et al, 2009; Casarotto et al, 2010; Kerwin et al, 2018).
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