Background: The principle of gain control determines the efficiency of neuronal processing and can be enhanced with pharmacological or brain stimulation methods. It is a key factor for cognitive control, but the degree of how much gain control may be enhanced underlies a physical limit.
Methods: To investigate whether MPH and tDCS share common underlying mechanisms and cognitive effects, we administered methylphenidate (MPH) and anodal tDCS (atDCS) over the right inferior frontal gyrus both separately and combined, while healthy adult participants (N=104) a performed response selection and inhibition task. The recorded EEG data were analyzed with a focus on theta band activity and source estimation analyses were conducted.
Results: The behavioral data show that MPH and atDCS revealed interactive effects on the ability to inhibit responses. Both MPH and atDCS modulated task-related theta oscillations in the supplementary motor area (SMA) when applied separately, making a common underlying mechanism likely. When both stimulation methods were combined, there was no doubling of effects in the SMA, but a shift to inferior frontal areas in the cortical network responsible for theta-driven processing.
Conclusions: The results indicate that both MPH and atDCS likely share a common underlying neuronal mechanism, and interestingly, they demonstrate interactive effects when combined, which are most likely due to the physical limitations of gain control increases. The current study provides critical groundwork for future combined applications of MPH and non-invasive brain stimulation.
Keywords: anodal tDCS; beamforming; gain control; methylphenidate; θ-oscillations.
© The Author(s) 2024. Published by Oxford University Press on behalf of CINP.