Marco Fuscà scite author profile

Transcranial alternating current stimulation (tACS) is used to modulate brain oscillations to measure changes in cognitive function. It is only since recently that brain activity in human subjects during tACS can be investigated. The present study aims to investigate the phase relationship between the external tACS signal and concurrent brain activity. Subjects were stimulated with tACS at individual alpha frequency during eyes open and eyes closed resting states. Electrodes were placed at Cz and Oz, which should affect parieto-occipital areas most strongly. Source space magnetoencephalography (MEG) data were used to estimate phase coherence between tACS and brain activity. Phase coherence was significantly increased in areas in the occipital pole in eyes open resting state only. The lag between tACS and brain responses showed considerable inter-individual variability. In conclusion, tACS at individual alpha frequency entrains brain activity in visual cortices. Interestingly, this effect is state dependent and is clearly observed with eyes open but only to a lesser extent with eyes closed.

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Friends, not foes: Magnetoencephalography as a tool to uncover brain dynamics during transcranial alternating current stimulation

Neuling

et al. 2015

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Brain oscillations are supposedly crucial for normal cognitive functioning and alterations are associated with cognitive dysfunctions. To demonstrate their causal role on behavior, entrainment approaches in particular aim at driving endogenous oscillations via rhythmic stimulation. Within this context, transcranial electrical stimulation, especially transcranial alternating current stimulation (tACS), has received renewed attention. This is likely due to the possibility of defining oscillatory stimulation properties precisely. Also, measurements comparing pre-tACS with post-tACS electroencephalography (EEG) have shown impressive modulations. However, the period during tACS has remained a blackbox until now, due to the enormous stimulation artifact. By means of application of beamforming to magnetoencephalography (MEG) data, we successfully recovered modulations of the amplitude of brain oscillations during weak and strong tACS. Additionally, we demonstrate that also evoked responses to visual and auditory stimuli can be recovered during tACS. The main contribution of the present study is to provide critical evidence that during ongoing tACS, subtle modulations of oscillatory brain activity can be reconstructed even at the stimulation frequency. Future tACS experiments will be able to deliver direct physiological insights in order to further the understanding of the contribution of brain oscillations to cognition and behavior.

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Decoding across sensory modalities reveals common supramodal signatures of conscious perception

Sanchez

Hartmann

Fuscà

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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This PDF file includes:Figs. S1 to S4 Tables S1 to S2 Fig. S1. Initial experiment. Catch and Sham trials event-related responses for different sensory modalities: auditory (left panel), tactile (middle panel) and visual (right panel). (A) Group eventrelated average of all brain sources absolute value average activity (solid line) and standard error of the mean (shaded area) for catch trials (red) and sham trials (blue) condition. Significant time windows are marked with bottom solid lines (black line: pBonferroni-corrected < 0.05) for the contrast catch vs. sham trials. The relative source localization maps are represented in part B for the average time period. (B) Significant source activity of the average time period marked in part A for the contrast catch vs. sham trials, masked at pcluster-corrected < 0.05.

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Brain criticality predicts individual synchronization levels in humans

Fuscà

Siebenhühner

Wang

et al. 2022

Preprint

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Moderate levels of synchronization of neuronal oscillations are essential for healthy brain dynamics. Synchronization levels exhibit large inter-individual variability the origins of which are unknown. Neuronal systems have been postulated to operate near a critical transition point or in an extended regime between disorder (subcritical) and order (supercritical phase) characterized by moderate synchronization and emergent power-law long-range temporal correlations (LRTCs). We investigated whether inter-individual variability in synchronization levels is explained by the individual position along the critical regime by analyzing magnetoencephalography (MEG) and intra-cerebral stereo-electroencephalography (SEEG) human resting-state data. Here we show that variability in synchronization levels exhibits a positive linear and quadratic relationships with LRTCs in healthy participants and brain areas. In the epileptogenic zone this correlation was negative. These results show that variability in synchronization levels is regulated by the individual position along an extended critical-like regime, with healthy brain areas tending to operate in its subcritical and epileptogenic areas in its supercritical side.

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Marco Fuscà

Eyes wide shut: Transcranial alternating current stimulation drives alpha rhythm in a state dependent manner

Friends, not foes: Magnetoencephalography as a tool to uncover brain dynamics during transcranial alternating current stimulation

Decoding across sensory modalities reveals common supramodal signatures of conscious perception

Brain criticality predicts individual synchronization levels in humans

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