Objective: Communication-through-coherence proposes that the phase synchronization (PS) of neural oscillations between cortical areas supports neural communication. In this study, we exploited transcranial magnetic stimulation (TMS)-evoked potentials (TEPs) to test this hypothesis at the macroscale level, i.e., whether PS between cortical areas supports interarea communication. TEPs are electroencephalographic (EEG) responses time-locked to TMS pulses reflecting interarea communication, as they are generated by the transmission of neural activity from the stimulated area to connected regions. If interarea PS is important for communication, it should be associated with the TEP amplitude in the connected areas. Methods: TMS was delivered over the left primary motor cortex (M1) of fourteen healthy volunteers, and 70-channel EEG was recorded. Early TEP components were source-localized to identify their generators, i.e., distant brain regions activated by M1 through effective connections. Next, linear regressions were used to test the relationship between the TEP amplitude and the pre-stimulus PS between the M1 and the connected regions in four frequency bands (range 4–45 Hz). Results: Pre-stimulus interarea PS in the alpha-band was positively associated with the amplitude of early TEP components, namely, the N15 (ipsilateral supplementary motor area), P25 (contralateral M1) and P60 (ipsilateral parietal cortex). Conclusions: Alpha-band PS predicts the response amplitude of the distant brain regions effectively connected to M1. Significance: Our study supports the role of EEG-PS in interarea communication, as theorized by communication-through-coherence.
Alpha-band cortico-cortical phase synchronization is associated with effective connectivity in the motor network / Zazio, A.; Miniussi, C.; Bortoletto, M.. - In: CLINICAL NEUROPHYSIOLOGY. - ISSN 1388-2457. - ELETTRONICO. - 132:10(2021), pp. 2473-2480. [10.1016/j.clinph.2021.06.025]
Alpha-band cortico-cortical phase synchronization is associated with effective connectivity in the motor network
Miniussi C.;Bortoletto M.
2021-01-01
Abstract
Objective: Communication-through-coherence proposes that the phase synchronization (PS) of neural oscillations between cortical areas supports neural communication. In this study, we exploited transcranial magnetic stimulation (TMS)-evoked potentials (TEPs) to test this hypothesis at the macroscale level, i.e., whether PS between cortical areas supports interarea communication. TEPs are electroencephalographic (EEG) responses time-locked to TMS pulses reflecting interarea communication, as they are generated by the transmission of neural activity from the stimulated area to connected regions. If interarea PS is important for communication, it should be associated with the TEP amplitude in the connected areas. Methods: TMS was delivered over the left primary motor cortex (M1) of fourteen healthy volunteers, and 70-channel EEG was recorded. Early TEP components were source-localized to identify their generators, i.e., distant brain regions activated by M1 through effective connections. Next, linear regressions were used to test the relationship between the TEP amplitude and the pre-stimulus PS between the M1 and the connected regions in four frequency bands (range 4–45 Hz). Results: Pre-stimulus interarea PS in the alpha-band was positively associated with the amplitude of early TEP components, namely, the N15 (ipsilateral supplementary motor area), P25 (contralateral M1) and P60 (ipsilateral parietal cortex). Conclusions: Alpha-band PS predicts the response amplitude of the distant brain regions effectively connected to M1. Significance: Our study supports the role of EEG-PS in interarea communication, as theorized by communication-through-coherence.File | Dimensione | Formato | |
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