Open Research Europe (Jul 2022)

Local brain-state dependency of effective connectivity: a pilot TMS–EEG study [version 2; peer review: 2 approved]

  • Matteo Fecchio,
  • Victor H. Souza,
  • Pantelis Lioumis,
  • Mario Rosanova,
  • Risto J. Ilmoniemi,
  • Tuomas P. Mutanen,
  • Ida Granö,
  • Jaakko O. Nieminen,
  • Aino Tervo

Journal volume & issue
Vol. 2

Abstract

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Background Spontaneous cortical oscillations have been shown to modulate cortical responses to transcranial magnetic stimulation (TMS). However, whether these oscillations influence cortical effective connectivity is largely unknown. We conducted a pilot study to set the basis for addressing how spontaneous oscillations affect cortical effective connectivity measured through TMS-evoked potentials (TEPs). Methods We applied TMS to the left primary motor cortex and right pre-supplementary motor area of three subjects while recording EEG. We classified trials off-line into positive- and negative-phase classes according to the mu and beta rhythms. We calculated differences in the global mean-field amplitude (GMFA) and compared the cortical spreading of the TMS-evoked activity between the two classes. Results Phase affected the GMFA in four out of 12 datasets (3 subjects × 2 stimulation sites × 2 frequency bands). Two of the observed significant intervals were before 50 ms, two between 50 and 100 ms, and one after 100 ms post-stimulus. Source estimates showed complex spatial differences between the classes in the cortical spreading of the TMS-evoked activity. Conclusions TMS-evoked effective connectivity seems to depend on the phase of local cortical oscillations at the stimulated site. This work paves the way to design future closed-loop stimulation paradigms.

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