Attention drives synchronization of alpha and beta rhythms between right inferior frontal and primary sensory neocortex

Sacchet, Matthew D.; LaPlante, Roan A.; Wan, Qian; Pritchett, Dominique L.; Lee, Adrian K. C.; Hämäläinen, Matti; Moore, Christopher I.; Kerr, Catherine E.; Jones, Stephanie R.

doi:10.1523/JNEUROSCI.1292-14.2015

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Attention drives synchronization of alpha and beta rhythms between right inferior frontal and primary sensory neocortex
Citation	Sacchet MD, LaPlante RA, Wan Q, Pritchett DL, Lee AK, Hämäläinen M, Moore CI, Kerr CE, Jones SR. J. Neurosci. 2015; 35(5): 2074-2082.
Affiliation	Athinoula A. Martinos Center For Biomedical Imaging, Massachusetts General Hospital, Charlestown, Massachusetts, 02129, Department of Neuroscience and Brown Institute for Brain Sciences, Brown University, Providence, Rhode Island, 02912, and Stephanie_Jones@brown.edu.
Copyright	(Copyright © 2015, Society for Neuroscience)
DOI	10.1523/JNEUROSCI.1292-14.2015
PMID	25653364
Abstract	The right inferior frontal cortex (rIFC) is specifically associated with attentional control via the inhibition of behaviorally irrelevant stimuli and motor responses. Similarly, recent evidence has shown that alpha (7-14 Hz) and beta (15-29 Hz) oscillations in primary sensory neocortical areas are enhanced in the representation of non-attended stimuli, leading to the hypothesis that allocation of these rhythms plays an active role in optimal inattention. Here, we tested the hypothesis that selective synchronization between rIFC and primary sensory neocortex occurs in these frequency bands during inattention. We used magnetoencephalography to investigate phase synchrony between primary somatosensory (SI) and rIFC regions during a cued-attention tactile detection task that required suppression of response to uncertain distractor stimuli. Attentional modulation of synchrony between SI and rIFC was found in both the alpha and beta frequency bands. This synchrony manifested as an increase in the alpha-band early after cue between non-attended SI representations and rIFC, and as a subsequent increase in beta-band synchrony closer to stimulus processing. Differences in phase synchrony were not found in several proximal control regions. These results are the first to reveal distinct interactions between primary sensory cortex and rIFC in humans and suggest that synchrony between rIFC and primary sensory representations plays a role in the inhibition of irrelevant sensory stimuli and motor responses. Language: en