Dynamic large-scale connectivity of intrinsic cortical oscillations supports adaptive listening in challenging conditions

Alavash, Mohsen and Tune, Sarah and Obleser, Jonas and Bizley, Jennifer K. (2021) Dynamic large-scale connectivity of intrinsic cortical oscillations supports adaptive listening in challenging conditions. PLOS Biology, 19 (10). e3001410. ISSN 1545-7885

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Abstract

In multi-talker situations, individuals adapt behaviorally to this listening challenge mostly with ease, but how do brain neural networks shape this adaptation? We here establish a long-sought link between large-scale neural communications in electrophysiology and behavioral success in the control of attention in difficult listening situations. In an age-varying sample of N = 154 individuals, we find that connectivity between intrinsic neural oscillations extracted from source-reconstructed electroencephalography is regulated according to the listener’s goal during a challenging dual-talker task. These dynamics occur as spatially organized modulations in power-envelope correlations of alpha and low-beta neural oscillations during approximately 2-s intervals most critical for listening behavior relative to resting-state baseline. First, left frontoparietal low-beta connectivity (16 to 24 Hz) increased during anticipation and processing of a spatial-attention cue before speech presentation. Second, posterior alpha connectivity (7 to 11 Hz) decreased during comprehension of competing speech, particularly around target-word presentation. Connectivity dynamics of these networks were predictive of individual differences in the speed and accuracy of target-word identification, respectively, but proved unconfounded by changes in neural oscillatory activity strength. Successful adaptation to a listening challenge thus latches onto two distinct yet complementary neural systems: a beta-tuned frontoparietal network enabling the flexible adaptation to attentive listening state and an alpha-tuned posterior network supporting attention to speech.

Item Type: Article
Subjects: Academic Digital Library > Biological Science
Depositing User: Unnamed user with email info@academicdigitallibrary.org
Date Deposited: 23 Dec 2022 04:29
Last Modified: 15 Feb 2024 04:17
URI: http://publications.article4sub.com/id/eprint/162

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