A rapid theta network mechanism for flexible information encoding

Elizabeth L. Johnson; Jack J. Lin; David King-Stephens; Peter B. Weber; Kenneth D. Laxer; Ignacio Saez; Fady Girgis; Mark D’Esposito; Robert T. Knight; David Badre

doi:10.1038/s41467-023-38574-7

A rapid theta network mechanism for flexible information encoding

Elizabeth L. Johnson^*, Jack J. Lin, David King-Stephens, Peter B. Weber, Kenneth D. Laxer, Ignacio Saez, Fady Girgis, Mark D’Esposito, Robert T. Knight, David Badre^*

^*Corresponding author for this work

Medical Social Sciences

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Flexible behavior requires gating mechanisms that encode only task-relevant information in working memory. Extant literature supports a theoretical division of labor whereby lateral frontoparietal interactions underlie information maintenance and the striatum enacts the gate. Here, we reveal neocortical gating mechanisms in intracranial EEG patients by identifying rapid, within-trial changes in regional and inter-regional activities that predict subsequent behavioral outputs. Results first demonstrate information accumulation mechanisms that extend prior fMRI (i.e., regional high-frequency activity) and EEG evidence (inter-regional theta synchrony) of distributed neocortical networks in working memory. Second, results demonstrate that rapid changes in theta synchrony, reflected in changing patterns of default mode network connectivity, support filtering. Graph theoretical analyses further linked filtering in task-relevant information and filtering out irrelevant information to dorsal and ventral attention networks, respectively. Results establish a rapid neocortical theta network mechanism for flexible information encoding, a role previously attributed to the striatum.

Original language	English (US)
Article number	2872
Journal	Nature communications
Volume	14
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-38574-7
State	Published - Dec 2023

Funding

We thank K. T. Jones, C. W. Hoy, B. J. Frick, N. Jaha, and R. T. Jimenez. This work was funded by grants from the National Institutes of Health (NINDS R00NS115918 to E.L.J.; NIMH R01MH111737 to M.D., R.T.K., and D.B.; NINDS R01NS021135 to R.T.K.; NINDS U19NS107609 to J.J.L. and R.T.K.) and Office of Naval Research (MURI N00014-16-1-2832 to D.B.).

ASJC Scopus subject areas

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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10.1038/s41467-023-38574-7

Cite this

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title = "A rapid theta network mechanism for flexible information encoding",

abstract = "Flexible behavior requires gating mechanisms that encode only task-relevant information in working memory. Extant literature supports a theoretical division of labor whereby lateral frontoparietal interactions underlie information maintenance and the striatum enacts the gate. Here, we reveal neocortical gating mechanisms in intracranial EEG patients by identifying rapid, within-trial changes in regional and inter-regional activities that predict subsequent behavioral outputs. Results first demonstrate information accumulation mechanisms that extend prior fMRI (i.e., regional high-frequency activity) and EEG evidence (inter-regional theta synchrony) of distributed neocortical networks in working memory. Second, results demonstrate that rapid changes in theta synchrony, reflected in changing patterns of default mode network connectivity, support filtering. Graph theoretical analyses further linked filtering in task-relevant information and filtering out irrelevant information to dorsal and ventral attention networks, respectively. Results establish a rapid neocortical theta network mechanism for flexible information encoding, a role previously attributed to the striatum.",

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AU - King-Stephens, David

AU - Weber, Peter B.

AU - Laxer, Kenneth D.

AU - Saez, Ignacio

AU - Girgis, Fady

AU - D’Esposito, Mark

AU - Knight, Robert T.

AU - Badre, David

PY - 2023/12

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AB - Flexible behavior requires gating mechanisms that encode only task-relevant information in working memory. Extant literature supports a theoretical division of labor whereby lateral frontoparietal interactions underlie information maintenance and the striatum enacts the gate. Here, we reveal neocortical gating mechanisms in intracranial EEG patients by identifying rapid, within-trial changes in regional and inter-regional activities that predict subsequent behavioral outputs. Results first demonstrate information accumulation mechanisms that extend prior fMRI (i.e., regional high-frequency activity) and EEG evidence (inter-regional theta synchrony) of distributed neocortical networks in working memory. Second, results demonstrate that rapid changes in theta synchrony, reflected in changing patterns of default mode network connectivity, support filtering. Graph theoretical analyses further linked filtering in task-relevant information and filtering out irrelevant information to dorsal and ventral attention networks, respectively. Results establish a rapid neocortical theta network mechanism for flexible information encoding, a role previously attributed to the striatum.

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A rapid theta network mechanism for flexible information encoding

Abstract

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