Neuronal timescales are functionally dynamic and shaped by cortical microarchitecture

Richard Gao; Ruud Lucas van den Brink; Thomas Pfeffer; Bradley Voytek

Neuronal timescales are functionally dynamic and shaped by cortical microarchitecture

Standard

Neuronal timescales are functionally dynamic and shaped by cortical microarchitecture. / Gao, Richard; van den Brink, Ruud Lucas; Pfeffer, Thomas; Voytek, Bradley.

in: ELIFE, Jahrgang 9, Nr. e61277, 2020.

Publikationen: SCORING: Beitrag in Fachzeitschrift/Zeitung › SCORING: Zeitschriftenaufsatz › Forschung › Begutachtung

Harvard

Gao, R, van den Brink, RL, Pfeffer, T & Voytek, B 2020, 'Neuronal timescales are functionally dynamic and shaped by cortical microarchitecture', ELIFE, Jg. 9, Nr. e61277.

APA

Gao, R., van den Brink, R. L., Pfeffer, T., & Voytek, B. (2020). Neuronal timescales are functionally dynamic and shaped by cortical microarchitecture. ELIFE, 9(e61277).

Vancouver

Gao R, van den Brink RL, Pfeffer T, Voytek B. Neuronal timescales are functionally dynamic and shaped by cortical microarchitecture. ELIFE. 2020; 9(e61277).

Bibtex

@article{a7beeb6479514c74836f5666304bee0b,

title = "Neuronal timescales are functionally dynamic and shaped by cortical microarchitecture",

abstract = "Complex cognitive functions such as working memory and decision-making require information maintenance over seconds to years, from transient sensory stimuli to long-term contextual cues. While theoretical accounts predict the emergence of a corresponding hierarchy of neuronal timescales, direct electrophysiological evidence across the human cortex is lacking. Here,we infer neuronal timescales from invasive intracranial recordings. Timescales increase along the principal sensorimotor-to-association axis across the entire human cortex, and scale with single-unit timescales within macaques. Cortex-wide transcriptomic analysis shows direct alignment between timescales and expression of excitation- and inhibition-related genes, as well as genes specific to voltage-gated transmembrane ion transporters. Finally, neuronal timescales are functionally dynamic: prefrontal cortex timescales expand during working memory maintenance and predict individual performance, while cortex-wide timescales compress with aging. Thus, neuronal timescales follow cytoarchitectonic gradients across the human cortex and are relevant for cognition in both short and long terms, bridging microcircuit physiology with macroscale dynamics and behavior.",

author = "Richard Gao and {van den Brink}, {Ruud Lucas} and Thomas Pfeffer and Bradley Voytek",

year = "2020",

language = "English",

volume = " 9",

journal = "ELIFE",

issn = "2050-084X",

publisher = "eLife Sciences Publications",

number = "e61277",

}

RIS

TY - JOUR

T1 - Neuronal timescales are functionally dynamic and shaped by cortical microarchitecture

AU - Gao, Richard

AU - van den Brink, Ruud Lucas

AU - Pfeffer, Thomas

AU - Voytek, Bradley

PY - 2020

Y1 - 2020

N2 - Complex cognitive functions such as working memory and decision-making require information maintenance over seconds to years, from transient sensory stimuli to long-term contextual cues. While theoretical accounts predict the emergence of a corresponding hierarchy of neuronal timescales, direct electrophysiological evidence across the human cortex is lacking. Here,we infer neuronal timescales from invasive intracranial recordings. Timescales increase along the principal sensorimotor-to-association axis across the entire human cortex, and scale with single-unit timescales within macaques. Cortex-wide transcriptomic analysis shows direct alignment between timescales and expression of excitation- and inhibition-related genes, as well as genes specific to voltage-gated transmembrane ion transporters. Finally, neuronal timescales are functionally dynamic: prefrontal cortex timescales expand during working memory maintenance and predict individual performance, while cortex-wide timescales compress with aging. Thus, neuronal timescales follow cytoarchitectonic gradients across the human cortex and are relevant for cognition in both short and long terms, bridging microcircuit physiology with macroscale dynamics and behavior.

AB - Complex cognitive functions such as working memory and decision-making require information maintenance over seconds to years, from transient sensory stimuli to long-term contextual cues. While theoretical accounts predict the emergence of a corresponding hierarchy of neuronal timescales, direct electrophysiological evidence across the human cortex is lacking. Here,we infer neuronal timescales from invasive intracranial recordings. Timescales increase along the principal sensorimotor-to-association axis across the entire human cortex, and scale with single-unit timescales within macaques. Cortex-wide transcriptomic analysis shows direct alignment between timescales and expression of excitation- and inhibition-related genes, as well as genes specific to voltage-gated transmembrane ion transporters. Finally, neuronal timescales are functionally dynamic: prefrontal cortex timescales expand during working memory maintenance and predict individual performance, while cortex-wide timescales compress with aging. Thus, neuronal timescales follow cytoarchitectonic gradients across the human cortex and are relevant for cognition in both short and long terms, bridging microcircuit physiology with macroscale dynamics and behavior.

M3 - SCORING: Journal article

VL - 9

JO - ELIFE

JF - ELIFE

SN - 2050-084X

IS - e61277

ER -