Imaging localized neuronal activity at fast time scales through biomechanics

Beitrag in einer Fachzeitschrift


Details zur Publikation

Autorinnen und Autoren: Patz S, Fovargue D, Schregel K, Nazari N, Palotai M, Barbone PE, Fabry B, Hammers A, Holm S, Kozerke S, Nordsletten D, Sinkus R
Zeitschrift: Science Advances
Jahr der Veröffentlichung: 2019
Band: 5
Heftnummer: 4
ISSN: 2375-2548


Abstract

Mapping neuronal activity noninvasively is a key requirement for in vivo human neuroscience. Traditional functional magnetic resonance (MR) imaging, with a temporal response of seconds, cannot measure high-level cognitive processes evolving in tens of milliseconds. To advance neuroscience, imaging of fast neuronal processes is required. Here, we show in vivo imaging of fast neuronal processes at 100-ms time scales by quantifying brain biomechanics noninvasively with MR elastography. We show brain stiffness changes of ∼10% in response to repetitive electric stimulation of a mouse hind paw over two orders of frequency from 0.1 to 10 Hz. We demonstrate in mice that regional patterns of stiffness modulation are synchronous with stimulus switching and evolve with frequency. For very fast stimuli (100 ms), mechanical changes are mainly located in the thalamus, the relay location for afferent cortical input. Our results demonstrate a new methodology for noninvasively tracking brain functional activity at high speed.


FAU-Autorinnen und Autoren / FAU-Herausgeberinnen und Herausgeber

Fabry, Ben Prof. Dr.
Lehrstuhl für Biophysik


Einrichtungen weiterer Autorinnen und Autoren

Boston University
Brigham and Women's Hospital (BWH)
King’s College London
Universität Zürich (UZH)
University of Oslo


Zitierweisen

APA:
Patz, S., Fovargue, D., Schregel, K., Nazari, N., Palotai, M., Barbone, P.E.,... Sinkus, R. (2019). Imaging localized neuronal activity at fast time scales through biomechanics. Science Advances, 5(4). https://dx.doi.org/10.1126/sciadv.aav3816

MLA:
Patz, Samuel, et al. "Imaging localized neuronal activity at fast time scales through biomechanics." Science Advances 5.4 (2019).

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Zuletzt aktualisiert 2019-23-05 um 14:38

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