Brain Connectivity Dissociates Responsiveness from Drug Exposure during Propofol-Induced Transitions of Consciousness.

Brain Connectivity Dissociates Responsiveness from Drug Exposure during Propofol-Induced Transitions of Consciousness.

Accurately measuring the neural correlates of consciousness is a grand challenge for neuroscience. Despite theoretical advances, developing reliable brain measures to track the loss of reportable consciousness during sedation is hampered by significant individual variability in susceptibility to ana...

Full description

Bibliographic Details
Main Authors: Srivas Chennu, Stuart O'Connor, Ram Adapa, David K Menon, Tristan A Bekinschtein
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2016-01-01
Series:PLoS Computational Biology
Online Access:https://doi.org/10.1371/journal.pcbi.1004669
id doaj-f7198b39e4f54658b542ac677179f296
record_format Article
spelling doaj-f7198b39e4f54658b542ac677179f2962021-04-21T15:43:16ZengPublic Library of Science (PLoS)PLoS Computational Biology1553-734X1553-73582016-01-01121e100466910.1371/journal.pcbi.1004669Brain Connectivity Dissociates Responsiveness from Drug Exposure during Propofol-Induced Transitions of Consciousness.Srivas ChennuStuart O'ConnorRam AdapaDavid K MenonTristan A BekinschteinAccurately measuring the neural correlates of consciousness is a grand challenge for neuroscience. Despite theoretical advances, developing reliable brain measures to track the loss of reportable consciousness during sedation is hampered by significant individual variability in susceptibility to anaesthetics. We addressed this challenge using high-density electroencephalography to characterise changes in brain networks during propofol sedation. Assessments of spectral connectivity networks before, during and after sedation were combined with measurements of behavioural responsiveness and drug concentrations in blood. Strikingly, we found that participants who had weaker alpha band networks at baseline were more likely to become unresponsive during sedation, despite registering similar levels of drug in blood. In contrast, phase-amplitude coupling between slow and alpha oscillations correlated with drug concentrations in blood. Our findings highlight novel markers that prognosticate individual differences in susceptibility to propofol and track drug exposure. These advances could inform accurate drug titration and brain state monitoring during anaesthesia.https://doi.org/10.1371/journal.pcbi.1004669
collection DOAJ
language English
format Article
sources DOAJ
author Srivas Chennu
Stuart O'Connor
Ram Adapa
David K Menon
Tristan A Bekinschtein
spellingShingle Srivas Chennu
Stuart O'Connor
Ram Adapa
David K Menon
Tristan A Bekinschtein
Brain Connectivity Dissociates Responsiveness from Drug Exposure during Propofol-Induced Transitions of Consciousness.
PLoS Computational Biology
author_facet Srivas Chennu
Stuart O'Connor
Ram Adapa
David K Menon
Tristan A Bekinschtein
author_sort Srivas Chennu
title Brain Connectivity Dissociates Responsiveness from Drug Exposure during Propofol-Induced Transitions of Consciousness.
title_short Brain Connectivity Dissociates Responsiveness from Drug Exposure during Propofol-Induced Transitions of Consciousness.
title_full Brain Connectivity Dissociates Responsiveness from Drug Exposure during Propofol-Induced Transitions of Consciousness.
title_fullStr Brain Connectivity Dissociates Responsiveness from Drug Exposure during Propofol-Induced Transitions of Consciousness.
title_full_unstemmed Brain Connectivity Dissociates Responsiveness from Drug Exposure during Propofol-Induced Transitions of Consciousness.
title_sort brain connectivity dissociates responsiveness from drug exposure during propofol-induced transitions of consciousness.
publisher Public Library of Science (PLoS)
series PLoS Computational Biology
issn 1553-734X
1553-7358
publishDate 2016-01-01
description Accurately measuring the neural correlates of consciousness is a grand challenge for neuroscience. Despite theoretical advances, developing reliable brain measures to track the loss of reportable consciousness during sedation is hampered by significant individual variability in susceptibility to anaesthetics. We addressed this challenge using high-density electroencephalography to characterise changes in brain networks during propofol sedation. Assessments of spectral connectivity networks before, during and after sedation were combined with measurements of behavioural responsiveness and drug concentrations in blood. Strikingly, we found that participants who had weaker alpha band networks at baseline were more likely to become unresponsive during sedation, despite registering similar levels of drug in blood. In contrast, phase-amplitude coupling between slow and alpha oscillations correlated with drug concentrations in blood. Our findings highlight novel markers that prognosticate individual differences in susceptibility to propofol and track drug exposure. These advances could inform accurate drug titration and brain state monitoring during anaesthesia.
url https://doi.org/10.1371/journal.pcbi.1004669
work_keys_str_mv AT srivaschennu brainconnectivitydissociatesresponsivenessfromdrugexposureduringpropofolinducedtransitionsofconsciousness
AT stuartoconnor brainconnectivitydissociatesresponsivenessfromdrugexposureduringpropofolinducedtransitionsofconsciousness
AT ramadapa brainconnectivitydissociatesresponsivenessfromdrugexposureduringpropofolinducedtransitionsofconsciousness
AT davidkmenon brainconnectivitydissociatesresponsivenessfromdrugexposureduringpropofolinducedtransitionsofconsciousness
AT tristanabekinschtein brainconnectivitydissociatesresponsivenessfromdrugexposureduringpropofolinducedtransitionsofconsciousness
_version_ 1714667216502259712

Similar Items