Spectrally resolved fast transient brain states in electrophysiological data

Diego Vidaurre; Andrew J. Quinn; Adam P. Baker; David Dupret; Alvaro Tejero-Cantero; Mark W. Woolrich

doi:10.1016/j.neuroimage.2015.11.047

Spectrally resolved fast transient brain states in electrophysiological data

Diego Vidaurre^*, Andrew J. Quinn, Adam P. Baker, David Dupret, Alvaro Tejero-Cantero, Mark W. Woolrich

^*Corresponding author for this work

Psychology

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

145 Citations (Scopus)

Abstract

The brain is capable of producing coordinated fast changing neural dynamics across multiple brain regions in order to adapt to rapidly changing environments. However, it is non-trivial to identify multiregion dynamics at fast sub-second time-scales in electrophysiological data. We propose a method that, with no knowledge of any task timings, can simultaneously identify and describe fast transient multiregion dynamics in terms of their temporal, spectral and spatial properties. The approach models brain activity using a discrete set of sequential states, with each state distinguished by its own multiregion spectral properties. This can identify potentially very short-lived visits to a brain state, at the same time as inferring the state's properties, by pooling over many repeated visits to that state. We show how this can be used to compute state-specific measures such as power spectra and coherence. We demonstrate that this can be used to identify short-lived transient brain states with distinct power and functional connectivity (e.g., coherence) properties in an MEG data set collected during a volitional motor task.

Original language	English
Pages (from-to)	81-95
Number of pages	15
Journal	NeuroImage
Volume	126
DOIs	https://doi.org/10.1016/j.neuroimage.2015.11.047
Publication status	Published - 1 Feb 2016

Bibliographical note

Funding Information:
DV is supported by a Wellcome Trust Strategic Award ( 098369/Z/12/Z ). AB is supported by a Wellcome Trust Strategic Award ( 102616/Z/13/Z ). DD is supported by the MRC UK MC/UU/12020/7 and MC/UU/12024 . MWW is supported by an Equipment Grant from the Wellcome Trust (092753/Z/10/Z) and an MRC UK MEG Partnership Grant ( MR/K005464/1 ). We thank George O'Neill and Matt Brookes for providing the MEG data used in our experiments.

Publisher Copyright:
© 2015 The Authors.

Keywords

Bayesian modelling
Coherence
MEG
Multitaper
Multivariate autoregressive model
Partial directed coherence
Sign ambiguity
Spectral estimation
Transient connectivity

ASJC Scopus subject areas

Neurology
Cognitive Neuroscience

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10.1016/j.neuroimage.2015.11.047

Cite this

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abstract = "The brain is capable of producing coordinated fast changing neural dynamics across multiple brain regions in order to adapt to rapidly changing environments. However, it is non-trivial to identify multiregion dynamics at fast sub-second time-scales in electrophysiological data. We propose a method that, with no knowledge of any task timings, can simultaneously identify and describe fast transient multiregion dynamics in terms of their temporal, spectral and spatial properties. The approach models brain activity using a discrete set of sequential states, with each state distinguished by its own multiregion spectral properties. This can identify potentially very short-lived visits to a brain state, at the same time as inferring the state's properties, by pooling over many repeated visits to that state. We show how this can be used to compute state-specific measures such as power spectra and coherence. We demonstrate that this can be used to identify short-lived transient brain states with distinct power and functional connectivity (e.g., coherence) properties in an MEG data set collected during a volitional motor task.",

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note = "Funding Information: DV is supported by a Wellcome Trust Strategic Award ( 098369/Z/12/Z ). AB is supported by a Wellcome Trust Strategic Award ( 102616/Z/13/Z ). DD is supported by the MRC UK MC/UU/12020/7 and MC/UU/12024 . MWW is supported by an Equipment Grant from the Wellcome Trust (092753/Z/10/Z) and an MRC UK MEG Partnership Grant ( MR/K005464/1 ). We thank George O'Neill and Matt Brookes for providing the MEG data used in our experiments. Publisher Copyright: {\textcopyright} 2015 The Authors.",

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AU - Woolrich, Mark W.

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N2 - The brain is capable of producing coordinated fast changing neural dynamics across multiple brain regions in order to adapt to rapidly changing environments. However, it is non-trivial to identify multiregion dynamics at fast sub-second time-scales in electrophysiological data. We propose a method that, with no knowledge of any task timings, can simultaneously identify and describe fast transient multiregion dynamics in terms of their temporal, spectral and spatial properties. The approach models brain activity using a discrete set of sequential states, with each state distinguished by its own multiregion spectral properties. This can identify potentially very short-lived visits to a brain state, at the same time as inferring the state's properties, by pooling over many repeated visits to that state. We show how this can be used to compute state-specific measures such as power spectra and coherence. We demonstrate that this can be used to identify short-lived transient brain states with distinct power and functional connectivity (e.g., coherence) properties in an MEG data set collected during a volitional motor task.

AB - The brain is capable of producing coordinated fast changing neural dynamics across multiple brain regions in order to adapt to rapidly changing environments. However, it is non-trivial to identify multiregion dynamics at fast sub-second time-scales in electrophysiological data. We propose a method that, with no knowledge of any task timings, can simultaneously identify and describe fast transient multiregion dynamics in terms of their temporal, spectral and spatial properties. The approach models brain activity using a discrete set of sequential states, with each state distinguished by its own multiregion spectral properties. This can identify potentially very short-lived visits to a brain state, at the same time as inferring the state's properties, by pooling over many repeated visits to that state. We show how this can be used to compute state-specific measures such as power spectra and coherence. We demonstrate that this can be used to identify short-lived transient brain states with distinct power and functional connectivity (e.g., coherence) properties in an MEG data set collected during a volitional motor task.

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Spectrally resolved fast transient brain states in electrophysiological data

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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