UH Biocomputation Group - ICAhttp://biocomputation.herts.ac.uk/2021-03-03T18:05:00+00:00Spatiotemporal Dynamics of the Brain at Rest Exploring EEG Microstates as Electrophysiological Signatures of BOLD Resting State Networks2021-03-03T18:05:00+00:002021-03-03T18:05:00+00:00David Haydocktag:biocomputation.herts.ac.uk,2021-03-03:/2021/03/03/spatiotemporal-dynamics-of-the-brain-at-rest-exploring-eeg-microstates-as-electrophysiological-signatures-of-bold-resting-state-networks.html<p class="first last">David Haydock's Journal Club session where he will talk about a paper "Spatiotemporal Dynamics of the Brain at Rest Exploring EEG Microstates as Electrophysiological Signatures of BOLD Resting State Networks"</p>
<p>This week on Journal Club session David Haydock will talk about a paper "Spatiotemporal Dynamics of the Brain at Rest Exploring EEG Microstates as Electrophysiological Signatures of BOLD Resting State Networks".</p>
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<p>Neuroimaging research suggests that the resting cerebral physiology is
characterized by complex patterns of neuronal activity in widely distributed
functional networks. As studied using functional magnetic resonance imaging
(fMRI) of the blood-oxygenation-level dependent (BOLD) signal, the resting
brain activity is associated with slowly fluctuating hemodynamic signals (10
s). More recently, multimodal functional imaging studies involving simultaneous
acquisition of BOLD-fMRI and electroencephalography (EEG) data have suggested
that the relatively slow hemodynamic fluctuations of some resting state
networks (RSNs) evinced in the BOLD data are related to much faster (100 ms)
transient brain states reflected in EEG signals, that are referred to as
"microstates".</p>
<p>To further elucidate the relationship between microstates and RSNs, we
developed a fully data-driven ap- proach that combines information from
simultaneously recorded, high-density EEG and BOLD-fMRI data. Using independent
component analysis (ICA) of the combined EEG and fMRI data, we identified
thirteen mi- crostates and ten RSNs that are organized independently in their
temporal and spatial characteristics, respec- tively. We hypothesized that the
intrinsic brain networks that are active at rest would be reflected in both the
EEG data and the fMRI data. To test this hypothesis, the rapid fluctuations
associated with each microstate were correlated with the BOLD-fMRI signal
associated with each RSN.</p>
<p>We found that each RSN was characterized further by a specific
electrophysiological signature involving from one to a combination of several
microstates. Moreover, by comparing the time course of EEG microstates to that
of the whole-brain BOLD signal, on a multi-subject group level, we unraveled
for the first time a set of microstate-associated networks that correspond to a
range of previously described RSNs, including visual, sensorimotor, auditory,
attention, frontal, visceromotor and default mode networks. These results
extend our understanding of the electrophysiological signature of BOLD RSNs and
demonstrate the intrinsic connec- tion between the fast neuronal activity and
slow hemodynamic fluctuations.</p>
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<p>Papers:</p>
<ul class="simple">
<li>H. Yuan, V. Zotev, R. Phillips, W. Drevets, J. Bodurka, <a class="reference external" href="https://doi.org/10.1016/j.neuroimage.2012.02.031">"Spatiotemporal Dynamics of the Brain at Rest Exploring EEG Microstates as Electrophysiological Signatures of BOLD Resting State Networks"</a>, 2012, NeuroImage, 60, 2062--2072</li>
</ul>
<p><strong>Date:</strong> 2021/03/05 <br />
<strong>Time:</strong> 14:00 <br />
<strong>Location</strong>: online</p>