Emerging concepts for the dynamical organization of resting-state activity in the brain

Deco, Gustavo; Jirsa, Viktor K.; McIntosh, Anthony R.

doi:10.1038/nrn2961

Cited by 1,524 publications

(1,341 citation statements)

References 83 publications

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“…Moreover, both the amplitude and phase of the ER and Background task ICs were very different in the slow wave band (Figure 6 (a)) -this could be due to the different morphology of these two types of task ICs. Meanwhile, the substantial overlap between rest and task classes in the slow wave band, in comparison to that observed for higher frequencies such as theta and alpha, is consistent with the VLF theoretical models and fMRI BOLD imaging studies on the slow waves (Fox et al 2006;Fransson, 2006;Sonuga Barke and Castellanos, 2007;Deco, 2011), which suggest that despite experiencing changes during different brain states the slow waves persist across these states. The slow wave mechanism that is affecting the brain sources and/or that is being affected by the different loadings during task does not operate in a binary fashion, i.e.…”

Section: Classification Resultssupporting

confidence: 80%

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Neuronal oscillations in the EEG under varying cognitive load: A comparative study between slow waves and faster oscillations

Demanuele

Broyd

Sonuga‐Barke

et al. 2013

Clinical Neurophysiology

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the support of our participants, Suzannah Helps (Developmental Brain-Behaviour Laboratory, School of Psychology, University of Southampton, UK) for her contributions to the task design, and Daniel Durstewitz (Central Institute of Mental Health, Mannheim, Germany) for useful comments on the manuscript. We also thank all three anonymous reviewers for their constructive comments. AbstractObjective: This study has been specifically designed to investigate very low frequency neuronal oscillations (VLFO, <0.5 Hz) during resting states and during goal-directed tasks of graded difficulty levels, quantify the changes that the slow waves undergo in these conditions and compare them with those for higher frequency bands (namely delta, theta and alpha).Methods: To this end we developed a multistage signal processing methodology comprising blind source separation coupled with a neural network based feature extraction and classification method.Results: Changes in the amplitude and phase of brain sources estimates in the VLF band between rest and task were enhanced with increased task difficulty, but remained lower than those experienced in higher frequency bands. The slow wave variations were also significantly correlated with task performance measures, and hence with the level of task-directed attention.Conclusions: These findings suggest that besides their prominent sensitivity to external stimulation, VLFOs also contribute to the cortical ongoing background activity which may not be specifically related to task-specific attention and performance.Significance: Our work provides important insight into the association between VLF brain activity and conventional EEG frequency bands, and presents a novel framework for assessing neural activity during various mental conditions and psychiatric states. Highlights• We present a novel approach for exploring the functional relationship between very low frequency EEG oscillations (VLFO, <0.5 Hz) recorded at rest and those following the transition to goaldirected tasks of graded difficulty levels.• We show that slow waves (i) are attenuated but not extinguished following a rest to task transition, and (ii) are sensitive to variations in cognitive load; (iii) the rest-to-task changes in the slow wave band correlate with performance measures and (iv) the changes are lower than those in higher frequency bands, tentatively suggesting the VLFOs' contribution to the cortical ongoing background activity.• We present a new signal processing methodology for quantifying changes in band-limited EEG activity -this method, developed to gain insight into the neurophysiological role of the slow waves, could be explored with respect to altered functioning of brain oscillators in psychiatric and neurobehavioural disorders such as schizophrenia and ADHD. C. Demanuele et al., 20123

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Section: Classification Resultssupporting

confidence: 80%

“…Rather the ongoing slow wave activity might be causing the resting brain to operate at the edge of bifurcation, awaiting the next cognitive act (Deco, 2011). Furthermore, the rest-to-task separation of the slow wave features, although low, might be reflecting the different…”

Section: Classification Resultsmentioning

confidence: 99%

Neuronal oscillations in the EEG under varying cognitive load: A comparative study between slow waves and faster oscillations

Demanuele

Broyd

Sonuga‐Barke

et al. 2013

Clinical Neurophysiology

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“…Findings such as these have led to the hypothesis that the dorsal posterior cingulate cortex (a key DMN hub) influences whole‐brain network meta‐stability, ‘tuning’ network interactions throughout the brain, thereby enabling rapid transitions between different neural states 22. Such dynamics have been argued to constitute the essence of the network basis of cognition 12, 39…”

Section: Discussionmentioning

confidence: 99%

Cognitive impairment in epilepsy: the role of reduced network flexibility

Tailby

Kowalczyk

Jackson

2017

Ann Clin Transl Neurol

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ObjectiveThe dominant model of cognitive impairment in focal epilepsy has emphasised structural bases for cognitive deficits. Current theories of cognition in the healthy brain emphasise the importance of the reweighting of brain network interactions in support of task performance. Here, we explore the hypothesis that cognitive deficits in epilepsy arise through abnormalities of dynamic functional network interactions.MethodWe studied 19 healthy controls and 37 temporal lobe epilepsy (TLE) patients, using a behavioural measure of verbal fluency (the Controlled Oral Word Association Test) and an fMRI verbal fluency paradigm (Orthographic Lexical Retrieval).ResultsBehaviourally, verbal fluency was significantly impaired in TLE. Psychophysiological interaction analyses of the fMRI data, which capture state‐dependent changes in network connectivity, revealed reduced task‐dependent modulations of connectivity from left superior medial frontal cortex to left middle frontal gyrus in TLE patients. Individual differences in verbal fluency among TLE cases was correlated with task‐dependent changes in connectivity from left posterior cingulate to left superior medial frontal cortex, and from left superior medial frontal cortex to a range of right predominant brain areas.InterpretationThese data reveal that the typical pattern of task‐driven shifts in network connectivity is not observed in TLE. Our observations go beyond simple structure‐function associations and suggest that failure of network flexibility can be an important contributor to cognitive impairment in epilepsy.

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“…Functional magnetic resonance imaging studies of brain networks aim to demonstrate correlations among BOLD fluctuations in different brain regions (Biswal et al, 1995), while those involving electro-or magnetoencephalography (EEG/MEG) typically evaluate correlations among fluctuations in the amplitude of oscillatory activity in different brain regions (de Pasquale et al, 2010;Fries, 2015). Researchers have proposed that the resting-state networks (RSNs) measured using fMRI (rsfMRI) reflect a sort of "constant inner state of exploration" that optimizes the system for a given impending input, thus influencing perception and cognitive processing (Deco et al, 2011). While this idea appears intuitive, the fluctuations observed using rsfMRI occur too slowly to be associated with preparation for a given unpredictable input and allow for a fast and adequate reaction.…”

Section: Introductionmentioning

confidence: 99%

EEG microstates as a tool for studying the temporal dynamics of whole-brain neuronal networks: A review

2018

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SummaryThe present review discusses a well-established method for characterizing resting-state activity of the human brain using multichannel electroencephalography (EEG). This method involves the examination of electrical microstates in the brain, which are defined as successive short time periods during which the configuration of the scalp potential field remains semi-stable, suggesting quasi-simultaneity of activity among the nodes of largescale networks. A few prototypic microstates, which occur in a repetitive sequence across time, can be reliably identified across participants. Researchers have proposed that these microstates represent the basic building blocks of the chain of spontaneous conscious mental processes, and that their occurrence and temporal dynamics determine the quality of mentation. Several studies have further demonstrated that disturbances of mental processes associated with neurological and psychiatric conditions manifest as changes in the temporal dynamics of specific microstates. Combined EEG-fMRI studies and EEG source imaging studies have indicated that EEG microstates are closely associated with resting-state networks as identified using fMRI. The scale-free properties of the time series of EEG microstates explain why similar networks can be observed at such different time scales.The present review will provide an overview of these EEG microstates, available methods for analysis, the functional interpretations of findings regarding these microstates, and their behavioral and clinical correlates.

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Emerging concepts for the dynamical organization of resting-state activity in the brain

Cited by 1,524 publications

References 83 publications

Neuronal oscillations in the EEG under varying cognitive load: A comparative study between slow waves and faster oscillations

Neuronal oscillations in the EEG under varying cognitive load: A comparative study between slow waves and faster oscillations

Cognitive impairment in epilepsy: the role of reduced network flexibility

EEG microstates as a tool for studying the temporal dynamics of whole-brain neuronal networks: A review

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