Identification of community structure-based brain states and transitions using functional MRI

•Community-based detection of discrete brain states using stochastic latent block model.•Bayesian change-point detection and model selection via posterior predictive discrepancy.•Markov chain Monte Carlo methods for estimation of community memberships.•Distinctive brain states for varying task deman...

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Published in:NeuroImage (Orlando, Fla.) Fla.), 2021-12, Vol.244, p.118635-118635, Article 118635
Main Authors: Bian, Lingbin, Cui, Tiangang, Thomas Yeo, B.T., Fornito, Alex, Razi, Adeel, Keith, Jonathan
Format: Article
Language:English
Subjects:
Bayes Theorem
Bayesian analysis
Bayesian inference
Brain - diagnostic imaging
Brain mapping
Change-point detection
Cognition
Community structure
Computer Simulation
Connectome
Dynamic functional connectivity
Experiments
Functional magnetic resonance imaging
Histological Techniques
Humans
Latent block model
Magnetic Resonance Imaging - methods
Markov analysis
Markov chain Monte Carlo
Memory
Mental task performance
Methods
Neural networks
Oxygen Saturation
Parameter estimation
Short term memory
Time Factors
Time series
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Summary:•Community-based detection of discrete brain states using stochastic latent block model.•Bayesian change-point detection and model selection via posterior predictive discrepancy.•Markov chain Monte Carlo methods for estimation of community memberships.•Distinctive brain states for varying task demands in working memory task fMRI. [Display omitted] Brain function relies on a precisely coordinated and dynamic balance between the functional integration and segregation of distinct networks. Characterizing the way in which brain regions reconfigure their interactions to give rise to distinct but hidden brain states remains an open challenge. In this paper, we propose a Bayesian method for characterizing community structure-based latent brain states and showcase a novel strategy based on posterior predictive discrepancy using the latent block model to detect transitions between community structures in blood oxygen level-dependent (BOLD) time series. The set of estimated parameters in the model includes a latent label vector that assigns network nodes to communities, and also block model parameters that reflect the weighted connectivity within and between communities. Besides extensive in-silico model evaluation, we also provide empirical validation (and replication) using the Human Connectome Project (HCP) dataset of 100 healthy adults. Our results obtained through an analysis of task-fMRI data during working memory performance show appropriate lags between external task demands and change-points between brain states, with distinctive community patterns distinguishing fixation, low-demand and high-demand task conditions.
ISSN:1053-8119
1095-9572
DOI:10.1016/j.neuroimage.2021.118635