Ranking of communities in multiplex spatiotemporal models of brain dynamics

As a relatively new field, network neuroscience has tended to focus on aggregate behaviours of the brain averaged over many successive experiments or over long recordings in order to construct robust brain models. These models are limited in their ability to explain dynamic state changes in the brai...

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Bibliographic Details
Main Authors: Deane, C.M (Author), Reinert, G.D (Author), Warnaby, C.E (Author), Wilsenach, J.B (Author)
Format: Article
Language:English
Published: Springer Science and Business Media Deutschland GmbH 2022
Subjects:
Online Access:View Fulltext in Publisher
LEADER 02466nam a2200241Ia 4500
001 10.1007-s41109-022-00454-2
008 220511s2022 CNT 000 0 und d
020 |a 23648228 (ISSN) 
245 1 0 |a Ranking of communities in multiplex spatiotemporal models of brain dynamics 
260 0 |b Springer Science and Business Media Deutschland GmbH  |c 2022 
856 |z View Fulltext in Publisher  |u https://doi.org/10.1007/s41109-022-00454-2 
520 3 |a As a relatively new field, network neuroscience has tended to focus on aggregate behaviours of the brain averaged over many successive experiments or over long recordings in order to construct robust brain models. These models are limited in their ability to explain dynamic state changes in the brain which occurs spontaneously as a result of normal brain function. Hidden Markov Models (HMMs) trained on neuroimaging time series data have since arisen as a method to produce dynamical models that are easy to train but can be difficult to fully parametrise or analyse. We propose an interpretation of these neural HMMs as multiplex brain state graph models we term Hidden Markov Graph Models. This interpretation allows for dynamic brain activity to be analysed using the full repertoire of network analysis techniques. Furthermore, we propose a general method for selecting HMM hyperparameters in the absence of external data, based on the principle of maximum entropy, and use this to select the number of layers in the multiplex model. We produce a new tool for determining important communities of brain regions using a spatiotemporal random walk-based procedure that takes advantage of the underlying Markov structure of the model. Our analysis of real multi-subject fMRI data provides new results that corroborate the modular processing hypothesis of the brain at rest as well as contributing new evidence of functional overlap between and within dynamic brain state communities. Our analysis pipeline provides a way to characterise dynamic network activity of the brain under novel behaviours or conditions. © 2022, The Author(s). 
650 0 4 |a Community ranking 
650 0 4 |a Generative models 
650 0 4 |a Model selection 
650 0 4 |a Multiplex networks 
650 0 4 |a Networks neuroscience 
650 0 4 |a Spatiotemporal networks 
700 1 |a Deane, C.M.  |e author 
700 1 |a Reinert, G.D.  |e author 
700 1 |a Warnaby, C.E.  |e author 
700 1 |a Wilsenach, J.B.  |e author 
773 |t Applied Network Science