A Novel Method for Constructing EEG Large-Scale Cortical Dynamical Functional Network Connectivity (dFNC): WTCS

Autor:	Dezhong Yao, Liuyi Song, Yu Zhang, Peiyang Li, Fali Li, Yajing Si, Lin Jiang, Chanlin Yi, Peng Xu, Ruwei Yao
Rok vydání:	2022
Předmět:	Computer science Electroencephalography Network topology Robustness (computer science) medicine Electrical and Electronic Engineering Signal processing medicine.diagnostic_test Artificial neural network business.industry Brain atlas Information processing Brain Signal Processing Computer-Assisted Pattern recognition Magnetic Resonance Imaging Computer Science Applications Human-Computer Interaction Control and Systems Engineering Neural Networks Computer Artificial intelligence business Software Biological network Information Systems
Zdroj:	IEEE Transactions on Cybernetics. 52:12869-12881
ISSN:	2168-2275 2168-2267
DOI:	10.1109/tcyb.2021.3090770
Popis:	As a kind of biological network, the brain network conduces to understanding the mystery of high-efficiency information processing in the brain, which will provide instructions to develop efficient brain-like neural networks. Large-scale dynamical functional network connectivity (dFNC) provides a more context-sensitive, dynamical, and straightforward sight at a higher network level. Nevertheless, dFNC analysis needs good enough resolution in both temporal and spatial domains, and the construction of dFNC needs to capture the time-varying correlations between two multivariate time series with unmatched spatial dimensions. Effective methods still lack. With well-developed source imaging techniques, electroencephalogram (EEG) has the potential to possess both high temporal and spatial resolutions. Therefore, we proposed to construct the EEG large-scale cortical dFNC based on brain atlas to probe the subtle dynamic activities in the brain and developed a novel method, that is, wavelet coherence-S estimator (WTCS), to assess the dynamic couplings among functional subnetworks with different spatial dimensions. The simulation study demonstrated its robustness and availability of applying to dFNC. The application in real EEG data revealed the appealing ``Primary peak'' and ``P3-like peak'' in dFNC network properties and meaningful evolutions in dFNC network topology for P300. Our study brings new insights for probing brain activities at a more dynamical and higher hierarchical level and pushing forward the development of brain-inspired artificial neural networks. The proposed WTCS not only benefits the dFNC studies but also gives a new solution to capture the time-varying couplings between the multivariate time series that is often encountered in signal processing disciplines.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::e7d65ff6a9c69e2f4c32f9760fc77b41 https://doi.org/10.1109/tcyb.2021.3090770 Zobrazit plný text záznamu