Data-driven visualization of multichannel EEG coherence networks based on community structure analysis

Data-driven visualization of multichannel EEG coherence networks based on community structure analysis

An electroencephalography (EEG) coherence network is a representation of functional brain connectivity, and is constructed by calculating the coherence between pairs of electrode signals as a function of frequency. Typical visualizations of coherence networks use a matrix representation with rows an...

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Bibliographic Details
Published in:Applied network science Vol. 3; no. 1; p. 41
Main Authors: Ji, Chengtao, Maurits, Natasha M., Roerdink, Jos B. T. M.
Format: Journal Article
Language:English
Published: Cham Springer International Publishing 26-09-2018
Springer Nature B.V
SpringerOpen
Subjects:
Apexes
Brain
Brain connectivity
Clutter
Cognitive tasks
Coherence
Community structure
Complexity
Computer Appl. in Social and Behavioral Sciences
Computer Science
Electrodes
Electroencephalography
Graph theory
Matrix representation
Multichannel data
Networks
Simulation and Modeling
Spatial data
Structural analysis
Visualization
Community structure
Visualization
Multichannel data
Brain connectivity
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Description
Summary:An electroencephalography (EEG) coherence network is a representation of functional brain connectivity, and is constructed by calculating the coherence between pairs of electrode signals as a function of frequency. Typical visualizations of coherence networks use a matrix representation with rows and columns representing electrodes and cells representing coherences between electrode signals, or a 2D node-link diagram with vertices representing electrodes and edges representing coherences. However, such representations do not allow an easy embedding of spatial information or they suffer from visual clutter, especially for multichannel EEG coherence networks. In this paper, a new method for data-driven visualization of multichannel EEG coherence networks is proposed to avoid the drawbacks of conventional methods. This method partitions electrodes into dense groups of spatially connected regions. It not only preserves spatial relationships between regions, but also allows an analysis of the functional connectivity within and between brain regions, which could be used to explore the relationship between functional connectivity and underlying brain structures. As an example application, the method is applied to the analysis of multichannel EEG coherence networks obtained from older and younger adults who perform a cognitive task. The proposed method can serve as a preprocessing step before a more detailed analysis of EEG coherence networks.
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ISSN:2364-8228
2364-8228
DOI:10.1007/s41109-018-0096-x