Graph Analysis and Visualization for Brain Function Characterization Using EEG Data

Abstract: Over the past few years, there has been an increased interest in studying the underlying neural mechanism of cognitive brain activity as well as in diagnosing certain pathologies. Noninvasive imaging modalities such as functional magnetic resonance imaging (fMRI), positron emission tomography (PET), and dynamic signal acquisition techniques such as quantitative electroencephalography (EEG) have been vastly used to estimate cortical connectivity and identify functional interdependencies among synchronized brain… Show more

“…All experiments showed that binary clustering coefficient and weighted average neighbourhood degree in effective networks enables us to differentiate alcoholics from normal subjects. This result is similar to results published in another research (Sakkalis et al 2010). Here, each node of weighted node betweenness centrality was compared between normal subjects and alcoholics, showing significant difference.…”

Automated network analysis to measure brain effective connectivity estimated from EEG data of patients with alcoholism

“…All experiments showed that binary clustering coefficient and weighted average neighbourhood degree in effective networks enables us to differentiate alcoholics from normal subjects. This result is similar to results published in another research (Sakkalis et al 2010). Here, each node of weighted node betweenness centrality was compared between normal subjects and alcoholics, showing significant difference.…”

Automated network analysis to measure brain effective connectivity estimated from EEG data of patients with alcoholism

“…where k u and k v are the degrees of the end vertices u and v, respectively, of edge {u,v} ∈ E. For directed unweighted graphs the above measure can still be used if we ignore the direction of edges [7]. The assortativity coefficient r lies in the range À1 r 1, where À1 indicates totally disassortative network while 1 indicates a totally assortative network.…”

“…The clustering coefficient for the whole graph is the average of C i for each node, C ¼ ∑ i ¼ 1 n C i /n, and is a measure of the tendency of graph nodes to form local clusters [7]. For unweighted graphs, the local CC associated with a node i having k i connections is defined as the ratio of the triangles that contain this node divided by the maximum possible number of such triangles k i (k i À 1)/2.…”

“…Special interest in using graph theory to study neural and functional networks has been in focus recently, since it offers a unique perspective of studying local and distributed brain interactions [7,8]. In this study, network topology and functional connectivity are evaluated by measuring several properties of the emerged graphs, i.e., mean vertex degree, clustering coefficient index, assortativity coefficient, shortest path length, and efficiency.…”

Graph-theoretic Indices of Evaluating Brain Network Synchronization: Application in an Alcoholism Paradigm

“…However, more sophisticated interdependence techniques addressing not only linear but also nonlinear synchronization and causality are also available and applied in certain pathologies like Epilepsy [ 12 ]. Such measures can act complementary to graph theoretic indices that characterize brain networks as discussed in [ 19 ] and can be used as input to BrainNetVis.…”

BrainNetVis: An Open-Access Tool to Effectively Quantify and Visualize Brain Networks