Graph analysis and modularity of brain functional connectivity networks: searching for the optimal threshold
C\'ecile Bordier, Carlo Nicolini, Angelo Bifone

TL;DR
This paper introduces a percolation analysis method grounded in statistical physics to identify the optimal sparsification threshold in brain functional connectivity networks, enhancing community detection accuracy amidst noise and variability.
Contribution
It demonstrates that percolation analysis can effectively determine the optimal threshold for community detection in brain networks, validated with synthetic and real data.
Findings
Percolation analysis identifies thresholds that maximize community structure information.
The method is robust against noise and data variability.
It improves community detection in brain connectivity studies.
Abstract
Neuroimaging data can be represented as networks of nodes and edges that capture the topological organization of the brain connectivity. Graph theory provides a general and powerful framework to study these networks and their structure at various scales. By way of example, community detection methods have been widely applied to investigate the modular structure of many natural networks, including brain functional connectivity networks. Sparsification procedures are often applied to remove the weakest edges, which are the most affected by experimental noise, and to reduce the density of the graph, thus making it theoretically and computationally more tractable. However, weak links may also contain significant structural information, and procedures to identify the optimal tradeoff are the subject of active research. Here, we explore the use of percolation analysis, a method grounded in…
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