Brain Fingerprinting-Based Community Structure

The ability to uniquely characterize individual subjects based on their functional connectome (FC), i.e., fingerprinting, is key for progress toward precision medicine. Over the past few years, a variety of methods have been proposed for fingerprinting. While early approaches focused on using either...

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Bibliographic Details
Published inProceedings (International Symposium on Biomedical Imaging) pp. 1 - 4
Main Authors Athamnah, Sema, Aviyente, Selin
Format Conference Proceeding
LanguageEnglish
Published IEEE 14.04.2025
Subjects
Biomedical imaging
Brain
community detection
Feature extraction
Fingerprint recognition
fingerprinting
Functional connectivity
Functional magnetic resonance imaging
multilayer graphs
Nonhomogeneous media
Optimization
Precision medicine
Principal component analysis
signed graph
Vectors
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Summary:The ability to uniquely characterize individual subjects based on their functional connectome (FC), i.e., fingerprinting, is key for progress toward precision medicine. Over the past few years, a variety of methods have been proposed for fingerprinting. While early approaches focused on using either the whole brain connec-tivity or pre-defined subnetwork connectivity to discriminate between subjects, more recently different feature extraction methods such as principal component analysis (PCA) have been used to ex-tract discriminative features. However, these methods do not iden-tify functionally interpretable network components, i.e., commu-nities, that contribute most to discrimination across subjects. In this paper, we introduce a fingerprinting approach based on community structure. In particular, we introduce a signed multilayer modularity optimization approach to identify the community structure across a group of subjects from resting state fMRI FCs. The optimal community structure for identifying subjects and discrimi-nating between different tasks is learned through a community in-dicator vector which quantifies the relevance of each community for a subject. The proposed framework is tested on the Midnight Scan Club (MSC) data across different tasks. High identification rates between resting state and different tasks indicate that an indi-vidual's community indicator vector is intrinsic to that individual independent of the task. The proposed framework also provides interpretability to fingerprinting by determining the most discrimi-native brain regions between task pairs.
ISSN:1945-8452
DOI:10.1109/ISBI60581.2025.10981160