Litcius/Paper detail

Seizure onset zone (SOZ) identification using effective brain connectivity of epileptogenic networks

Sai Sanjay Balaji, Keshab K. Parhi

2024Journal of Neural Engineering13 citationsDOIOpen Access PDF

Abstract

Abstract Objective . To demonstrate the capability of utilizing graph feature-based supervised machine learning (ML) algorithm on intracranial electroencephalogram recordings for the identification of seizure onset zones (SOZs) in individuals with drug-resistant epilepsy. Approach . Utilizing three model-free measures of effective connectivity (EC)-directed information, mutual information-guided Granger causality index (MI-GCI), and frequency-domain convergent cross-mapping (FD-CCM) - directed graphs are generated. Graph centrality measures at different sparsity are used as the classifier’s features. Main results . The centrality features achieve high accuracies exceeding 90% in distinguishing SOZ electrodes from non-SOZ electrodes. Notably, a sparse graph representation with just ten features and simple ML models effectively achieves such performance. The study identifies FD-CCM centrality measures as particularly significant, with a mean AUC of 0.93, outperforming prior literature. The FD-CCM-based graph modeling also highlights elevated centrality measures among SOZ electrodes, emphasizing heightened activity relative to non-SOZ electrodes during ictogenesis. Significance . This research not only underscores the efficacy of automated SOZ identification but also illuminates the potential of specific EC measures in enhancing discriminative power within the context of epilepsy research.

Topics & Concepts

Discriminative modelCentralityComputer scienceArtificial intelligencePattern recognition (psychology)EpilepsyGraphMachine learningPower graph analysisContext (archaeology)NeuroscienceTheoretical computer scienceMathematicsPsychologyBiologyPaleontologyCombinatoricsEEG and Brain-Computer InterfacesFunctional Brain Connectivity StudiesElectrochemical Analysis and Applications