Decoding the Stressed Brain with Geometric Machine Learning
This work addresses the need for objective stress detection methods, which could benefit mental and physical health monitoring, though it appears incremental as it builds on existing graph-based techniques.
The study tackled the problem of subjective stress detection by introducing a geometric machine learning framework that uses EEG recordings to detect stress, achieving superior performance over standard models on the SAM-40 dataset.
Stress significantly contributes to both mental and physical disorders, yet traditional self-reported questionnaires are inherently subjective. In this study, we introduce a novel framework that employs geometric machine learning to detect stress from raw EEG recordings. Our approach constructs graphs by integrating structural connectivity (derived from electrode spatial arrangement) with functional connectivity from pairwise signal correlations. A spatio-temporal graph convolutional network (ST-GCN) processes these graphs to capture spatial and temporal dynamics. Experiments on the SAM-40 dataset show that the ST-GCN outperforms standard machine learning models on all key classification metrics and enhances interpretability, explored through ablation analyses of key channels and brain regions. These results pave the way for more objective and accurate stress detection methods.