Functional MRI (fMRI) research, employing naturalistic stimuli like movies,
explores brain network interactions in complex cognitive processes such as
empathy. The empathy network encompasses multiple brain areas, including the
Insula, PFC, ACC, and parietal regions. Our novel processing pipeline applies
graph learning methods to whole-brain timeseries signals, incorporating
high-pass filtering, voxel-level clustering, and windowed graph learning with a
sparsity-based approach. The study involves two short movies shown to 14
healthy volunteers, considering 54 regions extracted from the AAL Atlas. The
sparsity-based graph learning consistently outperforms, achieving over 88%
accuracy in capturing emotion contagion variations. Temporal analysis reveals a
gradual induction of empathy, supported by the method's effectiveness in
capturing dynamic connectomes through graph clustering. Edge-weight dynamics
analysis underscores sparsity-based learning's superiority, while
connectome-network analysis highlights the pivotal role of the Insula,
Amygdala, and Thalamus in empathy. Spectral filtering analysis emphasizes the
band-pass filter's significance in isolating regions linked to emotional and
empathetic processing during empathy HIGH states. Key regions like Amygdala,
Insula, and Angular Gyrus consistently activate, supporting their critical role
in immediate emotional responses. Strong similarities across movies in graph
cluster labels, connectome-network analysis, and spectral filtering-based
analyses reveal robust neural correlates of empathy. These findings advance our
understanding of empathy-related neural dynamics and identify specific regions
in empathetic responses, offering insights for targeted interventions and
treatments associated with empathetic processing.Comment: 9 figures, 2 table