AI Article Synopsis
- Multilayer networks were utilized to examine abnormal dynamic changes in individuals with bipolar disorder (BD) compared to normal controls, highlighting shortcomings in existing methods by neglecting inter-layer information interactions.
- * Resting-state functional MRI data from 46 BD patients and 54 controls was analyzed, constructing multilayer temporal networks to assess differences in dynamic reconfiguration through coefficients of promiscuity, recruitment, and integration.
- * Findings indicated that BD patients showed significantly lower inter-layer coupling and integration, particularly in key brain networks, suggesting impaired communication and stability within and between networks while also demonstrating increased functional interactions in some areas.
Article Abstract
Multilayer networks have been used to identify abnormal dynamic reconfiguration in bipolar disorder (BD). However, these studies ignore the differences in information interactions between adjacent layers when constructing multilayer networks, and the analysis of dynamic reconfiguration is not comprehensive enough; Methods: Resting-state functional magnetic resonance imaging data were collected from 46 BD patients and 54 normal controls. A multilayer temporal network was constructed for each subject, and inter-layer coupling of different nodes was considered using network similarity. The promiscuity, recruitment, and integration coefficients were calculated to quantify the different dynamic reconfigurations between the two groups; Results: The global inter-layer coupling, recruitment, and integration coefficients were significantly lower in BD patients. These results were further observed in the attention network and the limbic/paralimbic and subcortical network, reflecting reduced temporal stability, intra- and inter-subnetwork communication abilities in BD patients. The whole-brain promiscuity was increased in BD patients. The same results were observed in the somatosensory/motor and auditory network, reflecting more functional interactions; Conclusions: This study discovered abnormal dynamic interactions of BD from the perspective of dynamic reconfiguration, which can help to understand the pathological mechanisms of BD.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11430687 | PMC |
| http://dx.doi.org/10.3390/brainsci14090935 | DOI Listing |
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