Bibliographic Details
| Title: |
Mapping epileptogenic brain using a unified spatial–temporal– spectral source imaging framework. |
| Authors: |
Jiang, Xiyuan1, Cai, Zhengxiang1, Gonsisko, Colton1, Worrell, Gregory A.2, He, Bin1 bhe1@andrew.cmu.edu |
| Source: |
Proceedings of the National Academy of Sciences of the United States of America. 12/16/2025, Vol. 122 Issue 50, p1-11. 11p. |
| Subjects: |
Spectral imaging, Brain function localization, Electrophysiology, Neurophysiology, Oscillations, Partial epilepsy, Computer-assisted image analysis (Medicine) |
| Abstract: |
Noninvasive electrophysiological source imaging (ESI) is a valuable tool for localizing and imaging brain activity, with significant potential to aid presurgical planning in focal drug-resistant epilepsy (fDRE) patients. Scalp electroencephalography (EEG) biomarkers, including interictal spikes, high-frequency oscillations (HFOs), and seizures, each offer unique capabilities in estimating the epileptogenic zone (EZ). However, there is a limited quantitative understanding of how these biomarkers differ in source-imaging precision, requiring distinct processing pipelines. Here, we developed a spatial–temporal–spectral imaging (STSI) framework for precision source imaging, and quantitatively evaluated various epilepsy biomarkers for source imaging in 2,081 individual events (spikes, HFOs, and seizures) from a cohort of 42 fDRE patients, comparing results to clinical ground truth such as surgical resection outcomes and intracranial EEG-defined seizure onset zones. The STSI enabled quantitative comparisons across key EEG epilepsy-related biomarkers, with averaged localization errors of 6.67 mm for seizures, 8.73 mm for HFOs overlapping with spikes (pHFO), 10.28 mm for HFO-riding spikes (pSpike), 19.59 mm for general spikes (aSpike), and 36.53 mm for general HFOs (aHFO), respectively, for seizure-free patients. These findings indicate that HFOs overlapping with spikes is the most spatially accurate interictal biomarker for mapping the EZ. The proposed STSI framework not only establishes a unified analysis approach for epileptic biomarkers to enhance presurgical planning in focal drug-resistant epilepsy, but could also generalize as a versatile tool for mapping event-related potentials, neural oscillations, and dynamic brain states, within a single framework to advance cognitive neuroscience research and clinical management of neurological and psychiatric disorders. [ABSTRACT FROM AUTHOR] |
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| Database: |
Engineering Source |
