FUNCTIONAL FRAGMENTATION AND STRUCTURAL DRIVERS OF THALAMO-CORTICAL CIRCUITS IN TEMPORAL LOBE EPILEPSY
W skrócie
[Preprint - wstępne wyniki] Badacze przeanalizowali dane z 250 pacjentów z padaczką skroniową i 259 zdrowych osób, aby zrozumieć, jak thalamus (głębokie struktury mózgu) komunikuje się z pozostałą częścią mózgu. Odkryli, że u pacjentów z padaczką połączenia między talamusem a korą mózgową oraz hipokampem są osłabione, zwłaszcza w regionach odpowiadających za pamięć i percepcję. Wyniki wskazują, że zaburzenia w połączeniach talamusu mogą wyjaśniać, dlaczego napady padaczki się rozprzestrzeniają, a także mogą pomóc przewidzieć, czy operacja chirurgiczna będzie skuteczna.
Oryginalny abstract (angielski)
Objective: In temporal lobe epilepsy (TLE), the thalamus acts as a nexus in a pathophysiological network that implicates mesiotemporal, subcortical, and neocortical regions. Studying a large multimodal and multicentre dataset, we profiled thalamic, hippocampal, and neocortical functional connectivity (FC), assessed structural mediators, and examined clinical associations. Methods. We studied resting-state FC alongside structural and diffusion MRI data in 250 unilateral TLE patients and 259 healthy controls, with measures aggregated across four independent datasets. Data were processed using open-access neuroinformatics workflows and analyzed at a subregional level to maximize anatomical precision. Statistical analysis and mediation models assessed between-group FC changes, structural contributors, and clinical correlations. Results. Compared to controls, TLE patients presented with reduced thalamo-cortical FC, which was most marked in mesiotemporal, fronto-central, and occipital regions. Thalamo-hippocampal FC was also reduced, with effects seen in all CA subfields. In the thalamus, FC reductions peaked in the ventral posterior nucleus when considering neocortical target regions and in the mediodorsal nucleus when considering hippocampal target regions. While ipsilateral hippocampal volume and diffusion changes mediated thalamo-hippocampal FC, thalamo-cortical FC appeared decoupled from structural alterations. Findings were consistent in left and right TLE patients, in patients with short and long disease duration, and across imaging sites, suggesting that thalamo-cortical FC imbalances are a consistent signature of TLE. Conversely, thalamo-hippocampal FC was elevated in patients with focal-to-bilateral-tonic-clonic seizures and FC alterations were more marked in the subgroup of operated patients that became seizure-free after surgery. Conclusion. Our multi-site findings demonstrate marked thalamic circuit fragmentation in TLE. Ipsilateral findings robustly showed subdivision-specific effects, which point to both mesiotemporal co-lateralization as well as broader system-level involvement. Mediation analyses furthermore confirmed a key role of hippocampal pathology in disrupted thalamo-hippocampal connectivity in TLE, while broader thalamo-cortical fragmentation becomes increasingly independent of mesiotemporal compromise. Critically, thalamic FC represents a network substrate for seizure generalization and can serve as a prognostic indicator for surgical outcome. These results underscore the contribution of the thalamus as a hub in macroscale dysfunction in TLE.
Metadane publikacji
Journal
Preprint (medRxiv/bioRxiv)
Data publikacji
11.07.2026
DOI
10.64898/2026.07.07.737072
Europe PMC ID
PPR1277769
Autorzy
Ding R, Xie K, Chen J, Ngo A, Fadaie F, Zhou G, Sahlas E, Dekraker J, Royer J, Rodriguez-Cruces R