Seizure freedom after surgical resection of diffusion‐weighted magnetic resonance imaging abnormalities.

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Title: Seizure freedom after surgical resection of diffusion‐weighted magnetic resonance imaging abnormalities.
Authors: Horsley, Jonathan (AUTHOR), Hall, Gerard (AUTHOR), Simpson, Callum (AUTHOR), Kozma, Csaba (AUTHOR), Thomas, Rhys (AUTHOR), Wang, Yujiang (AUTHOR), de Tisi, Jane (AUTHOR), Miserocchi, Anna (AUTHOR), McEvoy, Andrew (AUTHOR), Vos, Sjoerd (AUTHOR), Winston, Gavin (AUTHOR), Duncan, John (AUTHOR), Taylor, Peter N. (AUTHOR)
Source: Epilepsia (Series 4). Sep2025, Vol. 66 Issue 9, p3480-3490. 11p.
Subjects: Diffusion magnetic resonance imaging, Epilepsy, Brain imaging, Brain abnormalities, Surgery, Partial epilepsy, Treatment effectiveness
Abstract: Objective: Successful epilepsy surgery requires accurate localization and removal of the epileptogenic zone. Neuroimaging helps detect structural brain abnormalities to guide surgery, but current clinical practice does not use diffusion‐weighted magnetic resonance imaging (dwMRI). However, previous work has shown that diffusion abnormalities are present in epilepsy and may relate to the epileptogenic zone. Here, we investigate whether surgical resection of diffusion abnormalities relates to postoperative seizure freedom. Methods: We investigated the association between surgical resection of diffusion abnormalities and postoperative seizure freedom in 200 individuals with drug‐resistant focal epilepsy using dwMRI. A cohort of 97 healthy controls provided a normative baseline for dwMRI metrics, allowing calculation of voxelwise z‐scores to identify abnormal clusters in both gray and white matter. Results: Surgical resections overlapping with the largest abnormal cluster significantly correlated with sustained seizure freedom at 12 months (83% vs. 55%; p<.0001) and over 5 years (p<.0001). Notably, resecting only a small proportion of the largest cluster was associated with better seizure outcomes than cases with no resection of this cluster (p=.008). Furthermore, sparing the largest cluster but resecting other large clusters still improved seizure freedom rates compared to no overlap (p=.03). Significance: Our results suggest that abnormal clusters, identified using dwMRI, are integral to the epileptogenic network, and even a partial removal of such an abnormal cluster is sufficient to achieve seizure freedom. This study highlights the potential of incorporating dwMRI into presurgical planning to improve outcomes in focal epilepsy by reliably identifying and targeting diffusion abnormalities. [ABSTRACT FROM AUTHOR]
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Database: Psychology and Behavioral Sciences Collection
Description
Abstract:Objective: Successful epilepsy surgery requires accurate localization and removal of the epileptogenic zone. Neuroimaging helps detect structural brain abnormalities to guide surgery, but current clinical practice does not use diffusion‐weighted magnetic resonance imaging (dwMRI). However, previous work has shown that diffusion abnormalities are present in epilepsy and may relate to the epileptogenic zone. Here, we investigate whether surgical resection of diffusion abnormalities relates to postoperative seizure freedom. Methods: We investigated the association between surgical resection of diffusion abnormalities and postoperative seizure freedom in 200 individuals with drug‐resistant focal epilepsy using dwMRI. A cohort of 97 healthy controls provided a normative baseline for dwMRI metrics, allowing calculation of voxelwise z‐scores to identify abnormal clusters in both gray and white matter. Results: Surgical resections overlapping with the largest abnormal cluster significantly correlated with sustained seizure freedom at 12 months (83% vs. 55%; p<.0001) and over 5 years (p<.0001). Notably, resecting only a small proportion of the largest cluster was associated with better seizure outcomes than cases with no resection of this cluster (p=.008). Furthermore, sparing the largest cluster but resecting other large clusters still improved seizure freedom rates compared to no overlap (p=.03). Significance: Our results suggest that abnormal clusters, identified using dwMRI, are integral to the epileptogenic network, and even a partial removal of such an abnormal cluster is sufficient to achieve seizure freedom. This study highlights the potential of incorporating dwMRI into presurgical planning to improve outcomes in focal epilepsy by reliably identifying and targeting diffusion abnormalities. [ABSTRACT FROM AUTHOR]
ISSN:00139580
DOI:10.1111/epi.18490