Our work has demonstrated notable changes in the thalamus and basal ganglia characteristics due to focal epilepsy. Uniquely, we highlighted the added value of evaluating multiple features to understand the heterogeneity among focal epilepsy patients. Specifically, we found that changes in the structures' volumes are effective in distinguishing between patients and controls, while alterations in T1 properties are useful in differentiating between various epilepsy types. Importantly, these results were consistent across different subcortical parcellation schemes, reaffirming their reliability.
Moreover, our preprint that integrates sodium MRI with structural connectivity has identified a particular sodium metric, termed 'f', which is especially sensitive to the epileptogenicity of brain structures. On a global scale, we observed that sodium homeostasis differs in hub regions, showing higher sodium levels compared to non-hub regions. This finding underscores the sensitivity of sodium MRI to the degree of connectivity of brain regions.
Additionally, in another preprint, we proposed a framework based on structural connectivity pattern analysis that has the potential to optimize deep brain stimulation targeting. This framework could have significant implications for personalizing thalamic stimulation in focal epilepsy patients, offering a tailored approach to treatment that could enhance therapeutic outcomes.