Abstract
Epilepsy surgery is the treatment of choice for drug-resistant epilepsy patients. However, seizure-freedom is currently achieved in only 2/3 of the patients after surgery. In this study we have developed an individualized computational model based on MEG brain networks to explore seizure propagation and the efficacy of different virtual resections. Eventually, the goal is to obtain individualized models to optimize resection strategy and outcome. We have modelled seizure propagation as an epidemic process using the susceptible-infected (SI) model on individual brain networks derived from presurgical MEG. We included 10 patients who had received epilepsy surgery and for whom the surgery outcome at least one year after surgery was known. The model parameters were tuned in in order to reproduce the patient-specific seizure propagation patterns as recorded with invasive EEG. We defined a personalized search algorithm that combined structural and dynamical information to find resections that maximally decreased seizure propagation for a given resection size. The optimal resection for each patient was defined as the smallest resection leading to at least a 90% reduction in seizure propagation. The individualized model reproduced the basic aspects of seizure propagation for 9 out of 10 patients when using the resection area as the origin of epidemic spreading, and for 10 out of 10 patients with an alternative definition of the seed region. We found that, for 7 patients, the optimal resection was smaller than the resection area, and for 4 patients we also found that a resection smaller than the resection area could lead to a 100% decrease in propagation. Moreover, for two cases these alternative resections included nodes outside the resection area. Epidemic spreading models fitted with patient specific data can capture the fundamental aspects of clinically observed seizure propagation, and can be used to test virtual resections in silico. Combined with optimization algorithms, smaller or alternative resection strategies, that are individually targeted for each patient, can be determined with the ultimate goal to improve surgery outcome. MEG-based networks can provide a good approximation of structural connectivity for computational models of seizure propagation, and facilitate their clinical use.
Highlights
Engineering, Mathematics and Computer Science, Delft University of Technology, Delft, The Netherlands. *email: Scientific Reports | (2022) 12:4086
We found that the broad-band MEG-Amplitude Envelope Correlation (AEC) networks were a good surrogate for structural connectivity, with an average correlation of 0.51 ± 0.06 when considering the literature-based decay exponent and of 0.71 ± 0.08 when considering a modified exponent of −0.052 to fit this atlas resolution
Comparing the propagation patterns in the model to those observed clinically, we showed that this simple model reproduces the main aspects of the individual seizure propagation patterns, and that an alternative definition of the seed -based on the SEEG recordings- might provide a better reproduction of the observed propagation patterns
Summary
Engineering, Mathematics and Computer Science, Delft University of Technology, Delft, The Netherlands. *email: Scientific Reports | (2022) 12:4086. Going beyond topological network analysis, the simulation of ictal activity on top of brain networks can aid the identification of the EZ and prediction of surgery outcome, as well as predict possible side-effects Such computational models can be used to identify epileptogenic areas[33,34] or analyze different resection strategies[26,32,35–38], such that patient-specific resection strategies, that may lead to a better outcome or fewer side-effects than the standard surgery, can be tested[33,39–41]. Functional networks based on intracranial recordings[32,35,37,42,43] usually include ictal data and allow for highly precise characterization of some brain areas, spatial sampling is sparse and biased due to an a priori hypothesis of the EZ, which may lead to bias in the analysis These invasive recordings are not always part of the presurgical evaluation. MEG interictal resting-state functional brain networks have been used previously to identify the EZ11,27
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