Identifying spatio-temporal seizure propagation patterns in epilepsy using Bayesian inference

Vattikonda, Anirudh N.; Hashemi, Meysam; Sip, Viktor; Woodman, Michael; Bartolomei, Fabricē; Jirsa, Viktor K.

doi:10.1038/s42003-021-02751-5

Cited by 34 publications

(42 citation statements)

References 39 publications

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“…VEP uses personalized brain network models and machine learning methods by integrating epilepsy patient‐specific anatomical with functional data to provide a computational representation of the hypothesized epileptogenic and propagation zone networks in cerebral space. This method has recently been validated by modeling seizures previously recorded in SEEG 24,29 and on synthetic data 30,31 . The pilot study by Proix et al 29 further showed that VEP can reliably predict seizure propagation, suggesting that in the future this approach could improve SEEG analysis and consequently surgical prognosis.…”

Section: Introductionmentioning

confidence: 99%

Virtual epileptic patient brain modeling: Relationships with seizure onset and surgical outcome

et al. 2022

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Objective The virtual epileptic patient (VEP) is a large‐scale brain modeling method based on virtual brain technology, using stereoelectroencephalography (SEEG), anatomical data (magnetic resonance imaging [MRI] and connectivity), and a computational neuronal model to provide computer simulations of a patient's seizures. VEP has potential interest in the presurgical evaluation of drug‐resistant epilepsy by identifying regions most likely to generate seizures. We aimed to assess the performance of the VEP approach in estimating the epileptogenic zone and in predicting surgical outcome. Methods VEP modeling was retrospectively applied in a cohort of 53 patients with pharmacoresistant epilepsy and available SEEG, T1‐weighted MRI, and diffusion‐weighted MRI. Precision recall was used to compare the regions identified as epileptogenic by VEP (EZVEP) to the epileptogenic zone defined by clinical analysis incorporating the Epileptogenicity Index (EI) method (EZC). In 28 operated patients, we compared the VEP results and clinical analysis with surgical outcome. Results VEP showed a precision of 64% and a recall of 44% for EZVEP detection compared to EZC. There was a better concordance of VEP predictions with clinical results, with higher precision (77%) in seizure‐free compared to non‐seizure‐free patients. Although the completeness of resection was significantly correlated with surgical outcome for both EZC and EZVEP, there was a significantly higher number of regions defined as epileptogenic exclusively by VEP that remained nonresected in non‐seizure‐free patients. Significance VEP is the first computational model that estimates the extent and organization of the epileptogenic zone network. It is characterized by good precision in detecting epileptogenic regions as defined by a combination of visual analysis and EI. The potential impact of VEP on improving surgical prognosis remains to be exploited. Analysis of factors limiting the performance of the actual model is crucial for its further development.

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Section: Introductionmentioning

confidence: 99%

Virtual epileptic patient brain modeling: Relationships with seizure onset and surgical outcome

et al. 2022

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“…Taking advantage of recent advances in probabilistic programming languages (PPLs) for automatic Bayesian inference such as Stan (a state-of-the-art platform for statistical modeling), the feasibility of inverting the coupled Epileptor model that best explains patient's data from whole-brain source activity has been shown previously (Hashemi et al, 2020(Hashemi et al, , 2021. In other studies, efficient and robust inversion of seizure propagation on whole-brain intracranial recordings were achieved by either simplifying the seizure dynamics using a threshold model (Sip et al, 2021) which considerably restricts the range of model dynamics, or by embedding Epileptor equations as priors on brain source dynamics and using maximum a posteriori (MAP) techniques, which does not capture the uncertainty in parameters (Vattikonda et al, 2021). These issues could possibly be addressed by sampling the whole posterior of Epileptor parameters using gradient-based and self-tuning MCMC sampling algorithms such as No U-Turn sampler (NUTS; Hoffman and Gelman (2014)).…”

Section: Discussionmentioning

confidence: 99%

“…These issues could possibly be addressed by sampling the whole posterior of Epileptor parameters using gradient-based and self-tuning MCMC sampling algorithms such as No U-Turn sampler (NUTS; Hoffman and Gelman (2014)). However, MCMC sampling of the posterior density from sparse observations such as SEEG recordings becomes computationally infeasible, in particular when parameters in a high-dimensional model such as VEP show strong non-linear correlations or if the posterior exhibits pathological geometries such as Neal’s funnel with varying curvature (Betancourt et al, 2014; Vattikonda et al, 2021). Recently, a hybrid of NFs (such as inverse autoregressive flows parameterized by neural networks) and HMC called neural-transport (NeuTra) HMC (Hoffman et al, 2019) has been proposed to correct this sort of unfavorable geometry, while it works in the amortized setting.…”

Section: Discussionmentioning

confidence: 99%

Simulation-Based Inference for Whole-Brain Network Modeling of Epilepsy using Deep Neural Density Estimators

Hashemi¹,

Vattikonda²,

Jha³

et al. 2022

Preprint

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Whole-brain network modeling of epilepsy is a data-driven approach that combines personalized anatomical information with dynamical models of abnormal brain activity to generate spatio-temporal seizure patterns as observed in brain imaging signals. Such a parametric simulator is equipped with a stochastic generative process, which itself provides the basis for inference and prediction of the local and global brain dynamics affected by disorders. However, the calculation of likelihood function at whole-brain scale is often intractable. Thus, likelihood-free inference algorithms are required to efficiently estimate the parameters pertaining to the hypothetical areas in the brain, ideally including the uncertainty. In this detailed study, we present simulation-based inference for the virtual epileptic patient (SBI-VEP) model, which only requires forward simulations, enabling us to amortize posterior inference on parameters from low-dimensional data features representing whole-brain epileptic patterns. We use state-of-the-art deep learning algorithms for conditional density estimation to retrieve the statistical relationships between parameters and observations through a sequence of invertible transformations. This approach enables us to readily predict seizure dynamics from new input data. We show that the SBI-VEP is able to accurately estimate the posterior distribution of parameters linked to the extent of the epileptogenic and propagation zones in the brain from the sparse observations of intracranial EEG signals. The presented Bayesian methodology can deal with non-linear latent dynamics and parameter degeneracy, paving the way for reliable prediction of neurological disorders from neuroimaging modalities, which can be crucial for planning intervention strategies.

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“…This dual approach guides the identification of causal mechanisms, going beyond the estimation of statistical correlations in traditional data mining approaches. Examples include the Perturbation Complexity Index (PCI) used to assess effective connectivity ( Comolatti et al, 2019 ), variants of dynamic causal modeling used in The Virtual Brain (TVB; see below for examples of clinical applications) and uses of generative models in a “digital twin” approach ( Hashemi et al, 2020 ; Vattikonda et al, 2021 ), which optimizes parameters to best explain personalized data as a prelude to characterizing within and between subject variability.…”

Section: Brain Complexitymentioning

confidence: 99%

“… TVB, a data-driven neuroinformatics tool, fusing individual brain imaging data with atlas data and state-of-the-art brain modeling, for personalized simulations of brain activity and clinical interventions. Generative brain models operationalize a causal hypothesis, which is evaluated against the patient’s own brain imaging data using variants of dynamical causal modeling such as Monte Carlo simulations ( Hashemi et al, 2020 , 2021 ; Sip et al, 2021 ; Vattikonda et al, 2021 ; https://www.humanbrainproject.eu/en/medicine/the-virtual-brain/ ). …”

Section: The Role Of Modeling and Simulation In Diagnosis And Therapymentioning

confidence: 99%

Linking Brain Structure, Activity, and Cognitive Function through Computation

Amunts

DeFelipe

Pennartz

et al. 2022

eNeuro

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Identifying spatio-temporal seizure propagation patterns in epilepsy using Bayesian inference

Cited by 34 publications

References 39 publications

Virtual epileptic patient brain modeling: Relationships with seizure onset and surgical outcome

Virtual epileptic patient brain modeling: Relationships with seizure onset and surgical outcome

Simulation-Based Inference for Whole-Brain Network Modeling of Epilepsy using Deep Neural Density Estimators

Linking Brain Structure, Activity, and Cognitive Function through Computation

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