# Integrating Artificial Intelligence with Real-time Intracranial EEG   Monitoring to Automate Interictal Identification of Seizure Onset Zones in   Focal Epilepsy

**Authors:** Yogatheesan Varatharajah, Brent Berry, Jan Cimbalnik, Vaclav Kremen,, Jamie Van Gompel, Matt Stead, Benjamin Brinkmann, Ravishankar Iyer, and, Gregory Worrell

arXiv: 1812.06234 · 2018-12-18

## TL;DR

This study presents an AI-based method that combines multiple electrophysiological biomarkers and their temporal features to reliably identify seizure onset zones in patients with focal epilepsy, potentially reducing invasive monitoring time.

## Contribution

The paper introduces a novel AI approach that integrates multiple biomarkers and temporal data, overcoming inter-patient variability to improve SOZ localization accuracy.

## Key findings

- Achieved an average AUC of 0.73 in SOZ identification.
- Recording durations of 90-120 minutes are sufficient for accurate localization.
- Outperformed previous single-biomarker incidence-based methods.

## Abstract

An ability to map seizure-generating brain tissue, i.e., the seizure onset zone (SOZ), without recording actual seizures could reduce the duration of invasive EEG monitoring for patients with drug-resistant epilepsy. A widely-adopted practice in the literature is to compare the incidence (events/time) of putative pathological electrophysiological biomarkers associated with epileptic brain tissue with the SOZ determined from spontaneous seizures recorded with intracranial EEG, primarily using a single biomarker. Clinical translation of the previous efforts suffers from their inability to generalize across multiple patients because of (a) the inter-patient variability and (b) the temporal variability in the epileptogenic activity. Here, we report an artificial intelligence-based approach for combining multiple interictal electrophysiological biomarkers and their temporal characteristics as a way of accounting for the above barriers and show that it can reliably identify seizure onset zones in a study cohort of 82 patients who underwent evaluation for drug-resistant epilepsy. Our investigation provides evidence that utilizing the complementary information provided by multiple electrophysiological biomarkers and their temporal characteristics can significantly improve the localization potential compared to previously published single-biomarker incidence-based approaches, resulting in an average area under ROC curve (AUC) value of 0.73 in a cohort of 82 patients. Our results also suggest that recording durations between ninety minutes and two hours are sufficient to localize SOZs with accuracies that may prove clinically relevant. The successful validation of our approach on a large cohort of 82 patients warrants future investigation on the feasibility of utilizing intra-operative EEG monitoring and artificial intelligence to localize epileptogenic brain tissue.

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Source: https://tomesphere.com/paper/1812.06234