OBJECTIVE : Wearable seizure detection devices could provide more reliable seizure documentation outside the hospital compared to seizure self-reporting by patients, which is the current standard. Previously, during the SeizeIT1 project, we studied seizure detection based on behind-the-ear electroencephalography (EEG). However, the obtained sensitivities were too low for practical use, because not all seizures are associated with typical ictal EEG patterns. Therefore, in this paper, we aim to develop a multimodal automated seizure detection algorithm integrating behind-the-ear EEG and electrocardiography (ECG) for detecting focal seizures. In this framework, we quantified the added value of ECG to behind-the-ear EEG.
METHODS : This study analyzed three multicenter databases consisting of 135 patients having focal epilepsy and a total of 896 seizures. A patient-specific multimodal automated seizure detection algorithm was developed using behind-the-ear/temporal EEG and single-lead ECG. The EEG and ECG data were processed separately using machine learning methods. A late integration approach was applied for fusing those predictions.
RESULTS : The multimodal algorithm outperformed the EEG-based algorithm in two of three databases, with an increase of 11% and 8% in sensitivity for the same false alarm rate.
SIGNIFICANCE : ECG can be of added value to an EEG-based seizure detection algorithm using only behind-the-ear/temporal lobe electrodes for patients with focal epilepsy.
Vandecasteele Kaat, De Cooman Thomas, Chatzichristos Christos, Cleeren Evy, Swinnen Lauren, Macea Ortiz Jaiver, Van Huffel Sabine, Dümpelmann Matthias, Schulze-Bonhage Andreas, De Vos Maarten, Van Paesschen Wim, Hunyadi Borbála
ECG, behind-the-ear EEG, epilepsy, multimodal algorithms, reduced electrode montage, seizure detection, wearable sensors