Onset Detection of Epileptic Seizures From Accelerometry Signal

Epileptic seizures are the result of any abnormal asynchronous firing of cortical neurons. Seizures are abrupt and pose a risk of injury and fatal harm to the patient. Epilepsy affects patients quality of life (QOL) and imposes financial, social, and physical burden on the patient. The unpredictability associated with seizures further adds to the reduced QOL and increases dependence on caregivers and family members. A seizure triggered alarm system can reduce the risk of seizure-related injuries and aid in improving patient's QOL. This study presents real-time onset detection of seizures from accelerometry signal. An automated approach based on statistical machine learning is employed to learn the onset of seizures. To search for the optimal parameter that simultaneously maximizes detection sensitivity (sens) while minimizing false alarm rate (FAR) and latency, the epoch length is varied from $t=\{1,~10s\}$. Linear and non-linear time-varying dynamical patterns were extracted from every epoch using Poincaré plot analysis. The correlation patterns were learned using a kernalized support vector data descriptor. The preliminary analysis on accelerometry data collected from 8 epileptic patients with 9 generalized tonicclonic seizures (GTCS) shows promising results. The proposed algorithm detected all GTCS events (sens: 100%, FAR: 1. 09/24h) at 8s from onset. The proposed algorithm can lead to a sensitive, specific, and a relatively short-latency detection system for real-time remote monitoring of epileptic patients.

[1]  G. Baker,et al.  Determinants of quality of life in people with epilepsy. , 2009, Neurologic clinics.

[2]  C. Dolea,et al.  World Health Organization , 1949, International Organization.

[3]  M. Palaniswami,et al.  Complex Correlation Measure: a novel descriptor for Poincaré plot , 2009, BioMedical Engineering OnLine.

[4]  Marimuthu Palaniswami,et al.  Automatic Detection and Classification of Convulsive Psychogenic Nonepileptic Seizures Using a Wearable Device , 2016, IEEE Journal of Biomedical and Health Informatics.

[5]  Chandan Srivastava,et al.  Support Vector Data Description , 2011 .

[6]  Robert P. W. Duin,et al.  Support Vector Data Description , 2004, Machine Learning.

[7]  Helge B. D. Sørensen,et al.  Automated Algorithm for Generalized Tonic–Clonic Epileptic Seizure Onset Detection Based on sEMG Zero-Crossing Rate , 2012, IEEE Transactions on Biomedical Engineering.

[8]  Marimuthu Palaniswami,et al.  Detection of generalized tonic-clonic seizures using short length accelerometry signal , 2017, 2017 39th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).

[9]  R. Harner,et al.  Patient-Specific Early Seizure Detection From Scalp Electroencephalogram , 2010, Journal of clinical neurophysiology : official publication of the American Electroencephalographic Society.

[10]  Orrin Devinsky,et al.  Recognizing and preventing epilepsy-related mortality , 2016, Neurology.

[11]  Sabine Van Huffel,et al.  Automated Detection of Tonic–Clonic Seizures Using 3-D Accelerometry and Surface Electromyography in Pediatric Patients , 2016, IEEE Journal of Biomedical and Health Informatics.

[12]  T. Loddenkemper,et al.  Automated seizure detection systems and their effectiveness for each type of seizure , 2016, Seizure.

[13]  Ali H. Shoeb,et al.  An algorithm for seizure onset detection using intracranial EEG , 2011, Epilepsy & Behavior.

[14]  Rosalind W. Picard,et al.  Convulsive seizure detection using a wrist‐worn electrodermal activity and accelerometry biosensor , 2012, Epilepsia.

[15]  Tobias Loddenkemper,et al.  Seizure detection, seizure prediction, and closed-loop warning systems in epilepsy , 2014, Epilepsy & Behavior.