Abstract
BackgroundEpilepsy is a neurological disease characterized by unprovoked seizures in the brain. The recent advances in sensor technologies allow researchers to analyze the collected biological records to improve the treatment of epilepsy. Electroencephalogram (EEG) is the most commonly used biological measurement to effectively capture the abnormalities of different brain areas during the EEG seizures. To avoid manual visual inspection from long-term EEG readings, automatic epileptic EEG seizure detection has become an important research issue in bioinformatics.ResultsWe present a multi-context learning approach to automatically detect EEG seizures by incorporating a feature fusion strategy. We generate EEG scalogram sequences from the EEG records by utilizing waveform transform to describe the frequency content over time. We propose a multi-stage unsupervised model that integrates the features extracted from the global handcrafted engineering, channel-wise deep learning, and EEG embeddings, respectively. The learned multi-context features are subsequently merged to train a seizure detector.ConclusionsTo validate the effectiveness of the proposed approach, extensive experiments against several baseline methods are carried out on two benchmark biological datasets. The experimental results demonstrate that the representative context features from multiple perspectives can be learned by the proposed model, and further improve the performance for the task of EEG seizure detection.
Highlights
Epilepsy is a neurological disease characterized by unprovoked seizures in the brain
We develop a channel-wise deep learning module to learn a dictionary of EEG scalogram fragments by unsupervisedly extracting inherent features from each EEG channel
The proposed approach is a multi-stage unsupervised feature learning model that explicitly takes into account the features extracted from three modules, including the global handcrafted engineering, channel-wise deep learning, and EEG embeddings
Summary
Epilepsy is a neurological disease characterized by unprovoked seizures in the brain. The recent advances in sensor technologies allow researchers to analyze the collected biological records to improve the treatment of epilepsy. Electroencephalogram (EEG) is the most commonly used biological measurement to effectively capture the abnormalities of different brain areas during the EEG seizures. To avoid manual visual inspection from long-term EEG readings, automatic epileptic EEG seizure detection has become an important research issue in bioinformatics. People with epilepsy are two to three times more likely to die prematurely treatment and prevention to patients, epileptic seizure detection has garnered great interest among researchers in bioinformatics. The biological data recorded by pervasive sensors can be used to analyze clinical observations of epileptic seizures, and improve the treatment of epilepsy [8].
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