Attention-based deep convolutional neural network for classification of generalized and focal epileptic seizures

Epilepsy affects over 50 million people globally. Electroencephalography is critical for epilepsy diagnosis, but manual seizure classification is time-consuming and requires extensive expertise. This paper presents an automated multi-class seizure classification model using EEG signals from the Temp...

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Bibliographic Details
Published in:Epilepsy & behavior 2024-06, Vol.155, p.109732-109732, Article 109732
Main Authors: Gill, Taimur Shahzad, Zaidi, Syed Sajjad Haider, Shirazi, Muhammad Ayaz
Format: Article
Language:English
Subjects:
Adult
Attention - physiology
Convolution Neural Network
Deep Learning
Electroencephalogram
Electroencephalography - methods
Epilepsies, Partial - classification
Epilepsies, Partial - diagnosis
Epilepsies, Partial - physiopathology
Epilepsy
Epilepsy, Generalized - classification
Epilepsy, Generalized - diagnosis
Epilepsy, Generalized - physiopathology
Epileptic Seizures
Female
Humans
Male
Multi-Headed Attention Mechanism
Neural Networks, Computer
Seizures - classification
Seizures - diagnosis
Seizures - physiopathology
Young Adult
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Summary:Epilepsy affects over 50 million people globally. Electroencephalography is critical for epilepsy diagnosis, but manual seizure classification is time-consuming and requires extensive expertise. This paper presents an automated multi-class seizure classification model using EEG signals from the Temple University Hospital Seizure Corpus ver. 1.5.2. 11 features including time-based correlation, time-based eigenvalues, power spectral density, frequency-based correlation, frequency-based eigenvalues, sample entropy, spectral entropy, logarithmic sum, standard deviation, absolute mean, and ratio of Daubechies D4 wavelet transformed coefficients were extracted from 10-second sliding windows across channels. The model combines multi-head self-attention mechanism with a deep convolutional neural network (CNN) to classify seven subtypes of generalized and focal epileptic seizures. The model achieved 0.921 weighted accuracy and 0.902 weighted F1 score in classifying focal onset non-motor, generalized onset non-motor, simple partial, complex partial, absence, tonic, and tonic-clonic seizures. In comparison, a CNN model without multi-head attention achieved 0.767 weighted accuracy. Ablation studies were conducted to validate the importance of transformer encoders and attention. The promising classification results demonstrate the potential of deep learning for handling EEG complexity and improving epilepsy diagnosis. This seizure classification model could enable timely interventions when translated into clinical practice.
ISSN:1525-5050
1525-5069
DOI:10.1016/j.yebeh.2024.109732