Real-time epileptic seizure recognition using Bayesian genetic whale optimizer and adaptive machine learning

The electroencephalogram (EEG) has been commonly used to identify epileptic seizures, but identifi-cation of seizures from EEG remains a challenging task that requires qualified neurophysiologists. It is important to detect seizures in real time, which can be achieved in an internet of things (IoT)-based cloud platform to alert patients of impending seizures. Therefore, in this study, we propose a new model to recognize seizure states (e.g., ictal, preictal, interictal) from EEG in the IoT framework to monitor patients remotely. The proposed model uses an efficient hybrid genetic whale optimization algorithm (GWOA) based on naive Bayes (NB-GWOA) for feature selection, and an adaptive extreme learning machine (ELM) based on a differential evolutionary (DE) algorithm (DEELM) for classification. In the NB-GWOA method, the genetic algorithm serves to enhance the exploitation of the whale optimization algorithm in the search of the optimal solutions, while the naive Bayes method is used to determine a fitness function to assess every agent in the search space. GWOA has strong robustness and is capable of finding the best solutions in less than five iterations, so it is suitable for selecting discriminative features from a huge number of neurofeatures obtained from EEG. Further, the classification model is constructed based on ELM, which uses the DE algorithm for a fast and efficient learning solution. Results show that the proposed NB-GWOA-DEELM model can avoid over and under-fitting and can provide better and more accurate performance in classifying seizure states from EEG than its competitors. (C) 2021 Elsevier B.V. All rights reserved.

Automated summary

In this study, a new model is proposed to recognize seizure states from EEG within an IoT framework, utilizing innovative algorithms for feature selection and classification. Experimental results demonstrate that the model performs better and more accurately in identifying seizure states compared to existing methods.