Litcius/Paper detail

Bridging the gap between patient-specific and patient-independent seizure prediction via knowledge distillation

Di Wu, Jie Yang, Mohamad Sawan

2022Journal of Neural Engineering33 citationsDOIOpen Access PDF

Abstract

Abstract Objective. Deep neural networks (DNNs) have shown unprecedented success in various brain-machine interface applications such as epileptic seizure prediction. However, existing approaches typically train models in a patient-specific fashion due to the highly personalized characteristics of epileptic signals. Therefore, only a limited number of labeled recordings from each subject can be used for training. As a consequence, current DNN based methods demonstrate poor generalization ability to some extent due to the insufficiency of training data. On the other hand, patient-independent models attempt to utilize more patient data to train a universal model for all patients by pooling patient data together. Despite different techniques applied, results show that patient-independent models perform worse than patient-specific models due to high individual variation across patients. A substantial gap thus exists between patient-specific and patient-independent models. Approach . In this paper, we propose a novel training scheme based on knowledge distillation which makes use of a large amount of data from multiple subjects. It first distills informative features from signals of all available subjects with a pre-trained general model. A patient-specific model can then be obtained with the help of distilled knowledge and additional personalized data. Main results . Four state-of-the-art seizure prediction methods are trained on the Children’s Hospital of Boston-MIT sEEG database with our proposed scheme. The resulting accuracy, sensitivity, and false prediction rate show that our proposed training scheme consistently improves the prediction performance of state-of-the-art methods by a large margin. Significance. The proposed training scheme significantly improves the performance of patient-specific seizure predictors and bridges the gap between patient-specific and patient-independent predictors.

Topics & Concepts

Computer scienceMargin (machine learning)Artificial intelligencePoolingMachine learningGeneralizationMathematical analysisMathematicsEEG and Brain-Computer InterfacesAdvanced Neural Network ApplicationsEpilepsy research and treatment