利用脑电图像表示和深度学习实现癫痫发作的自动诊断

Taranjit Kaur, Tapan Kumar Gandhi
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引用次数: 3

摘要

背景:通过人工检查来识别癫痫发作及其复杂的脑电图(EEG)波形是费时、繁琐且容易人为错误的。这些问题促使了自动癫痫检测系统的设计,该系统可以通过提供快速准确的分析来协助神经生理学家。现有的自动癫痫检测系统要么基于机器学习,要么基于深度学习。基于机器学习的算法采用复杂的特征选择方法手工制作特征。其结果是,它们的性能随所采用的特征提取和选择技术的选择而变化。另一方面,基于深度学习的方法可以自动推断出分类任务所需的最佳特征子集,但它们的计算成本很高,并且在临床脑电图数据集上缺乏泛化。为了解决上述局限性,并考虑到连续小波变换(CWT)在更好地阐明脑电图信号的非平稳性方面的优势,我们提出了一种基于脑电图图像表示(通过在不同尺度和时间间隔应用小波变换构建)和迁移学习的癫痫检测方法。首先,对预训练模型进行脑电图像表征的微调,然后通过对网络的不同层进行激活,从训练模型中提取特征。随后,使用10倍数据划分方案将特征传递给支持向量机(SVM)进行分类。结果及与现有方法的比较:所提出的机制的分类性能达到了一个上限水平(准确率=99.50/98.67,灵敏度=100/100;特异性=99/96),标准和临床数据集优于现有的最先进的作品。结论深度学习领域的快速发展为癫痫的自动诊断带来了范式的转变。该工具有效地标记出相关的脑电图片段供临床医生审查,从而减少了扫描长时间脑电图记录的时间负担。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Automated diagnosis of epileptic seizures using EEG image representations and deep learning

Background

The identification of seizure and its complex waveforms in electroencephalography (EEG) through manual examination is time consuming, tedious, and susceptible to human mistakes. These issues have prompted the design of an automated seizure detection system that can assist the neurophysiologists by providing a fast and accurate analysis.

Methods

Existing automated seizure detection systems are either machine learning based or deep learning based. Machine learning based algorithms employ handcrafted features with sophisticated feature selection approaches. As a result of which their performance varies with the choice of the feature extraction and selection techniques employed. On the other hand, deep learning-based methods automatically deduce the best subset of features required for the categorization task but they are computationally expensive and lacks generalization on clinical EEG datasets. To address the above stated limitations and motivated by the advantage of continuous wavelet transform's (CWT) in elucidating the non-stationary nature of the EEG signals in a better way, we propose an approach based on EEG image representations (constructed via applying WT at different scale and time intervals) and transfer learning for seizure detection. Firstly, the pre-trained model is fine-tuned on the EEG image representations and thereafter features are extracted from the trained model by performing activations on different layers of the network. Subsequently, the features are passed through a Support Vector Machine (SVM) for categorization using a 10-fold data partitioning scheme.

Results and comparison with existing methods

The proposed mechanism results in a ceiling level of classification performance (accuracy=99.50/98.67, sensitivity=100/100 & specificity=99/96) for both the standard and the clinical dataset that are better than the existing state-of-the art works.

Conclusion

The rapid advancement in the field of deep learning has created a paradigm shift in automated diagnosis of epilepsy. The proposed tool has effectually marked the relevant EEG segments for the clinician to review thereby reducing the time burden in scanning the long duration EEG records.

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来源期刊
Neuroscience informatics
Neuroscience informatics Surgery, Radiology and Imaging, Information Systems, Neurology, Artificial Intelligence, Computer Science Applications, Signal Processing, Critical Care and Intensive Care Medicine, Health Informatics, Clinical Neurology, Pathology and Medical Technology
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