Positional multi-length and mutual-attention network for epileptic seizure classification

IF 2.1 4区医学 Q2 MATHEMATICAL & COMPUTATIONAL BIOLOGY Frontiers in Computational Neuroscience Pub Date : 2024-01-05 DOI:10.3389/fncom.2024.1358780

Guokai Zhang, Aiming Zhang, Huan Liu, Jihao Luo, Jianqing Chen

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Abstract

The automatic classification of epilepsy electroencephalogram (EEG) signals plays a crucial role in diagnosing neurological diseases. Although promising results have been achieved by deep learning methods in this task, capturing the minute abnormal characteristics, contextual information, and long dependencies of EEG signals remains a challenge. To address this challenge, a positional multi-length and mutual-attention (PMM) network is proposed for the automatic classification of epilepsy EEG signals. The PMM network incorporates a positional feature encoding process that extracts minute abnormal characteristics from the EEG signal and utilizes a multi-length feature learning process with a hierarchy residual dilated LSTM (RDLSTM) to capture long contextual dependencies. Furthermore, a mutual-attention feature reinforcement process is employed to learn the global and relative feature dependencies and enhance the discriminative abilities of the network. To validate the effectiveness PMM network, we conduct extensive experiments on the public dataset and the experimental results demonstrate the superior performance of the PMM network compared to state-of-the-art methods.

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用于癫痫发作分类的位置多长和相互关注网络

癫痫脑电图（EEG）信号的自动分类在诊断神经系统疾病方面发挥着至关重要的作用。虽然深度学习方法在这一任务中取得了可喜的成果，但捕捉脑电信号的微小异常特征、上下文信息和长期依赖关系仍是一项挑战。为了应对这一挑战，我们提出了一种位置多长和相互关注（PMM）网络，用于癫痫脑电信号的自动分类。PMM 网络包含一个位置特征编码过程，可从脑电信号中提取微小的异常特征，并利用分层残差扩张 LSTM（RDLSTM）的多长度特征学习过程来捕捉长上下文相关性。此外，还采用了相互关注特征强化过程来学习全局和相对特征依赖关系，从而增强网络的分辨能力。为了验证 PMM 网络的有效性，我们在公共数据集上进行了大量实验，实验结果表明 PMM 网络的性能优于最先进的方法。

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来源期刊

Frontiers in Computational Neuroscience MATHEMATICAL & COMPUTATIONAL BIOLOGY-NEUROSCIENCES

CiteScore

5.30

自引率

3.10%

发文量

166

审稿时长

6-12 weeks

期刊介绍： Frontiers in Computational Neuroscience is a first-tier electronic journal devoted to promoting theoretical modeling of brain function and fostering interdisciplinary interactions between theoretical and experimental neuroscience. Progress in understanding the amazing capabilities of the brain is still limited, and we believe that it will only come with deep theoretical thinking and mutually stimulating cooperation between different disciplines and approaches. We therefore invite original contributions on a wide range of topics that present the fruits of such cooperation, or provide stimuli for future alliances. We aim to provide an interactive forum for cutting-edge theoretical studies of the nervous system, and for promulgating the best theoretical research to the broader neuroscience community. Models of all styles and at all levels are welcome, from biophysically motivated realistic simulations of neurons and synapses to high-level abstract models of inference and decision making. While the journal is primarily focused on theoretically based and driven research, we welcome experimental studies that validate and test theoretical conclusions. Also: comp neuro