Early Diagnosis of Neurodegenerative Diseases Using CNN-LSTM and Wavelet Transform.

IF 5.9 Q1 Computer Science Journal of Healthcare Informatics Research Pub Date : 2023-02-13 eCollection Date: 2023-03-01 DOI:10.1007/s41666-023-00130-9

Elmira Amooei, Arash Sharifi, Mohammad Manthouri

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Abstract

Early diagnosis of neurodegenerative diseases has always been a major challenge that physicians and medical practitioners face. Therefore, using any method or device that helps with prognostics is of great importance. In recent years, deep neural networks have become popular in medical fields, and the reason is that these networks can help diagnose diseases quickly and precisely. In this research, two novel models based on a CNN-LSTM network are introduced. The main goal is to classify three neurodegenerative diseases, including ALS, Parkinson's disease, and Huntington's disease, from one another and from healthy control patients using the gait signals, which are transformed into spectrogram images. In the first model, the spectrogram images derived from the gait signals are fed into a CNN-LSTM network directly. This model achieved 99.42% accuracy. In the second model, the same input data was used to be classified using a CNN-LSTM network, which uses wavelet transform as a feature extractor before the LSTM unit. During the experiments with the second model, the detail sub-bands were eliminated one by one, and the classification results were compared. Comparing these two models has shown that using the wavelet transform and, in particular, the approximation sub-bands can result in a lighter and faster prognosis with nearly 103 times fewer training parameters overall. The classification result using only approximation sub-bands was 95.37%, using three sub-bands was 94.04%, and including all sub-bands was 94.53%, which is remarkable.

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利用 CNN-LSTM 和小波变换早期诊断神经退行性疾病

神经退行性疾病的早期诊断一直是医生和医务工作者面临的一大挑战。因此，使用任何有助于预后的方法或设备都非常重要。近年来，深度神经网络在医学领域大受欢迎，原因就在于这些网络可以帮助快速、精确地诊断疾病。在这项研究中，引入了两个基于 CNN-LSTM 网络的新型模型。主要目标是利用步态信号，将其转化为频谱图图像，对三种神经退行性疾病（包括渐冻人症、帕金森病和亨廷顿病）进行相互分类，以及对健康对照组患者进行分类。在第一个模型中，从步态信号中提取的频谱图图像直接输入 CNN-LSTM 网络。该模型的准确率达到 99.42%。在第二个模型中，使用 CNN-LSTM 网络对相同的输入数据进行分类，该网络在 LSTM 单元之前使用小波变换作为特征提取器。在第二个模型的实验中，细节子波段被逐一消除，并对分类结果进行了比较。这两个模型的比较结果表明，使用小波变换，特别是近似子带，可以使预报更轻、更快，总体上减少了近 103 倍的训练参数。仅使用近似子带的分类结果为 95.37%，使用三个子带的分类结果为 94.04%，而包含所有子带的分类结果为 94.53%，成绩斐然。

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来源期刊

Journal of Healthcare Informatics Research Computer Science-Computer Science Applications

CiteScore

13.60

自引率

1.70%

发文量

期刊介绍： Journal of Healthcare Informatics Research serves as a publication venue for the innovative technical contributions highlighting analytics, systems, and human factors research in healthcare informatics.Journal of Healthcare Informatics Research is concerned with the application of computer science principles, information science principles, information technology, and communication technology to address problems in healthcare, and everyday wellness. Journal of Healthcare Informatics Research highlights the most cutting-edge technical contributions in computing-oriented healthcare informatics. The journal covers three major tracks: (1) analytics—focuses on data analytics, knowledge discovery, predictive modeling; (2) systems—focuses on building healthcare informatics systems (e.g., architecture, framework, design, engineering, and application); (3) human factors—focuses on understanding users or context, interface design, health behavior, and user studies of healthcare informatics applications. Topics include but are not limited to: · healthcare software architecture, framework, design, and engineering;· electronic health records· medical data mining· predictive modeling· medical information retrieval· medical natural language processing· healthcare information systems· smart health and connected health· social media analytics· mobile healthcare· medical signal processing· human factors in healthcare· usability studies in healthcare· user-interface design for medical devices and healthcare software· health service delivery· health games· security and privacy in healthcare· medical recommender system· healthcare workflow management· disease profiling and personalized treatment· visualization of medical data· intelligent medical devices and sensors· RFID solutions for healthcare· healthcare decision analytics and support systems· epidemiological surveillance systems and intervention modeling· consumer and clinician health information needs, seeking, sharing, and use· semantic Web, linked data, and ontology· collaboration technologies for healthcare· assistive and adaptive ubiquitous computing technologies· statistics and quality of medical data· healthcare delivery in developing countries· health systems modeling and simulation· computer-aided diagnosis