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使用基于无限脉冲响应(IIR)滤波器的心电图机器学习和深度学习模型对非专业人员进行心律失常分类。

Arrhythmia classification for non-experts using infinite impulse response (IIR)-filter-based machine learning and deep learning models of the electrocardiogram.

作者信息

K Mallikarjunamallu, Syed Khasim

机构信息

School of Computer Science and Engineering, VIT-AP University, Amaravati, Andhra Pradesh, India.

出版信息

PeerJ Comput Sci. 2024 Jan 24;10:e1774. doi: 10.7717/peerj-cs.1774. eCollection 2024.

DOI:10.7717/peerj-cs.1774
PMID:38435599
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10909216/
Abstract

Arrhythmias are a leading cause of cardiovascular morbidity and mortality. Portable electrocardiogram (ECG) monitors have been used for decades to monitor patients with arrhythmias. These monitors provide real-time data on cardiac activity to identify irregular heartbeats. However, rhythm monitoring and wave detection, especially in the 12-lead ECG, make it difficult to interpret the ECG analysis by correlating it with the condition of the patient. Moreover, even experienced practitioners find ECG analysis challenging. All of this is due to the noise in ECG readings and the frequencies at which the noise occurs. The primary objective of this research is to remove noise and extract features from ECG signals using the proposed infinite impulse response (IIR) filter to improve ECG quality, which can be better understood by non-experts. For this purpose, this study used ECG signal data from the Massachusetts Institute of Technology Beth Israel Hospital (MIT-BIH) database. This allows the acquired data to be easily evaluated using machine learning (ML) and deep learning (DL) models and classified as rhythms. To achieve accurate results, we applied hyperparameter (HP)-tuning for ML classifiers and fine-tuning (FT) for DL models. This study also examined the categorization of arrhythmias using different filters and the changes in accuracy. As a result, when all models were evaluated, DenseNet-121 without FT achieved 99% accuracy, while FT showed better results with 99.97% accuracy.

摘要

心律失常是心血管疾病发病和死亡的主要原因。便携式心电图(ECG)监测仪已使用数十年,用于监测心律失常患者。这些监测仪提供心脏活动的实时数据,以识别不规则心跳。然而,心律监测和波形检测,尤其是在12导联心电图中,通过将其与患者病情相关联来解释心电图分析变得困难。此外,即使是经验丰富的从业者也发现心电图分析具有挑战性。所有这些都是由于心电图读数中的噪声以及噪声出现的频率。本研究的主要目标是使用所提出的无限脉冲响应(IIR)滤波器去除噪声并从心电图信号中提取特征,以提高心电图质量,非专家也能更好地理解。为此,本研究使用了来自麻省理工学院贝斯以色列医院(MIT - BIH)数据库的心电图信号数据。这使得采集到的数据能够使用机器学习(ML)和深度学习(DL)模型轻松评估,并分类为不同的心律。为了获得准确的结果,我们对ML分类器应用了超参数(HP)调整,对DL模型应用了微调(FT)。本研究还研究了使用不同滤波器对心律失常进行分类以及准确性的变化。结果,当对所有模型进行评估时,未进行FT的DenseNet - 121达到了99%的准确率,而FT显示出更好的结果,准确率为99.97%。

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