Real-Time Cardiac Abnormality Monitoring and Nursing for Patient Using Electrocardiographic Signals.

IF 1.9 4区 医学 Q3 CARDIAC & CARDIOVASCULAR SYSTEMS Cardiology Pub Date : 2024-06-17 DOI:10.1159/000539767
Huamin Ao, Enjian Zhai, Le Jiang, Kailin Yang, Yuxuan Deng, Xiaoyang Guo, Liuting Zeng, Yexing Yan, Moujia Hao, Tian Song, Jinwen Ge, Junpeng Chen
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Abstract

Introduction: Cardiovascular disease nursing is a critical clinical application that necessitates real-time monitoring models. Previous models required the use of multi-lead signals and could not be customized as needed. Traditional methods relied on manually designed supervised algorithms, based on empirical experience, to identify waveform abnormalities and classify diseases, and were incapable of monitoring and alerting abnormalities in individual waveforms.

Methods: This research reconstructed the vector model for arbitrary leads using the phase space-time-delay method, enabling the model to arbitrarily combine signals as needed while possessing adaptive denoising capabilities. After employing automatically constructed machine learning algorithms and designing for rapid convergence, the model can identify abnormalities in individual waveforms and classify diseases, as well as detect and alert on abnormal waveforms.

Result: Effective noise elimination was achieved, obtaining a higher degree of loss function fitting. After utilizing the algorithm in Section 3.1 to remove noise, the signal-to-noise ratio increased by 8.6%. A clipping algorithm was employed to identify waveforms significantly affected by external factors. Subsequently, a network model established by a generative algorithm was utilized. The accuracy for healthy patients reached 99.2%, while the accuracy for APB was 100%, for LBBB 99.32%, for RBBB 99.1%, and for P-wave peak 98.1%.

Conclusion: By utilizing a three-dimensional model, detailed variations in electrocardiogram signals associated with different diseases can be observed. The clipping algorithm is effective in identifying perturbed and damaged waveforms. Automated neural networks can classify diseases and patient identities to facilitate precision nursing.

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利用心电信号实时监测和护理病人的心脏异常。
导言心血管疾病护理是一项重要的临床应用,需要实时监测模型。以前的模型需要使用多导联信号,而且无法根据需要进行定制。传统方法依赖于根据经验手动设计的监督算法来识别波形异常和进行疾病分类,无法监测和警报单个波形的异常。方法 这项研究利用相位空间时间延迟法重建了任意导联的向量模型,使模型能够根据需要任意组合信号,同时具备自适应去噪功能。在采用自动构建的机器学习算法和快速收敛设计后,该模型可识别单个波形的异常并对疾病进行分类,还能检测异常波形并发出警报。结果 有效消除了噪声,获得了更高的损失函数拟合度。随后,利用单导联三维模型放大了心电信号的细节差异。使用裁剪算法去除受外界因素严重干扰的波形。然后,使用自动神经网络识别。针对不同的数据类型设计了有效的自动网络生成模型。患者识别的准确率为 98.2%,健康患者识别的准确率为 99.2%。结论 弹性小波神经网络可以自动去噪。通过三维模型,可以观察到不同疾病心电信号的细节变化。裁剪算法能有效识别被干扰和破坏的波形。自动神经网络能够进行疾病类型分类和患者身份分类。
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来源期刊
Cardiology
Cardiology 医学-心血管系统
CiteScore
3.40
自引率
5.30%
发文量
56
审稿时长
1.5 months
期刊介绍: ''Cardiology'' features first reports on original clinical, preclinical and fundamental research as well as ''Novel Insights from Clinical Experience'' and topical comprehensive reviews in selected areas of cardiovascular disease. ''Editorial Comments'' provide a critical but positive evaluation of a recent article. Papers not only describe but offer critical appraisals of new developments in non-invasive and invasive diagnostic methods and in pharmacologic, nutritional and mechanical/surgical therapies. Readers are thus kept informed of current strategies in the prevention, recognition and treatment of heart disease. Special sections in a variety of subspecialty areas reinforce the journal''s value as a complete record of recent progress for all cardiologists, internists, cardiac surgeons, clinical physiologists, pharmacologists and professionals in other areas of medicine interested in current activity in cardiovascular diseases.
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