Wearable Electrocardiogram Quality Assessment Using Wavelet Scattering and LSTM

As the fast development of wearable devices and Internet of things technologies, real-time monitoring of ECG signals is quite critical for cardiovascular diseases. However, dynamic ECG signals recorded in free-living conditions suffered from extremely serious noise pollution. Presently, most algorit...

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Autores principales: Liu, Feifei, Xia, Shengxiang, Wei, Shoushui, Chen, Lei, Ren, Yonglian, Ren, Xiaofei, Xu, Zheng, Ai, Sen, Liu, Chengyu
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Frontiers Media S.A. 2022
Materias:
Physiology
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9281614/
https://www.ncbi.nlm.nih.gov/pubmed/35845989
http://dx.doi.org/10.3389/fphys.2022.905447
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author Liu, Feifei
Xia, Shengxiang
Wei, Shoushui
Chen, Lei
Ren, Yonglian
Ren, Xiaofei
Xu, Zheng
Ai, Sen
Liu, Chengyu
author_facet Liu, Feifei
Xia, Shengxiang
Wei, Shoushui
Chen, Lei
Ren, Yonglian
Ren, Xiaofei
Xu, Zheng
Ai, Sen
Liu, Chengyu
author_sort Liu, Feifei
collection PubMed
description As the fast development of wearable devices and Internet of things technologies, real-time monitoring of ECG signals is quite critical for cardiovascular diseases. However, dynamic ECG signals recorded in free-living conditions suffered from extremely serious noise pollution. Presently, most algorithms for ECG signal evaluation were designed to divide signals into acceptable and unacceptable. Such classifications were not enough for real-time cardiovascular disease monitoring. In the study, a wearable ECG quality database with 50,085 recordings was built, including A/B/C (or high quality/medium quality/low quality) three quality grades (A: high quality signals can be used for CVD detection; B: slight contaminated signals can be used for heart rate extracting; C: heavily polluted signals need to be abandoned). A new SQA classification method based on a three-layer wavelet scattering network and transfer learning LSTM was proposed in this study, which can extract more systematic and comprehensive characteristics by analyzing the signals thoroughly and deeply. Experimental results ( mACC = 98.56%, mF ( 1 ) = 98.55%, Se (A) = 97.90%, Se (B) = 98.16%, Se (C) = 99.60%, + P (A) = 98.52%, + P (B) = 97.60%, + P (C) = 99.54%, F (1A) = 98.20%, F (1B) = 97.90%, F (1C) = 99.60%) and real data validations proved that this proposed method showed the high accuracy, robustness, and computationally efficiency. It has the ability to evaluate the long-term dynamic ECG signal quality. It is advantageous to promoting cardiovascular disease monitoring by removing contaminating signals and selecting high-quality signal segments for further analysis.
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spelling pubmed-92816142022-07-15 Wearable Electrocardiogram Quality Assessment Using Wavelet Scattering and LSTM Liu, Feifei Xia, Shengxiang Wei, Shoushui Chen, Lei Ren, Yonglian Ren, Xiaofei Xu, Zheng Ai, Sen Liu, Chengyu Front Physiol Physiology As the fast development of wearable devices and Internet of things technologies, real-time monitoring of ECG signals is quite critical for cardiovascular diseases. However, dynamic ECG signals recorded in free-living conditions suffered from extremely serious noise pollution. Presently, most algorithms for ECG signal evaluation were designed to divide signals into acceptable and unacceptable. Such classifications were not enough for real-time cardiovascular disease monitoring. In the study, a wearable ECG quality database with 50,085 recordings was built, including A/B/C (or high quality/medium quality/low quality) three quality grades (A: high quality signals can be used for CVD detection; B: slight contaminated signals can be used for heart rate extracting; C: heavily polluted signals need to be abandoned). A new SQA classification method based on a three-layer wavelet scattering network and transfer learning LSTM was proposed in this study, which can extract more systematic and comprehensive characteristics by analyzing the signals thoroughly and deeply. Experimental results ( mACC = 98.56%, mF ( 1 ) = 98.55%, Se (A) = 97.90%, Se (B) = 98.16%, Se (C) = 99.60%, + P (A) = 98.52%, + P (B) = 97.60%, + P (C) = 99.54%, F (1A) = 98.20%, F (1B) = 97.90%, F (1C) = 99.60%) and real data validations proved that this proposed method showed the high accuracy, robustness, and computationally efficiency. It has the ability to evaluate the long-term dynamic ECG signal quality. It is advantageous to promoting cardiovascular disease monitoring by removing contaminating signals and selecting high-quality signal segments for further analysis. Frontiers Media S.A. 2022-06-30 /pmc/articles/PMC9281614/ /pubmed/35845989 http://dx.doi.org/10.3389/fphys.2022.905447 Text en Copyright © 2022 Liu, Xia, Wei, Chen, Ren, Ren, Xu, Ai and Liu. https://creativecommons.org/licenses/by/4.0/This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
spellingShingle Physiology
Liu, Feifei
Xia, Shengxiang
Wei, Shoushui
Chen, Lei
Ren, Yonglian
Ren, Xiaofei
Xu, Zheng
Ai, Sen
Liu, Chengyu
Wearable Electrocardiogram Quality Assessment Using Wavelet Scattering and LSTM
title Wearable Electrocardiogram Quality Assessment Using Wavelet Scattering and LSTM
title_full Wearable Electrocardiogram Quality Assessment Using Wavelet Scattering and LSTM
title_fullStr Wearable Electrocardiogram Quality Assessment Using Wavelet Scattering and LSTM
title_full_unstemmed Wearable Electrocardiogram Quality Assessment Using Wavelet Scattering and LSTM
title_short Wearable Electrocardiogram Quality Assessment Using Wavelet Scattering and LSTM
title_sort wearable electrocardiogram quality assessment using wavelet scattering and lstm
topic Physiology
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9281614/
https://www.ncbi.nlm.nih.gov/pubmed/35845989
http://dx.doi.org/10.3389/fphys.2022.905447
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