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Real-time counting of wheezing events from lung sounds using deep learning algorithms: Implications for disease prediction and early intervention

This pioneering study aims to revolutionize self-symptom management and telemedicine-based remote monitoring through the development of a real-time wheeze counting algorithm. Leveraging a novel approach that includes the detailed labeling of one breathing cycle into three types: break, normal, and w...

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Autores principales: Im, Sunghoon, Kim, Taewi, Min, Choongki, Kang, Sanghun, Roh, Yeonwook, Kim, Changhwan, Kim, Minho, Kim, Seung Hyun, Shim, KyungMin, Koh, Je-sung, Han, Seungyong, Lee, JaeWang, Kim, Dohyeong, Kang, Daeshik, Seo, SungChul
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2023
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10659186/
https://www.ncbi.nlm.nih.gov/pubmed/37983213
http://dx.doi.org/10.1371/journal.pone.0294447
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author Im, Sunghoon
Kim, Taewi
Min, Choongki
Kang, Sanghun
Roh, Yeonwook
Kim, Changhwan
Kim, Minho
Kim, Seung Hyun
Shim, KyungMin
Koh, Je-sung
Han, Seungyong
Lee, JaeWang
Kim, Dohyeong
Kang, Daeshik
Seo, SungChul
author_facet Im, Sunghoon
Kim, Taewi
Min, Choongki
Kang, Sanghun
Roh, Yeonwook
Kim, Changhwan
Kim, Minho
Kim, Seung Hyun
Shim, KyungMin
Koh, Je-sung
Han, Seungyong
Lee, JaeWang
Kim, Dohyeong
Kang, Daeshik
Seo, SungChul
author_sort Im, Sunghoon
collection PubMed
description This pioneering study aims to revolutionize self-symptom management and telemedicine-based remote monitoring through the development of a real-time wheeze counting algorithm. Leveraging a novel approach that includes the detailed labeling of one breathing cycle into three types: break, normal, and wheeze, this study not only identifies abnormal sounds within each breath but also captures comprehensive data on their location, duration, and relationships within entire respiratory cycles, including atypical patterns. This innovative strategy is based on a combination of a one-dimensional convolutional neural network (1D-CNN) and a long short-term memory (LSTM) network model, enabling real-time analysis of respiratory sounds. Notably, it stands out for its capacity to handle continuous data, distinguishing it from conventional lung sound classification algorithms. The study utilizes a substantial dataset consisting of 535 respiration cycles from diverse sources, including the Child Sim Lung Sound Simulator, the EMTprep Open-Source Database, Clinical Patient Records, and the ICBHI 2017 Challenge Database. Achieving a classification accuracy of 90%, the exceptional result metrics encompass the identification of each breath cycle and simultaneous detection of the abnormal sound, enabling the real-time wheeze counting of all respirations. This innovative wheeze counter holds the promise of revolutionizing research on predicting lung diseases based on long-term breathing patterns and offers applicability in clinical and non-clinical settings for on-the-go detection and remote intervention of exacerbated respiratory symptoms.
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spelling pubmed-106591862023-11-20 Real-time counting of wheezing events from lung sounds using deep learning algorithms: Implications for disease prediction and early intervention Im, Sunghoon Kim, Taewi Min, Choongki Kang, Sanghun Roh, Yeonwook Kim, Changhwan Kim, Minho Kim, Seung Hyun Shim, KyungMin Koh, Je-sung Han, Seungyong Lee, JaeWang Kim, Dohyeong Kang, Daeshik Seo, SungChul PLoS One Research Article This pioneering study aims to revolutionize self-symptom management and telemedicine-based remote monitoring through the development of a real-time wheeze counting algorithm. Leveraging a novel approach that includes the detailed labeling of one breathing cycle into three types: break, normal, and wheeze, this study not only identifies abnormal sounds within each breath but also captures comprehensive data on their location, duration, and relationships within entire respiratory cycles, including atypical patterns. This innovative strategy is based on a combination of a one-dimensional convolutional neural network (1D-CNN) and a long short-term memory (LSTM) network model, enabling real-time analysis of respiratory sounds. Notably, it stands out for its capacity to handle continuous data, distinguishing it from conventional lung sound classification algorithms. The study utilizes a substantial dataset consisting of 535 respiration cycles from diverse sources, including the Child Sim Lung Sound Simulator, the EMTprep Open-Source Database, Clinical Patient Records, and the ICBHI 2017 Challenge Database. Achieving a classification accuracy of 90%, the exceptional result metrics encompass the identification of each breath cycle and simultaneous detection of the abnormal sound, enabling the real-time wheeze counting of all respirations. This innovative wheeze counter holds the promise of revolutionizing research on predicting lung diseases based on long-term breathing patterns and offers applicability in clinical and non-clinical settings for on-the-go detection and remote intervention of exacerbated respiratory symptoms. Public Library of Science 2023-11-20 /pmc/articles/PMC10659186/ /pubmed/37983213 http://dx.doi.org/10.1371/journal.pone.0294447 Text en © 2023 Im et al https://creativecommons.org/licenses/by/4.0/This is an open access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/) , which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
spellingShingle Research Article
Im, Sunghoon
Kim, Taewi
Min, Choongki
Kang, Sanghun
Roh, Yeonwook
Kim, Changhwan
Kim, Minho
Kim, Seung Hyun
Shim, KyungMin
Koh, Je-sung
Han, Seungyong
Lee, JaeWang
Kim, Dohyeong
Kang, Daeshik
Seo, SungChul
Real-time counting of wheezing events from lung sounds using deep learning algorithms: Implications for disease prediction and early intervention
title Real-time counting of wheezing events from lung sounds using deep learning algorithms: Implications for disease prediction and early intervention
title_full Real-time counting of wheezing events from lung sounds using deep learning algorithms: Implications for disease prediction and early intervention
title_fullStr Real-time counting of wheezing events from lung sounds using deep learning algorithms: Implications for disease prediction and early intervention
title_full_unstemmed Real-time counting of wheezing events from lung sounds using deep learning algorithms: Implications for disease prediction and early intervention
title_short Real-time counting of wheezing events from lung sounds using deep learning algorithms: Implications for disease prediction and early intervention
title_sort real-time counting of wheezing events from lung sounds using deep learning algorithms: implications for disease prediction and early intervention
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10659186/
https://www.ncbi.nlm.nih.gov/pubmed/37983213
http://dx.doi.org/10.1371/journal.pone.0294447
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