Feasibility and Validity of Using Deep Learning to Reconstruct 12-Lead ECG from Three‑Lead Signals
Background In the field of mobile health, portable dynamic electrocardiogram (ECG) monitoring devices often have a limited number of lead electrodes due to considerations, such as portability and battery life. This situation leads to a contradiction between the demand for standard 12‑lead ECG inform...
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2024
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ph-ateneo-arc.discs-faculty-pubs-14082024-04-15T08:31:31Z Feasibility and Validity of Using Deep Learning to Reconstruct 12-Lead ECG from Three‑Lead Signals Wang, Liang Hung Zou, Yu Yi Xie, Chao Xin Yang, Tao Abu, Patricia Angela R Background In the field of mobile health, portable dynamic electrocardiogram (ECG) monitoring devices often have a limited number of lead electrodes due to considerations, such as portability and battery life. This situation leads to a contradiction between the demand for standard 12‑lead ECG information and the limited number of leads collected by portable devices. Methods This study introduces a composite ECG vector reconstruction network architecture based on convolutional neural network (CNN) combined with recurrent neural network by using leads I, II, and V2. This network is designed to reconstruct three‑lead ECG signals into 12‑lead ECG signals. A 1D CNN abstracts and extracts features from the spatial domain of the ECG signals, and a bidirectional long short-term memory network analyzes the temporal trends in the signals. Then, the ECG signals are inputted into the model in a multilead, single-channel manner. Results Under inter-patient conditions, the mean reconstructed Root mean squared error (RMSE) for precordial leads V1, V3, V4, V5, and V6 were 28.7, 17.3, 24.2, 36.5, and 25.5 μV, respectively. The mean overall RMSE and reconstructed Correlation coefficient (CC) were 26.44 μV and 0.9562, respectively. Conclusion This paper presents a solution and innovative approach for recovering 12‑lead ECG information when only three‑lead information is available. After supplementing with comprehensive leads, we can analyze the cardiac health status more comprehensively across 12 dimensions. 2024-05-01T07:00:00Z text https://archium.ateneo.edu/discs-faculty-pubs/408 https://doi.org/10.1016/j.jelectrocard.2024.03.004 Department of Information Systems & Computer Science Faculty Publications Archīum Ateneo Bidirectional long short-term memory network Convolutional neural network Heartbeat segmentation Lead reconstruction Biomedical Computer Sciences Electrical and Computer Engineering Engineering Physical Sciences and Mathematics |
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Bidirectional long short-term memory network Convolutional neural network Heartbeat segmentation Lead reconstruction Biomedical Computer Sciences Electrical and Computer Engineering Engineering Physical Sciences and Mathematics |
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Bidirectional long short-term memory network Convolutional neural network Heartbeat segmentation Lead reconstruction Biomedical Computer Sciences Electrical and Computer Engineering Engineering Physical Sciences and Mathematics Wang, Liang Hung Zou, Yu Yi Xie, Chao Xin Yang, Tao Abu, Patricia Angela R Feasibility and Validity of Using Deep Learning to Reconstruct 12-Lead ECG from Three‑Lead Signals |
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Background
In the field of mobile health, portable dynamic electrocardiogram (ECG) monitoring devices often have a limited number of lead electrodes due to considerations, such as portability and battery life. This situation leads to a contradiction between the demand for standard 12‑lead ECG information and the limited number of leads collected by portable devices.
Methods
This study introduces a composite ECG vector reconstruction network architecture based on convolutional neural network (CNN) combined with recurrent neural network by using leads I, II, and V2. This network is designed to reconstruct three‑lead ECG signals into 12‑lead ECG signals. A 1D CNN abstracts and extracts features from the spatial domain of the ECG signals, and a bidirectional long short-term memory network analyzes the temporal trends in the signals. Then, the ECG signals are inputted into the model in a multilead, single-channel manner.
Results
Under inter-patient conditions, the mean reconstructed Root mean squared error (RMSE) for precordial leads V1, V3, V4, V5, and V6 were 28.7, 17.3, 24.2, 36.5, and 25.5 μV, respectively. The mean overall RMSE and reconstructed Correlation coefficient (CC) were 26.44 μV and 0.9562, respectively.
Conclusion
This paper presents a solution and innovative approach for recovering 12‑lead ECG information when only three‑lead information is available. After supplementing with comprehensive leads, we can analyze the cardiac health status more comprehensively across 12 dimensions. |
| format |
text |
| author |
Wang, Liang Hung Zou, Yu Yi Xie, Chao Xin Yang, Tao Abu, Patricia Angela R |
| author_facet |
Wang, Liang Hung Zou, Yu Yi Xie, Chao Xin Yang, Tao Abu, Patricia Angela R |
| author_sort |
Wang, Liang Hung |
| title |
Feasibility and Validity of Using Deep Learning to Reconstruct 12-Lead ECG from Three‑Lead Signals |
| title_short |
Feasibility and Validity of Using Deep Learning to Reconstruct 12-Lead ECG from Three‑Lead Signals |
| title_full |
Feasibility and Validity of Using Deep Learning to Reconstruct 12-Lead ECG from Three‑Lead Signals |
| title_fullStr |
Feasibility and Validity of Using Deep Learning to Reconstruct 12-Lead ECG from Three‑Lead Signals |
| title_full_unstemmed |
Feasibility and Validity of Using Deep Learning to Reconstruct 12-Lead ECG from Three‑Lead Signals |
| title_sort |
feasibility and validity of using deep learning to reconstruct 12-lead ecg from three‑lead signals |
| publisher |
Archīum Ateneo |
| publishDate |
2024 |
| url |
https://archium.ateneo.edu/discs-faculty-pubs/408 https://doi.org/10.1016/j.jelectrocard.2024.03.004 |
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