Next-Generation Fetal Heart Monitoring: Leveraging Neural Sequential Modeling for Ultrasound Analysis
Objective: Fetal heart rate (FHR) and its variability are crucial indicators of fetal well-being. One-dimensional Doppler ultrasound (DUS) has become a widely used tool for this monitoring purpose, particularly in low-resource settings, due to its affordability, portability, and simplicity. Yet, its...
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| Published in | IEEE transactions on biomedical engineering Vol. PP; pp. 1 - 12 |
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| Main Authors | , , , , |
| Format | Journal Article |
| Language | English |
| Published |
United States
IEEE
02.07.2025
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| Subjects | |
| Online Access | Get full text |
| ISSN | 0018-9294 1558-2531 1558-2531 |
| DOI | 10.1109/TBME.2025.3585461 |
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| Abstract | Objective: Fetal heart rate (FHR) and its variability are crucial indicators of fetal well-being. One-dimensional Doppler ultrasound (DUS) has become a widely used tool for this monitoring purpose, particularly in low-resource settings, due to its affordability, portability, and simplicity. Yet, its potential remains underexplored, with existing methods relying on rigid, non-adaptive algorithms that struggle to capture beat-to-beat variations. This study aims to bridge the gap by delivering reliable estimates through sequential modeling of regions of interest. Methods: We introduce AutoFHR, a novel interpretable neural temporal model based on dilated causal convolutions and attention mechanisms, designed to automatically estimate heartbeat locations within DUS signals. AutoFHR utilizes an innovative learning objective that minimizes generation error while uniquely incorporating a spectral fidelity term to retain the natural rhythm of fetal cardiac activity. Results: Cross-population, subject-independent evaluations demonstrate AutoFHR's proficiency in heartbeat localization, significantly outperforming conventional methods in FHR estimation while improving FHR variability analysis. AutoFHR achieves a root mean square error (RMSE) of 2.2 beats per minute (bpm) and 2.8 bpm, a maximum limit of agreement of 4.5 and 5.6 bpm, and an estimated bias of 0.3 and 0.1 bpm on the development and external validation datasets, respectively. Conclusions: Our findings indicate a strong correspondence between estimated and reference fetal electrocardiogram-derived heartbeats and highlight the model's generalizability and robustness over time. Significance: This work advances the clinical utility of DUS-based fetal monitoring by improving FHR analysis, supporting earlier detection of distress and expanding access to quality prenatal care in clinical and remote settings. |
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| AbstractList | Fetal heart rate (FHR) and its variability are crucial indicators of fetal well-being. One-dimensional Doppler ultrasound (DUS) has become a widely used tool for this monitoring purpose, particularly in low-resource settings, due to its affordability, portability, and simplicity. Yet, its potential remains underexplored, with existing methods relying on rigid, non-adaptive algorithms that struggle to capture beat-to-beat variations. This study aims to bridge the gap by delivering reliable estimates through sequential modeling of regions of interest.
We introduce AutoFHR, a novel interpretable neural temporal model based on dilated causal convolutions and attention mechanisms, designed to automatically estimate heartbeat locations within DUS signals. AutoFHR utilizes an innovative learning objective that minimizes generation error while uniquely incorporating a spectral fidelity term to retain the natural rhythm of fetal cardiac activity.
Cross-population, subject-independent evaluations demonstrate AutoFHR's proficiency in heartbeat localization, significantly outperforming conventional methods in FHR estimation while improving FHR variability analysis. AutoFHR achieves a root mean square error (RMSE) of 2.2 beats per minute (bpm) and 2.8 bpm, a maximum limit of agreement of 4.5 and 5.6 bpm, and an estimated bias of 0.3 and 0.1 bpm on the development and external validation datasets, respectively.
Our findings indicate a strong correspondence between estimated and reference fetal electrocardiogram-derived heartbeats and highlight the model's generalizability and robustness over time.
This work advances the clinical utility of DUS-based fetal monitoring by improving FHR analysis, supporting earlier detection of distress and expanding access to quality prenatal care in clinical and remote settings. Objective: Fetal heart rate (FHR) and its variability are crucial indicators of fetal well-being. One-dimensional Doppler ultrasound (DUS) has become a widely used tool for this monitoring purpose, particularly in low-resource settings, due to its affordability, portability, and simplicity. Yet, its potential remains underexplored, with existing methods relying on rigid, non-adaptive algorithms that struggle to capture beat-to-beat variations. This study aims to bridge the gap by delivering reliable estimates through sequential modeling of regions of interest. Methods: We introduce AutoFHR, a novel interpretable neural temporal model based on dilated causal convolutions and attention mechanisms, designed to automatically estimate heartbeat locations within DUS signals. AutoFHR utilizes an innovative learning objective that minimizes generation error while uniquely incorporating a spectral fidelity term to retain the natural rhythm of fetal cardiac activity. Results: Cross-population, subject-independent evaluations demonstrate AutoFHR's proficiency in heartbeat localization, significantly outperforming conventional methods in FHR estimation while improving FHR variability analysis. AutoFHR achieves a root mean square error (RMSE) of 2.2 beats per minute (bpm) and 2.8 bpm, a maximum limit of agreement of 4.5 and 5.6 bpm, and an estimated bias of 0.3 and 0.1 bpm on the development and external validation datasets, respectively. Conclusions: Our findings indicate a strong correspondence between estimated and reference fetal electrocardiogram-derived heartbeats and highlight the model's generalizability and robustness over time. Significance: This work advances the clinical utility of DUS-based fetal monitoring by improving FHR analysis, supporting earlier detection of distress and expanding access to quality prenatal care in clinical and remote settings. Fetal heart rate (FHR) and its variability are crucial indicators of fetal well-being. One-dimensional Doppler ultrasound (DUS) has become a widely used tool for this monitoring purpose, particularly in low-resource settings, due to its affordability, portability, and simplicity. Yet, its potential remains underexplored, with existing methods relying on rigid, non-adaptive algorithms that struggle to capture beat-to-beat variations. This study aims to bridge the gap by delivering reliable estimates through sequential modeling of regions of interest.OBJECTIVEFetal heart rate (FHR) and its variability are crucial indicators of fetal well-being. One-dimensional Doppler ultrasound (DUS) has become a widely used tool for this monitoring purpose, particularly in low-resource settings, due to its affordability, portability, and simplicity. Yet, its potential remains underexplored, with existing methods relying on rigid, non-adaptive algorithms that struggle to capture beat-to-beat variations. This study aims to bridge the gap by delivering reliable estimates through sequential modeling of regions of interest.We introduce AutoFHR, a novel interpretable neural temporal model based on dilated causal convolutions and attention mechanisms, designed to automatically estimate heartbeat locations within DUS signals. AutoFHR utilizes an innovative learning objective that minimizes generation error while uniquely incorporating a spectral fidelity term to retain the natural rhythm of fetal cardiac activity.METHODSWe introduce AutoFHR, a novel interpretable neural temporal model based on dilated causal convolutions and attention mechanisms, designed to automatically estimate heartbeat locations within DUS signals. AutoFHR utilizes an innovative learning objective that minimizes generation error while uniquely incorporating a spectral fidelity term to retain the natural rhythm of fetal cardiac activity.Cross-population, subject-independent evaluations demonstrate AutoFHR's proficiency in heartbeat localization, significantly outperforming conventional methods in FHR estimation while improving FHR variability analysis. AutoFHR achieves a root mean square error (RMSE) of 2.2 beats per minute (bpm) and 2.8 bpm, a maximum limit of agreement of 4.5 and 5.6 bpm, and an estimated bias of 0.3 and 0.1 bpm on the development and external validation datasets, respectively.RESULTSCross-population, subject-independent evaluations demonstrate AutoFHR's proficiency in heartbeat localization, significantly outperforming conventional methods in FHR estimation while improving FHR variability analysis. AutoFHR achieves a root mean square error (RMSE) of 2.2 beats per minute (bpm) and 2.8 bpm, a maximum limit of agreement of 4.5 and 5.6 bpm, and an estimated bias of 0.3 and 0.1 bpm on the development and external validation datasets, respectively.Our findings indicate a strong correspondence between estimated and reference fetal electrocardiogram-derived heartbeats and highlight the model's generalizability and robustness over time.CONCLUSIONSOur findings indicate a strong correspondence between estimated and reference fetal electrocardiogram-derived heartbeats and highlight the model's generalizability and robustness over time.This work advances the clinical utility of DUS-based fetal monitoring by improving FHR analysis, supporting earlier detection of distress and expanding access to quality prenatal care in clinical and remote settings.SIGNIFICANCEThis work advances the clinical utility of DUS-based fetal monitoring by improving FHR analysis, supporting earlier detection of distress and expanding access to quality prenatal care in clinical and remote settings. |
| Author | Motie-Shirazi, Mohsen Clifford, Gari D. Katebi, Nasim Rafiei, Alireza Sameni, Reza |
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| Snippet | Objective: Fetal heart rate (FHR) and its variability are crucial indicators of fetal well-being. One-dimensional Doppler ultrasound (DUS) has become a widely... Fetal heart rate (FHR) and its variability are crucial indicators of fetal well-being. One-dimensional Doppler ultrasound (DUS) has become a widely used tool... |
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| SubjectTerms | Biomedical engineering Deep learning Doppler effect Doppler ultrasound (DUS) Electrocardiography Estimation fetal health monitoring Fetal heart rate fetal heart rate (FHR) estimation generative modeling Heart rate variability Hospitals Monitoring Pediatrics Ultrasonic imaging variability analysis |
| Title | Next-Generation Fetal Heart Monitoring: Leveraging Neural Sequential Modeling for Ultrasound Analysis |
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