Wearable Monitoring and Interpretable Machine Learning Can Objectively Track Progression in Patients during Cardiac Rehabilitation
Abstract
:1. Introduction
2. Materials and Methods
2.1. Study Population
2.2. Multidisciplinary CR Program
2.3. Study Design
2.4. Feature Extraction
2.5. Linear Regression Model
2.6. Machine Learning Model Derivation
2.7. Feature Analysis and Tracking
3. Results
3.1. Functional Capacity
3.2. Linear Regression Model
3.3. Machine Learning Model Derivation
3.4. Feature Analysis and Tracking
3.5. Rehabilitation Tracking
4. Discussion
4.1. Main Findings
4.2. Linear and Nonlinear Regression Models
4.3. 3D Visualization of Functional Capacity on Population and Personal Level
4.4. Limitations and Future Perspectives
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Variable | Total Population (n = 89) |
---|---|
Anthropometric Features | |
Male | 65 (73%) |
Age, yrs | 63 ± 1 |
Height, m | 1.72 [1.70–1.74] |
Weight, kg | 79.2 ± 1.4 |
BMI, kg/m2 | 26.7 ± 0.4 |
LV ejection fraction, % | 46 [43–49] |
Comorbidities | |
Atrial fibrillation | 22 (25%) |
Hypertension | 38 (43%) |
Dyslipidemia | 39 (44%) |
Diabetes | 12 (14%) |
NYHA Class | |
Class I | 26 (29%) |
Class II | 44 (49%) |
Class III | 19 (21%) |
6MWD, m | |
Baseline | 484 ± 96 |
1st follow-up | 533 ± 100 |
2nd follow-up | 564 ± 100 |
3rd follow-up | 570 ± 103 |
End of study | 585 ± 104 |
Baseline VO2 max, mL/kg/min | 17.0 ± 5.1 |
Kernel Type | MAE ± STD | Features |
---|---|---|
RBF | 42.8 m ± 36.8 m | IMU effort, chronotropic response |
Linear | 55.2 m ± 51.3 | |
Polynomial order 2 | 45.3 m ± 43.3 m | |
Polynomial order 3 | 58.3 m ± 55 m | |
Polynomial order 4 | 259.4 m ± 68 m | |
RBF | 40.1 m ± 39.1 m | IMU effort, height |
Linear | 67.6 m ± 62.5 m | |
Polynomial order 2 | 257.3 m ± 70.3 m | |
Polynomial order 3 | 98.6 m ± 77.5 m | |
Polynomial order 4 | 284.1 m ± 92.6 m | |
RBF | 47.2 m ± 47.6 m | IMU effort |
Linear | 67.7 m ± 63.2 m | |
Polynomial order 2 | 90.7 m ± 60.7 m | |
Polynomial order 3 | 267.6 m ± 57.6 m | |
Polynomial order 4 | 285.6 m ± 67.6 m | |
RBF | 37.7 m ± 36.2 m | IMU effort, chronotropic response, height |
Linear | 55.0 m ± 51.8 m | |
Polynomial order 2 | 42.6 m ± 40.4 m | |
Polynomial order 3 | 44.6 m ± 50.7 m | |
Polynomial order 4 | 263.5 m ± 176 m | |
RBF | 60.0 m ± 58.7 m | Chronotropic response |
Linear | 131.0 m ± 110.4 m | |
Polynomial order 2 | 75.7 m ± 71.4 m | |
Polynomial order 3 | 83.2 m ± 71.7 m | |
Polynomial order 4 | 89.9 m ± 81.1 m | |
RBF | 67.5 m ± 67.1 m | Chronotropic response, height |
Linear | 100.1 m ± 85.3m | |
Polynomial order 2 | 65.5 m ± 59.3 m | |
Polynomial order 3 | 193.9 m ± 123.1 m | |
Polynomial order 4 | 250.5 m ± 408.4 m |
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De Cannière, H.; Corradi, F.; Smeets, C.J.P.; Schoutteten, M.; Varon, C.; Van Hoof, C.; Van Huffel, S.; Groenendaal, W.; Vandervoort, P. Wearable Monitoring and Interpretable Machine Learning Can Objectively Track Progression in Patients during Cardiac Rehabilitation. Sensors 2020, 20, 3601. https://doi.org/10.3390/s20123601
De Cannière H, Corradi F, Smeets CJP, Schoutteten M, Varon C, Van Hoof C, Van Huffel S, Groenendaal W, Vandervoort P. Wearable Monitoring and Interpretable Machine Learning Can Objectively Track Progression in Patients during Cardiac Rehabilitation. Sensors. 2020; 20(12):3601. https://doi.org/10.3390/s20123601
Chicago/Turabian StyleDe Cannière, Hélène, Federico Corradi, Christophe J. P. Smeets, Melanie Schoutteten, Carolina Varon, Chris Van Hoof, Sabine Van Huffel, Willemijn Groenendaal, and Pieter Vandervoort. 2020. "Wearable Monitoring and Interpretable Machine Learning Can Objectively Track Progression in Patients during Cardiac Rehabilitation" Sensors 20, no. 12: 3601. https://doi.org/10.3390/s20123601
APA StyleDe Cannière, H., Corradi, F., Smeets, C. J. P., Schoutteten, M., Varon, C., Van Hoof, C., Van Huffel, S., Groenendaal, W., & Vandervoort, P. (2020). Wearable Monitoring and Interpretable Machine Learning Can Objectively Track Progression in Patients during Cardiac Rehabilitation. Sensors, 20(12), 3601. https://doi.org/10.3390/s20123601