Abstract
An individual's cardiovascular state is a crucial aspect of healthy life. However, it is not routinely assessed outside the clinical setting. Smart wearables use photoplethysmography (PPG) to monitor the arterial pulse wave (PW) and estimate heart rate. The PPG PW is strongly influenced by the ejection of blood from the heart, providing opportunity to monitor cardiac parameters using smart wearables. The aim of this study was to investigate the feasibility of monitoring cardiac contractility and left ventricular ejection time (LVET) from a peripheral PPG signal.
PPG PWs were simulated under a range of cardiovascular conditions using a numerical model of PW propagation. PWs were simulated at measurement sites suitable for non-invasive measurements, including the upper arm, wrist, and neck. Indices of cardiac contractility and LVET were extracted from the first and second derivatives of the PPG PWs, and compared to reference values extracted from the blood pressure PW at the aortic root.
There was strong agreement between the estimated and reference values of LVET, indicating that it may be feasible to assess LVET from PPG signals, including those acquired by smart watches. The correlations between the estimated and reference contractility parameters were less strong, indicating that further work is required to assess contractility robustly using smart wearables.
This study demonstrated the feasibility of assessing LVET using smart wearables, which would allow individuals to monitor their cardiovascular state on a daily basis. Further development of techniques to monitor contractility would be particularly for safety monitoring during drug trials.
PPG PWs were simulated under a range of cardiovascular conditions using a numerical model of PW propagation. PWs were simulated at measurement sites suitable for non-invasive measurements, including the upper arm, wrist, and neck. Indices of cardiac contractility and LVET were extracted from the first and second derivatives of the PPG PWs, and compared to reference values extracted from the blood pressure PW at the aortic root.
There was strong agreement between the estimated and reference values of LVET, indicating that it may be feasible to assess LVET from PPG signals, including those acquired by smart watches. The correlations between the estimated and reference contractility parameters were less strong, indicating that further work is required to assess contractility robustly using smart wearables.
This study demonstrated the feasibility of assessing LVET using smart wearables, which would allow individuals to monitor their cardiovascular state on a daily basis. Further development of techniques to monitor contractility would be particularly for safety monitoring during drug trials.
Original language | English |
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Title of host publication | Proceedings |
Publisher | Multidisciplinary Digital Publishing Institute (MDPI) |
Volume | 4 |
Edition | ECSA-5 |
DOIs | |
Publication status | Published - 12 Feb 2019 |
Event | 5th International Conference on Sensors and Applications - Duration: 15 Nov 2018 → 30 Nov 2018 Conference number: 5 https://ecsa-5.sciforum.net/ |
Conference
Conference | 5th International Conference on Sensors and Applications |
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Abbreviated title | ECSA |
Period | 15/11/2018 → 30/11/2018 |
Internet address |
Keywords
- wearable sensors
- pulse wave
- left ventricular ejection time
- contractility
- photoplethysmogram
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Dive into the research topics of 'Using smart wearables to monitor cardiac ejection'. Together they form a unique fingerprint.Prizes
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Best Early Career Researcher
Charlton, P. (Recipient), 7 Sept 2018
Prize: Prize (including medals and awards)