Video-based heart rate monitoring across a range of skin pigmentations during an acute hypoxic challenge

Addison, Paul; Jacquel, Dominique; Foo, David M. H.; Borg, Ulf

doi:10.1007/s10877-017-0076-1

Cited by 19 publications

(14 citation statements)

References 30 publications

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“…However, the authors also mentioned that the lack of environmental control leads to increased humidity and possibly increased vasodilation [ 41 ]. In addition to these examples, numerous other studies that stratify results against Fitzpatrick classification identify the same trend; errors in determining heartrate from wearable PPG devices that use primarily green light as their source is increased in individuals with dark skin tones due to the high absorption caused by increased amounts of epidermal melanin [ 42 , 43 , 44 , 45 ]. Lastly, Bent et al published an experimental analysis of error observed in optical heart rate sensors manufactured by Apple (Apple Watch 4), Fitbit (Fitbit Charge 2), Garmin (Garmin Vivosmart 3), Xiaomi (Xiaomi Miband 3), Empatica (Empatica E4), and Biovotion (Biovation Everion) as a function of skin tone [ 46 ].…”

Section: Individual Variations In the Human Populationmentioning

confidence: 90%

Sources of Inaccuracy in Photoplethysmography for Continuous Cardiovascular Monitoring

et al. 2021

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Photoplethysmography (PPG) is a low-cost, noninvasive optical technique that uses change in light transmission with changes in blood volume within tissue to provide information for cardiovascular health and fitness. As remote health and wearable medical devices become more prevalent, PPG devices are being developed as part of wearable systems to monitor parameters such as heart rate (HR) that do not require complex analysis of the PPG waveform. However, complex analyses of the PPG waveform yield valuable clinical information, such as: blood pressure, respiratory information, sympathetic nervous system activity, and heart rate variability. Systems aiming to derive such complex parameters do not always account for realistic sources of noise, as testing is performed within controlled parameter spaces. A wearable monitoring tool to be used beyond fitness and heart rate must account for noise sources originating from individual patient variations (e.g., skin tone, obesity, age, and gender), physiology (e.g., respiration, venous pulsation, body site of measurement, and body temperature), and external perturbations of the device itself (e.g., motion artifact, ambient light, and applied pressure to the skin). Here, we present a comprehensive review of the literature that aims to summarize these noise sources for future PPG device development for use in health monitoring.

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Section: Individual Variations In the Human Populationmentioning

confidence: 90%

Sources of Inaccuracy in Photoplethysmography for Continuous Cardiovascular Monitoring

et al. 2021

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“…A couple of works considered the impact of skin pigmentation [51][52][53][54]. Those works show the tendency of higher values in the Fitzpatrick scale to degrade the results but proper methods might be able to compensate for the skin tone.…”

Section: Discussionmentioning

confidence: 99%

Cardiovascular assessment by imaging photoplethysmography – a review

Zaunseder

Trumpp

Wedekind

et al. 2018

Biomedical Engineering / Biomedizinische Technik

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Over the last few years, the contactless acquisition of cardiovascular parameters using cameras has gained immense attention. The technique provides an optical means to acquire cardiovascular information in a very convenient way. This review provides an overview on the technique's background and current realizations. Besides giving detailed information on the most widespread application of the technique, namely the contactless acquisition of heart rate, we outline further concepts and we critically discuss the current state.

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“…Perhaps the most obvious appearance characteristic when measuring the blood volume pulse optically is skin type. Previous work has found systematic biases in the performance of non-contact photoplethymography measurement algorithms with skin type [40], [22]. Specifically, performance is over signficantly poorer for darker skin types.…”

Section: Diversity Of Subjects In the Training Setmentioning

confidence: 99%

Synthetic Data for Multi-Parameter Camera-Based Physiological Sensing

McDuff¹,

Liu²,

Hernández³

et al. 2021

Preprint

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Synthetic data is a powerful tool in training data hungry deep learning algorithms. However, to date, camerabased physiological sensing has not taken full advantage of these techniques. In this work, we leverage a high-fidelity synthetics pipeline for generating videos of faces with faithful blood flow and breathing patterns. We present systematic experiments showing how physiologically-grounded synthetic data can be used in training camera-based multi-parameter cardiopulmonary sensing. We provide empirical evidence that heart and breathing rate measurement accuracy increases with the number of synthetic avatars in the training set. Furthermore, training with avatars with darker skin types leads to better overall performance than training with avatars with lighter skin types. Finally, we discuss the opportunities that synthetics present in the domain of camera-based physiological sensing and limitations that need to be overcome.

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Video-based heart rate monitoring across a range of skin pigmentations during an acute hypoxic challenge

Cited by 19 publications

References 30 publications

Sources of Inaccuracy in Photoplethysmography for Continuous Cardiovascular Monitoring

Sources of Inaccuracy in Photoplethysmography for Continuous Cardiovascular Monitoring

Cardiovascular assessment by imaging photoplethysmography – a review

Synthetic Data for Multi-Parameter Camera-Based Physiological Sensing

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