New principle for measuring arterial blood oxygenation, enabling motion-robust remote monitoring

Gastel, Mark van; Stuijk, Sander; Haan, G Gerard de

doi:10.1038/srep38609

Cited by 84 publications

(83 citation statements)

References 35 publications

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“…We demonstrate that, based on a dataset with only small variations in SpO 2 , an accurate calibration model can be determined which outperforms a calibration model based on modelling of the PPG spectrum. Furthermore, we show that the error only slightly increases using solely near-infrared (NIR) wavelengths when compared to the typical combination of visible red and NIR wavelengths, which confirms our earlier observations [8] and widens the scope for camera-based pulse-oximetry, e.g., for sleep or continuous 24/7 monitoring where patients are monitored in full darkness.…”

Section: Introductionsupporting

confidence: 85%

“…In this paper, we present an empirical, data-driven approach to estimate a calibration model for the indirect APBV method which can be applied to an arbitrary number and selection of wavelengths. This is relevant, as in our earlier paper [8], we showed that adding a third wavelength improves the robustness of the measurement. We demonstrate that, based on a dataset with only small variations in SpO 2 , an accurate calibration model can be determined which outperforms a calibration model based on modelling of the PPG spectrum.…”

Section: Introductionsupporting

confidence: 58%

“…Over the last few decades, methods have been presented which allow contactless monitoring of human vital signs with regular cameras in both visible and near-infrared conditions based on the detection of visually imperceptible skin color variations caused by blood volume variations. These vital signs include heart rate and derived features [3], respiration [4,5], and, more recently, oxygen saturation [4,[6][7][8][9][10]. Contactless monitoring is especially relevant for: (1) scenarios where direct skin contact should be prevented (e.g., premature infants [11,12] or patients with extensive burns [13]), (2) spot-check scenarios where a reading should be available within seconds, or (3) scenarios where the current diagnostic procedure could affect the clinical outcome (e.g., with polysomnography for sleep monitoring [14][15][16]).…”

Section: Introductionmentioning

confidence: 99%

“…This is particularly detrimental for measurements where amplitudes have to be extracted from individual PPG waveforms, e.g., for the measurement of peripheral blood oxygen saturation (SpO 2 ). This motivated the development of an indirect method for the estimation of SpO 2 using SpO 2 -dependent pulse signatures [8], which does not require the individual extraction of amplitudes. This method, denoted "APBV" (Adaptive-PBV), showed the feasibility of estimating SpO 2 from distorted PPG signals, e.g., during movement, where the conventional ratio-of-ratios based method renders inaccurate.…”

Section: Introductionmentioning

confidence: 99%

“…This principle works fine for clean signals, but is rendered inaccurate when the signals are noisy or corrupted by motion artifacts. This motivated the development of the APBV method [8], inspired by the PBV method for camera-based pulse extraction by De Haan et al [17] using the unique spectral signature of the blood volume pulse signal. A short description of the APBV method is provided in the next paragraph.…”

Section: Introductionmentioning

confidence: 99%

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Data-Driven Calibration Estimation for Robust Remote Pulse-Oximetry

2019

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Pulse-oximetry has become a core monitoring modality in most fields of medicine. Typical dual-wavelength pulse-oximeters estimate blood oxygen saturation (SpO 2 ) levels from a relationship between the amplitudes of red and infrared photoplethysmographic (PPG) waveforms. When captured with a camera, the PPG waveforms are much weaker and consequently the measurement is more sensitive to distortions and noises. Therefore, an indirect method has recently been proposed where, instead of extracting the relative amplitudes from the individual waveforms, the waveforms are linearly combined to construct a collection of pulse signals with different pulse signatures, each corresponding to a specific oxygen saturation level. This method has been shown to outperform the conventional ratio-of-ratios based methods, especially when adding a third wavelength. Adding wavelengths, however, complicates the calibration. Inaccuracies in the calibration model threaten the performance of the method. Opto-physiological models have been shown earlier to provide useful calibration parameter estimates. In this paper, we show that the accuracy can be improved using a data-driven approach. We performed 5-fold cross validation on recordings with variations in oxygen saturation and optimized for pulse quality. All evaluated wavelength combinations, also without visible red, meet the required ISO standard accuracy with the calibration from the proposed method. This scalable approach is not only helpful to fine-tune the calibration model, but even allows computation of the calibration model parameters from scratch without prior knowledge of the data acquisition details, i.e., the properties of camera and illumination.

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Section: Introductionsupporting

confidence: 85%

Section: Introductionsupporting

confidence: 58%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Data-Driven Calibration Estimation for Robust Remote Pulse-Oximetry

2019

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Skin‐Like Transparent Sensor Sheet for Remote Healthcare Using Electroencephalography and Photoplethysmography

Araki

Yoshimoto

Uemura

et al. 2022

Adv Materials Technologies

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institutions using large medical devices, such as magnetic resonance imaging devices, magnetoencephalograms, and electroencephalograms (EEGs), which must be operated in environments with extremely low external noise. [8] Their large size and specialist nature mean that trained personnel must selectively use these devices. In addition, monitoring using large medical devices induces different brain activity to that in the daily steady state. If brain activity could be monitored easily at home, like body temperature, blood pressure, and weight, then the signs of severe diseases could be recognized before their onset. Therefore, the development of small, high-accuracy EEG systems with minimal presence and discomfort is strongly desired.Wireless EEG systems have attracted attention for the elucidation, diagnosis, and treatment of certain disorders [2][3][4][5] and typically feature soft probes as key electronic components considering the low elasticity of skin. [10][11][12] Soft probes reduce invasiveness and hinder inflammation to skin during long-term use, [2][3][4][12][13][14][15] facilitating monitoring from surfaces of the human body. [2,9,[12][13][14][15][16][17][18] Conventional medical devices used for EEG recording require gel-or paste-based wet electrodes [19] to be attached to the head of the patient. During long-term use, these electrodes are prone to cause skin irritation due to water accumulation, and the initially low electrode/skin contact impedance increases as the electrode dries. [20,21] On the other hand, wearable headset-type systems with partially pressured dry electrodes have reduced electrode/skin contact impedance and eliminate exogenous noise for wireless EEG acquisition. [6,22,23] Although such systems benefit from a reduced attachment time, their size needs to precisely match the size of the head of the individual, and the applied attachment pressure (typically around 13.8 kPa) may induce skin irritation. [6,22,23] These drawbacks, as well as those associated with long-term use, need to be mitigated.In this study, an imperceptible EEG system was developed using a stretchable and transparent skin-like sensor sheet that is worn on the forehead (Figure 1a,b). The EEG system wirelessly monitors brain waves without physical or visual discomfort, with a measurement accuracy similar to that of medical equipment. This is achieved due to the high conductivity, high stretchability, high transparency, and ultralow noise of the The growing demand for efficient home healthcare applications for brain disorder diagnostics and treatment has inspired the development of wearable devices for monitoring brain activity. However, flexible probes that have improved biocompatibility for wearable devices are markedly affected by noise due to contact interface issues. In this study, a stretchable (≤1500% strain) and transparent (over 85% transmittance) biocompatible electrode that steadily adheres to skin is developed to fabricate an imperceptible sheet-type device that wirelessly records electroencephalograms (EEGs...

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Flexible and Multifunctional Skin Patch for Clinical Decision Support in Psychiatric Assessment

Kim,

Lee,

Lee

2024

Adv Materials Technologies

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The recent advances in flexible and wearable electronics, along with ubiquitous biosensing technologies have enabled the continuous monitoring of health conditions outside of medical facilities. Health‐monitoring tools based on wearable sensors must be more user‐friendly, informative, and cost‐effective for daily applications owing to the increased prevalence of chronic diseases and mental illnesses. In this study, a flexible and multifunctional skin patch and a custom‐designed application for wirelessly monitoring the wearer's physical and mental health conditions are proposed. The optimized design and soft‐covering materials of the skin patch enable long‐term attachment to the body without causing discomfort or irritation to the wearer. Onboard processing of the signals enables real‐time monitoring and signal acquisition of multiple biomarkers, including the blood oxygen saturation level (SpO2), pulse rate (PR), pulse rate variability (PRV), perfusion index (PI), body movement, and temperature during daily activities. The photoplethysmography (PPG)‐based biomarkers acquired from various body sites are compared and calibrated to verify its performance. Demonstrated pilot trial shows the potential application of the skin patch for clinical decision support in psychiatric assessments that can be implemented as an assistive mental illness monitoring system for psychiatrists and researchers.

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New principle for measuring arterial blood oxygenation, enabling motion-robust remote monitoring

Cited by 84 publications

References 35 publications

Data-Driven Calibration Estimation for Robust Remote Pulse-Oximetry

Data-Driven Calibration Estimation for Robust Remote Pulse-Oximetry

Skin‐Like Transparent Sensor Sheet for Remote Healthcare Using Electroencephalography and Photoplethysmography

Flexible and Multifunctional Skin Patch for Clinical Decision Support in Psychiatric Assessment

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