Hostname: page-component-848d4c4894-hfldf Total loading time: 0 Render date: 2024-05-30T15:31:50.474Z Has data issue: false hasContentIssue false
  • English
  • Français

Clinical applications of contactless photoplethysmography for vital signs monitoring in pediatrics: A systematic review and meta-analysis

Published online by Cambridge University Press:  25 May 2023

Melissa Bautista Open the ORCID record for Melissa Bautista [Opens in a new window] ,
Daniel Cave ,
Candice Downey ,
James R. Bentham  and
David Jayne
Melissa Bautista*
Affiliation:
University of Leeds, Leeds, West Yorkshire, UK General Surgery Department, St James’s University Hospital, Leeds Teaching Hospitals NHS Trust, Leeds, West Yorkshire, UK
Daniel Cave
Affiliation:
University of Leeds, Leeds, West Yorkshire, UK Leeds Children’s Hospital, Leeds Teaching Hospitals NHS Trust, Leeds, West Yorkshire, UK
Candice Downey
Affiliation:
University of Leeds, Leeds, West Yorkshire, UK General Surgery Department, St James’s University Hospital, Leeds Teaching Hospitals NHS Trust, Leeds, West Yorkshire, UK
James R. Bentham
Affiliation:
University of Leeds, Leeds, West Yorkshire, UK Leeds Children’s Hospital, Leeds Teaching Hospitals NHS Trust, Leeds, West Yorkshire, UK
David Jayne
Affiliation:
University of Leeds, Leeds, West Yorkshire, UK General Surgery Department, St James’s University Hospital, Leeds Teaching Hospitals NHS Trust, Leeds, West Yorkshire, UK
*
Corresponding author: M. Bautista, MBChB; Email: melissa.bautista3@nhs.net
Rights & Permissions [Opens in a new window]

Abstract

Background:

Contactless photoplethysmography (PPG) potentially affords the ability to obtain vital signs in pediatric populations without disturbing the child. Most validity studies have been conducted in laboratory settings or with healthy adult volunteers. This review aims to evaluate the current literature on contactless vital signs monitoring in pediatric populations and within a clinical setting.

Methods:

OVID, Webofscience, Cochrane library, and clinicaltrials.org were systematically searched by two authors for research studies which used contactless PPG to assess vital signs in children and within a clinical setting.

Results:

Fifteen studies were included with a total of 170 individuals. Ten studies were included in a meta-analysis for neonatal heart rate (HR), which demonstrated a pooled mean bias of −0.25 (95% limits of agreement (LOA), −1.83 to 1.32). Four studies assessed respiratory rate (RR) in neonates, and meta-analysis demonstrated a pooled mean bias of 0.65 (95% LOA, −3.08 to 4.37). All studies were small, and there were variations in the methods used and risk of bias.

Conclusion:

Contactless PPG is a promising tool for vital signs monitoring in children and accurately measures neonatal HR and RR. Further research is needed to assess children of different age groups, the effects of skin type variation, and the addition of other vital signs.

Keywords

Vital signs monitoringphotoplethysmographypaediatricschildrenneonatesheart raterespiratory ratesystematic reviewmeta-analysis
Type
Review Article
Information
Journal of Clinical and Translational Science , Volume 7 , Issue 1 , 2023 , e144
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Association for Clinical and Translational Science

Background

Photoplethysmography (PPG) is an optical technique which allows for measurement of parameters associated with cardiorespiratory function by detecting small blood volume changes within the skin [Reference Allen1]. Conventional PPG is widely used for pulse oximetry in most pediatric health care settings and requires contact with the skin. Camera-based PPG is an adaptation of this technique which uses a noncontact method of detecting these blood volume changes from a subject, with the use of a camera. This technique has gained interest due to the multiple advantages associated with noncontact methods of obtaining patient’s physiological parameters [Reference Hassan, Malik, Fofi, Saad, Karasfi, Ali and Meriaudeau2].

This technology is particularly interesting in pediatric populations due to the inherent advantages of covert vital signs measurements. It allows for less patient distress and eliminates the risk of Medical Adhesive Related Skin Injuries (MARSI) [Reference Wang, Xu, Chen, Lou, Tan and Xu3]. MARSI are common in neonatal populations due to their thin and delicate skin, with higher risk of iatrogenic skin damage [Reference Sardesai, Kornacka, Walas and Ramanathan4].

Camera-based PPG has the potential to provide similar information to currently available contact-based methods. Heart rate (HR), respiratory rate (RR), and oxygen saturations are vital signs readily obtained with PPG and used frequently within health care settings as part of the ongoing assessments of patients [Reference Bal5,Reference Antognoli, Marchionni, Nobile, Carnielli and Scalise6]. With further understanding of the PPG waveform and its association with physiological parameters, other potentially useful parameters such as HR variability and perfusion index can also be extracted. These parameters have been correlated with other clinical markers and have been demonstrated to add diagnostic value; however, they are not currently used in every day clinical practice [Reference Schena, Picciolli, Agosti, Zuppa, Zuccotti, Parola, Pomero, Stival, Markart, Graziani and Gagliardi7,Reference Bersani, Piersigilli and Gazzolo8].

There is academic interest in application of camera-based PPG alongside refinement of algorithms to improve data acquisition. Multiple studies have been conducted using cameras to obtain PPG signals and vital signs. The majority have been conducted in a laboratory setting. Camera-based PPG use in real-life clinical settings is lacking [Reference Pham, Poorzargar and Nagappa9]. Currently, there is minimal evidence on the accuracy and usability of camera-based PPG in pediatric populations including within clinical settings.

Primary and Secondary Objectives

The primary objectives of this systematic review are to summarize current knowledge on the clinical application of camera-based PPG in pediatrics with the hope of stimulating discussion on future trial design to evaluate the usefulness of this methodology in different clinical pediatric settings.

For the purpose for this study, a clinical setting was defined as either a clinical environment where patient assessments occurred or the assessment of patients with a particular clinical condition even if this occurred in a laboratory setting. The secondary objectives are to assess the accuracy of camera-based PPG in different clinical settings and demonstrate any barriers to camera-based PPGs further evaluation in clinical environments.

Methods

The search terms are available in supplementary material. This review adheres to the Preferred Reporting Items for Systematic reviews and Meta-analysis (PRISMA) guidelines.

Inclusion and Exclusion Criteria

Population: The study was limited to pediatric patients under the age of 16 years. Given the broad range of ages within this population, the authors further divided the age groups into preterm neonates (born before 37 weeks gestation), neonates (0–28 days of age), infants (29 days – 1 year), and children (1–16 years).

Intervention: Contactless vital signs monitoring using camera-based PPG methods.

Environments: Only studies conducted within a clinical setting were included or pediatric patients with a particular medical condition and in any setting.

Comparator: The authors included all studies fitting the inclusion criteria with an available comparator from established contact methods of vital signs monitoring.

Outcomes: Outcomes included the detection rate and accuracy of any physiological parameters (HR, RR, saturation level, and blood pressure). Where available, further details regarding the acceptability, adverse events, and barriers were included.

Exclusion: Non-English studies, conference abstracts, protocols, and reviews were excluded.

Search Strategy and Study Selection

An initial limited search was conducted to identify the appropriate search terms and available synonyms. The initial search terms were PPG, camera, and pediatrics. The final search terms can be found in appendix one.

Using a defined search strategy, OVID, WebOfScience, Cochrane library, and clinicaltrials.org were systematically searched by two independent investigators (MB and DC). The search was conducted from database inception to February 2022. All titles, abstracts, and then full texts were screened against the predetermined inclusion and exclusion criteria by the two investigators. The relevant research item abstracts were then reviewed to determine relevance. References of relevant review articles were also screened for other possible studies not picked up by the search terms. Comparing the final set of eligible papers between the two researchers (MB and DC) results in there being two discrepancies. These discrepancies were resolved through discussion.

Data Extraction

Results from the independent literature searches were compared to form the final list of included studies. Data extraction was completed by two independent researchers (MB and DC) using a predetermined data extraction tool on Microsoft Excel (Microsoft Corporations, 2018). Extracted parameters included number of participants, participant demographics, vitals signs recorded, comparators, details of the technology used, and the results. Study findings included data on accuracy, signal quality, and other relevant observations such as any potential side effects.

Risk of Bias Assessment

The authors used the Quality Assessment of Diagnostic Accuracy of Studies-2 (QUADAS-2) tool for risk of bias for comparative accuracy studies [Reference Whiting, Rutjes and Westwood10]. Two authors (MB and DC) independently completed the risk of bias assessment, and the results were compared, and discrepancies resolved through discussion. The risk of bias was completed for included studies and is shown in Supplementary Table 1.

Data Analysis

The methods and results of included studies are described using a narrative approach. Additionally, a pooled statistical analysis was conducted where possible for studies with similar populations and outcome measures. Studies could be included in the pooled analysis if results were described using Bland–Altman analysis [Reference Altman and Bland11]. For relevant studies that did not report Bland–Altman analyses, values of mean bias and 95% limits of agreement (LOA) were derived from available data where possible. A random effects model was used to calculate pooled mean bias and 95% LOA, and these are displayed for each outcome using Forest plots (Stata 17.0 MP, StataCorp LLC, Texas, USA). Study weighting was preformed using the inverse variance method.

We considered a p value <0.1 as statistically significant for heterogeneity between studies. I 2 25% was considered low heterogeneity, I 2 50% as intermediate heterogeneity, and I 2 75% as high heterogeneity.

Results

Search Results

Of the four databases searched, a total of 435 abstracts were screened for eligibility. Following screening, 90 research articles with full text were reviewed and a total of 15 studies were then included in this review (Fig. 1). Forty-two percent of the studies were not considered clinical due to the use of healthy volunteers to either validate the technology or refine algorithms. Twenty-eight percent were also excluded due to the use of the index finger over a smart device camera, although this technology uses camera-based PPG, it is considered a contact method. Twelve percent of the studies used alternative methods of obtaining vital signs.

Figure 1. PRISMA flow diagram. PPG = photoplethysmography.

Study Characteristics

A total of 15 studies and 170 individuals were included in the final review (Table 1). Most studies recruited neonatal intensive care inpatients (n = 14). Seven studies included a mixture of preterm and term neonates, three included preterm only, one included term only, and gestation was unknown in the remainder (n = 4). HR was the most frequently assessed vital sign (n = 12), followed by RR (n = 4) and oxygen saturation (n = 2). Eleven studies measured a single vital sign, and the remaining studies measured two. Studies varied in the imaging device used, with some using specialized red, green, and blue (RGB) cameras (n = 8) and others using digital cameras or web cameras (n = 7). The PPG algorithms used were different for each study.

Table 1. Description of included studies

AI = artificial intelligence; ECG = electrocardiogram; HR = heart rate; LOA = limits of agreement; NICU = neonatal intensive care unit; PICU = pediatric intensive care unit; PPG = photoplethysmography; RGB = red green blue; ROI = region of interest; RR = respiratory rate; SO2 = oxygen saturation.

ROI Selection

The selection of a region of interest (ROI) for PPG measurement demonstrated variation between the studies. Paul et al. used post-data acquisition analysis to find the ROI which provided the best quality signal, and this varied between participant and body part. Other studies used predetermined ROI with use of an automatic ROI detection method for obtaining PPG signals, with one study using artificial intelligence (AI) to detect the appropriate ROI [Reference Cenci, Liciotti, Frontoni, Mancini and Zingaretti16]. This study used a varied number of ROIs which were governed by which ROI was available at different time points to account for loss of ROI due to motion. Overall, various ROIs were used across studies including the face, forehead, hands, arms, and thorax.

Accuracy of Contactless PPG for Specific Clinical Applications

A summary of the results for included studies is shown in Table 2.

Table 2. Summary of findings table

ECG = electrocardiogram; HR = heart rate; LOA = limits of agreement; MAE = mean absolute error; PPG = photoplethysmography; RMSE = root mean squared error; RR = respiratory rate; SO2 = oxygen saturation.

Neonatal HR measurement

Neonatal HR measurement was measured in the clinical environment under visible light for all studies. Some studies measured HR continuously over a prolonged period [Reference Cenci, Liciotti, Frontoni, Mancini and Zingaretti16], while others acquired data intermittently, over a set period of time [Reference Aarts, Jeanne and Cleary13,Reference Klaessens, van den Born, van der Veen, Sikkens-van de Kraats, van den Dungen and Verdaasdonk14]. All studies used post-data acquisition processing to obtain the measured vital signs. Electrocardiogram (ECG) monitoring was used as the gold standard reference test in 8 out of 12 (67%) studies of HR measurement.

Aarts et al. used a digital camera to measure HR in 19 neonates under ambient light [Reference Klaessens, van den Born, van der Veen, Sikkens-van de Kraats, van den Dungen and Verdaasdonk14]. Videos of 1–5 minutes were taken, and then HR analyzed from various manually selected ROIs including the head, arm, and thorax. Authors demonstrated excellent agreement between contactless PPG and simultaneous ECG monitoring, with mean bias of 0.3 bpm and 95% LOA −5.0 to 5.5. Interestingly, contactless PPG was superior to pulse oximetry for HR measurement when both were compared to ECG [Reference Klaessens, van den Born, van der Veen, Sikkens-van de Kraats, van den Dungen and Verdaasdonk14].

We performed a meta-analysis to assess the accuracy of contactless PPG for HR measurement across all studies. The mean bias and 95% LOA were pooled across studies and were manually calculated from data provided, where possible. Two studies did not report the raw data, mean bias, or Bland–Altman plots and therefore could not be included in the meta-analysis. The results are shown in Fig. 2 and demonstrate a pooled mean bias of −0.25 (95% LOA −1.83 to 1.32) with an I 2 value for heterogeneity of 0% (95% confidence interval 0 to 62%). A sensitivity analysis was conducted with Paul et al. (2020) removed, and the significance of the results remain unchanged, with a pooled mean bias of −0.27 (95% LOA of −2.65 to 2.11) (Figure 1 in supplementary material).

Figure 2. Forest plot demonstrating the accuracy of contactless PPG monitoring for heart rate. PPG = photoplethysmography; LOA = limits of agreement; REML = restricted maximum likelihood.

Neonatal RR measurement

Four studies included methods for RR measurement in neonates using contactless PPG. Participants included preterm and term neonates that were studied during NICU admissions. One further study by Jorge et al. investigated the use of contactless PPG for the detection of apneic events in 30 preterm neonates [Reference Cobos-Torres, Abderrahim and Martínez-Orgado20]. Authors used a digital camera positioned over the incubator and were able to correctly detect 7 out of 10 apneic events and 34 of 44 artefactual events that would have triggered a false alarm with conventional monitoring. The majority of studies used impedance pneumography (IP) from ECG leads as the reference gold standard. All four studies reported the mean bias of RR measurement and could be included in the meta-analysis (Fig. 3). The results demonstrate a pooled mean bias of 0.65 (95% LOA of −3.08 to 4.37) and I 2 of 0% (95% confidence interval 0 to 85%).

Figure 3. Accuracy of contactless PPG for respiratory rate. PPG = photoplethysmography; LOA = limits of agreement; REML = restricted maximum likelihood.

Vital signs monitoring in children

One study recruited older children during pediatric intensive care (PICU) admissions. Bal et al. studied seven children aged 2 months to 14 years, and contactless PPG measurement of HR and oxygen saturations (SO2) was performed with a digital webcam [Reference Bal5]. Automated face detection followed by skin detection was used to identify the ROI, and PPG signal extracted from RGB pixel intensity. The mean bias for HR measurement was 2.6 bpm with LOA of ±6.9 bpm [Reference Bal5]. SO2 was estimated from red and blue signals using a “ratio of ratios” approach, and the authors demonstrated a strong correlation (correlation coefficient 0.71) in PICU patients.

Effects of Ethnicity and Skin Color

Wieler et al. reported Fitzpatrick skin color scales for the participants in their study, with one participant being V-VI. They conclude that there were too few skin type variations to allow for meaningful comparisons [Reference Wang, Chen, Sue, Lu and Chiou25]. Paul et al. acknowledged the skin color variations between North and South Indian participants but did not provide a subgroup analysis of the potential impact of skin color variation [Reference Chen, Jiang, Liu, Lu, Wang and Chen22]. Aarts et al. reported one participant with darker skin had a reduced signal-to-noise ratio (SNR); however, this did not compromise the ability to pick up HR [Reference Klaessens, van den Born, van der Veen, Sikkens-van de Kraats, van den Dungen and Verdaasdonk14]. No other studies reported skin color or ethnicity of included participants.

Risk of Bias

Following application of the QUADAS-2 tool to the studies, all studies were fully paired, but the majority lacked methodological and selection details to ensure accurate risk assessment and were assigned a moderate risk of bias. A common theme for the research studies included in the review was the selection of the best quality signal or results prior to comparison. A summary of the risk of bias assessment for each individual study is included in Fig. 2 of the supplementary material. Publication bias assessment was conducted by visualization of the funnel plot, which included studies measuring neonatal HR (Figure 3 supplementary material). On review of the funnel plot, there appears to be no publication bias. This was further supported by Egger’s test (p = 0.476) and Begg’s test (p = 0.531).

Discussion

This systematic review summarizes the current evidence for contactless PPG vital signs monitoring in pediatric patients. Using camera-based contactless monitoring in pediatric populations may be an accurate and safe alternative for measuring HR in children, especially neonates. This review demonstrated good accuracy between the contactless PPG methods compared to the current gold standards for both HR and RR monitoring in neonates. Contactless PPG may even be superior to conventional pulse oximetry for HR measurement [Reference Klaessens, van den Born, van der Veen, Sikkens-van de Kraats, van den Dungen and Verdaasdonk14]. There were no studies using contactless PPG to measure blood pressure or alternative physiological parameters such as HR variability, methods known to be achievable with contactless PPG in adults [Reference Crooks, West and Morling26].

There were no reports of adverse events related to the use of contactless PPG monitoring. Thermoregulation is an important factor, particularly in neonatal monitoring. Many of the included studies proposed a system for monitoring neonates in the incubator, with the camera set up externally, and reported good image quality and accuracy [Reference Altman and Bland11]. Any form of contactless PPG monitoring does require adequate ambient light and therefore may not be suitable for the continuous monitoring of preterm neonates in dark conditions. Infrared monitoring may offer an alternative solution for contactless monitoring in this population [Reference Scalise, Bernacchia, Ercoli and Marchionni12]. Another important feature is the ability of contactless PPG to detect clinical deterioration. Jorge et al. studied the detection of apneic events and proposed an algorithm that reduced the false alarm rate by 77% [Reference Cobos-Torres, Abderrahim and Martínez-Orgado20]. Future studies are required to ensure that contactless PPG is accurate over the entire range of neonatal HRs.

For clinical application, camera-based PPG methods must be accurate for all ethnicities and skin types. Conventional pulse oximeters using contact PPG can systematically overestimate the SO2 in patients of Black and Asian ethnicity, leading to delays in the detection of hypoxemia and escalation in management [Reference Fawzy, Wu and Wang27,28]. In our review, studies had small sample sizes and could not draw conclusions on the effects of skin-type variation and ethnicity on the accuracy of this technology. Wieler et al. reported the Fitzpatrick skin-type scale of neonates undergoing HR measurement; however, only one participant had skin-type V-VI [Reference Wang, Chen, Sue, Lu and Chiou25]. Aarts et al. studied one neonate of Hispanic ethnicity (Fitzpatrick type V) and were successfully able to measure HR despite a relatively lower signal strength [Reference Klaessens, van den Born, van der Veen, Sikkens-van de Kraats, van den Dungen and Verdaasdonk14]. Two studies of infants with darker skin types reported excellent agreement between contactless PPG and pulse oximetry [Reference Klaessens, van den Born, van der Veen, Sikkens-van de Kraats, van den Dungen and Verdaasdonk14,Reference Cenci, Liciotti, Frontoni, Mancini and Zingaretti16]. There is a need for further study of the effects of skin type on contactless PPG signal strength and accuracy.

Various other factors can influence the signal strength and measurement accuracy of contactless PPG. The brightness of ambient light is a commonly reported factor, and low light can result in reduced SNR [Reference Klaessens, van den Born, van der Veen, Sikkens-van de Kraats, van den Dungen and Verdaasdonk14]. One study reported an infant under bright phototherapy light had the highest signal quality, resulting in perfect correlation of HR measurement with ECG monitoring, however the authors fail to provide a supporting value [Reference Klaessens, van den Born, van der Veen, Sikkens-van de Kraats, van den Dungen and Verdaasdonk14], making the interpretation of this result difficult. Many studies also reported the challenges of patient movement and the ability to detect the measured vital sign [Reference Klaessens, van den Born, van der Veen, Sikkens-van de Kraats, van den Dungen and Verdaasdonk14,Reference Jorge19]. The difficulty lies in the inability to always keep ROI in the frame, and this motion artifact reduces SNR and therefore quality of the PPG waveform. One study observed an underestimation in HR measurement for children with lower hemoglobin levels [Reference Bal5]. Improvements in image resolution and algorithm developments are likely to reduce the influence of environmental factors.

Contactless vital signs monitoring has many advantages for use in clinical practice, including the avoidance of skin probes that may cause skin damage in neonates. The technology has significant potential for clinical application in infants and children, avoiding distress during measurement that may cause falsely abnormal vital signs. Preliminary clinical studies have reported good accuracy for neonatal HR and RR measurement, and this is demonstrated in our meta-analyses (Figs. 1 and 2). There remain issues with movement artifact, and there is a lack of standardization between available devices. With further development, this technology may have a wide variety of clinical applications in pediatric inpatient and outpatient settings.

Limitations

Included studies were mostly small, with variation in the camera used and image processing methods. On individual review of studies, most had a risk of bias and this was often related to unclear image processing methods or manual ROI selection, with no mention of blinding of the assessors. There was variation in the reporting of results and statistical methods, and therefore we were not able to include all studies in the meta-analyses. Those studies included in the meta-analyses used mean bias as the statistical method. This method of assessing differences has limitations, including an underestimation of difference where positive and negative values cancel out. This method was chosen as it was the most common statistical method provided by the included studies and therefore gave the largest amount of data to perform a meta-analysis. Most studies used ECG monitoring as the gold standard for HR monitoring; however, some used pulse oximetry which may also be affected by movement or skin type. Four out of the 15 studies reported funding sources (Table 2; Supplementary material), making it difficult to assess for funding bias; however, only one study claimed a potential conflict of interest. Future studies should prioritize automated methods of ROI selection and ensure the most suitable reference test is used. To aid clinical translation, technologies should prioritize real-time data acquisition for use in patient monitoring.

Conclusion

Contactless PPG is a promising tool for vital signs monitoring in children and accurately measures neonatal HR and RR without the need for a skin probe. However, a lack of standardization in the algorithms and reporting of results means comparison between studies is challenging. Further research is needed to assess children of different age groups, the effects of skin-type variation, and the addition of other vital signs.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/cts.2023.557.

Funding statement

There are no funders to report.

Competing interests

There are no competing interests to disclose.

Footnotes

Melissa Bautista and Daniel Cave are joint first authors.

References

Allen, J. Photoplethysmography and its application in clinical physiological measurement. Physiol Meas [Internet]. 2007;28(3):R1-39.Google ScholarPubMed
Hassan, MA, Malik, AS, Fofi, D, Saad, N, Karasfi, B, Ali, YS, Meriaudeau, F. Heart rate estimation using facial video: a review. Biomed Signal Process Control. 2017;1:346360.CrossRefGoogle Scholar
Wang, D, Xu, H, Chen, S, Lou, X, Tan, J, Xu, Y. Medical adhesive-related skin injuries and associated risk factors in a Pediatric Intensive Care Unit. Adv Skin Wound Care [Internet]. 2019;32(4):176182.CrossRefGoogle Scholar
Sardesai, SR, Kornacka, MK, Walas, W, Ramanathan, R. Iatrogenic skin injury in the neonatal intensive care unit. J Matern Fetal Neonatal Med. 2011;24(2):197203.CrossRefGoogle ScholarPubMed
Bal, U. Non-contact estimation of heart rate and oxygen saturation using ambient light. Biomed Opt Express. 2015;6(1):86.CrossRefGoogle ScholarPubMed
Antognoli, L, Marchionni, P, Nobile, S, Carnielli, V, Scalise, L. Assessment of cardio-respiratory rates by non-invasive measurement methods in hospitalized preterm neonates. MeMeA 2018 - 2018 IEEE Int Symp Med Meas Appl Proc. 2018.Google Scholar
Schena, F, Picciolli, I, Agosti, M, Zuppa, AA, Zuccotti, G, Parola, L, Pomero, G, Stival, G, Markart, M, Graziani, S, Gagliardi, L. Perfusion index and pulse oximetry screening for congenital heart defects. J Pediatr. 2017;183:7479.e1.CrossRefGoogle ScholarPubMed
Bersani, I, Piersigilli, F, Gazzolo, D, et al. Heart rate variability as possible marker of brain damage in neonates with hypoxic ischemic encephalopathy: a systematic review. Eur J Pediatr. 2021;180(5):13351345.CrossRefGoogle ScholarPubMed
Pham, C, Poorzargar, K, Nagappa, M, et al. Effectiveness of consumer-grade contactless vital signs monitors: A systematic review and meta-analysis. J Clin Monit Comput [Internet]. 2022;36(1):4154.CrossRefGoogle ScholarPubMed
Whiting, PF, Rutjes, AWS, Westwood, ME, et al. QUADAS-2: a revised tool for the quality assessment of diagnostic accuracy studies. Ann Intern Med [Internet]. 2011;155(8):529536.CrossRefGoogle ScholarPubMed
Altman, DG, Bland, JM. Measurement in medicine: the analysis of method comparison studies. Stat. 1983;32(3):307.Google Scholar
Scalise, L, Bernacchia, N, Ercoli, I, Marchionni, P. Heart rate measurement in neonatal patients using a webcamera, MeMeA 2012 - 2012 IEEE Symp Med Meas Appl Proc, 2012 69.Google Scholar
Aarts, LAM, Jeanne, V, Cleary, JP, et al. Non-contact heart rate monitoring utilizing camera photoplethysmography in the neonatal intensive care unit - a pilot study. Early Hum Dev. 2013;89(12):943948.CrossRefGoogle ScholarPubMed
Klaessens, JH, van den Born, M, van der Veen, A, Sikkens-van de Kraats, J, van den Dungen, FA, Verdaasdonk, RM. Development of a baby friendly non-contact method for measuring vital signs: First results of clinical measurements in an open incubator at a neonatal intensive care unit. Adv Biomed Clin Diagnostic Syst XII. 2014;8935:89351P.Google Scholar
Mestha, LK, Kyal, S, Xu, B, Lewis, LE, Kumar, V. Towards continuous monitoring of pulse rate in neonatal intensive care unit with a webcam, 2014 36th Annu Int Conf IEEE Eng Med Biol Soc EMBC 2014, 2014:38173820.Google Scholar
Cenci, A, Liciotti, D, Frontoni, E, Mancini, A, Zingaretti, P. Non-contact monitoring of preterm infants using RGB-D camera, Proc ASME Des Eng Tech Conf, 2016.Google Scholar
Gastel, van M, Stuijk, S, de Haan, G. Robust respiration detection from remote photoplethysmography. Biomed Opt Express. 2016;7(12):4941.CrossRefGoogle ScholarPubMed
Blanik, N, Heimann, K, Pereira, C, et al. Remote vital parameter monitoring in neonatology - robust, unobtrusive heart rate detection in a realistic clinical scenario. Biomed Tech (Berl). 2016;61(6):631643.CrossRefGoogle Scholar
Jorge, J. Non-contact monitoring of respiration in the neonatal intensive care unit, 12th IEEE Int Conf Autom Face Gesture Recognit (FG 2017), 2017: 286–93.CrossRefGoogle Scholar
Cobos-Torres, JC, Abderrahim, M, Martínez-Orgado, J. Non-contact, simple neonatal monitoring by photoplethysmography. Sensors (Basel). 2018;18(12):4362.CrossRefGoogle ScholarPubMed
Paul, M, Karthik, S, Joseph, J, et al. Non-contact sensing of neonatal pulse rate using camera-based imaging: a clinical feasibility study. Physiol Meas [Internet]. 2020;41(2):024001.Google ScholarPubMed
Chen, Q, Jiang, X, Liu, X, Lu, C, Wang, L, Chen, W. Non-contact heart rate monitoring in neonatal intensive care unit using RGB camera, Annu Int Conf IEEE Eng Med Biol Soc IEEE Eng Med Biol Soc Annu Int Conf, 2020, 2020:58225825.Google Scholar
Chen, Q, Wang, Y, Liu, X, et al. Camera-based heart rate estimation for hospitalized newborns in the presence of motion artifacts. Biomed Eng Online. 2021;20(1):122.CrossRefGoogle ScholarPubMed
Wieler, ME, Murphy, TG, Blecherman, M, Mehta, H, Bender, GJ. Infant heart-rate measurement and oxygen desaturation detection with a digital video camera using imaging photoplethysmography. J Perinatol. 2021;41(7):17251731.CrossRefGoogle ScholarPubMed
Wang, YJ, Chen, CH, Sue, CY, Lu, WH, Chiou, YH. Estimation of blood pressure in the radial artery using strain-based pulse wave and photoplethysmography sensors. Micromachines-BASEL. 2018;9(11):556.CrossRefGoogle ScholarPubMed
Crooks, CJ, West, J, Morling, JR, et al. Pulse oximeter measurements vary across ethnic groups: an observational study in patients with COVID-19. Eur Respir J. 2022;59(4):2103246.CrossRefGoogle ScholarPubMed
Fawzy, A, Wu, TD, Wang, K, et al. Racial and ethnic discrepancy in pulse oximetry and delayed identification of treatment eligibility among patients with COVID-19. JAMA Intern Med. 2022;182(7):730738.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. PRISMA flow diagram. PPG = photoplethysmography.

Figure 1

Table 1. Description of included studies

Figure 2

Table 2. Summary of findings table

Figure 3

Figure 2. Forest plot demonstrating the accuracy of contactless PPG monitoring for heart rate. PPG = photoplethysmography; LOA = limits of agreement; REML = restricted maximum likelihood.

Figure 4

Figure 3. Accuracy of contactless PPG for respiratory rate. PPG = photoplethysmography; LOA = limits of agreement; REML = restricted maximum likelihood.

Supplementary material: File

Bautista et al. supplementary material

Figures S1-S3 and Tables S1-S2

Download Bautista et al. supplementary material(File)
File 193 KB