Pediatric oncology patients are at high risk of developing clinical deterioration and organ dysfunction during their illness. Heart rate variability (HRV) measured using electrocardiography waveforms is associated with increased organ dysfunction and clinical deterioration in adult and pediatric patients in the intensive care unit (ICU). Here, we explore the feasibility of using photoplethysmography (PPG)-derived integer pulse rate variability (PRVi) to estimate HRV and determine its association with organ dysfunction in pediatric oncology patients in the ward and pediatric ICU. The advantage of using PPG sensor data over electrocardiography is its higher availability in most healthcare settings and in wearable technology. In a cohort of 38 patients, reduced median daily PRVi was significantly associated with increase in two pediatric organ dysfunction scores after adjusting for confounders (p < 0.001). PRVi shows promise as a real-time physiologic marker of clinical deterioration using highly-available PPG data, but further research is warranted.
Up to 38% of pediatric oncology patients will be admitted to a pediatric intensive care unit (PICU) within 3 years of their cancer diagnosis due to organ dysfunction, which can result in high morbidity and mortality.1 Improving our ability to detect clinical deterioration earlier could improve outcomes.
Reduced heart rate variability (HRV) derived from electrocardiographic waveform data is associated with increased risk of clinical deterioration.2,3 Integer heart rate variability (HRVi), derived using intermittent beat-per-minute measurements, has been shown to be an effective surrogate of HRV, even though it requires significantly less data than continuous waveform analysis.4,5 However, calculating HRVi requires electrocardiography data, which is harder to acquire and less available than photoplethysmography (PPG) data, particularly in children outside the PICU.6,7
The value of using PPG-derived integer pulse rate data to estimate HRV has not been previously reported. Therefore, we aimed to explore the feasibility of using integer pulse rate variability (PRVi) as a surrogate of HRV and to determine its association with two pediatric organ dysfunction scores in oncology patients admitted to the ward and PICU of a children’s hospital.
We collected 3.2 million pulse rates during 202 patient-days in 38 patients (median age 8.7 years). A total of 79% of measurements were made outside the PICU. There were 55,075 5-minute intervals with sufficient PPG data, of which 39,650 (72%) also had electrocardiography data. When both measurement were available, mean hourly PRVi had a strong correlation with mean hourly HRVi (r = 0.94, p < 0.001). Based on the Bland Altman plot, PRVi slightly overestimated HRVi, however, the bias was low at about 1 beat-per-minute above and below the mean (Fig. 1a). Median daily PRVi had a moderate-to-strong negative correlation with the daily pSOFA and PELOD scores across age groups (Pearson’s r = −0.6 to −0.7, p < 0.001). Reduced median daily PRVi was significantly associated with increased daily pSOFA and PELOD scores after controlling for confounders (both p < 0.001; Table 1). For illustration purposes, a time series for a patient who required admission to the PICU and mechanical ventilation is presented (Fig 1b).
Reduced PRVi, a new surrogate of HRV, is associated with increased organ dysfunction in pediatric oncology patients in the ward and in the PICU. After adjusting for possible confounders, a drop in the median PRVi by 1 beat-per-minute is associated with an increase in pSOFA score by one point and PELOD score by two points.
Reduced HRV has previously been associated with infection, subsequent clinical deterioration, organ failure, and mortality in children and adults.2,3,4,8 Studies of HRV have largely been limited to the critical care setting, in part due to the limited availability of continuous electrocardiographic data outside the ICU. Furthermore, a recent review of new monitoring technologies for pediatric organ dysfunction highlights the challenges of using electrocardiographic data for estimating HRV.7
PRVi is measured using non-invasive PPG, a sensor technology that is ubiquitous in the healthcare setting and increasingly available in wearable technology. This makes PRVi a highly accessible and available digital measure of clinical status, as opposed to other measures of HRV.6,7 In addition, the down-sampling involved with the intermittent data needed for calculating PRVi makes it computationally more feasible and generalizable than calculating HRV using continuous waveforms.
Our study was focused on exploring the feasibility of using PRVi in a relatively small cohort of pediatric oncology patients. Further validation in a larger cohort of high-risk patients in other settings, potentially including home monitoring with wearable technology, is warranted.
We collected electrocardiography-derived heart rate and PPG-derived pulse rate data every 5 s from monitors (Philips IntelliVue MX800) of 50 beds in the oncology ward and PICU of an academic children’s hospital between 2/2017-4/2017. The 5-second capture interval was chosen based on evidence from prior adult studies.4,5
HRVi was calculated as the standard deviation of the heart rate over 5 min using beat-per-minute measurements derived from electrocardiography data, using previously published criteria.4 PRVi was calculated in a similar manner but using PPG-based measurements. The 5-minute intervals with < 30 measurements were discarded (<5.3% of available intervals).5 Clinical data from the electronic health record was used to calculate the daily pediatric sequential organ failure assessment (pSOFA) score and the daily pediatric logistic organ dysfunction (PELOD) score.9,10 All measures were obtained from admission until discharge or hospital day 28, whichever came first.
The mean hourly PRVi was compared to the mean hourly HRVi, when both were available, using Pearson’s coefficient and the Bland Altman plot. The median daily PRVi was compared to the daily pSOFA and the daily PELOD scores using Pearson’s coefficient across three age groups (preschool [2–5 years], school-age [6–11 years], and adolescent [>11 years]), to account for age-dependent heart rate variation. Linear regression was performed to determine the association between PRVi and the two pediatric organ dysfunction scores after controlling for possible confounders. Analyses were performed using standard code in R, version 3.1 (R Project for Statistical Computing).
This study was approved by The University of Chicago Institutional Review Board with waiver of informed consent (IRB#16-1192).
The datasets generated and analyzed for this study are not publicly available due to Institutional Review Board and Health Insurance Portability and Accountability Act restrictions given the identifiable nature of the clinical data used. However, after the necessary approvals and on reasonable request, data will be available from the corresponding author.
Zinter, M. S., DuBois, S. G., Spicer, A., Matthay, K. & Sapru, A. Pediatric cancer type predicts infection rate, need for critical care intervention, and mortality in the pediatric intensive care unit. Intensive Care Med. 40, 1536–1544 (2014).
Ahmad, S. et al. Continuous multi-parameter heart rate variability analysis heralds onset of sepsis in adults. PLoS One. 4, e6642 (2009).
Griffin, M. P. et al. Heart rate characteristics: novel physiomarkers to predict neonatal infection and death. Pediatrics 116, 1070–1074 (2005).
Morris, J. A. Jr. et al. Adrenal insufficiency, heart rate variability, and complex biologic systems: a study of 1,871 critically ill trauma patients. J. Am. Coll. Surg. 204, 885–892 (2007). discussion 892-883.
Norris, P. R. et al. Cardiac uncoupling and heart rate variability stratify ICU patients by mortality: a study of 2088 trauma patients. Ann. Surg. 243, 804–812 (2006).
Schäfer, A. & Vagedes, J. How accurate is pulse rate variability as an estimate of heart rate variability? A review on studies comparing photoplethysmographic technology with an electrocardiogram. Int J. Cardiol. 166, 15–29 (2013).
Typpo, K. V. et al. Monitoring severity of multiple organ dysfunction syndrome: new technologies. Pediatr. Crit. Care Med. 18, S24–S31 (2017).
Ellenby, M. S. et al. Uncoupling and recoupling of autonomic regulation of the heart beat in pediatric septic shock. Shock 16, 274–277 (2001).
Leteurtre, S. et al. Development of a pediatric multiple organ dysfunction score: use of two strategies. Med Decis. Mak. 19, 399–410 (1999).
Matics, T. J. & Sanchez-Pinto, L. N. Adaptation and validation of a pediatric sequential organ failure assessment score and evaluation of the sepsis-3 definitions in critically ill children. JAMA Pediatr. 171(10), e172352 (2017).
The authors would like to acknowledge the Comer Development Board for their support of this study. They would also like to thank Juliane Bubeck-Wardenburg, Ross Leder, and the Center for Research Informatics for their support. This study was supported by the Comer Development Board 2015 RBC Race for the Kids fund. A.M. was supported by the National Heart, Lung, and Blood Institute (K12HL119995-05). L.N.S. was supported by the National Center for Advancing Translational Sciences of the National Institutes of Health (KL2TR000431). Funded by the Comer Development Board 2015 RBC Race for the Kids fund (PI: Sanchez-Pinto)
The authors declare no competing interests.
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Mayampurath, A., Volchenboum, S.L. & Sanchez-Pinto, L.N. Using photoplethysmography data to estimate heart rate variability and its association with organ dysfunction in pediatric oncology patients. npj Digital Med 1, 29 (2018). https://doi.org/10.1038/s41746-018-0038-0