Abstract
Early recognition of critically ill patients is of paramount importance to reduce pediatric mortality and morbidity. We created a risk stratification system combining vital parameters and predefined risk factors aimed at reducing the risk of unrecognized clinical deterioration compared with conventional Pediatric Early Warning Systems (PEWS). This single-center retrospective case cohort study included infants (gestational age ≥ 37 weeks) to adolescents (aged <18 years) with unplanned pediatric intensive care unit (PICU) admission between April 01, 2014, and February 28, 2018. The sensitivity in the 24 h prior to endpoint of the Pediatric Risk Evaluation and Stratification System (PRESS) was compared with that of the conventional PEWS and calculated as the proportion of study patients who received a high-risk score. Seventy-four PICU admissions were included. PRESS and PEWS sensitivities at 2 h prior to endpoint were 0.70 (95%CI 0.59 to 0.80) and 0.30 (95%CI 0.20 to 0.42) respectively (p < 0.001). Excluding patients with seizures, PRESS sensitivity increased to 0.75 (95%CI 0.64 to 0.85). Forty-nine patients (66%) scored positive on at least one high-risk factor, and “worried sign” was scored in 31 patients (42%).
Conclusion: Risk stratification seems advantageous for a faster detection of clinical deterioration, providing opportunity for earlier intervention.
What is Known: • Prompt detection of clinical deterioration is of essential importance to reduce morbidity and mortality. • Conventional Pediatric Early Warning Systems (PEWS) have limited sensitivity and a short window of detection of 1 to 2 h. | |
What is New: • Risk stratification based on context factors allows earlier identification of patients at risk, well before deviation of vital signs. • Risk stratification combined with continuous monitoring of deteriorating trends in vital signs could lead to the development of next-generation warning systems achieving true patient safety. |
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Introduction
Pediatric Early Warning Systems (PEWS) are used in most modern hospitals around the world, aimed at improving recognition of clinical deterioration in order to reduce mortality and morbidity. PEWS generally consist of a number of vital signs and other clinical indicators suggesting critical illness, often accompanied by an algorithm with rules for escalation and de-escalation of care.
Despite the considerable amount of literature concerning PEWS, the evidence supporting their effect is limited and various systematic reviews failed to demonstrate more than a positive trend on clinical outcomes [1, 4, 5, 15, 24]. A recent prospective multicenter randomized controlled trial of PEWS found no decrease in all-cause hospital mortality, although a composite outcome measure showed a significant reduction of late intensive care admissions [17]. A particular concern is the lack of standardization in PEWS, imposing a major challenge in comparing systems and limiting generalizability of study results. Studies from the UK and the Netherlands have identified largely different PEWS in pediatric units, with a considerable number remaining self-designed and unvalidated [10, 20, 26]. Variations in reference range of vital signs in pediatric patients provide an additional challenge. In contrast to these challenges, qualitative studies demonstrate positive effects of PEWS on situational awareness and overcoming communication obstacles such as hierarchical barriers [2, 3].
We anticipated that the rather limited sensitivity of PEWS could be a result of the narrow focus on vital signs, not addressing other factors that may also predict clinical deterioration. Therefore, in 2014, we designed and implemented the Pediatric Risk Evaluation and Stratification System (PRESS) [12], which integrates (1) a selection of predefined risk factors with (2) a previously validated PEWS [13] and (3) patient’s responsiveness (AVPU score). Based on a combination of these components, patients are stratified into three risk categories: high, medium, and low risk. High-risk patients (so called watchers) receive proactive checks upon their clinical condition. A recent qualitative study illustrated that the PRESS enhanced situational awareness in physicians and nurses [7], but to date the effect of the PRESS on timely recognition of clinical deterioration has not yet been quantified.
The primary goal of this study was to quantify the value of risk stratification by the PRESS in predicting clinical deterioration in hospitalized pediatric patients. The secondary aims were to provide new insight into the value of individual risk factors, to explore the impact of risk stratification on clinical outcomes, and to investigate factors in protocol adherence.
Methods
Setting
The Radboudumc Amalia Children’s Hospital is a Dutch tertiary referral hospital with three pediatric wards (72 beds) where specialized care is offered by a broad spectrum of surgical and non-surgical pediatric specialists and nurses. Monitoring of vital parameters and various emergency medical interventions (e.g., fluid challenge and supplemental oxygen) can be performed in the ward. Critically ill children can be transferred to a 10-bed pediatric intensive care unit (PICU). PICU mortality rate between 2014 and 2018 was 2.2%.
All patients in the ward are routinely scored by the nursing staff using our local PEWS [13] (a modified version of the Bedside PEWS [16]) and AVPU three times a day or more frequently in case of elevated scores and at least once daily when vital signs are stable for at least 24 h. The predefined risk factors are scored by the attending physician at least once daily during rounds. The predefined high-risk factors scored by PRESS include “worried sign” (physician, nurse, or family concern), “ICU involvement” (consultation of ICU specialists), “high-risk treatment” (complex and/or potentially risky procedures), “transferred patients from general hospitals” (referrals or transfers from general hospitals during on-call hours), and “abnormal pH or lactate” (≤ 7.20 and ≥ 4.0 mmol/l respectively). Patients are scored high risk if PEWS is ≥ 8 [13], if an AVPU score is “P” (responsive only to pain) or “U” (unresponsive), and/or if one high-risk factor is considered positive. The PEWS score and PRESS risk category are simplified into color codes. This results in a live dashboard, which assists the attending professionals to quickly identify watchers in the ward (Fig. 1). Watchers receive more proactive checks from professionals according to previously published standard operating procedures [7]. A validity indicator (indicating if a PRESS risk stratification has been performed that day) was added to the dashboard in 2017, to facilitate the detection of invalid PRESS scores and to enhance protocol adherence.
Study design
We conducted a single-center retrospective case cohort study. The performance of the PRESS was studied retrospectively over the period from April 1, 2014, to February 28, 2018. We included patients between 37 weeks gestational age and 18 years who, at any time during their admission to the pediatric ward, had deteriorated towards the endpoints “unplanned PICU admission” or “cardiopulmonary arrest.” Patients with a “do not resuscitate order” were excluded. Additionally, PICU admissions of a non-urgent nature were excluded, as well as readmissions to the PICU within 24 h (since these patients would always be marked as watcher patients according to standard operating procedures). Patients who were admitted to the pediatric wards for less than 2 h prior to reaching the defined endpoint were excluded, as this time period was considered insufficient for early detection. Exclusion was confirmed after review by a panel of two researchers (LT/JF).
The patients in this study were recruited from a list of unplanned PICU admissions drawn from the hospital’s electronic health record system. For specificity analyses, a random control sample in a 1:1 ratio to the study admissions was drawn from the list of pediatric ward admissions in 2017. The procedures of this study were in accordance with local ethical committee guidelines.
Data analysis
The PEWS scores and PRESS risk stratification in the 24 h prior to the endpoint were studied retrospectively based on data extracted from the electronic patient files. PRESS and PEWS scores were considered expired after 24 and 8 h respectively, in accordance with local protocol. Patients with a valid PRESS and PEWS score at the endpoint were included in the performance analyses. The sensitivity was calculated as the proportion of patients with cardiopulmonary arrest or unplanned PICU admission that received a high-risk PRESS stratification or PEWS above threshold (≥ 8). The specificity was determined as the proportion of control admissions in the general ward that did not receive any high-risk stratification during the total admission duration.
To assess the value of separate risk factors, we analyzed which risk factors were most commonly scored. Clinical outcomes in watcher and non-watcher patients were compared using the Pediatric Risk of Mortality III score (PRISM III) [18] and Pediatric Index of Mortality 2 score (PIM2) [23] mortality rate, resuscitation, and PICU interventions in the first 24 h after PICU admission. Additionally, protocol adherence was assessed with a comparison of the daily scoring of the PRESS between cohort pre- and post-implementation of the validity indicator.
Data analyses were performed using SPSS software (version 22.0). Summary statistics were obtained using the t test comparison of means, the Mann-Whitney U test, Pearson chi-square test, or Fisher’s exact test, as appropriate. A 2-sided p value of < 0.05 was considered significant.
Results
Patient characteristics
One hundred seventy-two unplanned PICU admissions were assessed for eligibility of which 98 were excluded (Fig. 2). Seventy-four admissions were included for sensitivity analysis. No additional patients were identified based on the endpoint cardiopulmonary arrest in the general ward. In order to include 75 controls, a total of 101 general ward admissions were assessed for eligibility (Fig. 2). The study cohort contained significantly less surgical patients. Further patient characteristics are described in Table 1.
Sensitivity and specificity
PRESS sensitivity was significantly higher than PEWS sensitivity in the 23 h prior to endpoint PICU admission (Fig. 3). PRESS and PEWS sensitivities at 2 h prior to endpoint were 0.70 (95%CI 0.59 to 0.80) and 0.30 (95%CI 0.20 to 0.42) respectively (p < 0.001) and 0.62 (95%CI 0.49 to 0.73) and 0.30 (95%CI 0.20 to 0.43) at 4 h to endpoint (p < 0.001). No significant differences in PRESS sensitivity were found in the subgroup analyses based on gender, age, and admitting specialism. However, PRESS sensitivity was significantly lower in patients with convulsions compared with those with all other diagnoses (0.29 versus 0.75, p < 0.05, Online Resource Table Ia). The PRESS specificity was 0.67 (95%CI 0.55–0.77).
Forty-nine patients (66%) scored positive on at least one high-risk factor (Online Resource Table Ib) “Worried sign” was the most prominent factor (42%). One patient (1%) was flagged exclusively by an elevated PEWS score. One patient (1%) was stratified as high risk based on “abnormal pH or lactate,” while retrospective analysis of laboratory results revealed that 15 patients (20%) could have been identified based on this risk factor. Three patients (4%) were missed because the PRESS stratification was not changed manually after the lab results were known, and all other patients with abnormal lab results scored positive on another high-risk factor.
Clinical outcomes
Overall PICU mortality in the study group was 7%, higher than expected according to PIM2 and PRISM III (Table 1). A non-significant difference in PICU mortality was found between watcher and non-watcher patients (4% vs 14% respectively, odds ratio 0.25 (95% confidence interval 0.04–1.64)).
Protocol adherence
Protocol adherence increased significantly after implementation of the validity indicator. For more detailed results, see the Online Resource.
Discussion
Key findings
The results of this study show that the PRESS reaches sensitivity comparable with that of other validated PEWS [13, 16] considerably earlier (from 4 h preceding the endpoint) allowing faster detection and proactive checks to prevent further deterioration. The sensitivity of the PRESS increased over the hours leading up to the event.
This study demonstrates that context risk factors are highly potent in identifying patients at risk for clinical deterioration attributing to 96% of PRESS sensitivity, while PEWS sensitivity remained remarkably low. It is likely that risk stratification based on pre-existing factors allows for earlier identification of patients at risk, well before deviation of vital signs. In our study population, abnormal lactate and/or pH could identify 20% of patients at risk, consistent with various previous studies supporting the use of lactate as a predictor in pediatric patients with sepsis [6, 14, 22]. It should be noted that these results do not validate these laboratory tests as screening tools in the general population, but should be put in perspective as a tool to raise situational awareness in risk patients.
It should be highlighted that “worried sign” was the most preeminent risk factor, consistent with previous studies that noted adding nurses’ worry as a criterion raised sensitivity of EWS [8]. The intuitive knowing that something is wrong is often based on unconscious observations and plays an important role in clinical decision-making [19]. Previous studies support the assumption that health professionals’ worry often precedes the deviation of vital signs [9, 21, 25]. Our data justifies the use of worried sign as an independent factor to escalate levels of care.
Surprisingly, the PEWS was found to have a substantially lower sensitivity than reported in earlier validation studies of the Bedside PEWS [16] and our modified PEWS [13]. We stipulated that this inconsistency would be due to our “work as done” analyses in which we included only actual calculated PEWS scores (but could be given up to 8 h previously), in contrast to the other validation studies that use reconstructed and pooled scores. A post hoc analysis including scores given at maximum 2 h prior to endpoint (n = 29) did however not lead to significant improvement of PEWS sensitivity. Another possible explanation for the underexpectation performance of PEWS is that earlier detection by the PRESS has influenced clinical decision-making, leading to earlier transfer to the PICU prior to the rather short window of detection (one to maximally 2 h) of the PEWS. In general, PEWS sensitivity is also limited by the rather broad intervals of age-specific reference values. Patients can shift from the p10 range to the p90 range of normal vitals without leading to an alarming PEWS score, and hence, trends in deterioration can easily be missed.
A remarkable result was that the mortality was higher than expected based on PIM2 and PRISM III prediction models and higher compared with the general local mortality rate. It seems likely that the unplanned nature of the PICU admissions, a known risk factor, contributed to this high mortality. Additionally, a post hoc analysis revealed that 82% of study patients and 100% of patients with fatal outcome were suffering from a complex chronic condition, another well-established risk factor for mortality [11, 27]. Clinical outcome measures did not differ significantly between watcher and non-watcher patients, suggesting equality of care and opposing neglect of non-watchers. As one would expect worse clinical outcome measures among the watchers, this could point to positive effects upon outcomes of risk stratification and proactive and intensified follow-up of these patients. However, our sample size was inadequate to assess infrequent outcome measures such as mortality; therefore, these results should be interpreted with caution.
Limitations
Three main limitations to this study can be identified. First, the interpretation of these results is limited as we performed a single-center study in a tertiary center using a unique stratification system. A considerable amount of patients were suffering from a complex chronic disease, limiting the external validity of our results. However, the contribution of risk factors to sensitivity of the PRESS is strong and it seems unrelated to the local context. Lessons learned from this study can be applied to PEWS in other contexts and are not solely restricted to pediatric practice.
Second, a considerable amount of data was missing from the patient files due to suboptimal protocol adherence. To reduce the effect of missing data, we excluded all patients with expired PRESS or PEWS scores. However, this provides a potential bias if severity of illness would influence the risk of missing data. Prospectively obtained data could have provided more complete data and therefore would have limited the possible influence of differences in patterns of missing data in patients with high and low PRESS and PEWS scores.
Final, the “work as done” analysis, in which scores were considered valid for several hours in accordance with local protocol, likely resulted in an underestimation of the theoretical PEWS and PRESS sensitivity, as it is well established that the sensitivity of PEWS decreases fast each extra hour preceding endpoint. Early warning is highly dependent on detecting deviation in trends of vitals, but in normal clinical practice, measurements are done infrequently and highly dependent on the time invested by nursing staff to complete measurements resulting in underperformance of the systems compared with theoretical capabilities.
Implications
The results of this study indicate that risk stratification can be of benefit to the early detection of patients at risk of clinical deterioration. In current practice, risk factors such as worried sign are often integrated in the PEWS as one of the scoring items, only leading to escalation of care when other items start to deviate and neglecting the significance of context factors as a separate predictor. Our study legitimizes a shift of focus to systems with risk stratification based on multiple context factors, each of which has different powers to (directly) escalate levels of care.
Continuous registration of vitals (e.g., by biomedical sensors) and detection of trends in personalized vital patterns (e.g., by intelligent software that analyzes and personalizes resulting data flow continuously) may increase EWS performance in clinical practice. Together with risk stratification and proactive follow-up of all watchers (including the ones with normal vitals) as done in the PRESS, this could lead to the development of a next-generation warning system that truly contributes to patient safety [28, 29].
Conclusions
This study has shown that early warning systems’ performance can be enhanced with risk stratification. These findings warrant a shift of focus to systems that combine context factors with vital signs in order to achieve earlier detection and intervention in patients at risk.
Abbreviations
- AVPU:
-
Alert, verbal, responsive to pain, unresponsive
- PEWS:
-
Pediatric Early Warning System
- PICU:
-
Pediatric intensive care unit
- PIM2:
-
Pediatric Index of Mortality 2
- PRESS:
-
Pediatric Risk Evaluation and Stratification System
- PRISM III:
-
Pediatric Risk of Mortality score III
References
Alam N, Hobbelink EL, van Tienhoven AJ, van de Ven PM, Jansma EP, Nanayakkara PW (2014) The impact of the use of the early warning score (EWS) on patient outcomes: a systematic review. Resuscitation 85(5):587–594. https://doi.org/10.1016/j.resuscitation.2014.01.013
Bonafide CP, Roberts KE, Weirich CM, Paciotti B, Tibbetts KM, Keren R, Barg FK, Holmes JH (2013) Beyond statistical prediction: qualitative evaluation of the mechanisms by which Pediatric Early Warning Scores impact patient safety. J Hosp Med 8(5):248–253. https://doi.org/10.1002/jhm.2026
Brady PW, Muething S, Kotagal U, Ashby M, Gallagher R, Hall D, Goodfriend M, White C, Bracke TM, DeCastro V, Geiser M, Simon J, Tucker KM, Olivea J, Conway PH, Wheeler DS (2013) Improving situation awareness to reduce unrecognized clinical deterioration and serious safety events. Pediatrics 131(1):e298–e308. https://doi.org/10.1542/peds.2012-1364
Chapman SM, Grocott MP, Franck LS (2010) Systematic review of paediatric alert criteria for identifying hospitalised children at risk of critical deterioration. Intensive Care Med 36(4):600–611. https://doi.org/10.1007/s00134-009-1715-x
Chapman SM, Wray J, Oulton K, Peters MJ (2016) Systematic review of paediatric track and trigger systems for hospitalised children. Resuscitation 109:87–109. https://doi.org/10.1016/j.resuscitation.2016.07.230
Choudhary R, Sitaraman S, Choudhary A (2017) Lactate clearance as the predictor of outcome in pediatric septic shock. J Emerg Trauma Shock 10(2):55–59. https://doi.org/10.4103/jets.jets_103_16
de Vries A, Draaisma JMT, Fuijkschot J (2017) Clinician perceptions of an early warning system on patient safety. Hosp Pediatr 7(10):7. https://doi.org/10.1542/hpeds.2016-0138
Douw G, Huisman-de Waal G, van Zanten AR, van der Hoeven JG, Schoonhoven L (2016) Nurses’ ‘worry’ as predictor of deteriorating surgical ward patients: a prospective cohort study of the Dutch-Early-Nurse-Worry-Indicator-Score. Int J Nurs Stud 59:134–140. https://doi.org/10.1016/j.ijnurstu.2016.04.006
Douw G, Huisman-de Waal G, van Zanten ARH, van der Hoeven JG, Schoonhoven L (2017) Capturing early signs of deterioration: the Dutch-Early-Nurse-Worry-Indicator-Score and its value in the rapid response system. J Clin Nurs 26(17–18):2605–2613. https://doi.org/10.1111/jocn.13648
Duncan HP (2007) Survey of early identification systems to identify inpatient children at risk of physiological deterioration. Arch Dis Child 92(9):828. https://doi.org/10.1136/adc.2006.112094
Edwards JD, Houtrow AJ, Vasilevskis EE, Rehm RS, Markovitz BP, Graham RJ, Dudley RA (2012) Chronic conditions among children admitted to U.S. pediatric intensive care units: their prevalence and impact on risk for mortality and prolonged length of stay*. Crit Care Med 40(7):2196–2203. https://doi.org/10.1097/CCM.0b013e31824e68cf
Fuijkschot J, draaisma JMT (2015) Pediatric Early Warning Systems: in search for the holy grail. Kinderarts Wetenschap 4(13):3
Fuijkschot J, Vernhout B, Lemson J, Draaisma JM, Loeffen JL (2015) Validation of a Paediatric Early Warning Score: first results and implications of usage. Eur J Pediatr 174(1):15–21. https://doi.org/10.1007/s00431-014-2357-8
Gorgis N, Asselin JM, Fontana C, Heidersbach RS, Flori HR, Ward SL (2017) Evaluation of the association of early elevated lactate with outcomes in children with severe sepsis or septic shock. Pediatr Emerg Care. https://doi.org/10.1097/pec.0000000000001021
Lambert V, Matthews A, MacDonell R, Fitzsimons J (2017) Paediatric early warning systems for detecting and responding to clinical deterioration in children: a systematic review. BMJ Open 7(3):e014497. https://doi.org/10.1136/bmjopen-2016-014497
Parshuram CS, Duncan HP, Joffe AR, Farrell CA, Lacroix JR, Middaugh KL, Hutchison JS, Wensley D, Blanchard N, Beyene J, Parkin PC (2011) Multicentre validation of the Bedside Paediatric Early Warning System score: a severity of illness score to detect evolving critical illness in hospitalised children. Crit Care 15(4):R184. https://doi.org/10.1186/cc10337
Parshuram CS, Dryden-Palmer K, Farrell C, Gottesman R, Gray M, Hutchison JS, Helfaer M, Hunt EA, Joffe AR, Lacroix J, Moga MA, Nadkarni V, Ninis N, Parkin PC, Wensley D, Willan AR, Tomlinson GA, Canadian Critical Care Trials G, the EI (2018) Effect of a Pediatric Early Warning System on all-cause mortality in hospitalized pediatric patients: the EPOCH randomized clinical trial. JAMA. 319:1002. https://doi.org/10.1001/jama.2018.0948
Pollack MM, Patel KM, Ruttimann UE (1996) PRISM III: an updated Pediatric Risk of Mortality score. Crit Care Med 24(5):743–752
Rew L, Barrow EM Jr (2007) State of the science: intuition in nursing, a generation of studying the phenomenon. ANS Adv Nurs Sci 30(1):E15–E25
Roland D, Oliver A, Edwards ED, Mason BW, Powell CV (2014) Use of paediatric early warning systems in Great Britain: has there been a change of practice in the last 7 years? Arch Dis Child 99(1):26–29. https://doi.org/10.1136/archdischild-2012-302783
Santiano N, Young L, Hillman K, Parr M, Jayasinghe S, Baramy LS, Stevenson J, Heath T, Chan C, Claire M, Hanger G (2009) Analysis of medical emergency team calls comparing subjective to “objective” call criteria. Resuscitation 80(1):44–49. https://doi.org/10.1016/j.resuscitation.2008.08.010
Scott HF, Brou L, Deakyne SJ, Kempe A, Fairclough DL, Bajaj L (2017) Association between early lactate levels and 30-day mortality in clinically suspected sepsis in children. JAMA Pediatr 171(3):249–255. https://doi.org/10.1001/jamapediatrics.2016.3681
Slater A, Shann F, Pearson G, Paediatric Index of Mortality Study G (2003) PIM2: a revised version of the paediatric index of mortality. Intensive Care Med 29(2):278–285. https://doi.org/10.1007/s00134-002-1601-2
Smith ME, Chiovaro JC, O'Neil M, Kansagara D, Quinones AR, Freeman M, Motu'apuaka ML, Slatore CG (2014) Early warning system scores for clinical deterioration in hospitalized patients: a systematic review. Ann Am Thorac Soc 11(9):1454–1465. https://doi.org/10.1513/AnnalsATS.201403-102OC
Tait D (2010) Nursing recognition and response to signs of clinical deterioration. Nurs Manag (Harrow) 17(6):31–35. https://doi.org/10.7748/nm2010.10.17.6.31.c8007
van Sambeeck SJ, Vos GD, Theeuwes BAM, van der Starre C, Fuijkschot J (2016) De Pediatric Early Warning Score (PEWS) en veilige(re) zorg in Nederland. Pract Pediatr 1(1):10–14
Verlaat CW, Visser IH, Wubben N, Hazelzet JA, Lemson J, van Waardenburg D, van der Heide D, van Dam NA, Jansen NJ, van Heerde M, van der Starre C, van Asperen R, Kneyber M, van Woensel JB, van den Boogaard M, van der Hoeven J, Skic (2017) Factors associated with mortality in low-risk pediatric critical care patients in the Netherlands. Pediatr Crit Care Med 18(4):e155–e161. https://doi.org/10.1097/PCC.0000000000001086
Weenk M, van Goor H, Frietman B, Engelen LJ, van Laarhoven CJHM, Smit J, Bredie SJH, van de Belt TH (2017) Continuous monitoring of vital signs using wearable devices on the general ward: pilot study. JMIR Mhealth Uhealth 5(7):e91. https://doi.org/10.2196/mhealth.7208
Weenk M, van Goor H, van Acht M, Engelen LJ, van de Belt TH, Bredie SJH (2018) A smart all-in-one device to measure vital signs in admitted patients. PLoS One 13(2):e0190138. https://doi.org/10.1371/journal.pone.0190138
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LT: study design, methodology, investigation, data curation, analysis, and drafting of manuscript. CWV: study design and reviewing of manuscript. JL: study design and reviewing of manuscript. JMTD: study design and reviewing of manuscript. JF: supervision, study design, methodology, investigation, data curation, analysis, and reviewing of manuscript.
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Teheux, L., Verlaat, C.W., Lemson, J. et al. Risk stratification to improve Pediatric Early Warning Systems: it is all about the context. Eur J Pediatr 178, 1589–1596 (2019). https://doi.org/10.1007/s00431-019-03446-0
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DOI: https://doi.org/10.1007/s00431-019-03446-0