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Weight Estimation for Drug Dose Calculations in the Prehospital Setting – A Systematic Review

Published online by Cambridge University Press:  13 July 2023

Mike Wells Open the ORCID record for Mike Wells [Opens in a new window] ,
Brendon Henry  and
Lara Goldstein
Mike Wells*
Affiliation:
Department of Emergency Medicine and Critical Care, Herbert Wertheim College of Medicine, Florida International University, Miami, Florida USA
Brendon Henry
Affiliation:
Department of Emergency Medicine and Critical Care, Herbert Wertheim College of Medicine, Florida International University, Miami, Florida USA
Lara Goldstein
Affiliation:
HCA Florida Aventura Hospital, Aventura, Florida USA
*
Correspondence: Prof. Mike Wells Department of Emergency Medicine and Critical Care Herbert Wertheim College of Medicine Florida International University Miami, Florida USA E-mail: [email protected]
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Abstract

Background:

Weight estimation is required to enable dose calculations for weight-based drugs administered during emergency care. The accuracy of the estimation will determine the accuracy of the administered dose. This is an important matter of patient safety. The objective of this systematic review was to collect, review, evaluate, and create a synthesis of the current literature focusing on the accuracy of weight estimation in the prehospital environment.

Methods:

This systematic review followed the PRISMA guidelines. Studies were identified and included if they were peer reviewed, full length, published in English, and contained original data. Studies utilizing any form of weight estimation methodology in the prehospital setting (in children or adults) were included. Data on the quality of the studies and accuracy of the weight estimation systems were extracted. Common themes were also identified.

Results:

Twenty-five studies met the inclusion criteria, with only nine studies (36.0%) containing useful weight estimation accuracy data. The overall quality of the studies was poor. The Broselow tape and paramedic estimates were the most studied methods of weight estimation, but there was insufficient evidence to support conclusions about accuracy. The major themes identified included the importance of accurate weight estimation and drug dosing as critical matters of patient safety, and the need for training to ensure these processes are performed accurately.

Conclusions:

There were limited robust data identified on the accuracy of different weight estimation methods used in the prehospital setting. Future high-quality clinical research in this area is of critical importance to ensure patient safety in the prehospital environment.

Keywords

Broselow tapedrug dosingPAWPER XL tapeweight estimation
Type
Systematic Review
Information
Prehospital and Disaster Medicine , Volume 38 , Issue 4 , August 2023 , pp. 471 - 484
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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 (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of the World Association for Disaster and Emergency Medicine

Introduction

The dosing of medications by Emergency Medical Services (EMS) paramedics is often based on weight, especially in children. Reference Stehman, Buckley and Dos Santos1 There is insufficient time and resources to weigh critically ill or injured patients in the prehospital setting, and having a safe, accurate, and reliable way to estimate weight is an integral step to ensuring positive outcomes. Reference Young and Korotzer2 With medication errors occurring in more than 28% of EMS encounters (when drugs are administered), and with weight estimation errors a significant contributor to these errors, a weight estimation technique that is rapid, accurate, reliable, and easy to use in the prehospital environment is essential. Reference Ramadanov, Klein, Schumann, Aguilar and Factors3 This would facilitate dose calculations by EMS practitioners and would also allow for the receiving facility to prepare for the patient’s arrival.

Weight estimation techniques in children have generally been well-described in the Emergency Medicine literature. They include parental estimations, visual estimations by health care providers, age-based formulas, length-based methods (such as the Broselow tape), and the newer – and most accurate – length- and habitus-based methods (such as the Mercy method and the PAWPER XL tape). Reference Wells, Goldstein and Bentley4 In adults, the need for weight-based dosing (and therefore, weight estimation) is less common than in children, but it is still important. Reference Wells, Goldstein and Cattermole5 Weight estimation methods in adults include self-estimations, estimations by family members, visual estimations by health care providers, anthropometric formulas, automated computerized methods, and the use of pediatric methods in adults. Reference Cattermole and Manirafasha6 Patient self-estimations have been shown to be the most accurate, but this might not be possible in an incapacitated patient, and a reliable method of estimation needs to be available.

There is very little known about what weight estimation methods are used in prehospital settings anywhere in the world. Reference Wells, Barnes and Vincent-Lambert7 There is less known about how accurate these methods are in the EMS environment. To the authors’ knowledge, there has not been a systematic review on prehospital weight estimation systems and how accurate and reliable the various methods are when used by EMS practitioners. This could be an important source of information to determine the best strategies for estimating weight by EMS practitioners. This information would also be useful for policymakers and protocol boards.

The purpose of this study was to conduct a comprehensive review, analysis, and synthesis of the existing literature on weight estimation practices in the prehospital emergency medical care setting. The specific aims were to evaluate the quality of relevant published research, to identify the weight estimation methods used in prehospital medicine, to assess the evidence supporting the effectiveness and accuracy of the described methods, and to identify important themes arising from the studies.

Methods

Identifying Relevant Studies

This systematic review was based on the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) methodology, with a protocol registered with PROSPERO (registration number CRD42021253761). No significant amendments of, or deviations from, the registered protocol were noted. A literature search was conducted for publications from January 1988 through September 2022 using PubMed (National Center for Biotechnology Information, National Institutes of Health; Bethesda, Maryland USA), Embase (Elsevier; Amsterdam, Netherlands), Web of Science (Clarivate Analytics; London, United Kingdom), and Google Scholar (Google Inc.; Mountain View, California USA) databases. The Boolean search terms “weight estimation” OR “weight prediction” AND “prehospital” OR “EMS” OR “Emergency Medical Services” OR “paramedic” OR “out of hospital” were used. Additional searches were done based on the “similar articles” section of PubMed and by reviewing the bibliographies (and the Medical Subject Headings [MeSH] terms) of the papers identified in the searches. To minimize reporting biases, broad inclusion criteria were used, and multiple databases were used for the search. This included searching for studies in the “grey literature.”

Study Selection

Studies were screened if they were peer reviewed, full length, published in English, and contained original data (Figure 1). Studies were considered for inclusion if they reported on weight estimation by any method, in any age group, and were related to EMS in any way. Studies on drug dosing accuracy were included if data pertaining to weight estimation were included. Studies were excluded if there was no reference to weight estimation. Screening was conducted by two researchers independently (BH and MW), and the identified articles were reviewed and screened by the other researcher.

Figure 1. PRISMA Flow Chart for the Identification and Selection of Studies.

Data Extraction

The following data were extracted from each included study: study information (publication date, number of patients, origin of study), study design, the methods of weight estimation used, the environment the study was performed in, the age range, the location, and the major findings. The data were extracted by one author (BH) and the accuracy independently confirmed by the other authors (MW, LG).

Data Analysis and Grading of Evidence

The approach used to assess the certainty of the evidence from the included studies included as assessment of the risk of bias (and study limitations), inconsistency in results (heterogeneity), indirectness of evidence, imprecision and statistical or methodological flaws, and publication bias. Each included study was graded for quality of evidence using a modified Newcastle-Ottawa scale, as has been described previously (Supplementary Table 1; available online only). Reference Wells, Goldstein and Bentley4 Each study could score a minimum of zero stars and a maximum of ten stars on the modified Newcastle-Ottawa scale. An assessment of selective non-reporting or under-reporting of results in the studies was included in the Newcastle-Ottawa scale. On this scale, a study with score from six to ten has high quality, four to five has a moderate risk of bias, and zero to three has a very high risk of bias. In addition, the Cochrane method for assessing bias in non-randomized studied was used, which assessed for selective reporting, incomplete outcome data, adequate control of confounders, blinding, appropriate comparability of cohorts, appropriate sample size, and appropriate selection. A formal assessment of heterogeneity was not conducted as there was an insufficient number of high-quality studies with data suitable for a pooled quantitative analysis.

Outcomes

The main outcomes of interest were the quality of the studies, the methods of weight estimation studied, and the accuracy of weight estimation by the studied methods (ideally percentage of estimates within 10% and 20% of actual measured weight [P10 and P20]). In addition, recurring themes arising in the included studies were identified and analyzed.

Results

Study Characteristics

A total of 25 studies which met the inclusion criteria addressing the subject of weight estimation in the prehospital setting were included (Table 1). Reference Dieckmann8Reference Ward, Taylor and Keeney31

Table 1. Studies Included in the Systematic Review Reference Dieckmann8Reference Ward, Taylor and Keeney31

Abbreviations: NOS, Newcastle Ottawa Scale (score in stars, from 0/worst to 10/best; P10, percentage of estimates within 10% of actual weight; P20, percentage of estimates within 20% of actual weight; GCS – Glasgow Coma Scale score; EMS, Emergency Medical Services; ED, emergency department; EMD, emergency medical dispatcher; HEMS, helicopter Emergency Medical Services; ROSC, return of spontaneous circulation; OHCA, out-of-hospital cardiac arrest; HCP, heath care provider.

Studies were conducted from 1994 through 2022. Most studies originated from the United States (19/25; 76.0%), with two studies (8.0%) originating from Australia, two (8.0%) from Germany, and two (8.0%) from South Africa. Twenty studies (80.0%) were pediatric weight estimation studies, three (12.0%) were adult weight estimation studies, and two studies (8.0%) included patients of all ages. There were 13/25 (52.0%) prospective studies, 8/25 (32.0%) retrospective record reviews, and 4/25 (16.0%) before-and-after studies. Of the 14 prospective studies, 9/14 (64.3%) were simulation studies. Five of the simulation studies used manikins, two used photographic images of children, and two used children as simulated patients. There were five clinical prospective studies (5/14; 35.7%), of which three were conducted in the prehospital environment, and two in the emergency department (ED; with paramedic estimators). The Broselow tape was evaluated in 12/25 studies (48.0%), paramedic estimates in 6/25 studies (24.0%), caregiver estimates in 4/25 studies (16.0%), other methods in 9/25 studies (36.0%), and unspecified methods in 5/25 studies (20.0%). Weight estimation accuracy was the primary objective of only 12/25 (48.0%) studies, while drug dosing accuracy was the primary objective in 13/25 (52.0%) studies.

Quality of the Studies

On the Newcastle-Ottawa scale, 16/25 studies (64.0%) were at very high risk of bias, 6/25 studies (24.0%) were at moderate risk of bias, and 3/25 (12.0%) of studies were high-quality studies. The results of the Cochrane assessment of risk of bias are shown in Figure 2a and Figure 2b. The major risks of bias in the identified studies were incomplete reporting of outcome data, inadequate control of confounders, and weak study design or selection methodology.

Figure 2a. Quality Assessment for the Included Studies. Note: The Cochrane grading for each individual study is shown.

Figure 2b. Risk of Bias Assessment for the Included Studies. Note: The cumulative scores for each category of risk are shown.

Accuracy Outcomes

The data on the accuracy outcomes are shown in Table 2. Only nine (9/25; 36.0%) studies presented data that were helpful to evaluate the performance of the weight estimation systems: the Broselow tape (two studies), paramedic estimates (six studies), caregiver estimates (one study), unknown method of estimation (two studies), PAWPER XL tape (two studies), and the Mercy method (one study). The remainder of the studies (16/25; 64.0%) evaluated the combined effects of weight estimation and drug dose calculations on the final drug dose accuracy.

Table 2. Accuracy Data for Weight Estimation Systems

Notes: aStudies in adults only; bStudies in adults and children; cStudies in children only; dStudies in manikins; eStudies in which the primary focus was on drug dosing accuracy, significant confounders for inferences about weight estimation accuracy.

Abbreviations: P10, percentage of estimates within 10% of actual weight; P20, percentage of estimates within 20% of actual weight; P50, percentage of estimates within 50% of actual weight; GCS, Glasgow Coma Scale score; BT, Broselow tape; ED, emergency department.

Major Themes

The major themes identified in the included articles, related to paramedic weight estimation, are shown in Table 3.

Table 3. Major Themes Identified from the Included Studies

Discussion

Medication errors during prehospital emergency care of children are known to be the among the most frequent and most severe. Reference Hoyle, Davis, Putman, Trytko and Fales15,Reference Kaufmann, Roth and Engelhardt25 This error is caused by two factors: errors in estimating the weight and errors during the drug dose calculation process. However, weight estimation is not always given sufficient importance. Reference Hirata, Kang, Ramirez, Kimata and Yamamoto32,Reference Kaufmann, Laschat and Wappler33 This is true not only in children, but in adults as well, when weight-based drugs are administered. Reference Wells, Goldstein and Cattermole5,Reference Barata, Benjamin, Mace, Herman and Goldman34 However, there remains a critical gap in knowledge concerning which weight estimation systems are the most accurate and appropriate for use in the prehospital setting. Reference Hoyle, Sleight, Henry, Chassee, Fales and Mavis35 As the safety and effectiveness of potentially life-saving drug therapy relies on accurate weight estimation, it is crucial to address this gap in understanding. The significance of this study lies in its contribution to addressing and highlighting this knowledge gap and providing valuable insights into improving patient safety and care in the prehospital environment.

Quality of the Studies

The current study highlights a significant gap in high-quality studies in EMS weight estimation. Despite its importance, the number of papers addressing this topic is limited, with only 25 identified, of which merely nine contained relevant data. This underscores the urgent need for further research in this area to improve the accuracy and reliability of EMS weight estimation, and ultimately enhance patient outcomes.

The study designs, sampling, and selection were found to be suboptimal. Many of the simulation studies relied on weight estimations from manikins or images rather than actual patients. These studies should only be regarded as preliminary reports, and the findings should not be generalized to clinical environments. Several of the clinical studies used a before-and-after methodology. This format is typically regarded as a low-quality study design, and the findings should also be regarded as hypothesis-generating rather than substantive. Reference Goodacre36 The lack of prospective clinical studies was notable and is indicative of the poor quality of the available evidence. Compounding these issues were the small sample sizes, and a preponderance of convenience sampling, further limited the studies’ power to provide meaningful conclusions.

The failure to describe potential confounders was also a major weakness. Most studies did not evaluate weight estimation accuracy in subgroups of body mass index/BMI (and age-groups in children). These two factors are known to have a significant impact on the accuracy of weight estimation methods. The failure to include this information makes it impossible to compare outcomes in different studies.

Some studies failed to specify the weight estimation methods used in the study. This dramatically limited the usefulness of the information obtained. There is limited value in studying weight estimation accuracy without this information.

Taken together, these findings highlight the need for more robust study designs, larger sample sizes, and the evaluation of relevant confounding factors in future investigations of weight estimation accuracy. Additionally, the standardization of weight estimation methods and data reporting across studies would greatly facilitate the comparison of results and the identification of best practices.

Accuracy Data

Studies from the Emergency Medicine literature have suggested that an acceptable standard for a weight estimation system is to achieve 70% of estimates within 10% of actual weight (P10 ≤ 70%) and 95% of estimates within 20% of actual weight (P20 ≤ 95%). Reference Wells, Goldstein and Bentley4,Reference Stewart37 This is a standard which is generally achieved by the newer length- and habitus-based weight estimation systems (such as the PAWPER XL tape and the Mercy method), and which is seldom reached by other methods, including the Broselow tape. Reference Young and Korotzer2,Reference Wells, Goldstein and Bentley4 In this review, only the PAWPER XL tape used by paramedics achieved this benchmark in two studies, and paramedic estimates of adults’ weights came close in a single study. Reference Wells, Goldstein and Bentley4,Reference Martin, Soria and Brown9,Reference Wells, Goldstein and Bentley26 None of these were clinical, prehospital studies, however.

The Broselow tape was found to out-perform paramedic estimates by Vilke, et al. Reference Vilke, Marino, Fisher and Chan10 Unfortunately, the acceptable error range used in this study was very large (±50%), which makes it difficult to compare these results with those from other studies. The only other useful study on the Broselow tape showed a poor accuracy in children and adolescent simulated patients. Reference Wells, Goldstein and Bentley26 From the studies that evaluated drug dosing accuracy with the Broselow tape, it is possible to infer that weight estimation was more accurate than paramedic “guesstimates” and age-based formulas, but there was no direct evidence presented in any study to support this. It is worth noting that the accuracy, and acceptability, of the Broselow tape has been questioned in the Emergency Medicine literature because of its inaccuracy in underweight and obese children. Reference Young and Korotzer2,Reference Wells, Goldstein and Bentley4,Reference Wells, Goldstein, Bentley, Basnett and Monteith38

The accuracy of visual estimates of weight by paramedics was poor, with the exception of a single study by Martin, et al. Reference Martin, Soria and Brown9 It has been well-established in other research that visual estimates of weight are unreliable, and frequently very inaccurate. There is reasonable consensus that this method of weight estimation should not be used. Reference Young and Korotzer2

Interestingly, the single study evaluating caregiver estimates of weight showed that these estimates were substantially less accurate than reported in previous studies in the Emergency Medicine and pediatrics literature. Reference Young and Korotzer2,Reference Wells, Goldstein and Bentley4,Reference Chassee, Reischmann, Mancera and Hoyle20 This was a pragmatic, real-world study in which 9-1-1 dispatchers obtained weight estimates from family members of sick children. This study is a useful warning that real-world scenarios may be very different to the typical settings used for weight estimation studies, and with substantially different results. This finding is significant, and important, because parental estimates of weight are considered to be the gold standard for weight estimates in children, but there have been few real-life studies to confirm this.

The only information on other methods of weight estimation showed that the PAWPER XL tape performed very well and the Mercy method moderately in studies by Wells, et al. Reference Wells, Goldstein and Bentley24,Reference Wells, Goldstein and Bentley26 Age-based formulas performed poorly and were only reported in a single study by Hoyle, et al. Reference Hoyle, Ekblad, Woodwyk, Brandt, Fales and Lammers28

In this review, when compared against doctors and nurses, there was no convincing evidence that paramedics were better or worse at estimating weight using the Broselow tape, the PAWPER XL tape, or the Mercy method. Reference Wells, Goldstein and Bentley4,Reference Wells, Goldstein and Bentley26 However, one study did find that paramedics were significantly less accurate than doctors and nurses at visual estimation of weight in adult patients. Reference Hall, Larkin, Trujillo, Hinds and Delaney12 This evidence from a single study is weak, however. Since visual estimation of weight is generally condemned as a poor method of weight estimation, the relevance is limited in any event. Reference Dearlove and Dearlove39,Reference Pintilie, Myint, Skinner, Potter and Metcalf40

Many articles not included in this review have suggested that a particular weight estimation system would be suitable for use during prehospital care, without actually studying it in this environment (eg, Lubitz, et al and Park, et al). Reference Lubitz, Seidel, Chameides, Luten, Zaritsky and Campbell41,Reference Park, Kwon and Jung42 It is not clear whether generalizing weight estimation performance data from a different environment, such as the ED, to the prehospital environment would be valid. In the Emergency Medicine and pediatric literature, the most accurate weight estimation methods in children are currently the PAWPER XL tape and the Mercy method. Reference Young and Korotzer2,Reference Wells, Goldstein and Bentley4 While it is possible that these methods could be accurate in the prehospital environment, their usability (with a comprehensive drug dosing guide) during the circumstances of prehospital emergency care would need to be tested and confirmed. Reference Cottrell, O’Brien and Curry43

Many of the included studies focused on the accuracy of drug dosing as the key outcome, but generally ignored the impact of inaccurate weight estimation on drug dose accuracy. Both weight estimation and the drug dose calculation and administration process need to be accurate and easy-to-use to ensure accurate drug delivery. Reference Kaufmann, Laschat and Wappler33,Reference Barata, Benjamin, Mace, Herman and Goldman34 This concept needs to be included in future research.

Themes

Four major themes were identified from the included studies. Firstly, the importance of accurate weight-based drug dosing was recognized as crucial for safe and effective emergency drug therapy in the EMS environment. This highlights the critical need for further research in this field. This has already been identified by patient safety organizations as a vital aspect of ED care, and applies equally to the prehospital environment. 44,Reference Bailey, Gaunt and Grissinger45 Secondly, both weight estimation and drug dose calculation were identified as key contributors to drug dosing errors, underscoring the critical importance of training to ensure these processes are conducted accurately and efficiently. This emphasizes the need for comprehensive guidance and on-going training for EMS personnel, using accurate weight estimation methods and guides to drug dose calculation. Thirdly, paramedic “guesstimates” of weight were deemed unreliable, with length-based tapes being a preferable alternative. However, these length-based tapes are not without their limitations, including incorrect usage and inaccuracies in underweight and obese children, as well as in older children. More accurate weight estimation methods should be considered. Lastly, weight estimation in adults has not been adequately studied, and there are currently no reliable methods for estimating weight in incapacitated adults in the EMS setting. This highlights a critical gap in the literature and the need for future research to develop accurate and reliable weight estimation methods for this population. Taken together, these findings emphasize the importance of accurate weight estimation and drug dose calculation in EMS, and the need for on-going research and training to improve patient outcomes and ensure optimal care in emergency situations.

Limitations

There were some important limitations in this study. Most importantly, there were limited data to draw firm conclusions about prehospital weight estimation because of the limited number of studies and the poor quality of many of the included research articles. Several studies were found in abstract form only and could not be included in this review, indicating a potential publication bias in this area of study.

Conclusion

Not enough is known about the practice of weight estimation in the EMS setting or by paramedics. That is the most important finding of this study. It was found that there was very limited published information available, and the quality of existing studies was suboptimal. Therefore, no real conclusions can be drawn regarding actual weight estimation practices, what methods are currently used, nor the performance of weight estimation systems in the EMS environment. This is a significant threat to patient safety in the EMS environment, and there is a critical and urgent need for high-quality research. Wide recognition was found in the literature on the importance of weight estimation accuracy, drug dosing accuracy, and training in these processes for EMS personnel. Future research should focus on real-world, high-quality clinical research identifying which methods of weight estimation are most accurate and easy-to-use, and which drug dosing guides are most accurate and easy-to-use in adults and children. In addition, appropriate training methods and protocols need to be developed and studied to determine how best to ensure competency by users, as well as adherence to best evidence practices in this regard.

Conflicts of interest

The authors report there are no competing interests to declare.

Supplementary Material

To view supplementary material for this article, please visit https://doi.org/10.1017/S1049023X23006027

References

Stehman, CR, Buckley, RG, Dos Santos, FL, et al. Bedside estimation of patient height for calculating ideal body weight in the emergency department. J Emerg Med. 2011;41(1):97101.CrossRefGoogle ScholarPubMed
Young, KD, Korotzer, NC. Weight estimation methods in children: a systematic review. Ann Emerg Med. 2016;68(4):441451.CrossRefGoogle ScholarPubMed
Ramadanov, N, Klein, R, Schumann, U, Aguilar, ADV, Factors, Behringer W., influencing medication errors in prehospital care: a retrospective observational study. Medicine (Baltimore). 2019;98(49):e18200.CrossRefGoogle ScholarPubMed
Wells, M, Goldstein, LN, Bentley, A. The accuracy of emergency weight estimation systems in children - a systematic review and meta-analysis. Int J Emerg Med. 2017;10(29):143.CrossRefGoogle ScholarPubMed
Wells, M, Goldstein, LN, Cattermole, GN. Development and validation of a length- and habitus-based method of total body weight estimation in adults. Am J Emerg Med. 2022;53:4453.CrossRefGoogle ScholarPubMed
Cattermole, GN, Manirafasha, A. Accuracy of weight estimation methods in adults, adolescents, and children: a prospective study. Emerg Med J. 2020;38(9):718723.CrossRefGoogle ScholarPubMed
Wells, M, Barnes, L, Vincent-Lambert, C. Pediatric weight estimation practices of advanced life support providers in Johannesburg, South Africa. Afr J Emerg Med. 2018;8(2):5154.CrossRefGoogle ScholarPubMed
Dieckmann, RA. Rectal diazepam for prehospital pediatric status epilepticus. Ann Emerg Med. 1994;23(2):216224.CrossRefGoogle ScholarPubMed
Martin, DR, Soria, DM, Brown, CG, et al. Agreement between paramedic-estimated weights and subsequent hospital measurements in adults with out-of-hospital cardiac arrest. Prehosp Disaster Med. 1994;9(1):5456.CrossRefGoogle ScholarPubMed
Vilke, GM, Marino, A, Fisher, R, Chan, TC. Estimation of pediatric patient weight by EMT-PS. J Emerg Med. 2001;21(2):125128.CrossRefGoogle ScholarPubMed
Anglemyer, BL, Hernandez, C, Brice, JH, Zou, B. The accuracy of visual estimation of body weight in the ED. Am J Emerg Med. 2004;22(7):526529.CrossRefGoogle ScholarPubMed
Hall, WL, Larkin, GL, Trujillo, MJ, Hinds, JL, Delaney, KA. Errors in weight estimation in the emergency department: comparing performance by providers and patients. J Emerg Med. 2004;27(3):219224.CrossRefGoogle ScholarPubMed
Kaji, AH, Gausche-Hill, M, Conrad, H, et al. Emergency medical services system changes reduce pediatric epinephrine dosing errors in the prehospital setting. Pediatrics. 2006;118(4):1493–500.CrossRefGoogle ScholarPubMed
Heyming, T, Bosson, N, Kurobe, A, Kaji, AH, Gausche-Hill, M. Accuracy of paramedic Broselow tape use in the prehospital setting. Prehosp Emerg Care. 2012;16(3):374380.CrossRefGoogle ScholarPubMed
Hoyle, JD, Davis, AT, Putman, KK, Trytko, JA, Fales, WD. Medication dosing errors in pediatric patients treated by emergency medical services. Prehosp Emerg Care. 2012;16(1):5966.CrossRefGoogle ScholarPubMed
Lammers, R, Byrwa, M, Fales, W. Root causes of errors in a simulated prehospital pediatric emergency. Acad Emerg Med. 2012;19(1):3747.CrossRefGoogle Scholar
Lim, CAE, Kaufman, BJ, O’Connor, J Jr, Cunningham, SJ. Accuracy of weight estimates in pediatric patients by prehospital Emergency Medical Services personnel. Am J Emerg Med. 2013;31(7):11081112.CrossRefGoogle ScholarPubMed
Lammers, R, Willoughby-Byrwa, M, Fales, W. Medication errors in prehospital management of simulated pediatric anaphylaxis. Prehosp Emerg Care. 2014;18(2):295304.CrossRefGoogle ScholarPubMed
Campagne, D, Young, M, Stroh, G, Wheeler, J. Pediatric tape: accuracy and medication delivery in the National Park Service. West J Emerg Med. 2015;16(5):665670.CrossRefGoogle ScholarPubMed
Chassee, T, Reischmann, D, Mancera, M, Hoyle, JD. Emergency medical dispatchers can obtain accurate pediatric weights from 9-1-1 callers. Prehosp Emerg Care. 2016;20(6):808814.CrossRefGoogle ScholarPubMed
Rappaport, LD, Brou, L, Givens, T, et al. Comparison of errors using two length-based tape systems for prehospital care in children. Prehosp Emerg Care. 2016;20(4):508517.CrossRefGoogle ScholarPubMed
Shah, MI, Carey, JM, Rapp, SE, et al. Impact of high-fidelity pediatric simulation on paramedic seizure management. Prehosp Emerg Care. 2016;20(4):499507.CrossRefGoogle ScholarPubMed
Hollis, GJ, Keene, TM, Ardlie, RM, Caldicott, DG, Stapleton, SG. Prehospital ketamine use by paramedics in the Australian Capital Territory: a 12-month retrospective analysis. Emerg Med Australas. 2017;29(1):8995.CrossRefGoogle ScholarPubMed
Wells, M, Goldstein, LN, Bentley, A. The use of body habitus reference images improves the ability of novices to accurately estimate children’s weight using the PAWPER XL tape system. J Emerg Med. 2017;54(2):165175.CrossRefGoogle ScholarPubMed
Kaufmann, J, Roth, B, Engelhardt, T, et al. Development and prospective federal state-wide evaluation of a device for height-based dose recommendations in prehospital pediatric emergencies: a simple tool to prevent most severe drug errors. Prehosp Emerg Care. 2018;22(2):252259.CrossRefGoogle ScholarPubMed
Wells, M, Goldstein, LN, Bentley, A. The accuracy of pediatric weight estimation during simulated emergencies: the effects of patient position, patient cooperation, and human errors. Afr J Emerg Med. 2018;8(2):4350.CrossRefGoogle Scholar
Boehringer, B, Pfohl, B, Tilney, PVR. Accuracy of critical care transport team estimation of patient height and weight in scene responses. Air Med J. 2020;39(4):262264.CrossRefGoogle ScholarPubMed
Hoyle, JD, Jr., Ekblad, G, Woodwyk, A, Brandt, R, Fales, B, Lammers, RL. Methods used to obtain pediatric patient weights, their accuracy and associated drug dosing errors in 142 simulated prehospital pediatric patient encounters. Prehosp Emerg Care. 2022;26(4):511518.CrossRefGoogle ScholarPubMed
Kaufmann, J, Uhl, S, Singer, E, et al. Improving pediatric drug safety in prehospital emergency care-10 years on. J Patient Saf. 2021;17(8):e12411246.CrossRefGoogle Scholar
Rappaport, LD, Markowitz, G, Hulac, S, Roosevelt, G. Medication errors in pediatric patients after implementation of a field guide with volume-based dosing. Prehosp Emerg Care. 2023;27(2):213220.CrossRefGoogle ScholarPubMed
Ward, CE, Taylor, M, Keeney, C, et al. The effect of documenting patient weight in kilograms on pediatric medication dosing errors in emergency medical services. Prehosp Emerg Care. 2023;27(2):263268.CrossRefGoogle ScholarPubMed
Hirata, KM, Kang, AH, Ramirez, GV, Kimata, C, Yamamoto, LG. Pediatric weight errors and resultant medication dosing errors in the emergency department. Pediatr Emerg Care. 2019;35(9):637642.CrossRefGoogle ScholarPubMed
Kaufmann, J, Laschat, M, Wappler, F. Medication errors in pediatric emergencies: a systematic analysis. Dtsch Arztebl Int. 2012;109(38):609616.Google ScholarPubMed
Barata, IA, Benjamin, LS, Mace, SE, Herman, MI, Goldman, RD. Pediatric patient safety in the prehospital/emergency department setting. Pediatr Emerg Care. 2007;23(6):412418.CrossRefGoogle ScholarPubMed
Hoyle, JD, Jr., Sleight, D, Henry, R, Chassee, T, Fales, B, Mavis, B. Pediatric prehospital medication dosing errors: a mixed-methods study. Prehosp Emerg Care. 2015;20(1):117124.CrossRefGoogle ScholarPubMed
Goodacre, S. Uncontrolled before-after studies: discouraged by Cochrane and the EMJ. Emerg Med J. 2015;32(7):507508.CrossRefGoogle ScholarPubMed
Stewart, D. Accuracy of the Broselow tape for estimating pediatric weight in two Australian emergency departments. University of Sydney; 2009. https://ses.library.usyd.edu.au//bitstream/2123/6265/1/Declan%20Stewart%20WPP%20final.pdf. Accessed April 24, 2023Google Scholar
Wells, M, Goldstein, LN, Bentley, A, Basnett, S, Monteith, I. The accuracy of the Broselow tape as a weight estimation tool and a drug-dosing guide - a systematic review and meta-analysis. Resuscitation. 2017;121:917.CrossRefGoogle Scholar
Dearlove, CB, Dearlove, O. Visual estimation of children’s weights. Anaesthesia. 1999;54(12):12281229.CrossRefGoogle ScholarPubMed
Pintilie, H, Myint, PK, Skinner, J, Potter, JF, Metcalf, AK. Poor visual estimation of stroke patients’ body weight by healthcare professionals has implications for stroke thrombolysis therapy. Int J Stroke. 2012;7(7):E67.CrossRefGoogle ScholarPubMed
Lubitz, DS, Seidel, JS, Chameides, L, Luten, RC, Zaritsky, AL, Campbell, FW. A rapid method for estimating weight and resuscitation drug dosages from length in the pediatric age group. Ann Emerg Med. 1988;17(6):576581.CrossRefGoogle ScholarPubMed
Park, JW, Kwon, H, Jung, JY, et al. “Weighing Cam:” a new mobile application for weight estimation in pediatric resuscitation. Prehosp Emerg Care. 2020;24(3):441450.CrossRefGoogle ScholarPubMed
Cottrell, EK, O’Brien, K, Curry, M, et al. Understanding safety in prehospital emergency medical services for children. Prehosp Emerg Care. 2014;18(3):350358.CrossRefGoogle ScholarPubMed
Pennsylvania Patient Safety Authority. Medication errors- significance of accurate patient weights. Pa Patient Saf Advis. 2009;6(1):1015.Google Scholar
Bailey, B, Gaunt, M, Grissinger, M. Update on medication errors associated with incorrect patient weights. Pa Patient Saf Advis. 2016;13(2):5057.Google Scholar
Figure 0

Figure 1. PRISMA Flow Chart for the Identification and Selection of Studies.

Figure 1

Table 1. Studies Included in the Systematic Review8–31

Figure 2

Figure 2a. Quality Assessment for the Included Studies. Note: The Cochrane grading for each individual study is shown.

Figure 3

Figure 2b. Risk of Bias Assessment for the Included Studies. Note: The cumulative scores for each category of risk are shown.

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Table 2. Accuracy Data for Weight Estimation Systems

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Table 3. Major Themes Identified from the Included Studies

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