Validation of anthropometric and bioelectrical impedance equations for the prediction of fat mass amongst South African children.

IF 5.7 2区医学 Q1 ENDOCRINOLOGY & METABOLISM

Diabetes, Obesity & Metabolism Pub Date : 2025-09-14 DOI:10.1111/dom.70129

M T Hudda, E van Niekerk, C M Sedumedi, L Moeng-Mahlangu, P H Whincup, J J Reilly, H S Kruger, M A Monyeki

{"title":"Validation of anthropometric and bioelectrical impedance equations for the prediction of fat mass amongst South African children.","authors":"M T Hudda, E van Niekerk, C M Sedumedi, L Moeng-Mahlangu, P H Whincup, J J Reilly, H S Kruger, M A Monyeki","doi":"10.1111/dom.70129","DOIUrl":null,"url":null,"abstract":"Background/aims: While several prediction equations which combine anthropometric, demographic, and/or bioelectrical impedance (BIA) variables to estimate childhood fat mass (FM) are available, comprehensive comparisons of their performance are lacking. We validated FM estimates for children from a range of published equations against reference-standard deuterium dilution observed FM.Methods: This cross-sectional study was based on 323 children (42% male) from South Africa of Black African ethnic origins aged 5 to 8 years with information on age, sex, ethnicity, height, weight, deuterium dilution observed FM, triceps and subscapular skinfold thickness, and BIA observed FM, resistance, and impedance. We extracted all equations from three systematic reviews of childhood FM prediction equations that used the above available predictors and were developed on more than 100 males and females. FM estimates from each equation were calculated and the performance of each, as well as FM reported from the BIA manufacturer software, was compared with deuterium dilution observed FM using statistics of R2, Calibration (slope and calibration-in-the-large), and root mean square error (RMSE).Results: Nineteen equations (1 based on basic anthropometry, 12 on skinfold thickness, 6 on BIA) were validated. R2 and RMSE values ranged between 58.3% (BIA manufacturer equation) and 89.0% (Britz et al. (2017) skinfold thickness equation), and between 1.1 kg (Wendel et al. (2016) skinfold thickness equation) and 3.4 kg (Horlick et al. (2002) BIA equation), respectively. Calibration varied considerably across the equations. From the basic anthropometry, skinfold thickness, and BIA categories, the best performing equations from each category were by: Hudda et al. (2019) (basic anthropometry), Wickramasinghe et al. (2008) (skinfold thickness), and Ramirez et al. (2012) (BIA).Conclusions: The performance of published equations varied considerably upon external validation in this South African childhood population. Notably, the Hudda et al. (2019) equation, which relies solely on readily available information of weight, height, sex, age and ethnicity, produced one of the highest R2 values, was well calibrated, and produced a low RMSE value (1.4 kg). Alternative equations which also performed very well relied on additional measurements of skinfold thickness and/or BIA which require equipment, training, extra costs and additional time to obtain.","PeriodicalId":158,"journal":{"name":"Diabetes, Obesity & Metabolism","volume":" ","pages":""},"PeriodicalIF":5.7000,"publicationDate":"2025-09-14","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Diabetes, Obesity & Metabolism","FirstCategoryId":"3","ListUrlMain":"https://doi.org/10.1111/dom.70129","RegionNum":2,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"ENDOCRINOLOGY & METABOLISM","Score":null,"Total":0}

引用次数: 0

Abstract

Background/aims: While several prediction equations which combine anthropometric, demographic, and/or bioelectrical impedance (BIA) variables to estimate childhood fat mass (FM) are available, comprehensive comparisons of their performance are lacking. We validated FM estimates for children from a range of published equations against reference-standard deuterium dilution observed FM.

Methods: This cross-sectional study was based on 323 children (42% male) from South Africa of Black African ethnic origins aged 5 to 8 years with information on age, sex, ethnicity, height, weight, deuterium dilution observed FM, triceps and subscapular skinfold thickness, and BIA observed FM, resistance, and impedance. We extracted all equations from three systematic reviews of childhood FM prediction equations that used the above available predictors and were developed on more than 100 males and females. FM estimates from each equation were calculated and the performance of each, as well as FM reported from the BIA manufacturer software, was compared with deuterium dilution observed FM using statistics of R², Calibration (slope and calibration-in-the-large), and root mean square error (RMSE).

Results: Nineteen equations (1 based on basic anthropometry, 12 on skinfold thickness, 6 on BIA) were validated. R² and RMSE values ranged between 58.3% (BIA manufacturer equation) and 89.0% (Britz et al. (2017) skinfold thickness equation), and between 1.1 kg (Wendel et al. (2016) skinfold thickness equation) and 3.4 kg (Horlick et al. (2002) BIA equation), respectively. Calibration varied considerably across the equations. From the basic anthropometry, skinfold thickness, and BIA categories, the best performing equations from each category were by: Hudda et al. (2019) (basic anthropometry), Wickramasinghe et al. (2008) (skinfold thickness), and Ramirez et al. (2012) (BIA).

Conclusions: The performance of published equations varied considerably upon external validation in this South African childhood population. Notably, the Hudda et al. (2019) equation, which relies solely on readily available information of weight, height, sex, age and ethnicity, produced one of the highest R² values, was well calibrated, and produced a low RMSE value (1.4 kg). Alternative equations which also performed very well relied on additional measurements of skinfold thickness and/or BIA which require equipment, training, extra costs and additional time to obtain.

查看原文本刊更多论文

南非儿童脂肪量预测的人体测量和生物电阻抗方程的验证。

背景/目的：虽然有几种结合人体测量学、人口统计学和/或生物电阻抗（BIA）变量来估计儿童脂肪量（FM）的预测方程，但缺乏对其性能的全面比较。我们根据一系列已发表的方程式验证了儿童的调频估计，对照参考标准氘稀释观察到的调频。方法：本横断面研究以323名年龄在5 - 8岁的南非黑人儿童（42%为男性）为基础，包括年龄、性别、种族、身高、体重、氘稀释观察FM、肱三头肌和肩胛下皮层厚度，BIA观察FM、阻力和阻抗。我们从三个使用上述预测因子的儿童FM预测方程的系统综述中提取了所有方程，这些方程是在100多名男性和女性中开发的。计算每个方程的调频估计，并使用R2、校准（斜率和校准-in- large）和均方根误差（RMSE）统计数据，将每个方程的性能以及BIA制造商软件报告的调频与氘稀释观察到的调频进行比较。结果：验证了19个方程（1个基于基础人体测量，12个基于皮褶厚度，6个基于BIA）。R2和RMSE值分别在58.3% （BIA制造商方程）和89.0% （Britz等人（2017）皮褶厚度方程）之间，以及1.1 kg （Wendel等人（2016）皮褶厚度方程）和3.4 kg （Horlick等人（2002）BIA方程）之间。各方程式的校准差异很大。从基本人体测量、皮褶厚度和BIA类别来看，每个类别中表现最好的方程分别是：Hudda等人（2019）（基本人体测量）、Wickramasinghe等人（2008）（皮褶厚度）和Ramirez等人（2012）（BIA）。结论：在南非儿童人群的外部验证中，已发表的方程的性能变化很大。值得注意的是，Hudda等人（2019）的方程仅依赖于现成的体重、身高、性别、年龄和种族信息，它产生了最高的R2值之一，校准得很好，并产生了较低的RMSE值（1.4 kg）。另一种表现也很好的方程依赖于额外的皮褶厚度和/或BIA测量，这需要设备、培训、额外的成本和额外的时间来获得。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Diabetes, Obesity & Metabolism 医学-内分泌学与代谢

CiteScore

10.90

自引率

6.90%

发文量

319

审稿时长

3-8 weeks

期刊介绍： Diabetes, Obesity and Metabolism is primarily a journal of clinical and experimental pharmacology and therapeutics covering the interrelated areas of diabetes, obesity and metabolism. The journal prioritises high-quality original research that reports on the effects of new or existing therapies, including dietary, exercise and lifestyle (non-pharmacological) interventions, in any aspect of metabolic and endocrine disease, either in humans or animal and cellular systems. ‘Metabolism’ may relate to lipids, bone and drug metabolism, or broader aspects of endocrine dysfunction. Preclinical pharmacology, pharmacokinetic studies, meta-analyses and those addressing drug safety and tolerability are also highly suitable for publication in this journal. Original research may be published as a main paper or as a research letter.