Comparison of body composition and adipokine levels between thin and normal-weight prepubertal children☆

Ambroszkiewicz, Jadwiga; Gajewska, Joanna; Szamotulska, Katarzyna; Rowicka, Grażyna; Klemarczyk, Witold; Chełchowska, Magdalena

doi:10.1016/j.jped.2016.11.004

Abstract

Objective:

Thinness can have substantial consequences for child development and health. Adipokines, including leptin and adiponectin, play a significant role in the regulation of important metabolic functions. The aim of this study was to investigate associations between body composition and serum leptin and adiponectin levels in thin and normal-weight children.

Methods:

The authors examined 100 healthy prepubertal children, who were divided into two subgroups: thin (n = 50) and normal-weight children (n = 50). Body composition was assessed by dual-energy X-ray absorptiometry. Serum concentrations of adipokines were determined by immunoenzymatic assays.

Results:

Thin children had a similar body height but significantly lower (p < 0.0001) body weight, body mass index, fat mass, lean mass, and bone mineral content compared with normal-weight children. Serum concentrations of leptin were about 2-fold lower (p < 0.0001) in thin vs. normal-weight subjects. Serum levels of total adiponectin, adiponectin multimers, and soluble leptin receptor (sOB-R) were similar in both groups. The leptin/soluble leptin receptor ratio and leptin/adiponectin ratios were lower (p < 0.0001) in thin vs. normal-weight children. In both groups of children, it was found that body composition parameters were positively related with leptin but not with adiponectin levels. Additionally, bone mineral content was positively related with body mass index, fat mass, lean mass, and leptin level in thin and normal-weight children.

Conclusions:

Prepubertal thin children have disturbances in body composition and adipokine profile. Early recognition of thinness and determination of body composition parameters and adipokine levels can be useful in medical and nutritional care of thin children for the optimization of bone mineral accrual.

KEYWORDS
Leptin; Adipomectin; Body composition; Thinness; Children

Resumo

Objetivo:

A magreza pode ter consequências substanciais para o desenvolvimento e a saúde das crianças. As adipocinas, inclusive a leptina e a adiponectina, desempenham um papel significativo na regulação de importantes funções metabólicas. O objetivo do estudo foi investigar as associações entre a composição corporal e os níveis séricos de leptina e adiponectina em crianças magras e com peso normal.

Métodos:

Examinamos 100 crianças pré-púberes saudáveis, divididas em dois subgrupos: crianças magras (n = 50) e com peso normal (n = 50). A composição corporal foi avaliada pelo método de absorciometria de dupla energia de raios X. As concentrações séricas das adipocinas foram determinadas por ensaios imunoenzimáticos.

Resultados:

As crianças magras apresentaram altura semelhante, porém peso corporal (p < 0,0001), índice de massa corporal (IMC), massa gorda, massa magra e conteúdo mineral ósseo (CMO) significativamente menores em comparação com crianças com peso normal. As concentrações séricas de leptina foram aproximadamente duas vezes mais baixas (p < 0,0001) em indivíduos magros do que em crianças com peso normal. Os níveis séricos de adiponectina total, multímeros de adiponectina e receptor de leptina solúvel (sOB-R) foram semelhantes em ambos os grupos. Os índices de leptina/sOB-R e leptina/adiponectina foram inferiores (p < 0,0001) em crianças magras do que crianças com peso normal. Em ambos os grupos de crianças descobrimos que os parâmetros de composição corporal estavam positivamente relacionados à leptina, porém não aos níveis de adiponectina. Além disso, observamos que o CMO estava positivamente relacionado ao IMC, à massa gorda, à massa magra e ao nível de leptina em crianças magras e com peso normal.

Conclusões:

As crianças pré-púberes magras têm alterações na composição corporal e no perfil de adipocinas. O reconhecimento precoce da magreza e a determinação dos parâmetros de composição corporal e dos níveis de adipocina podem ser úteis no cuidado médico e nutricional de crianças magras para aprimoramento do acúmulo mineral ósseo.

PALAVRAS-CHAVE
Leptina; Adiponectina; Composição corporal; Magreza; Crianças

Introduction

It is widely recognized that overweight and obesity in childhood should be closely monitored for public health policy reasons.¹1 de Onis M. Preventing childhood overweight and obesity. J Pediatr (Rio J). 2015;91:105-7. However, there is scant research examining the prevalence of thinness in early childhood, despite potential negative consequences for health and development across the course of life. The most widely studied index of nutritional status in adults has been body mass index (BMI). However, the definition of thinness is dissimilar between adults and children. The World Health Organization (WHO) defines thinness as BMI less than the fifth percentile of the reference values for normal-weight children. Cole et al.²2 Cole TJ, Flegal KM, Nicholls D, Jackson AA. Body mass index cut offs to define thinness in children and adolescents: international survey. BMJ. 2007;335:194. proposed a new graded definition of thinness in childhood and adolescence, based on pooled international data for BMI and linked to the WHO-recommended adult cut-off points. These international BMI cut-offs allow distinctions between different grades of thinness: grade 1 (17 to <18.5 - mild thinness), grade 2 (16 to <17 - moderate thinness), and grade 3 (<16 - severe thinness).

In the literature there are many studies presenting the prevalence of childhood thinness, including severe thinness, in low-income countries.³3 Monyeki MA, Awotidebe A, Strydom GL, de Ridder JH, Mamabolo RL, Kemper HC. The challenges of underweight and overweight in South African children: are we winning or losing the battle. A systematic review. Int J Environ Res Public Health. 2015;12:1156-73.^,⁴4 Poh BK, Wong JE, Norimah AK, Deurenberg P. Differences in body build in children of different ethnic groups and their impact on the prevalence of stunting, thinness, overweight, and obesity. Food Nutr Bull. 2016;37:3-13. Thinness was also observed in about 7-11% of Japanese children and 5-6% of Australian children, with a higher proportion in girls than boys.⁵5 Shirasawa T, Ochiai H, Nanri H, Nishimura R, Ohtsu T, Hoshino H, et al. Trends of underweight and overweight/obesity among Japanese schoolchildren from 2003 to 2012, defined by body mass index and percentage overweight cutoffs. J Epidemiol. 2015;25:482-8.^,⁶6 Clifford SA, Gold L, Mensah FK, Jansen PW, Lucas N, Nicholson JM, et al. Health-care costs of underweight, overweight and obesity: Australian population-based study. J Paediatr Child Health. 2015;51:1199-206. In developed European countries, thinness has been reported to range from 4.8% to 11.9% in girls, and from 3.1% to 9% in boys, but this prevalence differs by age, sex, and region.⁷7 Rosati P, Triunfo S, Zucchetti F, Gorca C, Chini R, Campana R. Screening of obesity, overweight and thinness in a children population in Rome, Italy. Minerva Pediatr. 2014;66:201-7.^,⁸8 Pearce A, Rougeaux E, Law C. Disadvantaged children at greater relative risk of thinness (as well as obesity): a secondary data analysis of the England National Child Measurement Programme and the UK Millennium Cohort Study. Int J Equity Health. 2015;14:61. In Poland, depending on the standard used, the prevalence of thinness was diagnosed in about 6-8% of boys and 9-11% of girls.⁹9 Grajda A, Kułaga Z, Gurzkowska B, Napieralska E, Litwin M. Regional differences in the prevalence of overweight, obesity and underweight among polish children and adolescents. Med Wieku Rozwoj. 2011;15:258-65.

It is important to note that not only optimal body weight but body composition, including bone mass, lean mass, and fat mass are relevant to child development and healthy life.¹⁰10 Bialo SR, Gordon CM. Underweight, overweight, and pediatric bone fragility: impact and management. Curr Osteoporos Rep. 2014;12:319-28. Changes in body composition, especially in fat mass and its distribution, are associated with alterations in the secretion of adipokines by adipose tissue. Among adipokines, leptin and adiponectin are of particular interest due to their opposing biologic functions and association with body weight. Leptin is an adipocyte-derived hormone, which plays a role not only in regulating appetite, reproductive capacity, and energy consumption, but also in bone metabolism through its paracrine or autocrine action on several systems. Clinical studies have shown that serum leptin concentration is proportional to total body weight and fat mass. Authors have reported elevated serum leptin levels in obesity and reduced levels in conditions of low body weight.¹¹11 Baskaran C, Eddy KT, Miller KK, Meenaghan E, Misra M, Lawson EA. Leptin secretory dynamics and associated disordered eating psychopathology across the weight spectrum. Eur J Endocrinol. 2016;174:503-12. Leptin interacts directly with the leptin receptor (OB-R), which in humans exists in four known isoforms with different C-terminal cytoplasmatic domains. The soluble leptin receptor (sOB-R) represents the main leptin-binding activity in human blood and modulates leptin levels by binding free leptin in circulation and preventing hormone degradation and clearance.¹²12 Schaab M, Kratzsch J. The soluble leptin receptor. Best Pract Res Clin Endocrinol Metab. 2015;29:661-70. Adiponectin is another biologically active adipokine expressed by mature adipocytes. Structurally, adiponectin belongs to the collagen superfamily. Its monomeric subunits, composed of a C-terminal globular domain, oligomerize to trimers that further associate through disulphide bonds with the collagenous domain to form polymeric complexes of a higher structure (hexamers). In serum, adiponectin circulates as high molecular weight (HMW), mid-molecular weight (MMW), and low molecular weight (LMW) adiponectin. HMW adiponectin appears to be an active form and the HMW/total adiponectin ratio is a better indicator of metabolic disturbances than total adiponectin.¹³13 Araki S, Dobashi K, Kubo K, Asayama K, Shirahata A. High molecular weight, rather than total, adiponectin levels better reflect metabolic abnormalities associated with childhood obesity. J Clin Endocrinol Metab. 2006;91:5113-6. Adiponectin plays a role in many physiological processes, including the metabolism of carbohydrates and fatty acids, insulin resistance, inflammation, and bone metabolism. Studies have shown that serum levels of adiponectin inversely correlate with BMI, fat mass, and bone mineral density in children and adults.¹⁴14 Mather KJ, Goldberg RB. Clinical use of adiponectin as a marker of metabolic dysregulation. Best Pract Res Clin Endocrinol Metab. 2014;28:107-17.

Until now, studies regarding body composition and adipokine status have mainly focused on obese patients. Authors have reported hyperleptinemia and hypoadiponectinemia associated with increased insulin resistance, diabetes, and metabolic syndrome in these subjects.¹⁵15 Groeneveld MP, Huang-Doran I, Semple RK. Adiponectin and leptin in human severe insulin resistance - diagnostic utility and biological insights. Biochimie. 2012;94:2172-9.

16 Redondo MJ, Rodriguez LM, Haymond MW, Hampe CS, Smith EO, Balasubramanyam A, et al. Serum adiposity-induced biomarkers in obese and lean children with recently diagnosed autoimmune type 1 diabetes. Pediatr Diabetes. 2014;15:543-9.^-¹⁷17 Falahi E, Khalkhali Rad AH, Roosta S. What is the best biomarker for metabolic syndrome diagnosis. Diabetes Metab Syndr. 2015;9:366-72. As yet, there have been limited reports regarding body composition and serum adipokine status in thin subjects, especially in prepubertal children. It is an important problem, because the prevalence of thinness among children, especially girls, has increased according to data from several countries.

The aim of the present study was (a) to examine the differences in body composition and adipokine levels among thin and normal-weight prepubertal children and (b) to investigate the possible association between the biochemical and anthropometric parameters in these groups of children.

Methods

The study included 100 children aged 5-10 years recruited between January 2014 and November 2015 from a group of consecutive patients seeking dietary counseling in the Department of Nutrition at the Institute of Mother and Child in Warsaw. Children qualified for the study were generally healthy, well-nourished, without endocrine disorders or genetic syndromes, without diseases that could affect nutritional status, growth, and pubertal development, and not requiring constant intake of medications. All children lived in an urban area in families with good economic status and remained on a mixed diet. Pubertal stage was assessed according to the Tanner scale. Children classified as Tanner stage 1 were included in this study, but subjects who showed pubertal development were excluded. According to Cole's international BMI cut-off points, the subjects were divided into two groups: thin children (n = 50) and normal-weight children (n = 50).

The study was conducted according to the principles of the Declaration of Helsinki and was approved by the Ethics Committee of the Institute of Mother and Child. Written informed consent was obtained from all parents of the children before their participation in the study.

Anthropometric measurements such as body height and weight were performed. Body height was measured with a stadiometer and recorded with a precision of 0.1 cm and body weight was assessed unclothed with a calibrated balance scale to the nearest 0.1 kg. BMI was calculated as body weight (kg) divided by height squared (m²). Body composition (fat mass [FM], lean mass [LM], bone mineral content [BMC]) was measured by dual-energy X-ray absorptiometry (DXA) using the Lunar Prodigy with pediatric software version 9.30.044 (General Electric Healthcare, WI, USA). All children were measured by trained staff with the same equipment, using standard positioning techniques.

Venous blood samples were collected in the morning hours between 8:00 and 10:00 am after an overnight fast and centrifuged at 1000 g for 10 min at 4 °C. Serum samples were stored at −20 °C until biochemical assay, but no longer than two months. Concentrations of leptin and sOB-R were determined using enzyme-linked immunosorbent assay (ELISA) kits from DRG Diagnostics (Marburg, Germany). Intra-assay variations (coefficient of variation [CV%]) were 5.95% and 7.10% for leptin and sOB-R, respectively. Inter-assay CVs were 8.66% and 6.21% for leptin and sOB-R, respectively. Serum levels of total adiponectin and its multimers were determined using an ELISA kit from ALPCO (Salem, NH, USA). This assay is designed for quantitative determination of total adiponectin as well as HMW, MMW, and LMW adiponectin. Adiponectin multimers were selectively measured after sample pretreatment with two proteases that specifically digested the trimeric forms, or both the hexameric and trimeric forms. Using this method, both total and HMW adiponectin were determined directly, but MMW adiponectin was calculated by subtracting the concentration of HMW from the concentration of combined MMW + HMW adiponectin and LMW adiponectin by subtracting the concentration of combined MMW + HMW from total adiponectin. In this assay, the detection limit was 0.019 ng/mL, intra-assay CVs were 5.4% for total adiponectin and 5.0% for HMW adiponectin, and inter-assay variations were 5.0% and 5.7% for total and HMW adiponectin, respectively.

The obtained results were statistically analyzed using SPSS version 23.0 software (IBM SPSS Statistics for Windows, NY, USA). All variables were tested for normality using the Kolmogorov-Smirnov test. Data are presented as means ± standard deviation (SD) for normally distributed data or medians and interquartile ranges (25-75th percentiles) for skewed distribution. Group differences were assessed using Student's t-test or the Mann-Whitney U test, as appropriate. Differences in anthropometric and biochemical parameters between children with thinness grades 1-3 were assessed by exact Jonckheere-Tentra test (p-value for trend). Multivariate regression analyses were performed with BMC, leptin (expressed as natural logarithm [ln]), and adiponectin as dependent variables, and anthropometric and biochemical parameters were selected as independent variables (separate models adjusted for age and sex) in thin and normal-weight groups. A p-value less than 0.05 was considered significant for all analyses.

Results

Data on the children's characteristics and anthropometry are presented in Table 1. The studied children were generally healthy. There was no difference in early life characteristics, such as maternal age, gestational age, or Apgar score. Thin children had a slightly lower birth weight than normal-weight children, but this difference was not statistically significant. Thin children did not differ in age, sex, or height compared with normal-weight children. However, thin subjects had significantly lower (p < 0.001) body weight, BMI, fat mass, and lean mass. The median values of total BMC and spine BMC were decreased (p < 0.001) in the group of thin children compared with the normal-weight group. Additionally, the ratio of FM/LM was also lower (p < 0.05) in thin subjects.

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Table 1
Children's characteristics and anthropometry.

Regarding adipokine levels, a more than 2-fold lower serum leptin level was found in thin children vs. normal-weight peers (Table 2). In the two studied groups, there were no differences in total adiponectin concentrations and its multimers (HMW, MMW, and LMW) as well as sOB-R. Additionally, the percentage of HMW adiponectin to total adiponectin was comparable in thin and normal-weight children. Hence, the ratios of leptin to sOB-R and leptin to total adiponectin were significantly lower (p < 0.0001) in thin children.

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Table 2
Serum concentrations of adipokines in groups of thin and normal-weight children.

According to Cole's cut-off points, thin children were classified into three subgroups: grade 1 (74%), grade 2 (20%), and grade 3 (6%). Significant differences in weight (p < 0.01), BMI (p < 0.001), BMI z-score (p < 0.001), BMC (p < 0.05), lean mass (p = 0.056), and spinal BMC (p = 0.054) were observed among the subgroups (grades 1-3) of thin children (Table 3).

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Table 3
Comparison of anthropometric and biochemical parameters in the subgroups of thin children (grades 1-3).

In multivariante regression analyses, BMC was significantly correlated with BMI (p < 0.01), lean mass (p < 0.001), leptin (<0.001), and OB-R (p < 0.05) in thin children and with BMI (p < 0.01), fat mass (p < 0.001), lean mass (p < 0.001), and leptin (p = 0.05) in normal-weight subjects (Table 4). Serum leptin level was highly correlated with BMC (p < 0.001) and spinal BMC (p < 0.001) in thin subjects, whereas, in the normal-weight group, a relationship was found between leptin and BMI (p < 0.01), fat mass (p < 0.01), and BMC (p = 0.05). No correlations were observed between serum levels of adiponectin and body composition parameters in both groups of children.

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Table 4
Multivariate regression with BMC, leptin, and total adiponectin as dependent variables and selected anthropometric and biochemical parameters as the independent variables (separate models adjusted for age and sex).

Discussion

Both extremes of the spectrum of weight, from obesity to underweight, may have serious health consequences for individuals. Studies in obese patients, and at the opposite end of the weight spectrum in patients with anorexia nervosa, have shown associations between body composition and bone status.¹⁸18 Faje A, Klibanski A. Body composition and skeletal health: too heavy? Too thin?. Curr Osteoporos Rep. 2012;10:208-16.^,¹⁹19 Misra M, Katzman DK, Cord J, Manning SJ, Mendes N, Herzog DB, et al. Bone metabolism in adolescent boys with anorexia nervosa. J Clin Endocrinol Metab. 2008;93:3029-36. In adults, low body weight is established as a predictor of low bone mineral content and a risk factor for fracture. There are only a few reports assessing body composition in thin healthy children.²⁰20 O'Dea JA, Amy NK. Perceived and desired weight, weight related eating and exercising behaviours, and advice received from parents among thin, overweight, obese or normal weight Australian children and adolescents. Int J Behav Nutr Phys Act. 2011;8:68.

21 Pietrobelli A, Faith MS, Wang J, Brambilla P, Chiumello G, Heymsfield SB. Association of lean tissue and fat mass with bone mineral content in children and adolescents. Obes Res. 2002;10:56-60.^-²²22 Vaitkeviciute D, Lätt E, Mäestu J, Jürimäe T, Saar M, Purge P, et al. Physical activity and bone mineral accrual in boys with different body mass parameters during puberty: a longitudinal study. PLoS ONE. 2014;9:e107759.

In the present study, differences in body composition were observed regarding lower fat mass, lean mass, and the ratio of fat mass to lean mass in thin children compared with normal-weight peers. Similar to these results, a clinical study conducted in Australia demonstrated that thin school children were less muscular, weaker, and less active than their normal-weight peers.²⁰20 O'Dea JA, Amy NK. Perceived and desired weight, weight related eating and exercising behaviours, and advice received from parents among thin, overweight, obese or normal weight Australian children and adolescents. Int J Behav Nutr Phys Act. 2011;8:68. These authors suggested that such children may have a range of significant health problems, including lower skeletal mass and increased risk of osteoporosis in later life. In the present study's thin subjects, lower median values of total BMC were found, as well as spinal BMC compared with normal-weight children. In this group of children, BMC was positively correlated with BMI, lean mass, serum leptin level, serum sOB-R level, ratio of leptin to sOB-R, and ratio of leptin to total adiponectin. Also, Pietrobelli et al.²¹21 Pietrobelli A, Faith MS, Wang J, Brambilla P, Chiumello G, Heymsfield SB. Association of lean tissue and fat mass with bone mineral content in children and adolescents. Obes Res. 2002;10:56-60. reported that fat mass and lean mass were independently associated with bone mineral content in children and adolescents. Vaitkeviciute et al.,²²22 Vaitkeviciute D, Lätt E, Mäestu J, Jürimäe T, Saar M, Purge P, et al. Physical activity and bone mineral accrual in boys with different body mass parameters during puberty: a longitudinal study. PLoS ONE. 2014;9:e107759. in a group of underweight boys, observed significantly lower body mass, fat mass, lean mass, and BMC compared with normal-weight boys. These authors suggested that thinness in childhood indicated a greater chance of lower bone mineral density in the future. The present study's results as well as the observations from other studies support the hypothesis that in thin children there are alterations in body composition and that a close association exists between body composition and bone mineral density. Moreover, bone status during childhood might be a strong predictor of bone status in young adulthood, when peak bone mass is achieved.

Recent advances from basic and clinical studies confirm the important role of adipokines in many metabolic processes.²³23 Kawai M, de Paula FJ, Rosen CJ. New insights into osteoporosis: the bone-fat connection. J Intern Med. 2012;272:317-29. Among them, leptin and adiponectin are unique hormones because their levels reflect the degree of fat accrual and they appear to be pleiotropic mediators. Changes in adipokine levels also modulate bone metabolism. Numerous studies have shown leptin and adiponectin secretory dynamics across the weight spectrum and the authors have concluded that the profile of adipokines in lean and obese subjects is different.¹¹11 Baskaran C, Eddy KT, Miller KK, Meenaghan E, Misra M, Lawson EA. Leptin secretory dynamics and associated disordered eating psychopathology across the weight spectrum. Eur J Endocrinol. 2016;174:503-12.^,²⁴24 Misra M, Klibanski A. Endocrine consequences of anorexia nervosa. Lancet Diabetes Endocrinol. 2014;2:581-92.

There are scant reports about adipokine status in thin healthy subjects. Ebert et al.²⁵25 Ebert T, Roth I, Richter J, Tönjes A, Kralisch S, Lossner U, et al. Different associations of adipokines in lean and healthy adults. Horm Metab Res. 2014;46:41-7. observed significantly higher serum levels of adiponectin and resistin and lower concentrations of leptin in lean healthy adults compared with overweight/obese subjects. However, Moscavitch et al.²⁶26 Moscavitch SD, Kang HC, Filho RA, Mesquita ET, Neto HC, Rosa ML. Comparison of adipokines in a cross-sectional study with healthy overweight, insulin-sensitive and healthy lean, insulin-resistant subjects, assisted by a family doctor primary care program. Diabetol Metab Syndr. 2016;8:9. reported comparable adiponectin levels in lean and overweight subjects. These results support the notion that several adipokines might be regulated in a different manner in lean adults compared with overweight or obese subjects and patients with eating disorders. As yet, in thin prepubertal children, the assessment of serum adipokines and their interrelations with body composition have not been ascertained in detail. Studies on adiponectin multimers are especially scarce.

In the group of thin children, the present study observed significantly lower serum leptin levels than in normal-weight children, and similar concentrations of total adiponectin as well as adiponectin multimers in both groups of children. Hence, the ratios of leptin to OB-R and leptin to adiponectin were significantly lower in thin subjects. Similarly, Martos-Moreno et al.²⁷27 Martos-Moreno GÁ, Kratzsch J, Körner A, Barrios V, Hawkins F, Kiess W, et al. Serum visfatin and vaspin levels in prepubertal children: effect of obesity and weight loss after behavior modifications on their secretion and relationship with glucose metabolism. Int J Obes (Lond). 2011;35:1355-62. found significantly lower concentrations of leptin and comparable values of total adiponectin and HMW adiponectin in thin prepubertal Spanish children vs. controls. In addition, Murdolo et al.²⁸28 Murdolo G, Nowotny B, Celi F, Donati M, Bini V, Papi F, et al. Inflammatory adipokines, high molecular weight adiponectin, and insulin resistance: a population-based survey in prepubertal schoolchildren. PLoS ONE. 2011;6:e17264. analyzed prepubertal Italian children and observed that leptin levels increased progressively from thin to overweight children. Additionally, the authors reported comparable concentrations of total adiponectin in lean and obese subjects, but also a tendency toward decreased levels of HMW adiponectin in obese subjects. They suggested that leptin and the leptin/HMW adiponectin ratio differed between lean and overweight individuals, and was significantly higher in those with adiposity. These studies as well as the present work showed that adipokine profiles were different in children with various BMIs. Notably, leptin, rather than adiponectin, emerges as a marker of the degree of adiposity in the young thin population. As expected, a significant positive association was demonstrated between serum leptin levels and anthropometric parameters in thin and normal-weight children. However, no correlations were observed between adiponectin levels and body composition parameters in both groups of children. Other researchers also found positive correlations between leptin levels and body composition parameters in adults and in children, and suggested a strong association of fat mass with leptin at every age, which is consistent with the notion that leptin acts as a signal of adiposity.²⁹29 Schoppen S, Riestra P, García-Anguita A, López-Simón L, Cano B, de Oya I, et al. Leptin and adiponectin levels in pubertal children: relationship with anthropometric variables and body composition. Clin Chem Lab Med. 2010;48:707-11.

Some studies reported that a number of early life characteristics - such as birth weight, gestational age, and maternal age at birth - might be associated with weight status and risk of thinness.⁸8 Pearce A, Rougeaux E, Law C. Disadvantaged children at greater relative risk of thinness (as well as obesity): a secondary data analysis of the England National Child Measurement Programme and the UK Millennium Cohort Study. Int J Equity Health. 2015;14:61.^,³⁰30 Kato R, Kubota M, Higashiyama Y, Nagai A. Longitudinal study of thinness from birth to early childhood: the association with parental thinness. Acta Paediatr. 2014;103:1285-9. In the present group of children there were no significant differences in birth weight, Apgar score, gestational age, or maternal age at birth. The thin children were healthy, without malnutrition or eating disorders, and almost 75% were classified as having mild thinness.

This study had a few potential limitations. First, the sample size was relatively small (especially after dividing the participants into subgroups according to grade of thinness), which lacks sufficient power to detect moderate associations with statistical significance. However, the studied group was homogeneous; all children were Caucasian, comparable in age and sex, living in an urban area. Second, there was lack of detailed nutritional and physical activity data for the studied children, but these children were healthy, without eating disorders, and remained on a traditional mixed diet. Third, only leptin and adiponectin concentrations were detected; other adipokines were not measured. However, the authors are planning to determine resistin, visfatin, and apelin in thin children. Additionally, not only total adiponectin concentrations were determined, but also HMW, MMW, and LMW multimers of adiponectin.

In conclusion, these findings demonstrate that as early as in prepubertal age, thin children exhibit a different body composition and pattern of adipokines, with major differences in leptin levels. Decreased BMC might be associated with lower serum leptin levels and the proportions of leptin to adiponectin in thin children. Early recognition of both underweight and overweight youth and the accompanying consequences on bone metabolism are important for the optimization of bone mineral accrual and prevention of bone loss. It is suggested that monitoring of body composition and adipokine status can be useful in medical and nutritional care of thin children to prevent health risks and reduce some diseases in later life.

☆
Please cite this article as: Ambroszkiewicz J, Gajewska J, Szamotulska K, Rowicka G, Klemarczyk W, Chełchowska M. Comparison of body composition and adipokine levels between thin and normal-weight prepubertal children. J Pediatr (Rio J). 2017;93:428-35.

Acknowledgments

The authors thank the staff of the Department of Internal Medicine, Endocrinology, and Diabetology at the Central Clinical Hospital of the Ministry of the Interior in Warsaw for their help in DXA measurements.

References

¹
de Onis M. Preventing childhood overweight and obesity. J Pediatr (Rio J). 2015;91:105-7.
²
Cole TJ, Flegal KM, Nicholls D, Jackson AA. Body mass index cut offs to define thinness in children and adolescents: international survey. BMJ. 2007;335:194.
³
Monyeki MA, Awotidebe A, Strydom GL, de Ridder JH, Mamabolo RL, Kemper HC. The challenges of underweight and overweight in South African children: are we winning or losing the battle. A systematic review. Int J Environ Res Public Health. 2015;12:1156-73.
⁴
Poh BK, Wong JE, Norimah AK, Deurenberg P. Differences in body build in children of different ethnic groups and their impact on the prevalence of stunting, thinness, overweight, and obesity. Food Nutr Bull. 2016;37:3-13.
⁵
Shirasawa T, Ochiai H, Nanri H, Nishimura R, Ohtsu T, Hoshino H, et al. Trends of underweight and overweight/obesity among Japanese schoolchildren from 2003 to 2012, defined by body mass index and percentage overweight cutoffs. J Epidemiol. 2015;25:482-8.
⁶
Clifford SA, Gold L, Mensah FK, Jansen PW, Lucas N, Nicholson JM, et al. Health-care costs of underweight, overweight and obesity: Australian population-based study. J Paediatr Child Health. 2015;51:1199-206.
⁷
Rosati P, Triunfo S, Zucchetti F, Gorca C, Chini R, Campana R. Screening of obesity, overweight and thinness in a children population in Rome, Italy. Minerva Pediatr. 2014;66:201-7.
⁸
Pearce A, Rougeaux E, Law C. Disadvantaged children at greater relative risk of thinness (as well as obesity): a secondary data analysis of the England National Child Measurement Programme and the UK Millennium Cohort Study. Int J Equity Health. 2015;14:61.
⁹
Grajda A, Kułaga Z, Gurzkowska B, Napieralska E, Litwin M. Regional differences in the prevalence of overweight, obesity and underweight among polish children and adolescents. Med Wieku Rozwoj. 2011;15:258-65.
¹⁰
Bialo SR, Gordon CM. Underweight, overweight, and pediatric bone fragility: impact and management. Curr Osteoporos Rep. 2014;12:319-28.
¹¹
Baskaran C, Eddy KT, Miller KK, Meenaghan E, Misra M, Lawson EA. Leptin secretory dynamics and associated disordered eating psychopathology across the weight spectrum. Eur J Endocrinol. 2016;174:503-12.
¹²
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Publication Dates

Publication in this collection
Jul-Aug 2017

History

Received
24 June 2016
Accepted
8 Nov 2016

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] ☆
Please cite this article as: Ambroszkiewicz J, Gajewska J, Szamotulska K, Rowicka G, Klemarczyk W, Chełchowska M. Comparison of body composition and adipokine levels between thin and normal-weight prepubertal children. J Pediatr (Rio J). 2017;93:428-35.

	Thin children n = 50	Normal-weight children n = 50	p-Value
Early life characteristics
Child's sex (male/female)	25/25	26/24	0.841
Birth weight (g)^a	3123 ± 569	3316 ± 652	0.160
Maternal age (years)^b	30 (27-32)	29 (25-31)	0.134
Gestational age (weeks)^b	40 (38-40)	40 (38-40)	0.663
Apgar score^b	10 (9-10)	10 (10-10)	0.113

Characteristics at enrollment
Age (years)^b	6.9 (6.0-8.0)	6.9 (5.1-8.9)	0.614
Body weight (kg)^a	19.8 ± 4.6	24.7 ± 6.5	<0.001
Body height (cm)^a	120.3 ± 11.7	123.3 ± 12.3	0.215
BMI (kg/m²)^a	13.5 ± 0.6	16.0 ± 1.5	<0.001
BMI z-score^b	-1.29 (-1.43 to -1.10)	-0.12 (-0.56 to 0.28)	<0.001
Fat mass (%)^a	18.3 ± 6.3	21.3 ± 6.4	0.021
Fat mass (kg)^a	3.16 ± 1.12	5.21 ± 2.72	<0.001
Lean mass (kg)^a	14.7 ± 4.4	18.2 ± 4.1	<0.001
Total BMC (kg)^a	0.63 ± 0.24	0.84 ± 0.24	<0.001
Spinal BMC (kg)^a	0.05 ± 0.02	0.07 ± 0.02	<0.001
FM/LM^a	0.23 ± 0.10	0.28 ± 0.11	0.018

	Thin children n = 50	Normal-weight children n = 50	p-Value
Leptin (ng/mL)^b	1.33 (0.65-1.62)	3.06 (1.60-5.18)	<0.001
sOB-R (ng/mL)^a	44.69 ± 13.88	45.47 ± 14.62	0.786
Total adiponectin (ng/mL)^a	8.24 ± 2.21	8.46 ± 2.47	0.647
HMW adiponectin (ng/mL)^a	4.81 ± 1.42	5.05 ± 1.97	0.486
MMW adiponectin (ng/mL)^a	1.74 ± 1.01	2.00 ± 1.21	0.239
LMW adiponectin (ng/mL)^a	1.51 ± 0.84	1.33 ± 0.96	0.320
Leptin/sOB-R^b	0.03 (0.02-0.04)	0.08 (0.03-0.14)	<0.001
Leptin/adiponectin^b	0.15 (0.07-0.24)	0.39 (0.19-0.61)	<0.001
HMW/total adiponectin (%)^a	58.25 ± 9.74	58.52 ± 11.92	0.903

	Thinness grade 1 (n = 37)	Thinness grade 2 (n = 10)	Thinness grade 3 (n = 3)	p-Value
Age (years)	7.2 ± 1.7	6.7 ± 1.9	7.3 ± 1.7	0.546
Birth weight (g)	3130 ± 623	3102 ± 219	3103 ± 780	0.815
Weight (kg)	20.5 ± 4.8	18.0 ± 3.4	16.4 ± 1.4	0.010
Height (cm)	121.4 ± 12.4	117.1 ± 10.4	117.0 ± 3.0	0.224
BMI (kg/m²)	13.8 ± 0.4	12.9 ± 0.2	12.0 ± 0.4	<0.001
BMI z-score	-1.1 (-1.2 to -1.1)	-1.7 (-1.8 to -1.3)	-1.8 (-2.2 to -2.2)	<0.001
Fat mass (kg)	3.25 ± 1.14	2.95 ± 1.17	2.85 ± 0.96	0.328
Fat mass (%)	17.9 ± 6.1	19.6 ± 6.5	19.0 ± 6.0	0.412
Lean mass (kg)	15.38 ± 4.54	12.83 ± 3.16	12.70 ± 4.40	0.056
Fat/lean mass ratio	0.23 ± 0.10	0.24 ± 0.10	0.25 ± 0.13	0.406
BMC (kg)	0.674 ± 0.259	0.529 ± 0.159	0.505 ± 0.162	0.048
Spinal BMC (kg)	0.56 ± 0.19	0.47 ± 0.12	0.41 ± 0.11	0.054
Leptin(ng/mL)	1.35 (0.64-1.60)	1.21 (0.64-1.99)	0.66 (0.59-0.60)	0.798
sOB-R (ng/mL)	45.3 ± 14.4	45.1 ± 13.4	36.2 ± 8.6	0.606
Leptin/sOB-R	0.026 (0.017-0.039)	0.027 (0.014-0.047)	0.022 (0.018-0.035)	0.999
Adiponectin (ng/mL)	8.21 ± 2.19	8.77 ± 2.27	6.87 ± 2.27	0.896
HMW (ng/mL)	4.87 ± 1.46	4.80 ± 1.33	4.20 ± 1.51	0.841
Leptin/adiponectin	0.16 (0.06-0.24)	0.12 (0.07-0.26)	0.10 (0.07-0.07)	0.791
HMW/adiponectin (%)	59.0 ± 10.6	54.7 ± 6.9	60.8 ± 2.8	0.558

Independent variables	Thin children			Normal-weight children
	β	95% CI for β	p	β	95% CI for β	p
BMC
BMI	0.127	0.043; 0.212	0.004	0.036	0.011; 0.062	0.006
Fat mass	0.034	-0.095; 0.028	0.279	0.028	0.013; 0.044	0.001
Lean mass	0.054	0.047; 0.060	<0.001	0.047	0.036; 0.058	0.001
Leptin	0.103	0.057; 0.149	<0.001	0.012	-0.7001; 0.024	0.050
sOB-R	0.005	0.002; 0.009	0.042	-0.001	-0.004; 0.002	0.705
Total adiponectin	-0.006	-0.032; 0.020	0.665	0.006	-0.010; 0.022	0.462
HMW adiponectin	-0.018	-0.058; 0.023	0.379	0.007	-0.014; 0.029	0.506
Leptin/sOB-R	5.106	2.892; 7.321	<0.001	0.286	-0.070; 0.642	0.113
Leptin/total adiponectin	0.864	0.494; 1.233	<0.001	0.111	-0.001; 0.223	0.051
HMW/total adiponectin	-0.001	-0.007; 0.005	0.648	0.001	-0.003; 0.004	0.637

lnLeptin
BMI	0.170	-0.204; 0.544	0.365	0.280	0.180; 0.452	0.002
Fat mass	-0.165	-0.416; 0.086	0.192	0.175	0.064; 0.285	0.003
BMC spine	28.212	13.166; 43.258	<0.001	16.341	-2.719; 35.400	0.091

Total adiponectin
BMI	0.056	0.992; 1.103	0.915	-0.156	-0.660; 0.347	0.535
Fat mass	0.085	-0.624; 0.795	0.809	0.104	-0.217; 0.424	0.517
BMC	-0.728	-4.090; 2.634	0.665	1.989	-3.412; 7.391	0.462
BMC spine	-23.745	-71.028; 23.537	0.317	8.046	-43.927; 60.019	0.757

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