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Vol. 34. Núm. 1.
Páginas 30-37 (marzo 2016)
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Vol. 34. Núm. 1.
Páginas 30-37 (marzo 2016)
Original article
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Association between fat mass index and fat-free mass index values and cardiovascular risk in adolescents
Associação entre índice de massa de gordura e índice de massa livre de gordura e risco cardiovascular em adolescentes
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Patrícia Morais de Oliveira, Fabiana Almeida da Silva, Renata Maria Souza Oliveira, Larissa Loures Mendes, Michele Pereira Netto, Ana Paula Carlos Cândido
Autor para correspondencia
anapaula.candido@ufjf.edu.br

Corresponding author.
Universidade Federal de Juiz de Fora (UFJF), Juiz de Fora, MG, Brazil
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Tablas (3)
Table 1. Comparison of the mean values of demographic, anthropometric, clinical, and biochemical variables and physical activity of the study population by sex (n=403). Juiz de Fora, MG, Brazil, 2014.
Table 2. Comparison between anthropometric, clinical, biochemical and physical activity characteristics regarding fat-free mass, fat-free mass index, fat mass and fat mass index of female adolescents. Juiz de Fora, MG, Brazil, 2014.
Table 3. Comparison between anthropometric, clinical, biochemical and physical activity regarding fat-free mass, fat-free mass index, fat mass and fat mass index of male adolescents. Juiz de Fora, MG, Brazil, 2014.
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Abstract
Objective

To describe the association between fat mass index and fat-free mass index values and factors associated with cardiovascular risk in adolescents in the city of Juiz de Fora, Minas Gerais.

Methods

Cross-sectional study was with 403 adolescents aged 10–14 years, from public and private schools. Anthropometric, clinical, and biochemical measurements were obtained, as well as self-reported time spent performing physical exercises, sedentary activities and sexual maturation stage.

Results

Regarding the nutritional status, 66.5% of the adolescents had normal weight, 19.9% were overweight and 10.2% were obese. For both genders, the fat mass index was higher in adolescents who had high serum triglycerides, body mass index and waist circumference.

Conclusions

Adolescents who had anthropometric, clinical and biochemical characteristics considered to be at risk for the development of cardiovascular disease had higher values of fat mass index. Different methodologies for the assessment of body composition make health promotion and disease prevention more effective.

Keywords:
Cardiovascular diseases/risk factors
Adolescent/growth and development
Body composition
Body fat
Resumo
Objetivo

Descrever a relação entre valores de índice de massa de gordura e índice de massa livre de gordura e fatores associados a risco cardiovascular em adolescentes de Juiz de Fora (MG).

Métodos

Estudo transversal feito com 403 adolescentes de 10-14 anos, de escolas públicas e privadas. Avaliaram-se medidas antropométricas, clínicas, bioquímicas, autorrelato do tempo dedicado ao exercício físico, atividades sedentárias e estágio de maturação sexual.

Resultados

Quanto ao estado nutricional, 66,5% dos adolescentes estavam eutróficos, 19,9% com sobrepeso e 10,2% obesos. Para ambos os sexos, o índice de massa de gordura foi maior nos adolescentes que estavam com triglicerídeos séricos, índice de massa corporal e circunferência da cintura elevados.

Conclusões

Os adolescentes que tinham características antropométricas, clínicas e bioquímicas consideradas de risco para o desenvolvimento de doenças cardiovasculares apresentaram maiores valores do índice de massa de gordura. Metodologias diferenciadas para avaliação da composição corporal tornam a promoção da saúde e a prevenção de agravos futuros mais eficazes.

Palavras-chave:
Doenças cardiovasculares/fatores de risco
Adolescente/crescimento e desenvolvimento
Composição corporal
Gordura corporal
Texto completo
Introduction

The increased prevalence of overweight in adolescents1 is associated with risk factors for cardiovascular disease in adulthood and results in high costs for public health.1 Currently, it is shown that body fat distribution has more influence than total body mass in the presence of cardiovascular risk factors.2–4 The ability to measure or quantify body fat stores is central for preventing and treating obesity-related diseases.2 Therefore, more accurate methods are needed to assess adiposity and do proper screening for early intervention.3–6

Body mass index (BMI) has been the most widely used anthropometric method for diagnosing overweight, but its predictive ability to identify young people with high body fat is open for discussion in scientific circles.5,6 It cannot discriminate between fat mass and lean mass, does not reflect the great changes in body composition that occur in this age group and are different between the sexes.5 So it would be more feasible to distinguish the body components through more precise measurements that consider the body fat percentage.2

VanItallie et al.7 proposed the use of fat mass index (FMI) and fat-free mass index (FFMI) for a more detailed anthropometric measurement, according to body compartments, by calculation that considers the amount of fat mass and fat-free mass in kg obtained by bioelectrical impedance, with the advantage of relating only one body weight component to the height squared and of being expressed in units that are common to BMI.8 With the use of these two indices, it becomes possible to judge whether a deficit or excess of body weight is selectively due to a change in fat-free mass, in fat mass, or both.8 Four typical situations can be identified: low FFMI and high FMI, corresponding to obesity; low FFMI and low FMI, corresponding to leanness; high FFMI and low FMI, corresponding to muscle hypertrophy; and high FFMI and high FMI, corresponding to combined excess of FFMI and FMI. The reference values of these two indices are not yet a consensus in the scientific literature, particularly for adolescents. In the study by Nakao and Komiya,9 the reference values of FFMI were 12.7–13.4kg/m2 for boys and 12–13kg/m2 for girls. As for FMI, the adopted reference values adopted were 2.8–3.6kg/m2 for boys and 3.2–3.8kg/m2 for girls.

Considering the need for a more detailed anthropometric assessment for adolescents, the aim of this study was to describe the relationship between the values of fat mass index and fat-free mass index and factors associated with cardiovascular risk in adolescents in the Juiz de Fora city, MG.

Method

Cross-sectional study was performed with adolescents, aged 10–14 years, attending public and private schools in Juiz de Fora, MG. The number of schools and students per institution, belonging to that age group, was obtained through the School Census provided by INEP 2009.10 Thirty-five schools were selected, based on the proportion by city regions. Total sample was based on three parameters: proportion of obesity in the age group studied (8%)11; a desired precision of 2% was accepted, with a significance level of 5%; and 20% losses were considered due to the absence of adolescents in days of data collection or refusal to participate (no consent of teen, or parent/guardian). Students were randomly selected through the table of random numbers and stratified according to sex, age, and proportion in each school.

Anthropometric, clinical, and biochemical measurements were evaluated. Students also reported how much time they spent practicing exercises, watching TV, playing video games and using the computer. Adolescents who engaged in over 300 minutes per week of physical activity were considered active.12 Tanner's scale13 was used for adolescents’ self-assessment of their sexual maturation, and the girls indicated the presence and age of menarche occurrence.

Body mass was measured using a bipolar bioimpedance scale (Tanita®BC-553, Illinois, USA) with a maximum capacity of 136kg, also used to assess body fat percentage. Height was measured by field stadiometer (Alturaexata®, Belo Horizonte, Brazil), with scale in centimeters and accuracy of 0.01m. The nutritional status of the adolescents was determined by BMI for age, according to the WHO classification criteria, where a BMI above the 85th percentile is classified as overweight.14 Waist circumference was obtained using a 1.5m simple and inelastic tape measure, with 0.01m interval. All measurements followed the procedures standardized by the WHO, and circumference values above the 85th percentile were considered high for both sexes. Regarding fat percentage, values greater than 30% for girls and 25% for boys were considered high and of risk.15

Tetrapolar bioimpedance Biodynamics 310® (Biodynamics Corporation, Washington, USA) was used with measurements performed according to the manufacturer's instructions. The resistance and reactance values found were used to determine the amount in kg of fat mass (FM) and fat-free mass (FFM). FMI was determined by dividing fat mass (in kilograms) by height squared (in meters). Similarly, FFMI was calculated by dividing lean mass (in kilograms) by height squared (in meters), as proposed by VanItallie et al.7 The average of the two closest values of the biceps, triceps, subscapular, and supra-iliac skinfold thickness measurements were added. Triceps and subscapular mean values of skin folds were also added separately. The analog skinfold caliper Lange® (Beta Technology, California, USA), with precision of 0.1mm in triplicate, was used to measure the skinfold of biceps (performed with bent elbows at 90°, halfway between the armpit and the cubital fossa), triceps (at midpoint of the distance between the acromion and the olecranon, on the back of the left arm), subscapular (in the lower angle of the scapula, at 45° diagonal), and supra-iliac (on the mid-axillary line, between the last rib and the iliac crest). The formula proposed by Deurenberg et al.16 was used for data analysis to predict values associated with body density and subsequently those associated with fat in relation to body weight.

Blood samples (6mL) were collected by venipuncture in the antecubital region of patients after 12-h fast to measure the levels of total cholesterol, fractions (HDL-c and LDL-c), and triglycerides. The procedures were standardized in the Biochemistry Laboratory of the School Hospital of the Federal University of Juiz de Fora (UFJF). To evaluate lipid changes, the reference values recommended by the Brazilian Society of Cardiology were applied.17 Values above 150mg/dL, 100mg/dL, and 100mg/dL for total cholesterol, triglycerides, and LDL-c, respectively, were considered high risk for adolescents of both sexes; whereas for HDL-c, values below 45mg/dL were considered risk for both boys and girls. Diagnosis of diabetes mellitus was determined according to the Brazilian Society of Diabetes criteria (fasting glucose above 100mg/dL).18 The parameters were analyzed by automatic analyzer Cobas Mira Plus® (Roche Diagnostics, Switzerland).

Blood pressure levels of students undergoing evaluation were measured three times with digital oscillometric device Omron HEM-705CP® (Omron Corporation, Brazil). The subjects were seated (left arm extended at heart level), and an interval of 10–15min was maintained between each measurement. Classification was based on the 5th Brazilian Guidelines on Hypertension from the average of the three measurements performed (systolic blood pressure and diastolic blood pressure above the 90th percentile).19

The project was approved by the Federal University of Juiz de Fora Institutional Review Board, Opinion No. 09/2010, and started after the consent of the legal guardians of adolescents and school directors.

In the statistical analysis, Student's t-test was used to assess the differences between the mean values of each variable in relation to sex. The analysis of variance (ANOVA) was used to compare mean values of body composition indices and its corresponding masses with the other studied variables. The SPSS version 17.0 software was used for statistical analysis, and a 5% significance level was admitted.

Results

A total of 403 adolescents were evaluated, 218 (54.1%) were female, mean age was 12.4±1.2 years. Age group distribution was similar between the sexes (p=0.30). The sample consisted of 66.5% eutrophic, 19.9% overweight, and 10.2% obese adolescents. Table 1 shows the characteristics of the study population stratified by sex.

Table 1.

Comparison of the mean values of demographic, anthropometric, clinical, and biochemical variables and physical activity of the study population by sex (n=403). Juiz de Fora, MG, Brazil, 2014.

Variable  Girls (n=218)Boys (n=185)p-valuea 
  Mean±SD  Mean±SD   
Age (years)  218  12.4±1.1  185  12.3±1.1  0.30 
Height (cm)  217  155.5±8.5  185  155.8±10.4  0.74 
Weight (kg)  217  49.3±13.2  185  48.0±12.8  0.33 
BMI (kg/m2218  20.2±4.6  185  19.5±3.5  0.16 
Bipolar body fat (%)  209  25.3±7.8  175  17.5±7.7  <0.01 
Waist circumference (cm)  213  66.9±9.9  183  67.7±9.7  0.39 
Sum of 4 folds (mm)  197  60.7±26.1  170  50.1±26.0  <0.01 
Sum of triceps and subscapular folds (mm)  197  31.5±13.1  170  26.7±13.1  <0.01 
Fat-free mass (kg)  218  33.9±8.3  185  35±12.4  0.30 
Fat-free mass index  218  13.9±2.9  185  14.2±4.1  0.42 
Fat mass (kg)  218  13.9±8.8  185  10.3±6.4  <0.01 
Fat mass index  218  5.7±3.4  185  4.8±2.5  <0.01 
Mean systolic blood pressure (mmHg)  218  109.0±9.9  184  110.3±10.8  0.22 
Mean diastolic blood pressure (mmHg)  218  68.1±6.5  184  66.5±7.0  <0.05 
Physical activity time (min/week)  213  171.4±120.8  181  269.1±165.7  <0.01 
Time watching TV, video game, and computer (h/week)  213  8.0±4.5  183  10.6±5.4  <0.01 
Total cholesterol (mg/dL)  202  153.1±26.2  176  150.4±25.9  0.32 
Glucose (mg/dL)  201  82.2±7.9  173  82.4±9.6  0.88 
Triglycerides (mg/dL)  202  69.6±30.7  176  67.2±32.3  0.47 
High density lipoprotein cholesterol (mg/dL)  162  48.7±8.9  145  46.7±11.2  0.09 
Low density lipoprotein cholesterol (mg/dL)  162  90.9±23.3  145  90.8±20.5  0.95 
a

Student's t-test.

Regarding body composition, female adolescents had higher percentages of body fat (determined by bipolar bioimpedance and sum of skinfolds), FM and FMI. Mean diastolic blood pressure was higher in females. Male adolescents spent more time on physical activity and also in sedentary practices, such as watching TV, playing video games, and using the computer, than female adolescents.

Tables 2 and 3 represent the mean value and standard deviation of anthropometric, clinical, and biochemical characteristics in relation to body composition indices and its corresponding masses for both female and male adolescents, respectively. For both sexes, higher mean values of FFM, FFMI, FM and FMI were found in adolescents with excess weight, high body fat and waist circumference. There was a significant difference in systolic blood pressure. Girls with SAP>p90 had higher mean values of FM and FMI, and boys in the same PAS classification had higher mean values of FM and FFM. Regarding sexual maturation, FFMI and FFM were higher in the postpubertal stage for both girls and boys. The same was seen for FM and FMI in female adolescents in postpubertal stage. In biochemical evaluation, female adolescents with HDL-c<45mg/dL had higher mean FFM, FFMI, FM and FMI; whereas triglyceride values were higher in female adolescents with high FM and FMI.

Table 2.

Comparison between anthropometric, clinical, biochemical and physical activity characteristics regarding fat-free mass, fat-free mass index, fat mass and fat mass index of female adolescents. Juiz de Fora, MG, Brazil, 2014.

Variables  Fat-free massMean±SD  Fat-free mass indexMean±SD  Fat massMean±SD  Fat mass indexMean±SD 
Body mass index
  155  32.1±7.3*  13.4±2.6*  10.0±4.4*  4.1±1.6* 
>P85  62  38.7±7.7*  15.5±2.4*  24.0±8.9*  9.6±3.3a
Bipolar fat
<30%  154  32.2±7.3*  13.4±2.6*  10.2±4.4*  4.2±1.7* 
>30%  54  39.2±8.0*  15.6±2.6*  25.0±9.0*  9.9±3.4* 
Waist circumference
  165  32.3±7.2*  13.5±2.5*  10.6±4.8*  4.4±1.9* 
>P 85  48  39.3±8.2*  15.5±2.8*  25.3±9.6*  10.0±3.6* 
Systolic blood pressure
  198  33.7±7.6  13.9±2.5  13.2±7.7*  5.4±2.99* 
>P90  19  35.7±13.9  13.9±5.2  21.8±13.9*  8.5±5.4* 
Diastolic blood pressure
  202  34.1±7.8  14.0±2.6  13.9±8.2  5.6±3.1 
>P90  15  31.1±13.3  12.9±5.3  15.1±14.4  6.2±5.7 
Physical activity
>300min/week  21  35.0±6.3  14.8±1.6  15.2±9.4  6.3±3.6 
<300min/weeka  192  33.7±8.5  13.8±3.0  13.8±8.7  5.6±3.3 
Sexual maturation
Prepubertal  54  28.6±8.1*a  13.0±3.3*a  9.5±6.5*a  4.2±2.7*a 
Pubertal  150  35.4±6.7*b  14.2±2.4*b  14.8±7.6*b  5.9±3.0*b 
Postpubertal  43.9±7.4*c  16.2±1.9*b  31.7±17.2*c  11.8±6.7*c 
Total cholesterol
<150mg/dL  94  34.8±8.9  13.9±3.2  14.0±8.1  5.6±3.1 
>150mg/dL  108  33.5±8.0  13.9±2.7  14.4±9.4  5.8±3.6 
Glucose
<100mg/dL  198  34.0±8.5  13.9±3.0  14.1±8.8  5.7±3.4 
>100mg/dL  34.1±4.5  13.7±0.8  14.8±10.1  5.8±3.9 
Triglycerides
<100mg/dL  171  33.7±8.6  13.8±3.1  13.5±8.0**  5.4±3.0** 
>100mg/dL  31  36.2±7.2  14.8±1.8  17.7±12.1**  7.2±4.7** 
High density lipoprotein cholesterol
>45mg/dL  111  32.7±8.4*  13.4±3.1*  12.9±8.1*  5.2±3.1* 
<45mg/dL  51  37.0±8.3*  14.8±2.8 *  18.1±10.0*  7.2±3.9* 
Low density lipoprotein cholesterol
<100mg/dL  104  34.4±9.2  13.8±3.4  14.2±8.0  5.6±3.0 
>100mg/dL  58  33.4±7.3  14.1±2.4  15.3±10.7  6.3±4.1 

Means with different letters are significantly different according to the Least Significant Difference test (LSD).

Student's t-test. *p<0.01; **p<0.05.

Table 3.

Comparison between anthropometric, clinical, biochemical and physical activity regarding fat-free mass, fat-free mass index, fat mass and fat mass index of male adolescents. Juiz de Fora, MG, Brazil, 2014.

Variables  Fat-free massMean±SD  Fat-free mass indexMean±SD  Fat massMean±SD  Fat mass indexMean±SD 
Body mass index
  124  32.5±11.3*  13.4±3.9*  7.1±3.2*  3.6±1.7* 
>P 85  59  40.7±11.9*  16.1±3.4*  17.3±5.9*  7.2±1.8* 
Bipolar fat
<25%  148  33.8±12.6**  13.7±4.2**  8.3±4.4*  4.0±1.9* 
>25%  31  38.9±10.2**  16.1±3.2**  19.6±6.0*  8.4±1.5* 
Waist circumference
  138  32.1±12.0*  13.3±4.3*  7.4±3.7*  3.9±1.9* 
>P 85  45  44.0±8.8*  16.9±1.4*  19.1±4.8*  7.5±1.9* 
Systolic blood pressure
  161  34.1±12.4**  14.0±4.2  9.8±6.2**  4.7±2.4 
>P 90  21  41.2±11.1**  15.8±2.0  13.8±7.4**  5.3±2.7 
Diastolic blood pressure
  172  34.7±12.5  14.1±4.2  10.2±6.4  4.7±2.4 
>P 90  11  39.1±9.2  15.5±1.6  12.0±5.6  4.9±2.8 
Physical activity
>300min/week  47  35.0±14.0  14.1±4.7  9.6±6.0  4.7±2.4 
<300min/week  134  34.9±11.9  14.2±3.9  10.5±6.6  4.8±2.5 
Sexual maturation
Prepubertal  68  29.0±11.0*a  12.9±4.6**a  9.2±5.9a  5.0±2.6a 
Pubertal  105  38.9±11.5*b  15.0±3.4**b  11.0±6.5a  4.6±2.4a 
Postpubertal  35.1±24.3*a  12.2±8.3**a  11.7±11.5a  6.2±3.1a 
Total cholesterol
<150mg/dL  84  38.0±13.0**  14.7±4.1  11.2±6.5  4.9±2.4 
>150mg/dL  92  33.5±10.0**  14.2±3.4  9.9±6.1  4.6±2.4 
Glucose
<100mg/dL  167  35.5±11.9  14.4±3.8  10.4±6.1**  4.7±2.4 
>100mg/dL  40.5±9.3  16.0±2.1  17.0±9.8**  6.5±3.5 
Triglycerides
<100mg/dL  149  35.2±12.4  14.3±3.9  9.8±6.0*  4.5±2.3** 
>100mg/dL  27  38.0±7.0  15.4±1.8  14.6±7.1*  5.9±2.9** 
High density lipoprotein cholesterol
>45mg/dL  76  31.9±12.4*  13.3±4.4*  8.5±5.1*  4.4±2.2 
<45mg/dL  69  39.1±10.4*  15.4±2.6*  12.5±6.8*  5.1±2.6 
Low density lipoprotein cholesterol
<100mg/dL  99  36.0±13.2  14.2±4.2  10.2±6.1  4.6±2.3 
>100mg/dL  46  33.9±8.9  14.7±2.7  10.9±6.6  4.9±2.6 

Means with different letters are significantly different according to the Least Significant Difference test (LSD).

Student's t-test. *p<0.01; **p<0.05.

In serum lipid values and fasting plasma glucose comparison, FFM was found to be higher in male adolescents with total cholesterol under 150mg/dL. Those with impaired fasting glucose had high FM. Moreover, males with serum triglycerides above 100mg/dL were characterized as having higher values of FM and FMI. It was found that adolescents with low serum levels of HDL-c had higher averages of FFM, FFMI, and FM.

Discussion

Obesity in adolescence is reaching increasing proportions and results in 21.5% of Brazilian adolescents with excess weight and obesity.1 Among the students of Juiz de Fora who participated in the study, the prevalence was 19.9% for overweight and 10.2% for obesity.

The results for body composition showed differences between the sexes. Female adolescents showed higher percentage of body fat and mass and FMI, similar to the study by Eissa et al.4 For both sexes, the highest average values of FFM, FFMI, FM and FMI were related to the anthropometric variables, which estimate total and central body fat (BMI, % fat, and waist circumference).

Body composition varies widely in adolescents; it depends on age, gender, ethnicity, height, and sexual maturation.5 During puberty, for both sexes, there is a weight increase in lean and fat tissue and bone mineral content,20 but the major growth and development conditioning of this stage of life results from sexual maturation, which contributes to dimorphism between girls and boys.21

In this study, FFMI and FFM were characterized by an increase in its values according to the pubertal stage, particularly in girls. In the sexual maturation process, height, lean muscle mass, and bone mineral content are directly proportional to the peak height velocity20 and, therefore, higher FFM and FFMI were found in postpubertal stage, similar to that reported by Miranda et al.22 The same was seen for FM and FMI in female adolescents, whose highest averages occurred in the postpubertal stage.

It is known that a certain storage of body fat is needed for the occurrence of pubertal growth spurt in both sexes and that the relative amount of fat in females increases progressively during adolescence.23 In the study by Miranda et al.,22 the highest accumulation was found in the prepubertal stage. However, higher body fat mass values in the postpubertal stage may be seen in adolescents who reach menarche at an early age and who need to reach a critical weight of at least 17% fat to start the growth spurt and reach menarche. There is also the influence of high blood concentrations of estradiol to stimulate greater lipogenesis.24 Furthermore, most adolescents in this study were in puberty stage, and the small sample size of the pre- and postpubescent stages may have contributed to the outcomes.

As for the boys, there was no significant difference in mean values of FM and FMI between pubertal stages, which corroborates the study by Borges et al.25 For boys, the largest contributor to increase BMI seems to be the increase in FFM.5 Most of our adolescents were in pubertal stage, which is characterized by height growth and increased lean mass.

According to Leccia et al.,26 sexual maturation seems to have an effect on blood pressure and acts primarily on body size. They found a strong correlation between height, body weight, and lean body mass with systolic blood pressure for both boys and girls and with diastolic blood pressure just for girls. In our study, higher diastolic blood pressure was found in girls, compared to males, and FFM was higher among boys who had high systolic blood pressure, probably because the increased muscle mass was greater in male adolescents. Weight gain and high body fat can significantly contribute to high blood pressure even in individuals classified as normotensive.27 Systolic blood pressure of adolescents in this study was associated with higher mean values of FMI and its corresponding mass for both sexes. According to Jessup and Harrell,28 systolic blood pressure increases in pubertal stage, regardless of age, particularly in girls. In this study, we found that most of the adolescents of both sexes were in the pubertal stage of maturation.

Literature shows that excess body fat can increase the risk of metabolic disorders, such as dyslipidemia, insulin resistance, and impaired glucose tolerance.29 The results of this study indicated that FM and FMI were higher for both boys and for girls with high serum triglycerides. The boys with impaired fasting glucose also had higher FM and FMI values.

However, FFM values were higher in adolescents with low levels of serum HDL-c of both sexes and increased total cholesterol in male adolescents. Changes in body composition and lipid profile during puberty may be influenced by reduced physical activity and change in eating habits and hormonal, which is common in adolescence.28 Although this study did not consider dietary and hormonal information, there was a significant difference in physical activity and sedentary activities between the sexes. Male adolescents spend more time doing physical exercise than girls. In the study by Schubert et al.,29 the increase in FFMI was associated with decreased HDL-c and high triglycerides. It is possible that the increase in FFM, followed by higher elevations of FM, may result in reduced concentrations of HDL-C and that the FFMI effect is masked by that of FMI. Pietrobelli et al.30 also found that the relationship of increased lean body mass and reduced serum levels of HDL-c suggest that the increase in serum triglycerides leads to the formation of particles smaller than HDL and an increase in HDL metabolism.

This study has some limitations. Although pressure measurements were standardized, they were performed in a single day, and the periods of time of physical activity were estimated by self-report of adolescents. However, they are methodologies considered more practical, feasible, and validated for cross-sectional studies, like the one performed.19 Still, the results of this study indicate that adolescents with anthropometric, clinical, and biochemical characteristics considered as risk for developing cardiovascular disease had higher FMI values. Regarding FFMI, the differences were not marked. Different methodologies for assessment of body composition and, consequently, cardiovascular risks to which adolescents are predisposed make health promotion and the prevention of future damage more effective.

Funding

Conselho Nacional de Desenvolvimento Científico e Tecnológico (edital MCT/CNPq, no. 14/2010 Universal).

Conflicts of interest

The authors declare no conflicts of interest.

Acknowledgements

We thank the schools of Juiz de Fora, MG, for supporting the work with the adolescents and for consenting to perform the study; the students of the Nutrition Course of the Federal University of Juiz de Fora for their assistance in data collection; the University Hospital of the Federal University of Juiz de Fora for the biochemical analysis of the study; and the CNPq for project financing.

References
[1]
Brasil – Ministério do Planejamento, Orçamento e Gestão; Instituto Brasileiro de Geografia e Estatística.
Pesquisa de orçamentos familiares 2008-2009: antropometria e estado nutricional de crianças, adolescentes e adultos no Brasil.
IBGE, (2010),
[2]
G. Peltz, M.T. Aguirre, M. Sanderson, M.K. Fadden.
The role of fat mass index in determining obesity.
Am J Hum Biol, 22 (2010), pp. 639-647
[3]
B. Bahadori, E. Uitz, K. Tonninger-Bahadori, I. Pestemer-Lach, M. Trummer, R. Thonhofer, et al.
Body composition: the fat-free mass index (FFMI) and the body fat mass index (BFMI) distribution among the adult Austrian population – results of a cross-sectional pilot study.
IJBCR, 4 (2006), pp. 123-128
[4]
M.A. Eissa, S. Dai, N.L. Mihalopoulos, R.S. Day, R.B. Harrist, D.R. Labarthe.
Trajectories of fat mass index, fat free-mass index, and waist circumference in children: Project HeartBeat.
Am J Prev Med, 37 (2009), pp. S34-S39
[5]
A.C. Vieira, M.M. Alvarez, V.M. Marins, R. Sichieri, G.V. Veiga.
Desempenho de pontos de corte do índice de massa corporal de diferentes referências na predição de gordura corporal em adolescentes.
Cad Saude Publica, 22 (2006), pp. 1681-1690
[6]
J.R. Alvero-Cruz, E. Alvarez Carnero, J.C. Fernández-García, J. Barrera Expósito, M.C. Carrillo de Albornoz Gil, L.B. Sardinha.
Validity of body mass index and fat mass index as indicators of overweight status in Spanish adolescents: Esccola Study.
Med Clin (Barc), 135 (2010), pp. 8-14
[7]
T.B. VanItallie, U.M. Yang, S.B. Heymsfield, R.C. Funk, R.A. Boileau.
Height-normalized indices of the body's fat-free mass and fat mass: potentially useful indicators of nutritional status.
Am J Clin Nutr, 52 (1990), pp. 953-959
[8]
H.R. Schutz, U.U. Kyle, C. Pichard.
Fat-free mass index and fat mass index percentiles in Caucasians aged 18–98y.
Int J Obes Relat Metab Disord, 26 (2002), pp. 953-960
[9]
T. Nakao, S. Komiya.
Reference norms for a fat-free mass index and fat mass index in the Japanese child population.
J Physiol Anthropol Appl Hum Sci, 22 (2003), pp. 293-298
[10]
INEP. Instituto Nacional de Estudos e Pesquisas Educacionais Anísio Teixeira [página na Internet]. Matrícula no ensino fundamental no município de Juiz de Fora, Minas Gerais [accessed September 2009]. Available from: http://www.edudatabrasil.inep.gov.index.htm.
[11]
M.M. Abrantes, J.A. Lamounier, E.A. Colosimo.
Prevalência de sobrepeso e obesidade nas regiões Nordeste e Sudeste do Brasil.
Rev Assoc Méd Bras, 49 (2003), pp. 162-166
[12]
M. Dobbins, K. de Corby, P. Robeson, H. Husson, D. Tirilis.
School-based physical activity programs for promoting physical activity and fitness in children and adolescents aged 6–18.
Cochrane Database Syst Rev, 21 (2009), pp. CD007651
[13]
J.M. Tanner.
Growth at adolescence.
Blackwell Scientific Publications, (1962),
[14]
M. De Onis, A.W. Onyango, E. Borghi, A. Siyam, C. Nishida, J. Siekmann.
Development of a WHO growth reference for school-aged children and adolescents.
Bull Word Health Organ, 85 (2007), pp. 660-667
[15]
World Health Organization.
Global strategy on diet, physical, activity and health.
WHO, (1997),
[16]
P. Deurenberg, J.J. Pieters, J.G. Hautvast.
The assessment of the body fat percentage by skinfold thickness measurements in childhood and young adolescence.
Br J Nutr, 63 (1990), pp. 293-303
[17]
I.C. Giuliano, B. Caramelli, L. Pellanda, B. Duncan, S. Mattos, F.H. Fonseca.
I diretriz de prevenção da aterosclerose na infância e adolescência.
Arq Bras Cardiol, 85 (2005), pp. 1-36
[18]
Sociedade Brasileira de Diabetes.
Atualização Brasileira sobre Diabetes.
Diagraphic, (2005),
[19]
Sociedade Brasileira de Cardiologia.
V Diretrizes Brasileiras de Hipertensão Arterial.
SBC, (2006),
[20]
R.M. Siervogel, E.W. Demerath, C. Schubert, K.E. Remsberg, W.C. Chumlea, S. Sun, et al.
Puberty and body composition.
Horm Res, 60 (2003), pp. 36-45
[21]
R.R. Gatti, R.P. Ribeiro.
Prevalência de excesso de peso em adolescentes segundo a maturação sexual.
Rev Salus, 1 (2007), pp. 175-182
[22]
V.P. Miranda, F.R. Faria, E.R. Faria, S.E. Priore.
Maturação somática e composição corporal em adolescentes eutróficos do sexo feminino com ou sem adequação de gordura corporal.
Rev Paul Pediatr, 32 (2014), pp. 78-84
[23]
A.P. Clemente, C.D. Santos, V.J. Martins, A.A. Benedito-Silva, M.P. Albuquerque, A.L. Sawaya.
Mild stunting is associated with higher body fat: study of a low-income population.
J Pediatr (Rio J), 87 (2011), pp. 138-144
[24]
F. Adami, F.A. Vasconcelos.
Obesidade e maturação sexual precoce em escolares de Florianópolis-SC.
Rev Bras Epidemiol, 11 (2008), pp. 549-560
[25]
F.S. Borges, S.M. Matsudo, V.K. Matsudo.
Perfil antropométrico e metabólico de rapazes pubertários da mesma idade cronológica em diferentes níveis de maturação sexual.
Rev Bras Ciénc Mov, 12 (2004), pp. 7-12
[26]
G. Leccia, T. Marotta, M.R. Masella, G. Mottola, G. Mitrano, F. Golia, et al.
Sex-related influence of body size and sexual maturation on blood pressure in adolescents.
Eur J Clin Nutr, 53 (1999), pp. 333-337
[27]
H.X. Corseuil, D.B.M. Barbosa, J.K.F. Mendes, J.C.F. Júnior, A.S. Lopes, E.L. Petrosk.
Excesso de peso e pressão arterial em adolescentes de João Pessoa-PB.
Rev Educ UEM, 20 (2009), pp. 273-280
[28]
A. Jessup, J.S. Harrell.
The metabolic syndrome: look for it in children and adolescents, too!.
Clin Diabetes, 23 (2005), pp. 26-32
[29]
C.M. Schubert, N.L. Rogers, K.E. Remsberg, S.S. Sun, W.C. Chumlea, E.W. Demerath, et al.
Lipids, lipoproteins, lifestyle, adiposity and fat-free mass during middle age: the Fels longitudinal study.
Int J Obes (Lond), 30 (2006), pp. 251-260
[30]
A. Pietrobelli, R.C. Lee, E. Capristo, R.J. Deckelbaum, S.B. Heymsfield.
An independent, inverse association of high-density-lipoproteincholesterol concentration with nonadipose body mass.
Am J Clin Nutr, 69 (1999), pp. 614-620
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