Population, design and sampling

Epidemiological study with a cross-sectional design, population-based, conducted with adolescents between 10 and 19 years old, of both sexes, selected from the rural and urban, public and private school population in the municipality of Viçosa, Minas Gerais (MG), Brazil, between the years 2010 and 2013. The sample size was calculated using the StatCalc of the Epi Info software, version 6.04, from a specific formula for cross-sectional studies, considering a total population of 11 898 adolescents in the city of Viçosa/MG⁽²⁰⁾, an expected prevalence of 50·0 %^{(Reference Luiz, Magnanini, Medronho, Carvalho and Block21)}, acceptable variability of 5 %, and 95 % confidence level, totaling a minimum sample of 372 adolescents. When 20 % was added to this to control for confounding factors, a minimum total of 447 was required. A total of 506 adolescents with an appropriate weight according to BMI/age⁽²²⁾ were evaluated in this study.

The inclusion criteria were no regular use of medications that alter blood glucose, insulinaemia, lipid metabolism, and/or blood pressure levels, no participation in a weight reduction or weight control programme, no regular use of diuretics/laxatives, not pregnant or having ever been pregnant, no neck deformities and no diagnosis of infection, acute inflammation or thyroid disease. According to these criteria, twenty-eight adolescents were excluded from the initial study sample.

All participants and their parents/guardians, in the case of volunteers under the age of 18, signed the Informed Consent Form, under the Declaration of Helsinki. The study was approved by the Ethics Committee on Human Research of the Federal University of Viçosa – Comitê de Ética em Pesquisas com Seres Humanos da Universidade Federal de Viçosa (Of. Ref. No. 0140/2010).

Anthropometry

Weight and height were measured by international standard techniques^{(Reference Lohman, Roche and Martorell23)} using electronic digital scales (LC 200PP, Marte®) and portable stadiometer (Alturexata®).

Waist circumference (WC) was obtained at the end of a normal expiration, at the midpoint between the lower margin of the last rib and the iliac crest^{(Reference Lohman, Roche and Martorell23)}, and used continuously. Hip circumference (HC) was measured in the gluteal region, around the largest horizontal circumference between the waist and the knees^{(Reference Lohman, Roche and Martorell23)}. The waist:hip ratio (WHR) was obtained by dividing the waist circumference (cm) by the hip circumference (cm), and the waist:height ratio (WHtR) was obtained by the quotient of the waist circumference (cm) by the height measurement (cm), evaluated continuously.

Neck circumference was measured at the midpoint between the spine and the anterior neck, except when the individual had pronounced thyroid cartilage (Adam’s apple). In these cases, the circumference was measured just below the thyroid cartilage^{(Reference Ben-Noun, Sohar and Laor24)}. This measure was used on an ongoing basis.

The Paediatric Body Adiposity Index (BAIp), calculated from the measurement of hip circumference and height, was also evaluated continuously, according to the equation: BAIp = ((hip circumference (cm)/(height (m))^0·8)–38^{(Reference El Aarbaoui, Samouda and Zitouni25)}.

Body composition assessment

For body composition analysis, the dual energy X-ray absorptiometry (DEXA) equipment (Lunar Prodigy Advance DXA System – analysis version: 13.31, GE Healthcare) was used. The participants were barefoot, wearing light clothing, no metal ornaments and fasting for 12 h. The evaluation was performed with each individual in the supine position, through a series of transverse scans from head to toe, with a whole-body scan duration of approximately 10 min. The body composition analysis included android fat, gynoid fat, total fat mass and trunk, arms, and legs fat. Arm and leg fat was defined, respectively, as the sum of the fat in two arms and two legs, both divided by two^{(Reference Ribeiro, Kogure and Lopes26)}. The following indices were calculated according to the fat distribution: android:gynoid ratio; trunk:legs ratio; trunk:arms ratio^{(Reference Ribeiro, Kogure and Lopes26,Reference Guimarães, Guimarães and Kakehasi27)} .

Besides, the fat mass index (FMI) and the fat-free mass index, proposed by Van Itallie et al. (1990)^{(Reference VanItallie, Yang and Heymsfield28)}, to have a more careful anthropometric evaluation, according to the body compartments, by calculation that considers the amount in kilograms of fat mass and fat-free mass relative to height, as follows: FMI = (body fat (kg)/height (m)²) and fat-free mass index = ((Weight (kg) – body fat (kg))/height (m)²).

The body composition analysis also included the lean mass of the legs and arms, and the following parameters were analysed: appendicular lean mass (ALM), obtained by adding the lean mass of the arms and legs. With the ALM data, the lean mass index relative to height (ALM/height², given in kg/m²)^{(Reference Baumgartner, Koehler and Gallagher29)}; the lean mass index relative to weight (ALM/weight × 100, given in %)^{(Reference Janssen, Heymsfield and Ross30)}; the lean mass index relative to BMI (lean mass index relative to height BMI: ALM/IMC, given in kg/kg/m²)^{(Reference Studenski, Peters and Alley31)} and the indices of metabolic load and capacity (IMLC), which relate total fat mass to total fat-free mass (TFFM) (total IMLC = total fat mass/TFFM)^{(Reference Siervo, Prado and Mire32)}, and trunk fat mass to ALM (regional IMLC = trunk fat mass/ALM) were obtained^{(Reference Siervo, Prado and Mire32)}.

Biochemical assessment

Blood samples (12 ml) were collected at the Clinical Analysis Laboratory of the Health Division of the Federal University of Viçosa, after a 12-hour fast, by venipuncture, with disposable syringes. The analyses were carried out at the Nutritional Biochemistry Laboratory of the Department of Nutrition and Health and at the Molecular Immunovirology Laboratory of the Department of General Biology, at the Federal University of Viçosa.

HDL, LDL and TAG analyses were performed on blood serum after the material had been centrifuged in an Excelsa 206 BL centrifuge for 10 min at 3500 rpm. HDL and TAG were measured by the colorimetric enzymatic method, with automation by the Cobas Mira Plus equipment (Roche Corp.), and LDL was calculated by Friedewald’s formula for TAG values lower than 400 mg/dl^{(Reference Friedewald, Levy and Fredrickson33)}. Classification of the lipid profile was performed according to the Integrated Guide for cardiovascular health and risk reduction in children and adolescents (Guia integrado para saúde cardiovascular e redução de risco em crianças e adolescentes)⁽³⁴⁾, in which altered values (mg/dl) for LDL ≥ 130; HDL < 40 and TAG ≥ 130 are considered.

Fasting blood glucose was measured by the enzymatic glucose-oxidase method using the Cobas Mira Plus (Roche Corp.) automation equipment, and it was considered an altered fasting blood glucose ≥ 100 mg/dl⁽³⁵⁾. Fasting insulin was measured by the electrochemiluminescence method. Insulin resistance was calculated through the mathematical model homoeostasis model assessment – insulin resistance, using insulin and fasting blood glucose levels. Homoeostasis model assessment – insulin resistance values ≥ 3·16 were considered as insulin resistance⁽³⁶⁾.

Blood pressure assessment

Blood pressure was measured, according to the protocol established by the VI Brazilian Guidelines on Hypertension (I Diretriz Brasileira de Hipertensão Arterial)^{(Reference de Andrade and Nobre37)}, using an automatic inflation blood pressure monitor (Omron® Model HEM-741 CINT), recommended by the Brazilian Society of Cardiology (Sociedade Brasileira de Cardiologia). The blood pressure was measured in the right and left arms, and the measurement was repeated twice in the arm with the highest pressure value, with a 1-minute interval between them, and the average of the last two measurements was taken.

Elevated blood pressure levels were defined as systolic or diastolic blood pressure ≥ percentile 90 by age, sex and height for the adolescents under 13 years of age and for the group aged 13 years and older, systolic blood pressure ≥ 120 mmHg or diastolic blood pressure ≥ 80 mmHg were considered elevated pressure levels, according to the recommendations of the American Academy of Pediatrics (2017)^{(Reference Flynn, Kaelber and Baker-Smith38)}.

Definition of the metabolically obese normal-weight phenotype

Adolescents who have adequate weight but the presence of at least one metabolic alteration^{(Reference Green, Jacques and Rogers8)} were considered MONW in this study. To evaluate the nutritional status of adolescents and classify them as normal-weight, the BMI was used, obtained by dividing the weight by the square of the height, with values between the percentiles ≥ 3 and < 85, analysed according to sex and age, according to the WHO⁽²²⁾.

Also, it was considered metabolic alterations: high blood pressure^{(Reference Flynn, Kaelber and Baker-Smith38)}, high fasting glucose⁽³⁵⁾, alteration in the lipid profile (low HDL, high LDL or TAG)⁽³⁴⁾, and insulin resistance by homoeostasis model assessment – insulin resistance⁽³⁶⁾. Alteration in at least one of these components defined the metabolic abnormality.

Covariates

A questionnaire was applied to evaluate the profile of the adolescents, such as age, sex and type of school where they study (public or private). Besides, the socio-economic condition was investigated through the application of a questionnaire that collects a variety of social and economic issues at the household level, using the same methodology adopted by the Survey on Living Standards (Pesquisa sobre Padrões de Vida – PPV)⁽³⁹⁾, which was classified as ‘adequate’ or ‘precarious and intermediate’.

The level of physical activity was assessed using the International Physical Activity Questionnaire – short version, validated for this population group^{(Reference Guedes, Lopes and Guedes40)} as a way to classify adolescents as sedentary, irregularly active, active and very active⁽⁴¹⁾. Considering the low prevalence of sedentarism in the studied population, we chose to group the sedentary and irregularly active individuals into insufficiently active, and those considered active and very active were grouped into physically active.

The dietary analysis was performed by applying the qualitative FFQ to know the frequency of consumption of food groups. The FFQ was applied individually, and the adolescents were instructed to report on the frequency of consumption in the month before the date of application of the questionnaire^{(Reference Serra-Majem, Aracenta-Bartrina, Serra-Majem, Aracenta-Bartrina and Mataix-Verdú42)}.

The list of foods that made up the FFQ was determined considering the foods that are part of the eating habits of adolescents in the city of Viçosa, MG, based on data from the application of 24-h recall tests on adolescents assisted by the Adolescent Health Care Program (Programa de Atenção à Saúde do Adolescente – PROASA) of UFV. Weekly consumption frequency was categorised as ≥ 4 or < 4 times a week^{(Reference Olafsdottir, Torfadottir and Arngrimsson43)}. The consumption of fruits, vegetables and legumes was used as a marker of a healthy diet.

Statistical analysis

The database was prepared by a double entry in Microsoft Office Excel 2007. The statistical analyses were performed in STATA software, version 14. The consistency and distribution of the quantitative variables were evaluated by histograms, coefficient of asymmetry and kurtosis and the Shapiro–Wilk normality test. Categorical variables were expressed as absolute and relative frequency; quantitative variables were expressed as mean and standard deviation or median and interquartile range. The statistical differences of the quantitative variables according to the presence or absence of the MONW phenotype were analysed by Student’s t test or the nonparametric Mann–Whitney test, according to the normality of the variables, as well as the homogeneity of variances. Statistical differences for categorical variables were calculated by the χ ² test; or Fisher’s exact test for when more than 20 % of the cells had expected counts < 5. In the bivariate analysis, P values < 0·20 were considered for inclusion in the regression models. The WHtR, WHR, android:gynoid ratio and regional IMLC were converted to Z-score in the regression models using the following equation:

Z-score = (individual anthropometric value - mean anthropometric value)/standard deviation^{(Reference Nascimento-Souza, Lima-Costa and Peixoto44)}.

To evaluate the associations of anthropometric and body composition parameters (explanatory variables) with the MONW phenotype (outcome variable), Poisson regression with robust variance was employed, and prevalence ratios (PR) with 95 % CI were estimated. Two independent models were built for each explanatory variable, one crude and one adjusted for potential confounding factors defined according to the literature^{(Reference Ruderman, Schneider and Berchtold6–Reference Karelis, St-Pierre and Conus17)} (age, sex, physical activity level, socio-economic condition, and fruit, vegetable and legume consumption). Regression analysis was used in the total sample, and there was also stratification by sex and age (10–13 years old, 14–16 years old and 17–19 years old). The significance level adopted in all analyses was 5 %.