Birth weight, life course factors and excess weight among schoolchildren in Niterói, Rio de Janeiro, Brazil in 2010

Noronha, Gisele Almeida de; Kale, Pauline Lorena; Torres, Tania Zdenka Guillén de; Vasconcelos, Jackeline Christiane Pinto Lobato; Kuschnir, Maria Cristina Caetano; Cavalcanti, Maria de Lourdes Tavares; Costa, Antonio José Leal; Szklo, Moyses

doi:10.1016/j.jped.2020.10.012

Abstract

Objective:

To investigate the association between birth weight and excess weight among students aged 6–14 years, adjusted for life course confounding factors.

Methods:

Cross-sectional study with 6–14-year-old schoolchildren in 2010; 795 school children from two public schools. In addition, a sub-sample was selected using a case-cohort study approach. Sociodemographic, breastfeeding, food introduction, previous weight gain, family history, current clinical and behavioral variables as well as maternal variables related to pregnancy, were collected. Multivariable weighted logistic regression was used to evaluate the association between birth weight and overweight. All prevalent cases of overweight (n = 160) were selected to compose the case group and a random sub-sample of all students participating in the study (n = 276 students, of whom 88 were cases) were the control group.

Results:

An unadjusted 6% increase in the excess weight prevalence ratio (p-value = 0.004) was found for each 100 g increase in birth weight. With adjustment for age, sex and behavioral variables (models 1 and 2), the association of birth weight with excess weight was positive and statistically significant, but it was no longer significant in the final model (model 3) when clinical variables were considered.

Conclusions:

Although some of the secondary associations were statistically significant, we could not identify a significant association between birthweight and excess weight in adolescents.

KEYWORDS
Birth weight; Information systems; Fetal development; Weight gain; Pediatric obesity

Introduction

The global increase in the prevalence of childhood obesity, the persistence of excess weight gain during childhood and adolescence into adult life,¹1 Lucas K, James P, Choh AC, Lee M, Czerwinski SA, Demerath EW, et al. The positive association of infant weight gain with adulthood body mass index has strengthened over time in the Fels Longitudinal Study. Pediatr Obes. 2018;13:476–84. and the possible metabolic health benefits of early intervention during childhood²2 Rinaudo P, Wang E. Fetal programming and metabolic syndrome. Annu Rev Physiol. 2012;74:107–30. have stimulated life course research that focuses on the effects of long-term exposures acting since the gestation to adult life or across generations and the life-course pathways.³3 Kuh D, Ben Shlomo Y, editors. A life course approach to chronic disease epidemiology. 2nd edn. Oxford, UK: Oxford University Press; 2004. p. 218–39.^,⁴4 Victora CG, González DA, Hallal PC. Epidemiologia do ciclo vital. In: Almeida Filho N, Barreto ML, editors. Epidemiologia & Saúde: Fundamentos, Métodos, Aplicações. Rio de Janeiro: Guanabara Koogan; 2012. p. 438–46.

Studies conducted by Barker and Osmond⁵5 Barker DJ, Osmond C. Infant mortality, childhood nutrition, and ischaemic heart disease in England and Wales. Lancet. 1986;1:1077–81. suggested that there is an association of perinatal and childhood factors with greater risk of disease in adult life. These studies introduced the fetal programming hypothesis, which suggests that babies in a restricted intrauterine environment are more likely to be born smaller than expected, while growing in a nutrient-rich environment increases the risk of developing metabolic diseases in which maternal, fetal and environmental factors interact.⁴4 Victora CG, González DA, Hallal PC. Epidemiologia do ciclo vital. In: Almeida Filho N, Barreto ML, editors. Epidemiologia & Saúde: Fundamentos, Métodos, Aplicações. Rio de Janeiro: Guanabara Koogan; 2012. p. 438–46. Birth weight as a proxy for fetal growth has been found to be associated with risk of cardiovascular disease in adults⁶6 Alexander BT, Dasinger JH, Intapad S. Fetal programming and cardiovascular pathology. Compr Physiol. 2015;5:997–1025., excess weight during childhood and central body fat during adolescence.⁷7 Oken E, Gillman MW. Fetal origins of obesity. Obes Res. 2003;11:496–506. A systematic review⁸8 Weng SF, Redsell SA, Swift JA, Yang M, Glazebrook CP. Systematic review and meta-analyses of risk factors for childhood overweight identifiable during infancy. Arch Dis Child. 2012;97:1019–26. conducted in 2012 exploring risk factors in the first year of life for excess weight during childhood showed that high birth weight, rapid early weight gain, excess pre-pregnancy weight, and smoking during pregnancy increased the risk of child overweight and obesity. The review also reported that breastfeeding and late introduction of solid foods were moderate protective factors against excess weight during childhood.

Results of studies have been inconsistent, and there are knowledge gaps about fetal programming in developing countries such as Brazil.⁹9 Bammann K, Peplies J, De Henauw S, Hunsberger M, Molnar D, Moreno LA, et al. Early life course risk factors for childhood obesity: the IDEFICS case-control study. PLoS One. 2014;9:e86914.^,¹⁰10 Gonçalves FC, Amorim RJ, Eickmann SH, Lira PI, Lima MC. The influence of low birth weight body proportionality and postnatal weight gain on anthropometric measures of 8-year-old children: a cohort study in Northeast Brazil. Eur J Clin Nutr. 2014;68:876–81. Analyzing multiple exposures and outcomes related to fetal programming, metabolic changes, and risk factors for chronic non-communicable diseases in a developing country will contribute to life course research.

The present study is justified by the high prevalence of overweight and obesity in the Brazilian population, conflicting findings regarding the association between birth weight and excess childhood weight, and dearth of research on the influence of other maternal, fetal and environmental factors. Thus, this study investigated the association between birth weight and excess weight among schoolchildren from ages 6–14 years, based on fetal programming that composes the life course epidemiology.

Methods

Design and study population

A case-control study was conducted in 2010, which included schoolchildren from ages 6–14 years. The study sample was selected from a nutrition survey¹¹11 Lobato JC, Costa AJ, Kale PL, Cavalcanti M de L, Kuschnir MC, Velarde LG, et al. Fetal programming and metabolic abnormalities: design of a case-control study. Rev Bras Epidemiol. 2016;19:52–62. involving 795 school children conducted in two public schools in Niterói, Rio de Janeiro State, Brazil, which were part of the Family Physician Program (acronym in Portuguese: PMF). This life course research, based on fetal programming, aimed to investigate associations between intrauterine growth restriction, the components of the metabolic syndrome, and the thickness of carotid arteries considering the growth and socioeconomic trajectories. Further details about the study can be found elsewhere.¹¹11 Lobato JC, Costa AJ, Kale PL, Cavalcanti M de L, Kuschnir MC, Velarde LG, et al. Fetal programming and metabolic abnormalities: design of a case-control study. Rev Bras Epidemiol. 2016;19:52–62.

Point prevalence rates of excess weight and low birth weight (<2500 g) were 29.7% and 7.7%, respectively. All cases of excess weight from the cross-sectional study sample were selected to form the case group. Of the 236 schoolchildren selected, 32.2% refused participation, leaving an analytic sample of 160 cases (Fig. 1). Of 481 school children comprising a random subsample of all children included in the cross-sectional survey, representing the controls in the present study, 276 were included in the present analysis (67.4%). Among these 276 children, 88 were also included in the case group (Fig. 1). The two groups were stratified by school (schools A and B) and age group (6–9 years and 10–14 years). The case-control ratio was 1:1.8. Since the control group comprised a subsample of the total sample, the calculation of the point prevalence odds ratio (cases/subsample) yielded a point prevalence ratio (PR).¹²12 Szklo M, Nieto FJ. Measuring Associations Between Exposures and Outcomes. In: Szklo M, Nieto FJ, editors. Epidemiology: Beyond the Basics. 3rd ed. Burlington: Jones & Bartlett Learning; 2014. p. 96–9. This strategy was used because when the prevalence of the outcome is high, as in the present study, selecting only non-cases for the control group yields the prevalence odds ratio, which overestimates the prevalence ratio.

Data were collected by trained health professionals and post-graduate students, who were supervised by the main investigators (AJLC, MLTC, PLK).

Age- and sex-adjusted body mass index (BMI, kg/m²2 Rinaudo P, Wang E. Fetal programming and metabolic syndrome. Annu Rev Physiol. 2012;74:107–30.) z-score ≥ +1.00 was defined as excess weight.¹³13 World Health Organization (WHO) Growth reference data for 5-19 years. [cited 2017 Nov]. Available from: http://www.who.int/growthref/en/, 2003.
http://www.who.int/growthref/en/,... Height and weight were measured using a portable stadiometer with accuracy of ± 0.5 cm and a calibrated digital scale with a capacity of 150 kg and accuracy of ±100 g, respectively.¹⁴14 Gordon CC, Chumlea WC, Roche AF. Stature recumbent length and weight. In: Lohman TG, Roche AF, Martorell R, editors. Anthropometric standardization reference manual. Champaign Illinois: Human Kinetics Books; 1988. p. 3–8. Height was measured twice. Participants were remeasured when there was a difference greater than 0.5 cm between the two measurements.

Blood pressure (BP) was measured twice using an electronic blood pressure monitor and an interval of five minutes between each measurement. The average (mean) systolic BP and diastolic BP (mmHg) was calculated. Pressure was remeasured when the difference between measurements was ≥5 mmHg; the measurement with the greatest discrepancy was discarded. Blood samples were collected after a 12-h fast and two plasma samples were stored in a freezer. The schoolchildren’s parents/guardians were interviewed to obtain information about family socioeconomic and demographic characteristics; reproductive history of the biological mother; schoolchildren’s history of breastfeeding, introduction of solid foods, and previous excessive weight gain; and family history of asthma, cardiovascular and metabolic diseases. The schoolchildren aged between 10 and 14 years were also interviewed about their life habits.

Figure 1
Flowchart with number of participants in each step of the study.

^a Not selected for case-control study.

Data were also linked to neonatal medical records kept at the PMF database; 268 records were found, comprising 63.1% of cases and 60.5% of controls (subsample). Linkage to the data obtained from the State of Rio de Janeiro’s Live Birth Information System (acronym in Portuguese, SINASC) yielded 250 pairs of records, comprising 57.5% of cases and 57.2% of controls.

The validity of the information on the schoolchildren’s birth weight had been tested in a previous study.¹⁵15 Noronha GA, Kale PL, Torres TZ, Costa AJ, Cavalcanti ML, Szklo M. Validade da informação sobre o peso ao nascer para estudos fundamentados na programação fetal. Cad Saude Publica. 2017;33:e00051816. Perinatal information was obtained from four sources, including SINASC (official date birth data, the most reliable informa- tion). The intra-class correlation coefficients (ICCs) of the SINASC birth weight with each one of the three other sources of information varied from 0.90 to 0.99. In the absence of SINASC information, data on birth weight were obtained from other sources of information, following a decreasing order of the estimated ICCs by two-way mixed-effectmodels: PMF, followed by the parent/guardian interview and self-completion of the parent/guardian questionnaire. Although records closer to the time of birth have advantages, the study conducted by Noronha et al.¹⁵15 Noronha GA, Kale PL, Torres TZ, Costa AJ, Cavalcanti ML, Szklo M. Validade da informação sobre o peso ao nascer para estudos fundamentados na programação fetal. Cad Saude Publica. 2017;33:e00051816. showed that recalling birth weight between 6 and 14 years after birth is a reliable option. The same algorithm used to complete the variable birth weight was used for the variable gestational age. The international standards for fetal growth,¹⁶16 Villar J, Cheikh Ismail L, Victora CG, Ohuma EO, Bertino E, Altman DG, et al. International standards for newborn weight, length, and head circumference by gestational age and sex: the Newborn Cross-Sectional Study of the INTERGROWTH-21st Project. Lancet. 2014;384:857–68. INTERGROWTH-21 Project, was used to identify and exclude inconsistencies between gestational age and birth weight.

Definition of exposure and covariates

Based upon the fetal programming hypothesis, the main exposure of interest was birth weight as a continuous measure that is associated with long-term disease risk.²2 Rinaudo P, Wang E. Fetal programming and metabolic syndrome. Annu Rev Physiol. 2012;74:107–30. Birth weight measurements were converted into 100-g units to facilitate the interpretation of the results.

The following covariates were considered as potentially confounding: a) demographic variables biological mother’s race/color (white, black, brown), household income, parent/guardian level of schooling at the time of the study (under eight years of schooling, equal to or over eight years of schooling), family size, maternal age at birth, and age in years and sex of the students; b) morbidity and behavioral maternal variables complications during pregnancy, such as high blood pressure and diabetes (yes/no); active and passive smoking at home or work at least once a week during pregnancy (yes/no); c) clinical variables length at birth (cm); and gestational age (preterm <37 weeks, or fullterm ≥37 weeks to < 43 weeks); breastfeeding (months); introduction before 6 months of solid and semi-solid healthy meals (e.g. meat and/or egg and/or fruit and/or vegetables); introduction of unhealthy foods before 12 months (coffee and/or cookies and/or industrialized drinks and/or sugar); parents’/guardians’ perceptions of excessive weight gain prior to the study. Weight gain was ascertained before 2 years of age, between 2 and 6 years, between 7 and 9 years, and between 10 and 14 years. These age groups were defined considering catch-up growth in the first two years of life,¹⁷17 Beltrand J, Nicolescu R, Kaguelidou F, Verkauskiene R, Sibony O, Chevenne D, et al. Catch-up growth following fetal growth restriction promotes rapid restoration of fat mass but without metabolic consequences at one year of age. PLoS One. 2009;4:e5343. prepubertal repletion phase, characterized by an increase of adipose tissue in preparation for the pubertal growth spurt between 7 and 10 years, and beginning of adolescence from 10 years of age on.

Additional variables included family history of cardiovascular and metabolic diseases (high blood pressure, stroke, acute myocardial infarction, diabetes, dyslipidemia, obesity) and asthma among parents and/or grandparents (yes/no); meal consumption patterns based on Prochnik Estima et al.,¹⁸18 Prochnik Estima CC, da Costa RS, Sichieri R, Pereira RA, da Veiga GV. Meal consumption patterns and anthropometric measurements in adolescents from a low socioeconomic neighborhood in the metropolitan area of Rio de Janeiro, Brazil. Appetite. 2009;52:735–9. as follows: main meal frequency (breakfast, lunch, and dinner), categorized as ‘‘daily’’, ‘‘three to six times a week’’, ‘‘once or twice a week’’, and ‘‘never or almost never’’. A score of ‘‘zero’’ for ‘‘daily’’ and ‘‘three’’ for ‘‘never or almost never’’ was given for each meal, resulting in a total score for the three meals of between zero and nine. A score of zero or one was regarded as satisfactory. Comorbidities and health problems included asthma¹⁹19 Solé D, Vanna AT, Yamada E, Rizzo MC, Naspitz CK. International Study of Asthma and Allergies in Childhood (ISAAC) written questionnaire: validation of the asthma component among Brazilian children. J Investig Allergol Clin Immunol. 1998;8: 376–82. (yes/no); hypertension;²⁰20 National High Blood Pressure Education Program Working Group on High Blood Pressure in Children and Adolescents. The fourth report on the diagnosis, evaluation, and treatment of high blood pressure in children and adolescents. Pediatrics. 2004;114:555–76. high fasting blood glucose level;²¹21 Expert Committee on the Diagnosis and Classification of Diabetes Mellitus. Report of the expert committee on the diagnosis and classification of diabetes mellitus. Diabetes Care. 2003;26:S5–20. lipid profile;²²22 Back Giuliano I de C, Caramelli B, Pellanda L, Duncan B, Mattos S, Fonseca FH, et al. I diretriz de prevenção da aterosclerose na infância e na adolescência. Arq Bras Cardiol. 2005;85:4–36. high fasting blood insulin level;²¹21 Expert Committee on the Diagnosis and Classification of Diabetes Mellitus. Report of the expert committee on the diagnosis and classification of diabetes mellitus. Diabetes Care. 2003;26:S5–20. and high C-reactive protein (CRP) blood level.²²22 Back Giuliano I de C, Caramelli B, Pellanda L, Duncan B, Mattos S, Fonseca FH, et al. I diretriz de prevenção da aterosclerose na infância e na adolescência. Arq Bras Cardiol. 2005;85:4–36.

We also investigated the association between birth weight and excess weight among schoolchildren included in the whole cross-sectional sample, which increased the sample size to 661, but limited the number of covariates. These included demographic variables, except household income and family size. The clinical variables included in the whole sample were only length at birth (cm), gestational age, exclusive breastfeeding (until 6 months), and blood pressure.

Statistical analysis

Mean and standard deviations were calculated for continuous variables, and proportions were calculated for the categorical variables for cases and controls. Student’s t-test or the chi-squared test were used to calculate statistical significance. Linearity between the continuous variables and outcome was also tested. For adjustment for confounding variables, weighted logistic regression was used.

First, univariate analysis was conducted adopting a significance level of 0.20 for inclusion in the multivariate analysis, so as to minimize the beta error. The variables weight gain between seven and nine years and weight gain between 10 and 14 years were controlled for age and sex. Collinearity and independence between variables were tested using Pearson’s correlation matrix and the chi-squared test, respectively. Multiple regression was performed adopting a significance level of 0.05. Goodness of fit was evaluated using the Hosmer-Lemeshow test. Statistical analysis was performed using the statistical software package Stata, version 12 (StataCorp LP, College Station, United States).

Ethical standards

This study was conducted according to the guidelines laid down in the Declaration of Helsinki and all procedures involving research study participants were approved by the Research Ethics Committee of the Institute for Collective Health Studies of the Federal University of Rio de Janeiro – IESC/UFRJ (application number 77-2008). Written informed consent was obtained from all subjects/patients.

Results

Case-control study

Unadjusted PRs of excess weight according to selected variables are shown in Table 1. This unadjusted model shows a 6% increase in the excess weight PR (p-value = 0.004) for each 100-g increase of birth weight. The following variables had a p < 0.20: age, parent/guardian level of schooling, family size, mother’s age, passive smoking, weight gain between 2 and 14 years of age, history of asthma, blood pressure, blood sugar, total cholesterol, high density lipoprotein cholesterol (HDL), total cholesterol/HDL ratio, triglyceride, insulin and CRP. These variables were included in the multiple regression models (Table 2). Although not statistically significant at p = 0.20, sex was entered in the multiple regression model as it could be a conditional confounder.

With adjustment for age, sex and behavioral variables (models 1 and 2), the association of birth weight with excess weight was positive and statistically significant, but it was no longer significant in the final model (model 3) when clinical variables (previous parents’/guardians’ perceptions of excessive weight gain, asthma, systolic blood pressure, blood sugar, total cholesterol/HDL ratio, triglyceride, insulin, CRP) were considered.

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Table 1
Unadjusted prevalence ratios of excess weight according to selected variables in schoolchildren aged between 6 and 14 years. Niterói, Rio de Janeiro, 2010.

The following additional covariables showed a significant association with excess weight: age, weight gain between 7–9 years, and blood triglyceride and insulin levels. The final model showed a good fit to the data (p-value = 0.485), and the assumptions of linearity and no collinearity were preserved.

Cross-sectional analysis of the whole sample

The unadjusted model shows a 6% increase in the excess weight PR (p-value < 0.0001) for each 100-g increase of birth weight, as in the case-control study. In the multivariate model, birth weight was statistically and positively associated with excess weight (PR = 1.05 p-value = 0.025) after adjustment for age, sex, mother’s age, race/color, schooling, length at birth and systolic blood pressure.

Discussion

In this study, we didn´t find a statistically significant association between birth weight and excess weight during childhood and adolescence, which therefore failed to support the hypothesis of fetal programming of excess weight. Several studies have shown inconsistent results, suggesting that further research on this topic is necessary.⁹9 Bammann K, Peplies J, De Henauw S, Hunsberger M, Molnar D, Moreno LA, et al. Early life course risk factors for childhood obesity: the IDEFICS case-control study. PLoS One. 2014;9:e86914.^,²³23 Araújo CL, Hallal PC, Nader GA, Neutzling MB, de Fátima Vieira M, Menezes AM, et al. Effect of birth size and proportionality on BMI and skinfold thickness in early adolescence: prospective birth cohort study. Eur J Clin Nutr. 2009;63:634–9.–²⁶26 Chen C, Jin Z, Yang Y, Jiang F, Huang H, Liu S, et al. Association of low birth weight with thinness and severe obesity in children aged 3-12 years: a large-scale population-based cross-sectional study in Shanghai. China. BMJ Open. 2019;9:e028738.

In a systematic review and meta-analysis of the association between birth weight and excess weight among children and adolescents,²⁴24 Yu ZB, Han SP, Zhu GZ, Zhu C, Wang XJ, Cao XG, et al. Birth weight and subsequent risk of obesity: a systematic review and meta-analysis. Obes Rev. 2011;12:525–42. 14 studies reported a positive association between high birth weight (>4000 g) and risk of excess weight, and 10 studies showed a negative association between low birth weight (<2500 g) and excess weight. In the latter studies, the association disappeared when two studies including children of low socioeconomic status were excluded.

In a large-scale cross-sectional population-based survey²⁶26 Chen C, Jin Z, Yang Y, Jiang F, Huang H, Liu S, et al. Association of low birth weight with thinness and severe obesity in children aged 3-12 years: a large-scale population-based cross-sectional study in Shanghai. China. BMJ Open. 2019;9:e028738. conducted in China that included 70,284 children aged 3–12 years, low birth weight (< 2500 g at birth, irrespective of gestational age) was positively associated with an increased risk of thinness and severe obesity but not associated with mod- erate obesity. On the other hand, high birth weight seemed to have a protective effect on thinness²⁶26 Chen C, Jin Z, Yang Y, Jiang F, Huang H, Liu S, et al. Association of low birth weight with thinness and severe obesity in children aged 3-12 years: a large-scale population-based cross-sectional study in Shanghai. China. BMJ Open. 2019;9:e028738. and was associated with an increased risk of childhood obesity.²⁷27 Kapral N, Miller SE, Scharf RJ, Gurka MJ, DeBoer MD. Associations between birthweight and overweight and obesity in school-age children. Pediatr Obes. 2018;13:333–41. In a study in Poland,²⁵25 Baran J, Weres A, Czenczek-Lewandowska E, Leszczak J, Kalandyk-Osinko K, Mazur A. Relationship between Children’s Birth Weight and Birth Length and a Risk of Overweight and Obesity in 4-15-Year-Old Children. Medicina (Kaunas). 2019;55:487. birth weight was positively related to BMI in 747 4 – 15-year-old children; however, no significant differences were found in birth weight with overweight/obese children. A matched case-control study of the impact of prenatal, perinatal and postnatal risk factors for obesity in children aged between 4 and 8 years conducted with 1024 pairs in various European countries⁹9 Bammann K, Peplies J, De Henauw S, Hunsberger M, Molnar D, Moreno LA, et al. Early life course risk factors for childhood obesity: the IDEFICS case-control study. PLoS One. 2014;9:e86914. reported negative and positive associations between obesity and low birth weight (below 2500 g) and obesity and high birth weight (over 4000 g), respectively. After weighting the data using an indicator of fat-free mass, the association of birth weight with obesity risk disappeared completely.

A cohort study conducted in 1993 with 5160 newborns in Pelotas, Brazil,²³23 Araújo CL, Hallal PC, Nader GA, Neutzling MB, de Fátima Vieira M, Menezes AM, et al. Effect of birth size and proportionality on BMI and skinfold thickness in early adolescence: prospective birth cohort study. Eur J Clin Nutr. 2009;63:634–9. showed in the adjusted analysis that for each increase of unit (Z-score) in birth weight, the BMI increases 0.46 kg m⁻² in BMI at age 11 years, regardless of sex.

Although not the focus of this study, the associations we found between the covariables and excess weight, previous excessive weight gain,¹⁰10 Gonçalves FC, Amorim RJ, Eickmann SH, Lira PI, Lima MC. The influence of low birth weight body proportionality and postnatal weight gain on anthropometric measures of 8-year-old children: a cohort study in Northeast Brazil. Eur J Clin Nutr. 2014;68:876–81.^,²⁸28 Lurbe E, Aguilar F, Álvarez J, Redon P, Torró MI, Redon J. Determinants of Cardiometabolic Risk Factors in the First Decade of Life: A Longitudinal Study Starting at Birth. Hypertension. 2018;71:437–43. high blood insulin,²⁹29 Tam CH, Wang Y, Luan J, Lee HM, Luk AO, Tutino GE, et al. Nonlinear relationship between birthweight and cardiometabolic risk factors in Chinese adolescents and adults. Diabet Med. 2015;32:220–5.^,³⁰30 Chissini RBC, Kuschnir MC, de Oliveira CL, Giannini DT, Santos B. Cutoff values for HOMA-IR associated with metabolic syndrome in the Study of Cardiovascular Risk in Adolescents (ERICA Study). Nutrition. 2020;71:110608. and triglyceride levels²⁹29 Tam CH, Wang Y, Luan J, Lee HM, Luk AO, Tutino GE, et al. Nonlinear relationship between birthweight and cardiometabolic risk factors in Chinese adolescents and adults. Diabet Med. 2015;32:220–5. are consistent with the findings of other studies. During pubescence, there is a physiological increase in circulating insulin, thus contributing to rapid growth and body modification.³⁰30 Chissini RBC, Kuschnir MC, de Oliveira CL, Giannini DT, Santos B. Cutoff values for HOMA-IR associated with metabolic syndrome in the Study of Cardiovascular Risk in Adolescents (ERICA Study). Nutrition. 2020;71:110608. Nevertheless, the association between a lower proportion of muscle tissue, derived from intrauterine growth restriction, and a greater proportion of fat mass, derived from catch-up growth, may increase predisposition to chronic non-communicable diseases in the future.¹⁰10 Gonçalves FC, Amorim RJ, Eickmann SH, Lira PI, Lima MC. The influence of low birth weight body proportionality and postnatal weight gain on anthropometric measures of 8-year-old children: a cohort study in Northeast Brazil. Eur J Clin Nutr. 2014;68:876–81. In individuals who have suffered malnutrition in the uterine environment and start to have a diet rich in calories, their fetal programming to develop an economic metabolism becomes harmful.⁴4 Victora CG, González DA, Hallal PC. Epidemiologia do ciclo vital. In: Almeida Filho N, Barreto ML, editors. Epidemiologia & Saúde: Fundamentos, Métodos, Aplicações. Rio de Janeiro: Guanabara Koogan; 2012. p. 438–46. Fetal metabolic adaptation increases the risk of obesity, diabetes, and other chronic diseases.⁴4 Victora CG, González DA, Hallal PC. Epidemiologia do ciclo vital. In: Almeida Filho N, Barreto ML, editors. Epidemiologia & Saúde: Fundamentos, Métodos, Aplicações. Rio de Janeiro: Guanabara Koogan; 2012. p. 438–46. There is strong evidence that cardiovascular diseases begin to develop early in life, meaning that it is vital to monitor main risk factors from childhood, particularly among people who are overweight.²⁹29 Tam CH, Wang Y, Luan J, Lee HM, Luk AO, Tutino GE, et al. Nonlinear relationship between birthweight and cardiometabolic risk factors in Chinese adolescents and adults. Diabet Med. 2015;32:220–5.

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Table 2
Multivariate-adjusted prevalence ratios of excess weight according to selected variables in schoolchildren aged between 6 and 14 years. Niterói, Rio de Janeiro, 2010.

Life course epidemiological studies of excess weight tend to be prospective birth cohort studies, which have proved to be ideal for evaluating etiological hypotheses. However, they are particularly complex and require long periods of time, which can result in losses to follow-up and the need for substantial funding, often rendering research difficult.⁴4 Victora CG, González DA, Hallal PC. Epidemiologia do ciclo vital. In: Almeida Filho N, Barreto ML, editors. Epidemiologia & Saúde: Fundamentos, Métodos, Aplicações. Rio de Janeiro: Guanabara Koogan; 2012. p. 438–46. Considering these limitations, case-cohort study designs can enhance the feasibility of research, as they are less costly and more efficient, making them a useful alternative for obtaining almost as much information as in a full cohort.¹²12 Szklo M, Nieto FJ. Measuring Associations Between Exposures and Outcomes. In: Szklo M, Nieto FJ, editors. Epidemiology: Beyond the Basics. 3rd ed. Burlington: Jones & Bartlett Learning; 2014. p. 96–9.

Furthermore, the availability of multiple, wide-ranging secondary sources of data on the period up to 2 years of age allowed our study to capture reliable and valid information on the main exposure variable, birth weight.¹⁵15 Noronha GA, Kale PL, Torres TZ, Costa AJ, Cavalcanti ML, Szklo M. Validade da informação sobre o peso ao nascer para estudos fundamentados na programação fetal. Cad Saude Publica. 2017;33:e00051816. In addition, and notwithstanding the cross-sectional study design, temporality of the events, birth weight and overweight in childhood and adolescence are accurately recorded.

The study had a number of limitations. First, the sample size resulted in a low frequency of low birthweight. Second, previous weight gain depended not only on the parents’/guardians’ memory, but also on their perceptions. Third, the limited availability of accurate data on gestational age meant that it was only possible to consider a single dichotomous variable (preterm or full term). Finally, it was not possible to identify the time of the occurrence of the outcome.

In conclusion, the present study provides valuable information on the association between birth weight and excess weight in a sample of schoolchildren aged 6–14 years. Although the main relationship hypothesized in this study was not statistically significant, statistically significant associations were found between excess weight and age, weight gain between 7 and 9 years of age, blood triglyceride and insulin levels.

Financial Support

Conselho Nacional de Desenvolvimento Científico e Tecnológico-CNPq(MCT/CNPq 15/2007–Universal; n^◦ 481094/2007-5); Fundação Carlos Chagas Filho de Amparo à Pesquisa no estado do Rio de Janeiro-FAPERJ (E-26 110.986/2008); Financiadora de Estudos e ProjetosFINEP/

Ministério da Ciência e Tecnologia – FINEP; Departamento de Ciência e Tecnologia – DECITMinistério da Saúde (0436/08).

Acknowledgements

The authors would like to acknowledge the insightful comments from IESC teachers and doctoral students, in particular Dr. Katia Vergetti Bloch. We also thank all the schoolchildren and guardians who agreed to participate in the study.

References

¹
Lucas K, James P, Choh AC, Lee M, Czerwinski SA, Demerath EW, et al. The positive association of infant weight gain with adulthood body mass index has strengthened over time in the Fels Longitudinal Study. Pediatr Obes. 2018;13:476–84.
²
Rinaudo P, Wang E. Fetal programming and metabolic syndrome. Annu Rev Physiol. 2012;74:107–30.
³
Kuh D, Ben Shlomo Y, editors. A life course approach to chronic disease epidemiology. 2nd edn. Oxford, UK: Oxford University Press; 2004. p. 218–39.
⁴
Victora CG, González DA, Hallal PC. Epidemiologia do ciclo vital. In: Almeida Filho N, Barreto ML, editors. Epidemiologia & Saúde: Fundamentos, Métodos, Aplicações. Rio de Janeiro: Guanabara Koogan; 2012. p. 438–46.
⁵
Barker DJ, Osmond C. Infant mortality, childhood nutrition, and ischaemic heart disease in England and Wales. Lancet. 1986;1:1077–81.
⁶
Alexander BT, Dasinger JH, Intapad S. Fetal programming and cardiovascular pathology. Compr Physiol. 2015;5:997–1025.
⁷
Oken E, Gillman MW. Fetal origins of obesity. Obes Res. 2003;11:496–506.
⁸
Weng SF, Redsell SA, Swift JA, Yang M, Glazebrook CP. Systematic review and meta-analyses of risk factors for childhood overweight identifiable during infancy. Arch Dis Child. 2012;97:1019–26.
⁹
Bammann K, Peplies J, De Henauw S, Hunsberger M, Molnar D, Moreno LA, et al. Early life course risk factors for childhood obesity: the IDEFICS case-control study. PLoS One. 2014;9:e86914.
¹⁰
Gonçalves FC, Amorim RJ, Eickmann SH, Lira PI, Lima MC. The influence of low birth weight body proportionality and postnatal weight gain on anthropometric measures of 8-year-old children: a cohort study in Northeast Brazil. Eur J Clin Nutr. 2014;68:876–81.
¹¹
Lobato JC, Costa AJ, Kale PL, Cavalcanti M de L, Kuschnir MC, Velarde LG, et al. Fetal programming and metabolic abnormalities: design of a case-control study. Rev Bras Epidemiol. 2016;19:52–62.
¹²
Szklo M, Nieto FJ. Measuring Associations Between Exposures and Outcomes. In: Szklo M, Nieto FJ, editors. Epidemiology: Beyond the Basics. 3rd ed. Burlington: Jones & Bartlett Learning; 2014. p. 96–9.
¹³
World Health Organization (WHO) Growth reference data for 5-19 years. [cited 2017 Nov]. Available from: http://www.who.int/growthref/en/, 2003.
» http://www.who.int/growthref/en/,
¹⁴
Gordon CC, Chumlea WC, Roche AF. Stature recumbent length and weight. In: Lohman TG, Roche AF, Martorell R, editors. Anthropometric standardization reference manual. Champaign Illinois: Human Kinetics Books; 1988. p. 3–8.
¹⁵
Noronha GA, Kale PL, Torres TZ, Costa AJ, Cavalcanti ML, Szklo M. Validade da informação sobre o peso ao nascer para estudos fundamentados na programação fetal. Cad Saude Publica. 2017;33:e00051816.
¹⁶
Villar J, Cheikh Ismail L, Victora CG, Ohuma EO, Bertino E, Altman DG, et al. International standards for newborn weight, length, and head circumference by gestational age and sex: the Newborn Cross-Sectional Study of the INTERGROWTH-21st Project. Lancet. 2014;384:857–68.
¹⁷
Beltrand J, Nicolescu R, Kaguelidou F, Verkauskiene R, Sibony O, Chevenne D, et al. Catch-up growth following fetal growth restriction promotes rapid restoration of fat mass but without metabolic consequences at one year of age. PLoS One. 2009;4:e5343.
¹⁸
Prochnik Estima CC, da Costa RS, Sichieri R, Pereira RA, da Veiga GV. Meal consumption patterns and anthropometric measurements in adolescents from a low socioeconomic neighborhood in the metropolitan area of Rio de Janeiro, Brazil. Appetite. 2009;52:735–9.
¹⁹
Solé D, Vanna AT, Yamada E, Rizzo MC, Naspitz CK. International Study of Asthma and Allergies in Childhood (ISAAC) written questionnaire: validation of the asthma component among Brazilian children. J Investig Allergol Clin Immunol. 1998;8: 376–82.
²⁰
National High Blood Pressure Education Program Working Group on High Blood Pressure in Children and Adolescents. The fourth report on the diagnosis, evaluation, and treatment of high blood pressure in children and adolescents. Pediatrics. 2004;114:555–76.
²¹
Expert Committee on the Diagnosis and Classification of Diabetes Mellitus. Report of the expert committee on the diagnosis and classification of diabetes mellitus. Diabetes Care. 2003;26:S5–20.
²²
Back Giuliano I de C, Caramelli B, Pellanda L, Duncan B, Mattos S, Fonseca FH, et al. I diretriz de prevenção da aterosclerose na infância e na adolescência. Arq Bras Cardiol. 2005;85:4–36.
²³
Araújo CL, Hallal PC, Nader GA, Neutzling MB, de Fátima Vieira M, Menezes AM, et al. Effect of birth size and proportionality on BMI and skinfold thickness in early adolescence: prospective birth cohort study. Eur J Clin Nutr. 2009;63:634–9.
²⁴
Yu ZB, Han SP, Zhu GZ, Zhu C, Wang XJ, Cao XG, et al. Birth weight and subsequent risk of obesity: a systematic review and meta-analysis. Obes Rev. 2011;12:525–42.
²⁵
Baran J, Weres A, Czenczek-Lewandowska E, Leszczak J, Kalandyk-Osinko K, Mazur A. Relationship between Children’s Birth Weight and Birth Length and a Risk of Overweight and Obesity in 4-15-Year-Old Children. Medicina (Kaunas). 2019;55:487.
²⁶
Chen C, Jin Z, Yang Y, Jiang F, Huang H, Liu S, et al. Association of low birth weight with thinness and severe obesity in children aged 3-12 years: a large-scale population-based cross-sectional study in Shanghai. China. BMJ Open. 2019;9:e028738.
²⁷
Kapral N, Miller SE, Scharf RJ, Gurka MJ, DeBoer MD. Associations between birthweight and overweight and obesity in school-age children. Pediatr Obes. 2018;13:333–41.
²⁸
Lurbe E, Aguilar F, Álvarez J, Redon P, Torró MI, Redon J. Determinants of Cardiometabolic Risk Factors in the First Decade of Life: A Longitudinal Study Starting at Birth. Hypertension. 2018;71:437–43.
²⁹
Tam CH, Wang Y, Luan J, Lee HM, Luk AO, Tutino GE, et al. Nonlinear relationship between birthweight and cardiometabolic risk factors in Chinese adolescents and adults. Diabet Med. 2015;32:220–5.
³⁰
Chissini RBC, Kuschnir MC, de Oliveira CL, Giannini DT, Santos B. Cutoff values for HOMA-IR associated with metabolic syndrome in the Study of Cardiovascular Risk in Adolescents (ERICA Study). Nutrition. 2020;71:110608.

Publication Dates

Publication in this collection
11 Oct 2021
Date of issue
Sep-Oct 2021

History

Received
4 June 2020
Accepted
8 Oct 2020
Published
6 Dec 2020

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] Financial Support

Conselho Nacional de Desenvolvimento Científico e Tecnológico-CNPq(MCT/CNPq 15/2007–Universal; n^◦ 481094/2007-5); Fundação Carlos Chagas Filho de Amparo à Pesquisa no estado do Rio de Janeiro-FAPERJ (E-26 110.986/2008); Financiadora de Estudos e ProjetosFINEP/

Ministério da Ciência e Tecnologia – FINEP; Departamento de Ciência e Tecnologia – DECITMinistério da Saúde (0436/08).

Variables	Unadjusted PR (CI 95%)		p-value
Birthweight (100 g)	1.06	(1.02–1.10)	0.004
Age (years)	0.92	(0.84–1.00)	0.054
Sex
Female	1.00
Male	1.05	(0.71–1.56)	0.797
Maternal race/color
White	1.00
Black	1.12	(0.54–2.31)	0.748
Brown	0.95	(0.62–1.47)	0.830
Parent/guardian level of schooling at the time of the study
≥8 years	1.00
<8 years	0.75	(0.50–1.13)	0.174
Family size	0.83	(0.70−0.98)	0.029
Mother’s age (years)	1.03	(1.00–1.06)	0.082
Diabetes during pregnancy	2.68	(0.44–16.35)	0.284
Smoking during pregnancy	0.82	(0.50–1.33)	0.424
Passive smoking^a a Passive smoking during pregnancy at home, work, or outside for at least one day/week.
No	1.00
Yes	0.76	(0.51–1.13)	0.173
Length at birth (cm)	1.04	(0.97–1.12)	0.234
Gestational age
Preterm	1.00
Full term	0.70	(0.28–1.74)	0.446
Breastfeeding (months)	1.00	(0.99–1.01)	0.448
Early food introduction^b b Food introduction (meat and/or egg and/or fruit and/or vegetables) before 6 months.	1.20	(0.80–1.79)	0.374
Introduction of unhealthy foods^c c Introduction of unhealthy foods (coffee and/or cookies and/or industrialized drinks and/or sugar) before 12 months.	1.17	(0.74–1.86)	0.502
Weight gain before age 2 years^d d Previous parents’/guardians’ perceptions of excessive weight gain.
No	1.00
Yes	1.20	(0.60–2.39)	0.604
Weight gain between 2 and 6 years of age^d d Previous parents’/guardians’ perceptions of excessive weight gain.
No	1.00
Yes	2.13	(1.09–4.18)	0.027
Weight gain between 7 and 9 years^d,e
No	1.00
Yes	4.13	(1.97–8.64)	0.000
Weight gain between 10 and 14 years^d,e
No	1.00
Yes	3.64	(1.52–8.73)	0.004
Family History
Cardiovascular disease^f	0.70	(0.37–1.32)	0.271
Metabolic diseases^g g Parents or grandparents have/had metabolic disease (diabetes or dyslipidemia or obesity).	1.28	(0.81–2.04)	0.288
Asthma	1.10	(0.71–1.71)	0.673
Unsatisfactory meal consumption pattern	1.10	(0.74–1.64)	0.638
Asthma
No	1.00
Yes	1.64	(0.91–2.96)	0.096
Blood pressure
Systolic (mmHg)	1.02	(1.00–1.04)	0.036
Blood sugar (mg/dL)	1.03	(1.00–1.06)	0.023
Total cholesterol (mg/dL)	1.00	(0.99–1.01)	0.167
HDL (mg/dL)	0.98	(0.96–1.00)	0.059
LDL (mg/dL)	1.00	(0.99–1.00)	0.844
TC/HDL ratio	1.36	(1.11–1.67)	0.003
Triglyceride (mg/dL)	1.01	(1.01–1.02)	0.000
Insulin (µ,IU/mL)
1st quartile	2.48	(1.29–4.76)	0.006
2nd quartile	3.37	(1.77–6.43)	0.000
3rd quartile	4.82	(2.55–9.13)	0.000
CRP
<0.3 mg/dL	1.00
≥0.3 mg/dL	2.07	(1.25–3.42)	0.005

Variables	Model 1^a a Model 1: demographic variables (age, sex, parent/guardian level of schooling at the time of the study, number of people in the family [or family size], mother’s age). PR (CI 95%)		p-value	Model 2^b b Model 2: model 1 + behavioral variable (passive smoking). PR (CI 95%)		p-value	Model 3^c c Model 3: model 2 + clinical variables (previous parents’/guardians’ perceptions of excessive weight gain, asthma, systolic blood pressure, blood sugar, CT/HDL ratio, triglyceride, insulin, CRP). PR (CI 95%)		p-value
Birth weight (in 100 g)	1.05	1.01−1.10	0.010	1.05	1.01−1.10	0.019	1.04	0.99−1.09	0.110
Age (years)	0.92	0.83−1.02	0.121	0.92	0.83−1.02	0.123	0.84	0.73−0.95	0.010
Sex
Female	1.00			1.00			1.00
Male	1.04	0.67−1.59	0.864	1.00	0.65−1.54	0.992	1.43	0.83−2.45	0.199
Parent/guardian level of schooling at the time of the study
≥8 years	1.00			1.00			1.00
<8 years	0.87	0.56−1.36	0.554	0.85	0.54−1.33	0.479	0.78	0.46−1.32	0.361
Family size	0.81	0.67−0.98	0.030	0.80	0.66−0.97	0.025	0.82	0.65−1.02	0.079
Mother’s age (years)	1.02	0.99−1.06	0.167	1.02	0.99−1.05	0.181	1.01	0.97−1.04	0.581
Passive smokingd
No	–			1.00			1.00
Yes	–			0.87	0.55−1.36	0.538	0.74	0.43−1.27	0.281
Weight gain between 2 and 6 years of agee
No	–			–			1.00
Yes	–			–			1.11	0.42−2.91	0.825
Weight gain between 7 and 9 yearse
No	–			–			1.00
Yes	–			–			2.82	1.07−7.45	0.036
Weight gain between 10 and 14 yearse
No	–			–			1.00
Yes	–			–			3.01	0.91−9.98	0.070
Asthma
No	–			–			1.00
Yes	–			–			1.70	0.80−3.63	0.169
Systolic blood pressure (mmHg)	–			–			1.00	0.97−1.03	0.716
Blood sugar (mg/dL)	–			–			1.00	0.97−1.04	0.739
CT/HDL ratio	–			–			1.05	0.81−1.36	0.692
Triglyceride (mg/dL)	–			–			1.01	1.01−1.02	0.042
Insulin (¼IU/mL)
1st quartile	–			–			1.80	0.87−3.76	0.113
2nd quartile	–			–			2.54	1.16−5.54	0.019
3rd quartile	–			–			2.29	0.94−5.54	0.067
CRP
<0.3 mg/dL	–			–			1.00
≥0.3 mg/dL	–			–			1.52	0.78−2.97	0.212

Brasil