Low birth weight (LBW) is associated with an increased risk of mortality, adverse metabolic conditions, and long-term chronic morbidities. The relationship between LWB and short maternal stature coupled with nutritional status was investigated in poor communities.
A cross-sectional population-based study involving 2226 mother-child pairs was conducted during the period 2009-2010 in shantytowns of Maceió, Alagoas, Brazil. Associations between LBW and maternal sociodemographics, stature and nutritional status were investigated. The outcome variable was birth weight (< 2500g and ≥ 2500g). The independent variables were the age, income, educational background, stature and nutritional status (eutrophic, underweight, overweight and obese) of the mother. The frequency of LBW was 10%. Short-statured mothers (1st quartile of stature ≤ 152cm) showed a tendency of increased risk of LBW children compared to mothers in the 4th quartile of stature (>160.4cm) (OR: 1.42, 95% CI: 0.96 - 1.09, p = 0.078). Children from short-statured mothers weighed an average of 125g less than those from taller mothers (3.18±0.56kg vs. 3.30±0.58kg, respectively p = 0.002). Multivariate analyses showed that short stature, age < 20y (OR: 3.05, 95% CI:1.44 - 6.47) or were underweight (OR: 2.26, 95% CI:0.92 - 5.95) increased the risk of LBW, while overweight (OR: 0.38, 95% CI:0.16 - 0.95) and obesity (OR: 0.39, 95% CI:0.11 - 1.31) had lower risk for LBW. In taller mothers, lower income and underweight were associated with LBW (OR: 1.88, 95% CI: 1.07 - 3.29 and 2.85, 95% CI:1.09 - 7.47, respectively), and obese mothers showed a trend of increased risk of LBW (OR: 1.66, 95% CI:0.84 - 3.25).
Overweight was found to have a protective effect in short-statured mothers, indicating that a surplus of energy may diminish the risk of LBW. Short-statured younger mothers, but not taller ones, showed higher risk of LBW. The mother being underweight, regardless of stature, was associated with LBW.
Citation: Britto RPdA, Florêncio TMT, Benedito Silva AA, Sesso R, Cavalcante JC, Sawaya AL (2013) Influence of Maternal Height and Weight on Low Birth Weight: A Cross-Sectional Study in Poor Communities of Northeastern Brazil. PLoS ONE 8(11): e80159. doi:10.1371/journal.pone.0080159
Editor: Barbara T Alexander, Univ Mississippi Medical Center, United States of America
Received: December 3, 2012; Accepted: October 9, 2013; Published: November 11, 2013
Copyright: © 2013 Britto et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: The authors wish to thank the Fundação de Amparo à Pesquisa do Estado de Alagoas (FAPEAL) for financial support. The funding authority had no role in the study design, data collection and analysis, decision to publish the material or in the preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Globally, approximately 20 million infants are born with low birth weight (LBW < 2500 g) annually. Approximately 95% of LBW infants are born in developing countries. The two main reasons for LBW are preterm birth (
< 37 weeks) and intrauterine growth restriction (IUGR). Low birth weight is considered to be one of the most significant factors associated with neonatal, post-natal and infant mortality as well as the increased risk of diseases in adulthood. Determinants of LBW may differ between populations depending on whether LBW is due to growth restriction or prematurity. Sixty-four percent of the worldwide deaths of children under the age of five in 2010 were attributable to infectious causes, and preterm birth complications were the second-leading cause of death. Preterm birth complications (14.1%), intrapartum-related complications (9.4%), and sepsis or meningitis (5.2%) were the leading causes of neonatal death. In older children, pneumonia (14.1%), diarrhea (9.9%), and malaria (7.4%) claimed the most lives. Brazil is among the 10 countries with the highest number of preterm births.
One of the most important determinants of fetal growth and birth weight is maternal nutritional status[5-7]. Studies have found that short maternal stature increases the risk of LBW and offspring mortality, underweight and stunting. A recent systematic review and meta-analyses found that short-statured women have a higher unadjusted risk of preterm birth and LBW, and tall women have approximately one half of the unadjusted risk of LBW compared to women of the reference height.
In addition, body mass index [BMI = weight (kg)/height (m)2] plays a critical role in the determination of gestational outcome, as maternal overweight and underweight are both strong predictors of birth weight[11,12]. A meta-analysis of 78 studies involving more than one million women in developed and developing countries revealed that maternal undernutrition was strongly associated with a greater risk of LBW. On the other hand, a meta-analysis of 84 studies consisting of a similar number of women indicated that maternal overweight or obesity might reduce the risk of LBW and that the protective influence appeared to be stronger in developing countries, although the authors identified this association as spurious and due to bias in the analysis. Based on the above research, it is evident that maternal stature and BMI both contribute significantly to the birth weight of children, but no information is available regarding the impact of the combination of short stature and BMI on the risk of LBW.
The Brazilian state of Alagoas has the lowest human development index (0.677) in the country. The population of Alagoas is estimated to be around three million, and 56.6% of the population live in absolute poverty; 32.2% live in extreme poverty. Of the irregular settlements in the state (e.g., shantytowns and illegally occupied urban areas), 94.6% are located in the capital city of Maceió. Previous studies conducted by our research group in the shantytowns of Maceió have revealed a high prevalence of individuals presenting with a combination of short stature and obesity, particularly women[19,20].
The aim of the present study was to examine the hypothesis that obese mothers of short stature are at increased risk of bearing children with LBW, as has been described previously for undernourished mothers of short stature. For this purpose, the association between LBW and short maternal stature, coupled with maternal current nutritional status, has been investigated in a sample population drawn from poor communities in Maceió-AL, Brazil.
The study was approved by the Ethics Committees in Research of the Federal University of Alagoas (Maceió, AL, Brazil; protocol number 20090132001-6) and of the Federal University of São Paulo (São Paulo, SP, Brazil; protocol number 1731/11). The aims and objectives of the study were explained to all potential participants, and it was emphasized that participation was voluntary. Written informed consent was obtained from the mothers for themselves and on behalf of the children participants prior to the commencement of the study. None of the invited participants refused to participate in the study.
The cross-sectional, population-based study was conducted during a one-year period (2009-2010) in shantytowns located on the periphery of Maceió. The necessary sample size was estimated using the StatCalc module in Epi Info™ (version 3.5.1.), assuming a LBW prevalence of 8%, a study power of 80% and a type one error of 5%. The minimum sample population required to comply with these criteria was estimated at 2972 children, i.e., 129 children per visited shantytown.
Data were collected in the homes of participants using a pre-tested structured questionnaire. In each shantytown, visits commenced at a previously selected corner starting point and continued in a clockwise direction. At each home, residents were asked if there was at least one child under 5 years of age living in the home. If there was no such child in the home, the researcher moved to the next dwelling until a sufficient number of households were sampled. Children with unconfirmed birth weight; children with genetic, endocrine or anatomical abnormalities that could compromise evaluation; pregnant or lactating women; mothers less than 18 or more than 49 years old; and non-biological mothers were excluded from the analysis.
Determination of Nutritional Status
Maternal nutritional status was based on BMI using the cutoff points recommended by the World Health Organization (WHO) as follows: underweight, BMI < 18.5 kg/m2; eutrophic, BMI 18.5 to <25 kg/m2; overweight, BMI 25 to < 30 kg/m2; and obese, BMI ≥ 30 kg/m2 . Anthropometric measurements were taken with the mothers barefoot and wearing light clothes. Body weight was determined using a portable digital scale with 180 kg capacity and 100 g sensitivity, and height was determined with the individual in an orthostatic position with the aid of a portable stadiometer consisting of a non-extendable 2 m measuring tape divided into 0.1 cm increments. Short stature was adopted as an indicator of undernutrition in early life. For the purpose of this study, mothers were classified according to stature quartiles based on the sample population, with those in the 1st quartile (height < 152 cm, equivalent to < 3rd percentile for 19-year-old women according to WHO), considered to be of short stature, while those in the 4th quartile (> 160.4 cm, or > 43rd percentile of the WHO reference) were considered to be the reference group for analyzing the variables of interest. Previous studies from our research group[22,23] have used this method of height stratification as an adjustment for the generally low socioeconomic status of this population. As described above, the highest quartile mean in the study sample did not reach the 50th percentile of the WHO reference. In addition, our previous studies found significant relationships between adults with short stature (1st quartile), the comorbidities and the nutritional status of children.
The nutritional status of children was assessed from the weight and height/length measurements, which were standardized according to technical recommendations. Children were stratified with respect to the anthropometric indices height-for-age and weight-for-height Z-scores (HAZ and WHZ, respectively), according to gender and age, utilizing the reference distribution proposed by WHO. The data were calculated using WHO Anthro software . Children presenting HAZ < -2.0 were classified as short stature, whereas those with WHZ > +1.5 and > +2.0 were classified as overweight and obese, respectively. Birth weights were obtained from the medical records of the children, and a cutoff value of 2,500 g was adopted for the definition of LBW.
The associations between LBW and maternal sociodemographics, stature and nutritional status were investigated. The mean differences in birth weight values were distributed according to the maternal stature quartiles and evaluated using one-way analysis of variance (ANOVA) and the Tukey post-hoc tests.
The dependent variable was birth weight, which was dichotomized as < 2500 g and ≥ 2500 g. The independent (explanatory) variables were the mother’s age at birth (
< 20 and ≥ 20 years), family income (≤ ½ and > ½ Brazilian minimum salary), length of schooling (< 4 and ≥ 4 years), stature and nutritional status (eutrophic, underweight, overweight and obese), according to the above-mentioned cutoffs).
The associations between LBW and the independent variables were tested. Univariate analyses were based on the Pearson x2-test and on the crude odds ratios with 95% confidence intervals (95% CI). In multivariate analyses using logistic regression, the criterion for inclusion of independent variables in the model was whether they were associated with the dependent variable in the univariate analyses at the p ≤ 0.20 level. Only those independent variables with p < 0.05 remained in the final regression models. Adjusted odds ratios (95% CI) were calculated. As we detected a modification of the effect of maternal BMI by stature in relation to LBW, the analyses were stratified by maternal stature. We used the first and the fourth stature quartiles in these analyses to maximize the chance of detecting an effect due to differences in stature and to obtain a clear separation between the groups of low and normal stature.
The differences were considered statistically significant when the probability of alpha error was less than 5% (P < 0.05).
Statistical analyses were performed using Epi Info™, version 3.5.1, and Statistica™, version 11.
In the present study, 2226 mother-child pairs were included from 23 shantytowns; 51% of the children were girls (1413), and 49% were boys (1349). The population was very homogeneous with respect to socioeconomic and educational levels (Table 1). The average monthly family income was Brazilian reals (R$) 452 ± 322, equivalent to US$ 224 ± 160, at an exchange rate of US$ 2.02, in September 2012. The majority of families (70%) reported a monthly income of less than one minimum Brazilian salary (R$ 622 or US$ 308), while a considerable number (25.5%) reported an even lower household income (
< ½ minimum salary). Fifty percent of the mothers had attended school for less than 4 years. Forty-six percent of the children were overweight or obese, and 5% were underweight. The mean birth weight of the children was 3230 ± 575 g (Table 1). Short stature was observed in 25% of the women. Slightly under half (47.5%) of the short-statured mothers were either overweight or obese. Ten percent of the children surveyed had LBW. The frequencies of LBW were 11.6% in girls and 8.1% in boys (Pearson x2-test, P = 0.003, OR: 1.460 CI 95%:1.13 - 1.88).
|Age, yr||27.3 (13 - 55)|
|Length of schooling, yr||2.9 ± 1.3|
|Low level of education (< 4 years)||910 (40.9)|
|Low family income (< ½ Brazilian minimum salary)||568 (25.5)|
|Stature, m||1.56 ± 0.06|
|BMI, kg/m2||25.1 ± 5.0|
|Eutrophic (BMI ≥ 18.5 and BMI ≤ 25.0 kg/m2)||1110 (50.1)|
|Underweight (BMI < 18.5 kg/m2)||114 (5.1)|
|Overweight (BMI > 25.0 and BMI < 30.0 kg/m2)||653 (29.3)|
|Obese (BMI ≥ 30 kg/m2)||349 (15.7)|
|Birth weight, g||3230±575|
The analysis of the sociodemographic characteristics of the mothers associated with LBW is shown in Table 2. Younger mothers (less than 20 years of age) had more than twice the risk of having LBW children, and lower family income (≤ ½ Brazilian minimum salary) was also associated with an increased risk (34%) of LBW. Regarding maternal nutritional status, underweight mothers were almost 3 times more likely to deliver children with LBW (P<0.0001), while a 32% lower chance was observed for overweight mothers compared to mothers with a normal body mass index.
|Parameter||Low Birth Weight||LBW odds ratio (95% CI)||P Value|
|Yes, N (%)||No, N (%)|
|< 20||36 (18.0)||164 (82.0)||2.22 (1.50-3.28)||<0.0001|
|≥ 20†||181 (9.0)||1828 (91.0)|
|≤ 0.5 min salary||68 (12.0)||500 (88.0)||1.34 (0.99-1.81)||0.061|
|> 0.5 min salary†||153 (9.2)||1503 (90.8)|
|Schooling length, yr|
|< 4||97 (10.7)||813 (89.3)||1.09 (0.81-1.49)||0.560|
|≥ 4†||89 (9.8)||817 (90.2)|
|Body Mass Index|
|Eutrophic†||115 (10.4)||996 (89.6)||1|
|Underweight||25 (21.9)||89 (78.1)||2.43 (1.48-3.91)||<0.0001|
|Overweight||50 (7.7)||602 (92.3)||0.72 (0.51-1.01)||0.060|
|Obese||32 (9.2)||317 (90.8)||0.87 (0.57-1.31)||0.585|
|1st quartile (≤ 152 cm)||66 (11.8)||491 (88.2)||1.42 (0.96-2.09)|
|4th quartile (> 160. 4 cm) †||49 ( 8.7)||517 (91.3)||0.078|
To maximize the possibility of detecting the influence of maternal stature in LBW, we contrasted the first (stature less or equal to 152 cm) and fourth (above 160.4 cm) height quartiles (Table 2). Mothers in the first quartile of stature had a tendency of increased risk (42%) of having LBW children compared with those in the 4th stature quartile (p=0.078).
Considering the relation between child birth weight and maternal stature, children of mothers in the 1st quartile of stature weighed an average of 125 g less than those of mothers in the 4th quartile (p= 0.002) (Table 3). The mean birth weights of children of mothers in the 1st, 2nd and 3rd quartiles of stature were not significantly different.
|Maternal Stature||N||Birth weight, kg|
|1st quartile (≤ 152 cm)||557||3.18±0.56|
|2nd quartile (>152 cm and ≤156 cm)||552||3.20±0.55|
|3rd quartile (>156 cm and ≤ 160.4 cm)||551||3.24±0.61|
|4th quartile (>160.4 cm)||566||3.30±0.58*#|
Because we detected a modification of the effect of maternal BMI by stature in relation to LBW children, we stratified the analysis of factors influencing birth weight by maternal stature. Table 4 and 5 show the results from the univariate and multivariate analysis of factors associated with low birth weight stratified by maternal stature. Tables 4 and 5 correspond to the 1st and 4th quartiles of maternal stature, respectively.
|univariate analysis||multivariate analysis|
|Parameter||Low Birth Weight||LBW odds ratio||p-value||LBW odds ratio||p-value|
|Yes, N (%)||No, N (%)||(95% CI)||(95% CI)|
|<20||11 (21.2)||41 (78.8)||3.36 (1.60-7.08)||0.0014||3.05 (1.44-6.47)||0.003|
|≥20†||38 (7.4)||476 (92.6)|
|≤0.5 min. salary||11 (8.7)||115 (91.3)||1.01 (0.44-2.32)||0.978|
|>0.5 min salary†||38 (8.6)||402 (90.8)|
|Length of schooling, yr|
|<4||24 (10.5)||205 (89.5)||1.42 (0.75-2.69)||0.285|
|≥4†||18 (7.6)||218 (92.4)|
|Maternal Body Mass Index|
|Eutrophic†||32 (10.4)||276 (89.6)|
|Underweight||8 (23.5)||26 (76.5)||3.68 (1.57-8.67)||0.003||2.26 (0.92-5.95)||0.075|
|Overweight||6 (4.0)||144 (96.0)||0.36 (0.15-0.87)||0.023||0.38 (0.16-0.95)||0.037|
|Obese||3 (4.1)||71 (95.9)||0.41 (0.12-1.36)||0.143||0.39 (0.11-1.31)||0.125|
|univariate analysis||multivariate analysis|
|Parameter||Low Birth Weight||LBW odds ratio||p-value||LBW odds ratio||p-value|
|Yes, N (%)||No, N (%)||(95% CI)||(95% CI)|
|<20||8 (18.2)||36 (81.8)||1.82 (0.80-4.12)||0.151|
|≥20†||55 (10.9)||450 (89.1)|
|≤0.5 min. salary||27 (16.6)||136 (83.4)||1.81 (1.06-3.07)||0.028||1.88 (1.07-3.29)||0.027|
|>0.5 min salary†||39 (9.9)||355 (90.1)|
|Length of schooling, yr|
|<4||27 (11.2)||215 (88.8)||0.78 (0.44-1.37)||0.389|
|≥4†||28 (13.9)||174 (86.1)|
|Maternal Body Mass Index|
|Normal weight†||29 (10.9)||236 (89.1)|
|Underweight||7 (23.3)||23 (76.7)||2.41 (0.99-5.88)||0.052||2.85 (1.09-7.47)||0.032|
|Overweight||14 (8.7)||147 (91.3)||0.63 (0.34 1.17)||0.145||0.78 (0.38-1.61)||0.502|
|Obese||16 (15.8)||85 (84.2)||1.53 (0.83-2.81)||0.172||1.66 (0.84-3.25)||0.140|
In mothers of short stature (1st quartile), univariate analysis showed that younger age at childbirth and underweight were significantly associated with LBW (OR: 3.36 and 3.68, respectively), but overweight decreased the risk of giving birth to a child with LBW compared with normal BMI (OR: 0.36, 95% CI: 0.15-0.87) (Table 4). Multivariate analysis confirmed these results, as LBW remained associated with maternal age below 20 years (OR= 3.05, 95% CI: 1.44 - 6.47), although the effect of underweight was attenuated (OR: 2.26, 95% CI: 0.92-5.95). Overweight mothers had a significantly lower risk of LBW (OR: 0.38), and the same trend of decreased risk was observed in obese mothers, although this effect was not statistically significant.
The results for the mothers in the 4th stature quartile are presented in Table 5. The univariate analysis revealed that lower family income and being underweight were related to LBW (OR: 1.81 and 2.41, respectively), and obese, but not overweight, mothers showed a tendency towards increased risk of LBW. Age, family income, BMI, underweight, overweight and obesity were then included in the multivariate analysis. The results confirmed a significant association between both lower family income and underweight and LBW (OR: 1.88 and 2.85, respectively). The data from obese mothers demonstrated a similar trend, although not statistically significant, for increased risk of LBW (OR: 1.66, 95% CI: 0.84-3.25).
The causes of LBW are different in developing and developed countries. In developed countries, preterm birth is major cause of LBW, whereas in developing nations, most LBW newborns are born at term but are small for gestational age (SGA). Because it is relatively difficult to obtain accurate gestational age estimates in very low income communities, we used birth weight to compare the nutritional status of the mother to the birth conditions of the child. The prevalence of LBW (10%) in this study population from shantytowns around the state capital Maceió was 17.5% higher than that reported for the state of Alagoas (7.6%) and 15% higher than the average in Brazil (8.4%). The prevalence of LBW in Brazil has remained stable (approximately 8%) since 2000 despite an increase in the number of preterm births. One possible explanation for this stability is the reduction in the frequency of intrauterine growth retardation, which counterbalances the negative effects of increased premature births. The prevalence of LBW within Brazil is, however, somewhat perplexing in that the richer and more developed areas exhibit a higher prevalence of LBW than the less privileged regions. It has been suggested that this apparent paradox may result from inadequate recordkeeping and the lower survival rate of premature babies in the poorest municipalities. In isolated areas of the country, data such as gestational age, birth weight, number of home births and number of live births may be recorded incorrectly or not at all. Indeed, it is estimated that the frequency of underreporting of birth events in Brazil is approximately 7.2%[29,30].
Various studies have shown that poor families in different parts of the world have a greater risk for children with LBW than their more affluent counterparts[31-34]. A recent report from the United States confirmed that low income and income inequality exert a negative effect on birth weight. The present study corroborates these findings because family income was found to be inversely associated with LBW throughout the entire sample and for normal stature mothers in the 4th quartile (OR: 1.34, 95% CI: 0.99-1.81, P = 0.06 and adjusted OR: 1.88, 95% IC: 1.07-3.29, P = 0.027, respectively), although other factors were more relevant as determinants of LBW in short-statured mothers. In addition to being an extremely poor population, the average height of all mothers was low, 156 cm, which corresponds to the 15th percentile of the WHO reference for 19-year-old girls . For this reason, we divided the population into quartiles of stature and compared the lowest quartile to the highest quartile. A significant negative effect on the birth weight of children was observed when comparing mothers in the first and second quartiles of stature to those in the fourth quartile of stature.
No association between length of schooling and LBW could be established in the present study, most likely because the sample population was very homogeneous with respect to this variable. The mean length of schooling was 2.9 years, and more than 40% of the mothers had less than 4 years of education. However, the association between poor maternal education and LBW has been observed in developed and developing countries and is well described in the literature[8,36]. A study of 78,582 children from Rio de Janeiro, Brazil, concluded that both level of education and maternal age were strongly associated with LBW.
Along with the factors mentioned above, gender can also influence the fetal weight[38,39]. The results presented herein revealed that the risk of LBW was 46% higher in girls, a finding that agrees with those from previous studies conducted in the southern Brazilian state of Paraná and in Indonesia.
The results of the present study confirmed that young mothers (
< 20 years old) were 2.2 times more likely to give birth to children with LBW than their older counterparts when the entire sample was considered. This association became insignificant when mothers in the fourth quartile of stature were assessed, while younger short-statured mothers were 3.1 times more likely to give birth to LBW infants. This finding demonstrates a stronger likelihood of giving birth at an early age among short-statured mothers.
Maternal BMI is known to be a determining factor for fetal development in that both excess weight and weight deficiency can lead to adverse gestational outcomes[12,13,42]. A cohort study demonstrated that maternal underweight not only increased the risk of LBW but also the risk of premature births and neonatal mortality. Additionally, a study of more than 2 million children and 751,912 low- and medium-income mothers from 54 emerging countries found a direct relationship between short maternal stature and increased LBW, perinatal mortality and stature deficit in their children.
The present study confirmed a strong association between LBW and maternal underweight, regardless of stature, as underweight mothers were 2.43-fold more likely to have LBW offspring than the group as a whole. On the other hand, a marginal protective effect of overweight in mothers was found (OR; 0.72, 95% CI: 0.51-1.01, P = 0.060). As the effect of BMI appeared to be different in mothers of short and normal stature, we carried out an analysis stratified according to the 1st (short) and 4th (normal) stature quartiles. In short-statured mothers, age and underweight were associated with LBW; overweight mothers were protected (adjusted OR: 0.38, 95% CI: 0.16-0.95, P = 0.037) against having LBW children, and this tendency was also observed among obese mothers. Among mothers in the 4th stature quartile, income and underweight were the factors associated with LBW in the multivariate analysis; however, in this subgroup, being overweight or obese was not significantly associated with protection against LBW. Obese mothers showed a trend towards increased risk of LBW (OR: 1.66, 95% CI: 0.84-3.25, P = 0.14). These results show that, in addition to the association between LBW, maternal short stature and undernutrition that has been described in the literature, mothers who were overweight at the time of the study were less likely to have babies with LBW. We can speculate that in extreme poverty, overweight acts as a protective factor and ensures better health for the children of mothers with short stature. This finding is the opposite of those described for developed countries such as England and the United States, where overweight (BMI > 25 kg/m2) non-short mothers were observed to have a higher risk of adverse fetal and perinatal complications and infant death [44,45]. Among mothers with normal stature, the results of the present study, although not significant, indicated a higher risk of LBW in those with obesity at the time of the study. This finding is in line with the literature results concerning the harmful consequences of maternal obesity on fetuses and infants in developed countries[44,45] .
It is well known that adult short stature reflects health processes throughout life and is associated with nutritional stress during the early stages of life[8,9,46]. The biomechanical characteristics of mothers of short-stature must also be considered because this condition is associated with a narrower pelvis, which increases the likelihood of cephalopelvic disproportion and obstructed labor. Moreover, a short-statured mother may not be able to supply sufficient amounts of nutrients to the fetus, a situation that results in greater susceptibility to a negative gestational outcome. Within this context, overweight short-statured mothers have a surplus of energy and/or nutrients that may protect the fetuses.
The present study reports the effects of combined maternal short stature and overweight or obesity on the birth weight of children for the first time . The coexistence of stature deficit and excess weight is being observed at an increasingly early age in developing countries. A study conducted in 2001 established that the prevalence of overweight and obese women of short stature in poor communities of Alagoas was 30%, while a more recent investigation revealed that the phenomenon of stunting in combination with obesity had become prevalent in underprivileged children from the same area. In the present study, we observed that the frequency of overweight and obesity was 20% higher when combined with short stature (47.6%) than when combined with normal stature (39.5%).
Our study has several limitations: the lack of an assessment of other risk factors for low birth weight, such as smoking status and alcohol intake, parity, and other maternal and obstetric conditions; the inability to discriminate between at-term and premature children; and the cross-sectional study design that prevented us from establishing a clearer causal relationship between the mothers’ BMI and LBW. Mothers’ BMI was determined an average of 30 months following childbirth. We believe that it is unlikely that maternal BMI changed dramatically after childbirth, as the establishment of obesity, overweight or even undernutrition in adult, low-income women usually requires several years and is directly related to their long-term living conditions.
In conclusion, the most important finding of this study was that overweight short-statured mothers showed a significantly lower risk of LBW. Thus, overweight seemed to be a protective factor against LBW in extreme poverty conditions. In addition, younger mothers had a higher risk of LBW and the effect was stronger among those with short stature, as the effect was not significant among normal-stature mothers when analyzed alone. Income had a negative impact on birth weight only in the normal-statured mothers, while in short-statured mothers, the negative effects of low age and the protective effects of overweight remained the most important factors in the multivariate analysis. Our other results are agree with the literature, as maternal underweight, regardless of stature, was associated with LBW, and taller women (4th quartile) gave birth to significantly heavier babies compared those in the first and second quartile. Because this is a cross-sectional study, prospective studies are necessary to confirm the present findings.
Conceived and designed the experiments: ALS TMTF. Performed the experiments: RPAB. Analyzed the data: JCC ALS RS AABS. Contributed reagents/materials/analysis tools: RPAB JCC TMTF RS AABS ALS. Wrote the manuscript: RPAB. Participated in the collection and analysis of data: RPAB. Drafted the manuscript: RPAB. Performed the statistical analysis of the data: AABS RS. Interpreted the results: AABS RS. Helped with the statistical analysis of the data: JCC. Responsible for the study design and final revision of the paper: TMTF ALS.
- 1. Imdad A, Bhutta ZA (2013) Nutritional management of the low birth weight/preterm infant in community settings: a perspective from the developing world. J Pediatr 162: S107-S114. doi:10.1016/j.jpeds.2012.11.060. PubMed: 23445841.
- 2. WHO (2004) Low Birth Weight: Country, regional and global estimates In: The United Nations Children’s Fund and World Health Organization.
- 3. Liu L, Johnson HL, Cousens S, Perin J, Scott S et al. (2012) Global, regional, and national causes of child mortality: an updated systematic analysis for 2010 with time trends since 2000. Lancet 379: 2151-2161. doi:10.1016/S0140-6736(12)60560-1. PubMed: 22579125.
- 4. WHO (2012) Born too soon: The Global Action Report on Preterm Birth. March of Dimes, PMNCH, Save the Children, WHO. In: CP HowsonMV KinneyJE Lawn. World Health Organization. Geneva.
- 5. Kramer MS (1987) Determinants of low birth weight: methodological assessment and meta-analysis. Bull World Health Organ 65: 662-737. PubMed: 3322602.
- 6. WHO (1995) Maternal anthropometry and pregnancy outcomes: a WHO Collaborative Study. Bull World Health Organ 73 Suppl: 1-59.
- 7. Pandey M (2009) Maternal health and child mortality in rural India. Delhi: Institute of Economic Growth, University of Delhi Enclave . 23 pp. Available: . http://mpra.ub.unimuenchen.de/15934/1/MPRA_paper_15934.pdf . Accessed 5 August 2012.
- 8. Elshibly EM, Schmalisch G (2008) The effect of maternal anthropometric characteristics and social factors on gestational age and birth weight in Sudanese newborn infants. BMC Public Health 8: 244. doi:10.1186/1471-2458-8-244. PubMed: 18638377.
- 9. Ozaltin E, Hill K, Subramanian SV (2010) Association of maternal stature with offspring mortality, underweight, and stunting in low- to middle-income countries. JAMA 303: 1507-1516. doi:10.1001/jama.2010.450. PubMed: 20407060.
- 10. Han Z, Lutsiv O, Mulla S, McDonald SD (2012) Maternal height and the risk of preterm birth and low birth weight: a systematic review and meta-analyses. J Obstet Gynaecol Can 34: 721-746. PubMed: 22947405.
- 11. Black RE, Allen LH, Bhutta ZA, Caulfield LE, de Onis M et al. (2008) Maternal and child undernutrition: global and regional exposures and health consequences. Lancet 371: 243-260. doi:10.1016/S0140-6736(07)61690-0. PubMed: 18207566.
- 12. Heslehurst N, Rankin J, Wilkinson JR, Summerbell CD (2010) A nationally representative study of maternal obesity in England, UK: trends in incidence and demographic inequalities in 619 323 births, 1989-2007. Int J Obes (Lond) 34: 420-428. doi:10.1038/ijo.2009.250. PubMed: 20029373.
- 13. Han Z, Mulla S, Beyene J, Liao G, McDonald SD et al. (2011) Maternal underweight and the risk of preterm birth and low birth weight: a systematic review and meta-analyses. Int J Epidemiol 40: 65-101. doi:10.1093/ije/dyq195. PubMed: 21097954.
- 14. McDonald SD, Han Z, Mulla S, Beyene J, Group KS (2010) Overweight and obesity in mothers and risk of preterm birth and low birth weight infants: systematic review and meta-analyses. BMJ 341: c3428. doi: 10.1136/bmj.c3428
- 15. Baumann R, Abramo L, Bolduc K (2008) Emprego, Desenvolvimento Humano e Trabalho Decente: A Experiência Brasileira Recente. Brasília: Comissão Econônomica para a América Latina e o Caribe/ Programa das Nações Unidas para o Desenvolvimento/ Organização Internacional do Trabalho. Brasil. 176 pp.. Available: . http://www.cepal.org/brasil/noticias/noticias/3/34013/EmpregoDesenvHumanoTrabDecente.pdf . Accessed 7 August 2012.
- 16. IBGE (2010) Banco de Dados - Estado de Alagoas. Rio de Janeiro: IBGE. Available: . http://www.ibge.gov.br/estadosat/perfil.php?sigla=al. Accessed. 6 January 2012.
- 17. IPEA (2010) Dimensão, evolução e projeção da pobreza por região e por estado no Brasil. In: 58. Comunicados do IPEA n°58. Rio de Janeiro: IPEA. 14 pp. Available: . http://www.ipea.gov.br/portal/imagens/stories/PDFs/100713_comunicado58.pdf. Accessed 12 janeiro 2012.
- 18. IBGE (2010) Censo demográfico 2010. Aglomerados subnormais: primeiros resultados. Rio de Janeiro: IBGE. 259 pp. Available: http://www.ibge.gov.br/home/estatistica/populacao/censo2010/aglomerads_subnormais/agsn2010.pdf. Accessed 5 August 2012.
- 19. Britto RPA, Florêncio TMTM, Costa ACS, Pinheiro ME (2011) Baixa estatura, obesidade abdominal e fatores de risco cardiovascular em mulheres de baixa renda. Ver Bras Med 68: 277-285.
- 20. Florêncio TM, Ferreira HS, de França AP, Cavalcante JC, Sawaya AL (2001) Obesity and undernutrition in a very-low-income population in the city of Maceió, northeastern Brazil. Br J Nutr 86: 277-284. doi:10.1079/BJN2001396. PubMed: 11502242.
- 21. WHO (2007) Growth reference data for 5-19 years. Available: http://www.who.int/growthref/en/. Accessed July 2013.
- 22. Florêncio TT, Ferreira HS, Cavalcante JC, Sawaya AL (2004) Short stature, obesity and arterial hypertension in a very low income population in North-Eastern Brazil. Nutr Metab Cardiovasc Dis 14: 26-33. doi:10.1016/S0939-4753(04)80044-9. PubMed: 15053161.
- 23. Florêncio TT, Ferreira HS, Cavalcante JC, Stux GR, Sawaya AL (2007) Short stature, abdominal obesity, insulin resistance and alterations in lipid profile in very low-income women living in Maceió, north-eastern Brazil. Eur J Cardiovasc Prev Rehabil 14: 346-348. doi:10.1097/01.hjr.0b013e328010f24d. PubMed: 17446818.
- 24. WHO (2006) Child growth standards. Geneva: WHO. Available: http://who.int/childgrowth/en. Accessed 9 June 2011.
- 25. WHO (2011). HO Anthro (version 3.2.2, January 2011) and macros Geneva: WHO. Available: http://www.who.int/childgrowth/software/en/.Accessed 9 June 2011.
- 26. Goplan C (1995) LBWs: Significance and implications. In: editors. Nutrition in Children: developing country concerns. New Delhi: Department of Pediatrics. pp. 1-33.
- 27. da Sáude Ministério. de Saúde Indicadores. Indicadores e dados básicos. 2010ndicadores de fatores de risco e de proteção: Brasília: Ministério da Saúde, DATASUS. Available: . http;//tabnet.datasus.gov.br/cgi/tabcgi.exe?idb2010/g16.def. Accessed. 10 December 2011.
- 28. Victora CG, Aquino EM, do Carmo Leal M, Monteiro CA, Barros FC et al. (2011) Maternal and child health in Brazil: progress and challenges. Lancet 377: 1863-1876. doi:10.1016/S0140-6736(11)60138-4. PubMed: 21561656.
- 29. Blanc AK, Wardlaw T (2005) Monitoring low birth weight: an evaluation of international estimates and an updated estimation procedure. Bull World Health Organ 83: 178-185. PubMed: 15798841.
- 30. Andrade CL, Szwarcwald CL, Castilho EA (2008) [Low birth weight in Brazil according to live birth data from the Ministry of Health, 2005]. Cad Saude Publica 24: 2564-2572. doi:10.1590/S0102-311X2008001100011. PubMed: 19009136.
- 31. Walton E (2009) Residential segregation and birth weight among racial and ethnic minorities in the United States. J Health Soc Behav 50: 427-442. doi:10.1177/002214650905000404. PubMed: 20099449.
- 32. Walker SP, Wachs TD, Gardner JM, Lozoff B, Wasserman GA et al. (2007) Child development: risk factors for adverse outcomes in developing countries. Lancet 369: 145-157. doi:10.1016/S0140-6736(07)60076-2. PubMed: 17223478.
- 33. Dibben C, Sigala M, Macfarlane A (2006) Area deprivation, individual factors and low birth weight in England: is there evidence of an "area effect"? J Epidemiol Community Health 60: 1053-1059. doi:10.1136/jech.2005.042853. PubMed: 17108301.
- 34. Colen CG, Geronimus AT, Bound J, James SA (2006) Maternal upward socioeconomic mobility and black-white disparities in infant birthweight. Am J Public Health 96: 2032-2039. doi:10.2105/AJPH.2005.076547. PubMed: 17018818.
- 35. Olson ME, Diekema D, Elliott BA, Renier CM (2010) Impact of income and income inequality on infant health outcomes in the United States. Pediatrics 126: 1165-1173. doi:10.1542/peds.2009-3378. PubMed: 21078730.
- 36. Joseph KS, Fahey J, Platt RW, Liston RM, Lee SK et al. (2009) An outcome-based approach for the creation of fetal growth standards: do singletons and twins need separate standards? Am J Epidemiol 169: 616-624. PubMed: 19126584.
- 37. Barbas DdS, Costa AJL, Luiz RR, Kale PL (2009) Determinantes do peso insuficiente e do baixo peso ao nascer na cidade do Rio de Janeiro, Brasil, 2001. Epidemiol Serv Saúde. doi: 10.5123/s1679-49742009000200007
- 38. Saenger P, Czernichow P, Hughes I, Reiter EO (2007) Small for gestational age: short stature and beyond. Endocr Rev 28: 219-251. PubMed: 17322454.
- 39. Bryan SM, Hindmarsh PC (2006) Normal and abnormal fetal growth. Horm Res 65 Suppl 3: 19-27. doi:10.1159/000091502. PubMed: 16612110.
- 40. Uchimura TT, Pelissari DM, Uchimura NS (2008) [Low birth weight and associated factors]. Rev Gaucha Enferm 29: 33-38. PubMed: 18767358.
- 41. Sebayang SK, Dibley MJ, Kelly PJ, Shankar AV, Shankar AH et al. (2012) Determinants of low birthweight, small-for-gestational-age and preterm birth in Lombok, Indonesia: analyses of the birthweight cohort of the SUMMIT trial. Trop Med Int Health 17: 938-950. doi:10.1111/j.1365-3156.2012.03039.x. PubMed: 22943372.
- 42. Nohr EA, Vaeth M, Baker JL, Sørensen TIa, Olsen J et al. (2008) Combined associations of prepregnancy body mass index and gestational weight gain with the outcome of pregnancy. Am J Clin Nutr 87: 1750-1759. PubMed: 18541565.
- 43. Kalk P, Guthmann F, Krause K, Relle K, Godes M et al. (2009) Impact of maternal body mass index on neonatal outcome. Eur J Med Res 14: 216-222. doi:10.1186/2047-783X-14-S4-216. PubMed: 19541579.
- 44. Tennant PW, Rankin J, Bell R (2011) Maternal body mass index and the risk of fetal and infant death: a cohort study from the North of England. Hum Reprod 26: 1501-1511. doi:10.1093/humrep/der052. PubMed: 21467206.
- 45. Vasudevan C, Renfrew M, McGuire W (2011) Fetal and perinatal consequences of maternal obesity. Arch Dis Child Fetal Neonatal Ed 96: F378-F382 doi:10.1136/adc.2009.170928. PubMed: 20530101.
- 46. Kuh D, Wadsworth M (1989) Parental height: childhood environment and subsequent adult height in a national birth cohort. Int J Epidemiol 18: 663-668. doi:10.1093/ije/18.3.663. PubMed: 2807671.
- 47. Ferreira HaS, Luciano SC (2010) Prevalence of extreme anthropometric measurements in children from Alagoas, Northeastern Brazil. Rev Saude Publica 44: 377-380. doi:10.1590/S0034-89102010005000001. PubMed: 20339640.