Skip to main content
PMC home page
BMC Public Health logoLink to BMC Public Health
. 2013 Nov 28;13:1098. doi: 10.1186/1471-2458-13-1098

Nutritional status of children under 5 years of age in the Brazilian Western Amazon before and after the Interoceanic highway paving: a population-based study

Alanderson A Ramalho 1, Saulo AS Mantovani 1, Breno M Delfino 1, Thasciany M Pereira 1, Antonio C Martins 1, Humberto Oliart-Guzmán 1, Athos M Brãna 1, Fernando LCC Branco 1, Rhanderson G Campos 1, Andréia S Guimarães 1, Thiago S Araújo 1, Cristieli SM Oliveira 1, Cláudia T Codeço 2, Pascoal T Muniz 1, Mônica da Silva-Nunes 1,
PMCID: PMC4219516  PMID: 24283293

Abstract

Background

The aim of this study was to analyse the prevalence of undernutrition, overweight and associated factors, before and after the implementation of the Interoceanic Highway.

Methods

A population-based cross-sectional study on children under 5 years of age was conducted in the municipality of Assis Brasil, AC, Brazil, in 2003 and 2010. Prevalence of undernutrition was observed by using height-for-age Z-scores (HAZ) and adopting a cut-off point equal to or lower than a -2 Z-score. Overweight prevalence was defined by a cut-off point equal to or greater than a +2 Z-score of the WHZ index. Z-scores were calculated relative to WHO 2006 reference data. Semi-structured questionnaires were applied to the children’s guardians, investigating family socio-economic and demographic characteristics, morbidities, access to services and child care. Associated factors were identified by hierarchical multiple logistic regression analysis.

Results

The prevalence of low HAZ (undernutrition) was 7.0% in 2003 and 12.2% in 2010. The prevalence of high WHZ (overweight) was 1.0% and 6.6% for 2003 and 2010, respectively. It was not possible to adjust the multiple model for the year 2003. The factors associated with low HAZ in 2010 were: wealth index, the situation of living with biological parents, maternal height and presence of open sewage, whereas the factors associated with a high WHZ in the same year were: child’s age, mother’s time of residence in the location, mother’s body mass index.

Conclusions

Overweight increase within this undernutrition scenario reveals that the process of nutritional transition began in this Amazonian city only in the last decade, and therefore, it is delayed when compared to overweight in other parts of Brazil. Such nutritional transition in Assis Brasil may have been facilitated by the construction of the Interoceanic Highway.

Background

The period between weaning and the age of five is nutritionally regarded as the most vulnerable period of the life cycle because that is when rapid growth, loss of passive immunity and the development of the immune system against infection occur [1,2]. Additionally, environmental changes can also affect child nutrition. Thus, monitoring the nutritional status of children is a fundamental instrument for measuring the population’s health [3].

In recent decades, Brazil has recorded a decline in child malnutrition and an increase in overweight [3,4]; however, there are significant regional disparities. In the Northern region of Brazil, where the state of Acre is located, the prevalence of low height-for-age (HAZ) and high weight-for-height (WHZ) have been 14.8% and 6.2%, respectively [5] whereas the national rates for such prevalence are 6.7% low HAZ and 7.3% high WHZ.

An important characteristic that may explain this difference is the geographic isolation that the inhabitants of the Amazon region are exposed to due to the lack of roads. In the state of Acre, there are still several municipalities that have no road access and can be reached only by air or water. To reverse this geographic isolation, several roads have been built in the Amazon region, and in 2001, the Interoceanic Road began to be paved, linking Brazil, Peru and Bolivia, with an estimated cost of US$ 810 million [6].

Until 2000, the state of Acre had only one paved road, and the transit of people and food between some cities could take up to one week. This was the case of the municipality of Assis Brasil, which was subject to geographic isolation. With the construction of the Interoceanic Highway between 2001 and 2003, this situation began to change, and physical access to this city from the capital changed from 7 days to 4 hours.

In January 2003, while there were still twenty kilometres of unpaved road in the Interoceanic Highway in the Brazilian perimeter, we performed a nutritional assessment of the children’s population under 5 years of age in the urban area of Assis Brasil aiming to determine the prevalence of malnutrition in an isolated Amazonian population [7]. Seven years after the completion of paving of this international road, we reassessed the prevalence of malnutrition undernutrition and overweight) in this city in order to evaluate a possible relationship between changes in geographic isolation and factors associated with malnutrition.

Methods

Study area

Assis Brasil is located in the Acre River Valley, and it is 344 miles southwest of Rio Branco, the capital of Acre state (Figure 1). It occupies an area of 4,974 km2, and it borders the municipality of Brasileia to the east, the cities of Iñapari (Peru) and Bolpebra (Bolivia) to the south, and the municipality of Sena Madureira to the north.

Figure 1.

Figure 1

Open in a new tab

Map showing the location of Brazil, the Amazon, Acre state and the municipality of Assis Brasil. The map inside the box shows the Interoceanic Highway connecting Brazil to the Pacific Ocean.

In 2000, Assis Brasil had a total population of 3,264 people (1,708 males and 1,556 females). Of these, 13.39% were aged 0–4 years. For the year 2003, the population was estimated in 3,668 residents. In 2010, the total population increased to 6,017, (3,057 males and 2,960 females), of whom 12.76% were aged 0 to 4 years [8].

Study design and population

The population investigated consisted of a census with 200 children under 5 years of age living in the urban areas of Assis Brasil, state of Acre, Brazil, in 2003 and 388 children in 2010. These children were located by using the census records of the only Public Health Unit, which included all children at this age living in the urban area. The presence of diseases that would make anthropometric measurement impossible was the exclusion criterion.

Data collection occurred in January and February 2003 and 2010 by means of semi-structured questionnaires and in order to investigate socio-economic characteristics, environmental characteristics, maternal and paternal characteristics, gestational characteristics, child access to services and care, characteristics of childbirth and breastfeeding, self-reported morbidities; diagnosis of anaemia; diagnosis of intestinal parasites.

Both in 2003 and 2010, data about family and the family head’s income were collected. However, this information was unsuitable for analysis due to several reasons (inconsistent income due to temporary jobs, refusal to inform about income or unknown incomes of all family members and incomes in the form of goods instead of money). Therefore, we chose to design a household wealth index, as validated by Filmer and Pritchett for urban areas [9], which is described in the statistical section.

A digital pediatric scale (Soehnle®) with accuracy of 10 g and a maximum capacity of 16 kg was used for the measurement of body weight of children under 2 years. For children over 2 years, we used a portable digital scale (Plenna®) with precision of 100 g and maximum capacity of 150 kg. The length of children under 2 years was obtained by a portable infantometer with accuracy of 0.1 cm placed on a flat surface. The height of children over 2 years was measured by using a wooden stadiometer with accuracy of 0.1 cm fixed to a wall without skirting boards at an angle of 90° to the ground. All anthropometric measurements were performed in duplicate. When the two measurements were discrepant, a third measurement was taken, and the two closest were selected. For analysis, the mean value of duplicates generated indicators in the form of height-for-age (HAZ) and weight-for-height (WHZ) Z-scores. Values from the World Health Organisation [10] were used as a reference and calculated by using WHO Anthro software v.3.2.2 (Department of Nutrition, WHO, Geneva). The cut-off points were: for undernutrition ≤ -2 HAZ and for overweight ≥ +2 WHZ [11]. Extreme values below -6 Z-score and above +6 Z-score were excluded from the analyses. The same routine applied for children over 2 years was used for measuring the mothers’ weight and height; the body mass index value established by the World Health Organisation was used as reference [12]. In 2003, one child was excluded from the research for presenting values below -6 Z-score for the anthropometric indices evaluated, and in 2010, 10 children did not complete anthropometric examination.

Both the interviews and the anthropometric examination were performed by the authors. In 2003, MdaSN and TSA conducted the interviews; a nutritionist (PTM) trained a nurse (TSA) and both performed the anthropometric evaluation. In 2010, new interviewers (medical students listed as authors) trained by MdaSN and TSA conducted the interviews, and two nutritionists (AAR and PTM) and two medical students (trained by AAR, PTM and TSA) performed the anthropometric evaluations.

Statistical analysis

The socio-economic index was obtained by Principal Component Analysis (PCA), using the XLSTAT software, version 7.5.2 (Addinsoft, New York, NY) and parameters Covariance (n-1) and Correlation biplot/Coefficient = n, as described by Filmer and Pritchett [9]. The household wealth index was created based on the presence of twenty-one consumer goods and household appliances (television set, music system, DVD player, gas stove, refrigerator, washing machine, telephone, bicycle, blender, electric iron, car, sofa, satellite dish, mobile phone, motorcycle, computer, boat, motor boat, water well, power generator and microwave oven) as described in previous publications/studies [7,9,13]. The Jolliffe method adapted for the covariance matrix [14] was used to exclude unimportant variables. For 2003, only five variables remained in the analysis, and for 2010 thirteen variables were maintained in the score. The first principal component explained 61.11% of total variance in 2003 and 30.06% of total variance in 2010. The scores for each variable were added to estimate the household wealth index, which was stratified in two groups (the poorer half and the richer half). For each year, this procedure was performed for all children versus only one child per household in order to check for non-independence of individual information. The comparison of the indices calculated by each technique showed no statistical differences, thus we opted to use the index per household instead of the index per child.

Exploratory analysis. A database was created with SPSS 13.0 software (SPSS Inc., Chicago, IL). The distribution of the independent variables was identified by using the Kolmogorov-Smirnov test. Student’s T test was used to compare means, and the chi-square test was utilized to compare frequencies or proportions with α = 0.05 as the critical level for years 2003 and 2010. Exploratory univariate logistic regression analysis, using the R software version 2.14.0 (The R Foundation for Statistical Computing), examined potential risk factors and confounders, including categorical individual-level variables, continuous individual level variables, categorical household-level variables and continuous household-level variables for 2003 and 2010.

The factors associated with undernutrition and high overweight were identified by hierarchical multiple logistic regression analysis using the conceptual model (Table 1) and adapted procedures from previous studies [15-17]. Separate multiple logistic regression models for the year 2010 were fitted to individual- and household-level variables using manual inclusion and following from distal to proximal blocks of variables. Covariates were maintained in subsequent multivariate models, together with the a-priori potential confounders (age and gender), if they were associated with the outcome, in exploratory unadjusted analysis, at a level of significance of 20%, in each block. It was not possible to adjust the multiple model for 2003, and for this year, we presented the results of the univariate analyses only.

Table 1.

Conceptual model for hierarchical analysis of factors associated with overweight and malnutrition

Distal Block 1: Environmental and socio-economic
 
 Socio-economic variables
Wealth index
Household type
House floor type
Home ownership
Receipt of benefits
Food production for own consumption
Environmental Variables
Waste collection
Presence of open sewage
Presence of electric power supply
 
 Water well or drinking water treatment Toilet type
Intermediate
 Block 2: Maternal and paternal characteristics
Age
Gender
Marital status
Skin colour
Schooling
Paid work
Smoking
Consumption of alcoholic beverages
Time living in the municipality
Maternal height
Maternal body mass index
Block 3: Gestational characteristics
Number of pregnancies
Pre-natal care
Morbidity during pregnancy
Block 4: Access to services and child care
Living with biological parents
Attending nursery or school
 
 Monitoring through health care service
Proximal
 Block 5: Characteristics of child birth and breastfeeding
Birth weight
Duration of exclusive breastfeeding
Duration of total breastfeeding
Block 6: Morbidity
Self-reported morbidities
Hospitalisation at least once in life
Diagnosis of anaemia
  Diagnosis of intestinal parasites
Open in a new tab

Adapted from UNICEF [20].

The goodness of fit was assessed by analysis of variance, Akaike’s information criterion (AIC) values or odds ratio (OR) changes. The existence of significant interaction terms was evaluated and none was found. Diagnostic tests were applied to identify outliers, using the R 2.14.0 software package. No outliers (important influential points) were identified for any of the variables included in the final model.

Additional analyses were performed using the exact logistic regression package erlm in order to approximate exact conditional inference for logistic regression models presenting a small number of events (less than 30 events) [18]. We also used mixed the effects of logistic regression (MASS library of R program) to explore the association between individual and household-level covariates and the occurrence of undernutrition and overweight, taking into account the nested structure of the data (some of the children shared the same household). Results were very similar to those obtained with the previous generalised linear model with fixed effects only. Both models resulted in similar OR estimates and similar confidence intervals to those shown by the logistic regression model described earlier, and therefore, results are not presented.

Ethical considerations

The study was approved by the Ethics Committee for Experimentation with Human Beings at the University of São Paulo (810/2002) and the Federal University of Acre (23107.014335/2009-69). Informed consent was obtained from each participant’s legal guardian.

Results

Comparison of the city before and after the construction of the Interoceanic Road

Between 2003 and 2010, some important economic, social and demographic changes occurred in the city. There was an increase in the number of elementary schools and teachers, and a new university campus was opened. For the first time, the city received offices of several public and private agencies, such Banco do Brasil, the Federal Police, the Federal Revenue Agency, the National Health Surveillance Agency, the Reference Center for Social Security and a Prosecutor’s Office. A new Basic Health Unit for the rural area was implemented in 2006. Between 2005 and 2010 new health care services started to be offered for free, such as screening for metabolic diseases and monitoring of hypertension and diabetes, besides the programs already in place in the county since 2003.

Parental and children’s socio-economic characteristics in 2003 and 2010

Table 2 shows the distribution of children studied by year of the population census, according to family socio-demographic and economic characteristics. The population distribution by gender and age were similar in both periods. Females accounted for 47% of children in 2003 and 50.8% in 2010 (p = 0.386). The average age was 2.43 years in 2003 and 2.43 years in 2010 (SD 2003: 1.37, SD 2010: 1.47, t-test: 0.997).

Table 2.

Distribution of children (%) under 5 years according to socio-demographic and economic characteristics

 
 2003
 2010
  
 
 (n = 200)
 (n = 388)
  
Variables N* % N* % p-value**
Gender
 
  
  
  
  
 Male
 94
 47.0%
 197
 50.8%
 0.386
 Female
 106
 53.0%
 191
 49.2%
Age
 
  
  
  
  
 Under 1 year
 35
 17.5%
 81
 20.9%
 0.499
 From 1 to 2 years
 45
 22.5%
 86
 22.2%
 From 2 to 3 years
 42
 21.0%
 60
 15.5%
 From 3 to 4 years
 43
 21.5%
 86
 22.2%
 From 4 to 5 years
 35
 17.5%
 75
 19.3%
Predominant material in the house floor
 
  
  
  
  
 Cement, brick, ceramic tile, slab-stone
 32
 16.0%
 112
 28.9%
 0.001
 Wood or soil
 168
 84.0%
 275
 71.1%
Electric power supply at home
 
  
  
  
  
 Lacking
 22
 11.0%
 12
 3.1%
 < 0.001
 Present
 178
 89.0%
 376
 96.9%
Drinking water treatment
 
  
  
  
  
 Without treatment; lack of mineral water
 65
 32.5%
 135
 34.8%
 < 0.001
 Mineral water without treatment
 15
 7.5%
 131
 33.8%
 Boiled, strained or filtered
 84
 42.0%
 84
 21.6%
 Chlorinated
 36
 18.0%
 38
 9.8%
Waste disposal
 
  
  
  
  
 Council collection
 179
 89.5%
 370
 95.4%
 0.024
 Buried or burned
 8
 4.0%
 8
 2.1%
 Dumped in land or river
 13
 6.5%
 10
 2.6%
Open sewage
 
  
  
  
  
 Lacking
 161
 80.9%
 235
 60.6%
 < 0.001
 Present
 38
 19.1%
 153
 39.4%
Sanitary installation
 
  
  
  
  
 Toilet (with running water)
 31
 15.5%
 242
 62.4%
 < 0.001
 Pit toilet
 128
 64.0%
 110
 28.4%
 Lacking sanitary installations
 41
 20.5%
 36
 9.3%
Production of food for own consumption
 
  
  
  
  
 No
 84
 71.8%
 177
 45.6%
 < 0.001
 Yes 33 28.2% 211 54.4%  
Open in a new tab

Assis Brasil, AC, 2003 and 2010.

*Missing in some variables **Person’s chi-square test.

By comparing the periods, it is observed that there was an increase in the use of cement, bricks, ceramic tiles or stone-slab as the predominant materials for house floor finishing (16% to 28.9%, p <0.001); the presence of electric power supply at home (89% to 96.9%, p <0.001); the acquisition of mineral water (7.5% to 33.8%, p <0.001) and consequent decrease in drinking water treatment. An increase in open sewage systems (19.1% to 39.4%, p <0.001), the number of sanitary facilities with running water (15.5% to 62.4%, p <0.001), food production for household consumption (28.2% to 54.4%, p <0.001) and household waste collection by the public system (89.5% to 95.4%, p = 0.024) was also observed. No difference household type was observed (p = 0.138).

Table 3 illustrates the distribution of children younger than 5 years, according to parental characteristics in the years 2003 and 2010. By comparing these periods, a rise in parental schooling above 8 years of school attendance (father: 42.9% to 66.2%, p <0.001 and mother: 40.2% to 49.6%, p <0.001), father’s paid work in the last 30 days (91.1% to 63.1%, p <0.001), maternal overweight (26.9% to 47.3%, p <0.001) and mother’s average age (26 to 28 years, p = 0.005) was observed. There was no statistically significant difference for years 2003 and 2010 as regards average maternal height (about 159 cm, p = 0.916), maternal marital status (p = 0.627) or mother’s paid work in the last 30 days (p = 0.094). In 2010, the median length of maternal residency in the community was 15 years (minimum 2 weeks, maximum78 years), and 58.5% of the mothers had been living in the city for longer than 7 years. This information was not obtained for the year 2003.

Table 3.

Distribution of children (%) under 5 years according to paternal characteristics

 
 2003
 2010
  
 
 (n = 200)
 (n = 388)
  
Categorical variables
 N*
 %
 N*
 %
 p-value**
Continuous variables #   Mean(SD)   Mean(SD)  
Father’s schooling (years)
 
  
  
  
  
 Did not go to school
 15
 8.2%
 -
 -
 < 0.001 '
 1 to 4 years inclusive
 50
 27.5%
 70
 20.1%
 5 to 8 years inclusive
 39
 21.4%
 48
 13.8%
More than 8 years
 78
 42.9%
 231
 66.2%
Father’s paid work in the last 30 days
 
  
  
 No
 17
 8.9%
 81
 20.9%
 < 0.001
 Yes
 173
 91.1%
 245
 63.1%
Maternal marital situation
 
  
  
  
  
 Lack of a partner
 26
 22.2%
 93
 24.4%
 0.627
 Presence of a partner
 91
 77.8%
 288
 75.6%
Maternal schooling(years)
 
  
  
  
  
 Did not go to school
 8
 6.8%
 -
 -
 < 0.001 '
 1 to 4 years inclusive
 27
 23.1%
 88
 25.2%
 5 to 8 years inclusive
 35
 29.9%
 88
 25.2%
 More than 8 years
 47
 40.2%
 173
 49.6%
Mother’s paid work in the last 30 days
 
  
  
 No
 67
 59.3%
 259
 67.8%
 0.094
 Yes
 46
 40.7%
 123
 32.2%
Maternal age #
 
  
  
  
  
 Average (years)
 183
 26.21 (7.64)
 378
 28.43 (9.33)
 0.005
Maternal height #
 
  
  
  
  
 Average (cm)
 187
 158.5 (5.29)
 350
 158.8 (39.63)
 0.916
Maternal BMI
 
  
  
  
  
 Below 25 kg/m2
 128
 73.1%
 184
 52.7%
 < 0.001
 Equal or above 25 kg/m2
 47
 26.9%
 165
 47.3%
Maternal time of residence in the urban area
 
  
  
  
  
 Less than 1 year
 -
 43
 11.1%
 -
 Between 1 and 7 years
 107
 27.6%
 7 years or more   227 58.5%  
Open in a new tab

Assis Brasil, AC, 2003 and 2010.

*Missing in some variables.

**p-values without a mark ( ): Pearson’s chi-square test; with a mark ( ' ): Fisher's exact test.

#Continuous variables.

Table 4 shows the characteristics of children under 5 years of age in the two studied years, according to individual socio-demographic, birth and breastfeeding characteristics, and morbidities. When comparing results for 2003 and 2010, there was no significant difference in delivery type (p = 0.065), low birth weight (p = 0.085), breastfeeding at birth (p = 0.158), duration of exclusive breastfeeding (p = 0.123) and the situation of living with biological parents (p = 0.501). However a reduction in the number of diarrhoea cases in the last 15 days (34.5% to 18.2%, p <0.001) and an increased number of children hospitalized at least once in life were observed (19.3% for 37.2%, p <0.001).

Table 4.

Distribution of children (%) under 5 years according to socio-demographic, birth and breastfeeding characteristics, and morbidities

 
 2003
 2010
  
 
 (n = 200)
 (n = 388)
  
Categorical variables N* % N* % p-value**
Living with biological parents
 
  
  
  
  
 Living with biological mother and father
 139
 69.5%
 259
 66.8%
 0.501
 Living with only one biological parent or neither one
 61
 30.5%
 129
 33.2%
Delivery type
 
  
  
  
  
 Natural
 146
 86.4%
 292
 79.8%
 0.065
 C-section
 23
 13.6%
 74
 20.2%
Birth weight
 
  
  
  
  
 Above 2,500 g
 166
 94.9%
 305
 90.5%
 0.085
 Below or equal to 2,500 g
 9
 5.1%
 32
 9.5%
Breastfeeding at birth
 
  
  
  
  
 Lacking
 11
 5.6%
 12
 3.2%
 0.158
 Present
 184
 94.4%
 364
 96.8%
Duration of exclusive breastfeeding †
 
  
  
  
 More than 30 days
 114
 64.0%
 159
 56.8%
 0.123
 Equal to or less than 30 days
 64
 36.0%
 121
 43.2%
Diarrhoea in the last 15 days
 
  
  
  
  
 Lacking
 131
 65.5%
 315
 81.8%
 < 0.001
 Present
 69
 34.5%
 70
 18.2%
Hospitalisation at least once in life
 
  
  
  
  
 No
 159
 80.7%
 243
 62.8%
 < 0.001
 Yes
 38
 19.3%
 144
 37.2%
Anaemia diagnosis
 
  
  
  
  
 No
 69
 49.6%
 252
 72.2%
 < 0.001
 Yes
 70
 50.4%
 97
 27.8%
Parasitosis diagnosis
 
  
  
  
  
 No
 110
 68.3%
 207
 62.3%
 0.194
 Yes
 51
 31.7%
 125
 37.7%
Has lived in rural or riverine area before
 
  
  
  
  
 No
 197
 98.5%
 363
 93.6%
 0.007′
 Yes
 3
 1.5%
 25
 6.4%
Child length of time living in the urban area
 
  
  
  
  
 Since birth
 181
 90.5%
 311
 80.2%
 0.001
 After birth 19 9.5% 77 19.8%  
Open in a new tab

Assis Brasil, AC, 2003 and 2010.

*Missing in some variables.

**p-values without a mark ( ): Pearson’s chi-square test; with a mark ( ' ): Fisher's exact test.

Excluding children that were only breastfed.

The percentage of children that had lived in rural or riverine areas prior to moving to the urban area increased (1.50% to 6.40%, p = 0.007). As this may suggest a migration movement from rural and riverine areas to the urban area of Assis Brasil, the study population was further stratified according to place of residence at birth (urban or not urban). For the year 2003, there were no significant differences. In 2010, children that had lived outside the urban area prior to the study showed some worsened socio-economic features, such as more houses with a wooden floor (p = 0.024), lack of electric power in the house (p = 0.001); suboptimal drinking water treatment (p = 0.006) and lower maternal schooling (p = 0.043).

Prevalence of anthropometric extremes

Table 5 shows the prevalence of anthropometric indicators of undernutrition and overweight for children under 5 years, according to the studied years. By comparing the two periods, significant differences in high WHZ were observed. The prevalence of high WHZ increased (1.0% to 6.6%, p = 0.002), but there were there was no difference in the prevalence of low HAZ (7% to 12.2%, p = 0.055).

Table 5.

Prevalence (%) of anthropometric indicators of children under 5 years

 
 2003
 2010
  
 
 (n = 199)
 (n = 378)
  
Indicators n % n % p-value*
Low height-for-age (stunting)
 
  
  
  
  
 No
 185
 93.0%
 332
 87.8%
 0.055
 Yes
 14
 7.0%
 46
 12.2%
High weight-for-height (overweight)
 
  
  
  
  
 No
 197
 99.0%
 353
 93.4%
 0.002'
 Yes 2 1.0% 25 6.6%  
Open in a new tab

Assis Brasil, AC, 2003 and 2010.

*p-values without a mark ( ): Pearson’s chi-square test; with a mark ( ' ): Fisher's exact test.

Due to socio-economic differences according to the time when the children had been living in the municipality, the prevalence of anthropometric indicators was also stratified by this variable. For the year 2003 no significant differences were identified. In 2010, about 23.3% of the children who had not been living in the urban area since birth showed a height-for-age deficit (p = 0.002).

Undernutrition

Table 6 shows the prevalence and factors associated with undernutrition in 2003 by univariate logistic regression. Table 7 shows the factors associated with undernutrition in the studied population in 2010 obtained by hierarchical multiple analysis. From the first block, variables wealth index (poorer half, OR: 5.87; CI 95%: 2.33 to 14.76) and open sewage (OR: 2.27; CI 95%: 1.08 to 4.72) remained in the model. From the second block, only maternal height (lower half, OR: 3.53, CI 95%: 1.58 to 7.86) remained associated with undernutrition. In the fourth block, only variable living with biological parents remained in the model (living with only one parent or none, OR: 2.27, CI 95%: 1.08 to 4.76). No variables from the third, fifth and sixth blocks remained in the model. No concomitant morbidities remained in the final model. The gender and age variables were used in the model as controls. Results from a separate model stratified by place of birth (urban x rural) showed similar results to those in the main model, suggesting that although the prevalence of undernutrition in children that had lived part of their lives outside the urban area of the city was high, all other factors associated with undernutrition remained the same.

Table 6.

Prevalence (%) and Odds Ratio (OR) of low height-for-age in children under 5 years according to socio-demographic and economic characteristics, 2003

Categorical variables
 N* (n = 199)
 %
 Crude
 p value**
Continuous variables #   Mean(SD) OR  
Home ownership
 
  
  
  
 Own home (fully owned or mortgaged)
 162
 4.9%
 1
 0.027
 Rented, gifted or invaded
 37
 16.2%
 3.726
Electric power supply
 
  
  
  
 Lacking
 22
 22.7%
 1
 0.011 '
 Present
 177
 5.1%
 0.182
Wealth index
 
  
  
  
 Richer half
 104
 1.9%
 1
 0.004 '
 Poorer half
 95
 12.6%
 7.373
Mother schooling (years)
 
  
  
  
 Did not go to school
 8
 37.5%
 1
 < 0.001
 1 to 4 years
 27
 7.4%
 0.013
 Above 4 years
 81
 1.2%
 0.002
p linear tendency
  
  
  
 0.003
Maternal height (cm) #
186
 158.5 (5.29)
 0.855
 0.01
Number of pregnancies #
113
 2.63 (2.21)
 1.35
 0.018
Anaemia diagnosis
 
  
  
  
 No
 69
 49.64%
 1
 0.176
 Yes 70 50.36% 3.09  
Open in a new tab

Assis Brasil, AC, 2003.

*Missing in some variables.

**p-values without a mark ( ): Pearson’s chi-square test; with a mark ( ' ): Fisher's exact test.

Table 7.

Factors associated with a low height-for-age in children under 5 years obtained by hierarchical multiple analysis, 2010

Variables Crude OR p value** Adjusted OR* (CI 95%) p value**
Wealth index
 
  
  
  
  
 Richer half
 1
  
 1
  
  
 Poorer half
 7.2
 < 0.001
 5.87
 (2.33 – 14.76)
 < 0.001
Open sewage
 
  
  
  
  
 Lacking
 1
  
 1
  
  
 Present
 2.82
 0.001
 2.27
 (1.08 – 4.72)
 0.029
Living with biological parents
 
  
  
  
  
 Living with biological father and mother
 1
  
 1
  
  
 Living with one biological parent or neither one
 2.56
 0.004
 2.27
 (1.08 – 4.76)
 0.031
Maternal height (cm)
 
  
  
  
  
 Taller half (156.5 to 178.5)
 1
  
 1
  
  
 Shorter half (138.8 to 156.5)
 3.72
 < 0.001
 3.53
 (1.58 – 7.86)
 0.002
Anaemia diagnosis
 
  
  
  
  
 No
 1
 0.003
 -
 -
 -
 Yes
 2.74
Parasitosis diagnosis
 
  
  
  
  
 No
 1
 0.54
 -
 -
 -
 Yes 1.25        
Open in a new tab

Assis Brasil, AC, 2010.

*Odds Ratio (OR) adjusted by all variables in the table, gender and age.

**Wald test.

Overweight

Factors associated with overweight in children under 5 years, obtained through hierarchical multiple regression analysis are presented in Table 8. From the second block variables, maternal BMI (≥ 25 kg/m2, OR: 3.31, CI 95%: 1.25 - 8.75) and the mother’s time of residency in the municipality (years of residence, OR: 1.07, CI 95%: 1.03 to 1.11) remained associated with overweight. Among the variables of the first, third, fourth, fifth and sixth blocks, none remained in the model. Variables gender and age (in years, OR = 0.58, CI 95%: 0.38 to 0.87) were added to the model as controls.

Table 8.

Factors associated with high weight-for-height in children under 5 years obtained by hierarchical multiple analysis, 2010

Variables Crude OR p value** Adjusted OR* (CI 95%) P value**
Child age
 
  
  
  
  
 Age in years
 0.67
 0.025
 0.58
 (0.38 – 0.87)
 0.009
Maternal IBM
 
  
  
  
  
 Below 25 kg/m2
 1
  
 1
  
  
 Equal or above 25 kg/m2
 2.68
 0.034
 3.31
 (1.25 – 8.75)
 0.016
Mother’s time residing in town
 
  
  
  
  
 Years 1.05 0.002 1.07 (1.03 – 1.11) < 0.001
Open in a new tab

Assis Brasil, AC, 2010.

*Odds Ratio (OR) adjusted by all variables in the table and gender.

**Wald test.

Discussion

Improvements in socio-economic conditions, parental education, water supply, and decrease in the global burden of disease in Assis Brasil were observed between the studied periods. However, population growth in the period from 2003 to 2010 was higher than usual. The municipality did not have adequate urban infrastructure to receive this demand, resulting in increased areas of illegal settlements. This may partly explain the increased presence of open sewage observed when comparing periods.

In this study, undernutrition rates did not change significantly over the decade. In 2003, undernutrition prevalence in Assis Brasil (7.0%) was similar to the Brazilian average of 8.7% [19], but while in 2006 the national average decreased to 6.7% [5], in the city of Assis Brasil, undernutrition rates remained high (12.2%) until 2010.

Obesity occurs more often in the first years of the life cycle, between 5 and 6 years of age, and in adolescence [20,21]. In the present study, the prevalence of overweight increased from 1% to 6% between 2003 and 2010, reaching the national average identified in PNDS 2006 [5]. This may reflect an increasing growth in children’s overweight and a future public health problem for the region. A possible explanation for this phenomenon is undernutrition early in life due to poor maternal nutrition and inadequate nutrition in early childhood, predisposing the body to store fat when eating foods rich in carbohydrates and fats. [22].

Another explanation for the overweight increase is the nutrition transition. The name “ nutrition transition” means a change in nutritional patterns related to food intake resulting from changes in social, economic and demographic status that affect health [23]. According to Batista Filho and Rissin [24], the nutrition transition is a process characterised by four stages. In the first stage, the disappearance of acute and severe protein malnutrition related to protein intake deficiency is observed. In the second stage the disappearance of protein-energy malnutrition characterised as insufficient intake of calories and nutrients occurs. The third phase is characterised by the appearance of the binomial overweight/obesity on a population scale, caused by excessive food intake associated with increasing sedentariness. And the last stage of the transition is set in the correction of short stature, since there is no longer a poor intake of nutrients [24].

Several authors have reported that the process of demographic and economic transition observed in developing countries such as Brazil, contributes to the nutrition transition [23-25]. Reported studies show that Brazil is currently in the fourth stage of the nutritional transition process. However, this process is not uniform, and Assis Brasil, which is located in an underdeveloped region of the country, is still between the second and third stages, with increased overweight rates, but sustained chronic undernutrition. This is suggested by the high prevalence of low HAZ and high WHZ, as found in this study.

The process of nutritional transition is marked by the intake of a high calorie diet, rich in saturated fat and refined carbohydrates, which are characteristics of most industrialized foods, as well as by low intake of complex carbohydrates and fibers. The implementation of the Interoceanic Highway may have promoted the arrival of new foods from other regions of Brazil and Peru. When assessing the perception of the changes brought by BR-137 (Transoceanic Highway) to Assis Brasil residents in 2010, Martins et al. (unpublished observations) found that 89.7% of respondents reported improvements in the variety and availability of food and 8.8.5% reported improvements in the local market. Poor logistic access to Assis Brasil before the BR-317 was related to the unavailability of perishable foods at home. In addition, preliminary results from the Feeding Infants and Toddlers Study (FITS) confirm an excessive intake of industrialised food by children at this age [26].

Factors associated with undernutrition were mostly related to socio-economic status (wealth index, living conditions and schooling and number of pregnancies) and maternal height. Similar findings from 47 countries suggested that low height-for-age led to a greater association with socio-economic inequality than did low weight-for-height [27]. A comparison of national nutritional surveys corroborate this information, describing that 21.7% of the reduction in the prevalence of child malnutrition between 1996 and 2006 can be attributed to the increasing purchasing power of Brazilian families. The government is partly responsible for this increase by granting benefits to mothers or guardians in poorer families [3].

The presence of open sewage was associated at a distal level with undernutrition in 2010. This has been reported elsewhere [28,29]. Souza et al. (2012), while assessing malnutrition in two municipalities in the state of Acre in 2003, found that children exposed to open sewage near home were more likely to show low height-for-age in relation to the unexposed ones [17]. When analysing national surveys, Monteiro et al. [30] also confirmed the association between inadequate sanitation and undernutrition. The possible biological relationship between undernutrition and open sewage is the increase in the number of cases of diarrhoea and intestinal parasitosis as well as other morbidities, resulting in growth retardation.

For the year 2003, poor maternal education levels showed greater association with low height-for-age than did socio-economic variables. Other studies on the relation between social and environmental conditions and malnutrition in São Paulo, Belo Horizonte, Maceió and Rio Grande do Sul also showed this association [31-34]. This relationship may result from the basic information on the importance of personal and household hygiene habits and practices of adequate nutrition for child growth and development. Drachler et al. [35] reported that the mother figure represents the bond between children and the environment, besides the fact that it is also the mother who usually decides on her family’s eating habits and on hygiene and immunization care. In 2010, an increase in maternal educational levels was observed, and it was not associated with undernutrition anymore.

In this study, for the year 2003, each new pregnancy increased the chance of an already existing child under 5 years of age to develop low height-for-age by 35%. Eastwood and Lipton [36] showed that, in families with low purchasing power, the impact of high fertility on the family income was more pronounced. Therefore, multiple pregnancies may have had an impact on socio-economic conditions in 2003, thus contributing to less food available and higher levels of undernutrition.

The effect of maternal height in child height can be explained as a biological relationship and, at the same time, as the result of socio-economic long-standing unfavorable conditions that had affected the mother in the past and are presently affecting their children as well. Previous studies have also shown this association between maternal height and stunting [31,37,38], and between maternal height and poverty and adverse socio-environmental conditions. Therefore, maternal short stature can predict undernutrition in children [31,37,38].

Although the prevalence of anemia and intestinal parasitosis was higher in undernourished children, these two morbidities were not associated with undernutrition in the final model possibly because they have similar associated factors and are not the cause of undernutrition per se. Some studies have already reported that inadequate sanitary conditions are associated with anaemia [39,40] as well as undernutrition in children [28,29].

Overweight in Assis Brasil was associated with child age, time of residence in the town and maternal BMI. The inverse association between age and overweight, found in this study, has also been reported by other Brazilian studies [41-43]. A study conducted in southern Brazil [42] reported a negative trend between age and overweight and obesity, which is possibly explained by the result of increased physical activity throughout the years, but no confirmatory studies have been published so far.

While low maternal height was associated with undernutrition, maternal overweight was a predictor of child overweight in this study as well. This is a common association reported extensively elsewhere [35,44-49]. According to Maffeis et al. [50], the main risk factor for childhood obesity is still parental' obesity, occurring as a result of genetic representation concomitant with environmental influences. However, the mother is the main agent in determining the dietary habits adopted by a child, since she is the main individual involved in the selection and preparation of food [49].

In 2010, the length of time during which the mother had been living in the municipality was associated with overweight children. Each year of maternal residence in the municipality increased the chance of a child′s being overweight by 7%. The most likely hypothesis would be the rural exodus promoted by the Transoceanic Highway or the migration of people from other municipalities with poor conditions in search of better living conditions and the contact with industrialised food rich in fat and carbohydrates. This hypothesis is supported by three main findings: approximately 19.8% of the children were born outside the urban area and migrated to it when they were between 1 and 5 years old; undernutrition among children born in rural areas was high in this study, and overweight prevalence was higher in children whose families had been living in the urban area for a longer periods.

The main limitation of this study is that the cross-sectional design precludes a cause-and-effect relationship between the studied variables. Therefore, the associated factors observed should be interpreted as associations between events, and not as risk factors. Another limitation is that the population size is small for detecting events and therefore there may be an overestimation of the strengths of the associations described. This must be taken into account when interpreting results. Finally, not all variables studied in 2010 were investigated in 2003, so we may not have been able to detect all possible associated factors in 2003, such as the number of years of maternal residency in the urban area.

Conclusions

Comparing the years 2003 and 2010, an increase in the prevalence of overweight (high WHA) and in the prevalence of undernutrition (low HAZ) was observed. Factors associated with undernutrition in the municipality are especially related to socio-economic status and maternal characteristics. On the other hand, the progress of overweight in this conservation of undernutrition reveals that the process of nutritional transition began in this Amazonian city only in the last decade, and therefore, it is delayed when compared to nutritional transition in other parts of Brazil. Such transition in Assis Brasil may have been facilitated by the construction of the Interoceanic Highway. Factors associated with overweight in Assis Brasil for the year 2010 were children′s age, mother’s time of residency in the municipality and maternal BMI.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

M da SN, PTM, AAR, SASM, BMD, TMP, ACM, HOG, AMB, FLCCB, RGC, ASG, TSA and CSMO designed the study and collected the data. All authors analysed the data under the supervision of M da SN, CTC, and PTM. AAR and M da SN wrote the manuscript. All other authors revised the manuscript and contributed to the discussion of the results and revision of the intellectual contents in the research. All authors approved the final version of the manuscript.

Pre-publication history

The pre-publication history for this paper can be accessed here:

http://www.biomedcentral.com/1471-2458/13/1098/prepub

Contributor Information

Alanderson A Ramalho, Email: alandersonalves@hotmail.com.

Saulo AS Mantovani, Email: sauloaugustomantovani@hotmail.com.

Breno M Delfino, Email: brenomd_@hotmail.com.

Thasciany M Pereira, Email: thascy_moraes@hotmail.com.

Antonio C Martins, Email: antonio_camargo0@yahoo.com.br.

Humberto Oliart-Guzmán, Email: hosoliart@hotmail.com.

Athos M Brãna, Email: athosbrana@hotmail.com.

Fernando LCC Branco, Email: flccbranco@uol.com.br.

Rhanderson G Campos, Email: doutorhanderson@yahoo.com.br.

Andréia S Guimarães, Email: andreia_ufac@yahoo.com.br.

Thiago S Araújo, Email: thiagoacre@gmail.com.

Cristieli SM Oliveira, Email: crisufac@yahoo.com.br.

Cláudia T Codeço, Email: claudia.codeco@gmail.com.

Pascoal T Muniz, Email: pascoaltorres@uol.com.br.

Mônica da Silva-Nunes, Email: msnunes1@yahoo.com.br.

Acknowledgements

We thank the population and the local-health and government authorities in Assis Brasil for their help. We also thank the mayor of Assis Brasil, Ms. Maria Eliane Cariús, for her collaboration. This study received financial support from UFAC (Brazil) and FUNTAC (Programa Pesquisa para o SUS Edital MS/CNPq/FDCT-FUNTAC/SESACRE n. 01/09) as well as support from the UFAC Master’s Program in Public Health. Research fellowships were awarded by CNPq, UFAC, DECIT and CAPES-Reuni.

References

  1. Béhar M. Evaluación de la situación nutricional en grupos de población. Arch Latinoam Nutr. 1972;22:335–342. [PubMed] [Google Scholar]
  2. Monte CMG. Desnutrição: um desafio secular à nutrição infantil. J Pediatr (Rio J) 2000;76(Suppl 3):S285–S297. doi: 10.2223/jped.165. [DOI] [PubMed] [Google Scholar]
  3. Monteiro CA, Benicio MHD, Konno SC, Silva ACF, Lima ALL, Conde WL. Causes for the decline in child undernutrition in Brazil, 1996–2007. Rev Saude Publica. 2009;43:35–43. doi: 10.1590/s0034-89102009000100005. [DOI] [PubMed] [Google Scholar]
  4. Monteiro CA, Conde WL, Popkin BM. Is obesity replacing or adding to undernutrition? Evidence from different social classes in Brazil. Pub Health Nut. 2002;5:105–112. doi: 10.1079/PHN2001281. [DOI] [PubMed] [Google Scholar]
  5. Brasil. Ministério da Saúde. Pesquisa Nacional de Demografia e Saúde da Criança e da Mulher. Brasília; 2009. http://bvsms.saude.gov.br/bvs/pnds/ [Google Scholar]
  6. Brown IF, Brilhante SHC, Mendoza E, Oliveira IR. In: Encuentro Internacional de Integracion Regional – Bolivia, Brasil y Peru. Centro Peruano de Estudios Internacionales, editor. Lima; 2002. Estrada de Rio Branco, Acre, Brasil aos Portos do Pacífico: como maximizar os benefícios e minimizar os prejuízos para o desenvolvimento sustentável da Amazônia Sul - Ocidental; pp. 1–8. [Google Scholar]
  7. Muniz PT, Castro TG, Araújo TS, Nunes NB, Silva-Nunes M, Hoffmann EHE, Ferreira MU, Cardoso MA. Child health and nutrition in the Western Brazilian Amazon: population-based surveys in two counties in Acre State. Cad Saude Publica. 2007;23:1283–1293. doi: 10.1590/S0102-311X2007000600004. [DOI] [PubMed] [Google Scholar]
  8. Instituto Brasileiro de Geografia e Estatística. Resultados parciais do Estado do Acre no Censo 2010. http://www.ibge.gov.br/home/estatistica/populacao/censo2010/tabelas_pdf/total_populacao_acre.pdf.
  9. Filmer D, Pritchett LH. Estimating wealth effects without expenditure data - or tears: an application to educational enrollments in states of India. Demography. 2001;38:115–132. doi: 10.1353/dem.2001.0003. [DOI] [PubMed] [Google Scholar]
  10. World Health Organization. WHO child growth standards based on length/height, weight and age. Acta Paediatr. 2006;450:S76–S85. doi: 10.1111/j.1651-2227.2006.tb02378.x. [DOI] [PubMed] [Google Scholar]
  11. World Health Organization Expert Committee on Physical Status. Physical status: the use and interpretation of anthropometry: report of a WHO expert committee. Geneva: World Health Organization; 1995. [PubMed] [Google Scholar]
  12. World Health Organization. Obesity: Preventing and Managing the Global Epidemic. Geneva; 1998. [PubMed] [Google Scholar]
  13. da Silva-Nunes M, Codeço CT, Malafronte RS, da Silva NS, Juncansen C, Muniz PT, Ferreira MU. Malaria on the Amazonian frontier: transmission dynamics, risk factors, spatial distribution, and prospects for control. Am J Trop Med Hyg. 2008;79:624–635. [PubMed] [Google Scholar]
  14. Jolliffe IT. Discarding variables in a principal component analysis II: real data. J R Stat Soc. C (Applied Statistics) 1973;22:21–31. [Google Scholar]
  15. Victora CG, Huttly S, Fuchs S, Olinto M. The role of conceptual frameworks in epidemiological analysis: a hierarchical approach. Int J Epidemiol. 1997;26:224–227. doi: 10.1093/ije/26.1.224. [DOI] [PubMed] [Google Scholar]
  16. UNICEF. The State of the World’s Children. 1998. http://www.unicef.org/sowc98.
  17. Souza OF, Benício MHD, Castro TG, Muniz PT, Cardoso MA. Desnutrição em crianças menores de 60 meses em dois municípios no Estado do Acre: prevalência e fatores associados. Rev Bras Epidemiol. 2012;15:221–221. [Google Scholar]
  18. Zamar D, McNeney B, Graham J. Elrm: software implementing exact-like inference for logistic regression models. J Stat Softw. 2007;21(3):1–18. [Google Scholar]
  19. Instituto Brasileiro de Geografia e Estatística. Pesquisa de Orçamentos Familiares 2002 – 2003: Análise da disponibilidade domiciliar de alimentos e do estado nutricional no Brasil. Rio de Janeiro: IBGE; 2004. [Google Scholar]
  20. Dietz WH. The obesity epidemic in young children. Reduce television viewing and promote playing. BMJ. 2001;322:313–314. doi: 10.1136/bmj.322.7282.313. [DOI] [PMC free article] [PubMed] [Google Scholar]
  21. Ebbeling CB, Pawlak DB, Ludwig DS. Childhood obesity: public health crisis, common sense cure. Lancet. 2002;360:473–482. doi: 10.1016/S0140-6736(02)09678-2. [DOI] [PubMed] [Google Scholar]
  22. Sawaya AL, Roberts S. Stunting and future risk of obesity: principal physiological mechanisms. Cad Saude Publica. 2003;19(Suppl 1):S21–S28. doi: 10.1590/s0102-311x2003000700003. [DOI] [PubMed] [Google Scholar]
  23. Popkin BM. The nutrition transition and obesity in the developing world. J Nutr. 2001;22:355–375. doi: 10.1093/jn/131.3.871S. [DOI] [PubMed] [Google Scholar]
  24. Batista Filho M, Rissin A. A transição nutricional no Brasil: tendências regionais e temporais. Cad Saude Publica. 2003;19(Suppl 1):S181–S191. doi: 10.1590/s0102-311x2003000700019. [DOI] [PubMed] [Google Scholar]
  25. Monteiro CA, Mondini L, Souza ALM, Popkin BM. In: Velhos e novos males da saúde no Brasil: a evolução do país e de suas doenças. Monteiro CA, editor. São Paulo: Hucitec; 2000. Da desnutrição para a obesidade: a transição nutricional no Brasil; pp. 247–255. [Google Scholar]
  26. Siega-Riz AM, Deming DM, Reidy KC, Fox MK, Condon E, Briefel RR. Food consumption patterns of infants and toddlers: Where are we now? J Am Diet Assoc. 2010;110(Suppl 3):S38–S51. doi: 10.1016/j.jada.2010.09.001. [DOI] [PubMed] [Google Scholar]
  27. Van de Poel E, Hosseinpoor AR, Speybroeck N, Van Ourtia T, Vega J. Socioeconomic inequality in malnutrition in developing countries. Bull World Health Organ. 2008;86:286–291. doi: 10.2471/BLT.07.044800. [DOI] [PMC free article] [PubMed] [Google Scholar]
  28. Aerts D, Drachler M, Giugliani E. Determinants of growth retardation in Southern Brazil. Cad Saude Publica. 2004;20:1182–1190. doi: 10.1590/S0102-311X2004000500011. [DOI] [PubMed] [Google Scholar]
  29. Rissin A, Batista Filho M, Benício MHA, Figueiroa J. Condições de moradia como preditores de riscos nutricionais em crianças de Pernambuco. Brasil Rev Bras Saude Mater Infant. 2006;6:59–67. doi: 10.1590/S1519-38292006000100007. [DOI] [Google Scholar]
  30. Monteiro CA, Benício MHA, Freitas ICM. In: Velhos e novos males da saúde no Brasil: a evolução do país e de suas doenças. Monteiro CA, editor. São Paulo: Hucitec; 2000. Evolução da mortalidade infantil e retardo de crescimento nos anos 90: causas e impacto sobre desigualdades regionais; pp. 393–420. [Google Scholar]
  31. Silveira KBR, Alves JFR, Ferreira HS, Sawaya AL, Florêncio TMMT. Association between malnutrition in children living in favelas, maternal nutritional status, and environmental factors. J Pediatr. 2010;86:215–220. doi: 10.1590/S0021-75572010000300009. [DOI] [PubMed] [Google Scholar]
  32. França E, Souza JM, Guimarães MDC, Goulart EMA, Colosimo E, Antunes CMF. Associação entre fatores sócio-econômicos e mortalidade infantil por diarréia, pneumonia e desnutrição em região metropolitana do Sudeste do Brasil: um estudo caso-controle. Cad Saude Publica. 2001;17:1437–1447. doi: 10.1590/S0102-311X2001000600027. [DOI] [PubMed] [Google Scholar]
  33. Florêncio TMMT, Ferreira HS, França APT, Cavalcante JC, Sawaya AL. Obesity and undernutrition in a very-low-income population in the city of Maceió, northeastern Brazil. Br J Nutr. 2001;86:277–283. doi: 10.1079/BJN2001396. [DOI] [PubMed] [Google Scholar]
  34. Victora CG, Vaughan JP, Kirkwood BR, Martines JC, Barcelos LB. Risk factors for malnutrition in Brazilian children: The role of social and environmental variables. Bull World Health Organ. 1986;64:299–309. [PMC free article] [PubMed] [Google Scholar]
  35. Drachler ML, Macluf SPZ, Leite JCC, Aerts DRGC, Giugliani ERJ, Horta BL. Fatores de risco para sobrepeso em crianças no sul do Brasil. Cad Saude Publica. 2003;19:1073–1081. doi: 10.1590/S0102-311X2003000400029. [DOI] [PubMed] [Google Scholar]
  36. Eastwood R, Lipton M. The impact of changes in human fertility on poverty. J Develop Stud. 1999;36:1–30. [Google Scholar]
  37. Ashworth A, Morris SS, Lira PIC. Postnatal growth patterns of full-term low birth weight infants in Northeast Brazil are related to socioeconomic status. J Nutr. 1997;127:1950–1956. doi: 10.1093/jn/127.10.1950. [DOI] [PubMed] [Google Scholar]
  38. Engstron EM, Anjos LA. Déficit estatural nas crianças brasileiras: relação com condições sócio-ambientais e estado nutricional materno. Cad Saude Publica. 1999;15:559–567. doi: 10.1590/S0102-311X1999000300013. [DOI] [PubMed] [Google Scholar]
  39. Assis AMO, Barreto ML, Gomes GSS, Prado MS, Santos NS, Santos LMP, Sampaio LR, Ribeiro RC, Oliveira LPM, Oliveira VA. Childhood anemia prevalence and associated factors in Salvador, Bahia, Brazil. Cad Saude Publica. 2004;20:1633–1641. doi: 10.1590/S0102-311X2004000600022. [DOI] [PubMed] [Google Scholar]
  40. Silva ACL, Filho MB, Miglioli TC. Prevalência e fatores de risco de anemia em mães e filhos no Estado do Pernambuco. Rev Bras Epidemiol. 2008;11:266–277. doi: 10.1590/S1415-790X2008000200008. [DOI] [Google Scholar]
  41. Vitolo MR, Gama CM, Bortolini GA, Campagnolo PDB, Drachler ML. Some risk factors associated with overweight, stunting and wasting among children under 5 years old. J Pediatr. 2008;84:251–257. doi: 10.2223/JPED.1776. [DOI] [PubMed] [Google Scholar]
  42. Vieira MFA, Araújo CLP, Hallal PC, Madruga SW, Neutzling MB, Matijasevich A, Leal CMA, Menezes AMB. Estado nutricional de escolares de 1a a 4a séries do Ensino Fundamental das escolas urbanas da cidade de Pelotas, Rio Grande do Sul. Brasil Cad. Saude Publica. 2008;24:1667–1674. doi: 10.1590/S0102-311X2008000700021. [DOI] [PubMed] [Google Scholar]
  43. Dallabona A, Cabral SC, Höfelman DA. Variáveis infantis e maternas associadas à presença de sobrepeso em crianças de creches. Rev Paul Pediatr. 2010;28:304–313. doi: 10.1590/S0103-05822010000400004. [DOI] [Google Scholar]
  44. Danielzik S, Czerwinski-Mast M, Langnäse K, Dilba B, Müller MJ. Parental overweight, socioeconomic status and high birth weight are the major determinants of overweight and obesity in 5–7 y-old children: baseline data of the Kiel Obesity Prevention Study (KOPS) Int J Obes Relat Metab Disord. 2004;28:1494–1502. doi: 10.1038/sj.ijo.0802756. [DOI] [PubMed] [Google Scholar]
  45. Engstrom EM, Anjos LA. Relação entre o estado nutricional materno e sobrepeso nas crianças brasileiras. Rev Saude Publica. 1996;30:233–239. doi: 10.1590/S0034-89101996000300005. [DOI] [PubMed] [Google Scholar]
  46. Kain J, Albala C, García F, Andrade M. Obesidad en el preescolar: evolución antropométrica y determinantes socioeconómicos. Rev Med Chilena. 1998;126:271–278. [PubMed] [Google Scholar]
  47. He Q, Ding ZY, Fong DYT, Karlberg J. Risk factors of obesity in preschool children in China: a population-based case–control study. Int J Obes. 2000;24:1528–1536. doi: 10.1038/sj.ijo.0801394. [DOI] [PubMed] [Google Scholar]
  48. Hui LL, Nelson EAS, Yu LM, Li AM, Fok TF. Risk factors for childhood overweight in 6- to 7-y-old Hong Kong children. Int J Obes. 2003;27:1411–1418. doi: 10.1038/sj.ijo.0802423. [DOI] [PubMed] [Google Scholar]
  49. Marins VMR, Almeida RMVR, Pereira RA, Barros MBA. The relationship between parental nutritional status and overweight children/adolescents in Rio de Janeiro, Brazil. Pub Health. 2004;118:43–49. doi: 10.1016/S0033-3506(03)00145-8. [DOI] [PubMed] [Google Scholar]
  50. Maffeis C, Zantedeschi P, Filippi L, Matti P, Boscarol G, Grezzani A, Pinelli L, Zaffanello M. Patterns of food intake and obesity in Italian children. Int J Obes. 1999;23(Suppl 5):S44. [Google Scholar]

Articles from BMC Public Health are provided here courtesy of BMC

RESOURCES