Built environment, contextual income, and obesity in older adults: evidence from a population-based study

Araújo, Carolina Abreu Henn de; Giehl, Maruí W. Corseuil; Danielewicz, Ana Lúcia; Araujo, Pierre Guedes de; d’Orsi, Eleonora; Boing, Antonio Fernando

doi:10.1590/0102-311x00060217

Abstract

The objective was to verify the association between built environment, contextual income, and obesity in older adults in Florianópolis, Santa Catarina State, Brazil. This was a cross-sectional study in a sample of 1,197 older people (≥ 60 years) evaluated in the EpiFloripa Older Adults Cohort in 2013/2014. The outcomes were overall obesity, abdominal obesity, waist circumference (WC), and body mass index (BMI). Contextual income in the census tract and characteristics of the built environment were analyzed using data from the Florianópolis Institute of Urban Planning (IPUF) and the 2010 Population Census. Logistic and multilevel linear regression models were used. For older women, intermediate mean income was associated with lower odds of abdominal and overall obesity, while higher percentage of paved streets in the census tract was associated with lower odds of abdominal obesity; one percentage point increment in local commerce decreased WC by 0.20cm, and a one percentage point increase in paved streets decreased WC by 0.43cm and BMI by 0.22kg/m². For older men, better street connectivity and intermediate percentage of local commerce were associated with lower odds of overall obesity; the increment in street density decreased WC by 0.34cm and BMI by 10kg/m²; a one-point increment in lighting increased WC by 0.51cm and BMI by 0.11kg/m². The results showed different associations according to sex and target outcome, highlighting the need for further studies to explore additional relevant contextual variables for these outcomes in older adults.

Keywords:
Obesity; Aged; Social Class

Introduction

Obesity is considered a global epidemic that affects all age brackets and accounts for the death of approximately 2.8 million individuals per year ¹1. World Health Organization. Obesity: preventing and managing the global epidemic. Geneva: World Health Organization; 2000. (WHO Technical Report Series, 894).. More specifically in the older adult population, epidemiological studies have identified growing obesity prevalence rates and strong negative health impacts ²2. Gutiérrez-Fisac JL, León-Muñoz LM, Regidor E, Banegas J, Rodríguez-Artalejo F. Trends in obesity and abdominal obesity in the older adult population of Spain (2000-2010). Obes Facts 2013; 6:1-8.^,³3. Mitchell RJ, Lord SR, Harvey LA, Close JCT. Associations between obesity and overweight and risk of falls, health status and quality of life in the elderly. Aust N Z J Public Health 2014; 38:13-8..

Data from 12 European countries show obesity prevalence ranging from 12% to 41% in older women and 8% to 24% in older men ⁴4. de Groot LC, Verheijden MW, de Henauw S, Schroll M, van Staveren WA; SENECA Investigators. Lifestyle, nutritional status, health, and mortality in elderly people across Europe: a review of the longitudinal results of the SENECA study. J Gerontol A Biol Sci Med Sci 2004; 59:1277-84.. High prevalence has also been observed in Japan ⁵5. Tamakoshi A, Kawado M, Ozasa K, Tamakoshi K, Lin Y, Yagyu K, et al. Impact of smoking and other lifestyle factors on life expectancy among Japanese: findings from the Japan Collaborative Cohort (JACC) Study. J Epidemiol 2010; 20:370-6., Australia ⁶6. Pink B, Allbon P. The health and welfare of Australia's Aboriginal and Torres Strait Islander peoples 2008. Canberra: Australian Bureau of Statistics/Australian Institute of Health and Welfare; 2008. (ABS Catalogue, 4704.0/AIHW Catalogue, IHW 21)., and Latin American countries ⁷7. Al Snih S, Graham JE, Kuo YF, Goodwin JS, Markides KS, Ottenbacher KJ. Obesity and disability: relation among older adults living in Latin America and the Caribbean. Am J Epidemiol 2010; 171:1282-8.. In Brazil, according to data from 2013, approximately one out of four women and one out of five men from 65 to 74 years were obese ⁸8. Instituto Brasileiro de Geografia e Estatística. Pesquisa Nacional de Saúde 2013. Rio de Janeiro: Instituto Brasileiro de Geografia e Estatística; 2014..

Obesity is associated with various health problems such as type 2 diabetes, hypertension, cardiovascular diseases, and certain types of cancer ⁹9. World Health Organization. World health statistics: 2012. v. 27. Geneva: World Health Organization; 2012.. The presence of these conditions together with physiological alterations of aging such as decreased bone mineral density and increased visceral fat ¹⁰10. Tchernof A, Després J-P. Pathophysiology of human visceral obesity: an update. Physiol Rev 2013; 93:359-404. contribute to functional incapacities and increased mortality risk in the older population ¹¹11. Wu CY, Chou YC, Huang N, Chou YJ, Hu HY, Li CP. Association of body mass index with all-cause and cardiovascular disease mortality in the elderly. PLoS One 2014; 9:e102589..

Various individual demographic and socioeconomic characteristics show positive associations with obesity ¹²12. Oliveira TC, Medeiros WR, Lima KC. Diferenciais de mortalidade por causas nas faixas etárias limítrofes de idosos. Rev Bras Geriatr Gerontol 2015; 18:85-94., but the influence of environmental factors on the occurrence of this outcome has been studied less. Some studies have found that residing in neighborhoods with higher mean income is associated with lower odds of obesity, independently of individual characteristics ¹³13. Tucker-Seeley RD, Subramanian SV, Li Y, Sorensen G. Neighborhood safety, socioeconomic status, and physical activity in older adults. Am J Prev Med 2009; 37:207-13.^,¹⁴14. Pruchno R, Wilson-Genderson M, Gupta AK. Neighborhood food environment and obesity in community-dwelling older adults: individual and neighborhood effects. Am J Public Health 2014; 104:924-9.^,¹⁵15. Troped PJ, Starnes HA, Puett RC, Tamura K, Cromley EK, James P, et al. Relationships between the built environment and walking and weight status among older women in three U.S. States. J Aging Phys Act 2014; 22:114-25.. Neighborhoods with low socioeconomic status offer fewer facilities for physical activities while including more small markets and fast food restaurants that sell high-energy, unhealthy foods ¹⁶16. Morland K, Wing S, Roux AD, Poole C. Neighborhood characteristics associated with the location of food stores and food service places. Am J Prev Med 2002; 22:23-9., in a sense making the neighborhood itself obesogenic ¹⁷17. Booth KM, Pinkston MM, Poston WSC. Obesity and the built environment. J Am Diet Assoc 2005; 105(5 Suppl 1):S110-7..

Meanwhile, neighborhoods with a higher proportion of green areas, large supermarkets, and recreational areas tend to facilitate regular exercise and adequate eating, enhance the feeling of local safety, and foster greater social interaction between neighbors and friends, thus decreasing the odds of becoming obese ¹⁸18. King AC, Sallis JF, Frank LD, Saelens BE, Cain K, Conway TL, et al. Aging in neighborhoods differing in walkability and income: associations with physical activity and obesity in older adults. Soc Sci Med 2011; 73:1525-33.^,¹⁹19. Bell JA, Hamer M, Shankar A. Gender-specific associations of objective and perceived neighborhood characteristics with body mass index and waist circumference among older adults in the English Longitudinal Study of Ageing. Am J Public Health 2014; 104:1279-86.. In urban places, characteristics such as higher proportion of paved streets, good connectivity between streets, and larger supply of commercial establishments tend to reflect an environment with better infrastructure, where residents can move around more easily on foot and acquire healthier habits ²⁰20. Frank LD, Andresen MA, Schmid TL. Obesity relationships with community design, physical activity, and time spent in cars. Am J Prev Med 2004; 27:87-96.. All these characteristics suggest even greater relevance for older people, who spend most of their time in domestic and/or community activities and thus use their neighborhood environment more intensely when compared to younger adults ²¹21. Robert SA. Socioeconomic position and health: the independent contribution of community socioeconomic context. Annu Rev Sociol 1999; 25:489-516..

Despite the findings published to date, most studies on this topic have been done in high-income countries ¹⁴14. Pruchno R, Wilson-Genderson M, Gupta AK. Neighborhood food environment and obesity in community-dwelling older adults: individual and neighborhood effects. Am J Public Health 2014; 104:924-9.^,¹⁵15. Troped PJ, Starnes HA, Puett RC, Tamura K, Cromley EK, James P, et al. Relationships between the built environment and walking and weight status among older women in three U.S. States. J Aging Phys Act 2014; 22:114-25.^,¹⁸18. King AC, Sallis JF, Frank LD, Saelens BE, Cain K, Conway TL, et al. Aging in neighborhoods differing in walkability and income: associations with physical activity and obesity in older adults. Soc Sci Med 2011; 73:1525-33.^,¹⁹19. Bell JA, Hamer M, Shankar A. Gender-specific associations of objective and perceived neighborhood characteristics with body mass index and waist circumference among older adults in the English Longitudinal Study of Ageing. Am J Public Health 2014; 104:1279-86.^,²⁰20. Frank LD, Andresen MA, Schmid TL. Obesity relationships with community design, physical activity, and time spent in cars. Am J Prev Med 2004; 27:87-96.^,²²22. Berke EM, Koepsell TD, Moudon AV, Hoskins RE, Larson EB. Association of the built environment with physical activity and obesity in older persons. Am J Public Health 2007; 97:486-92.^,²³23. Glass TA, Rasmussen MD, Schwartz BS. Neighborhoods and obesity in older adults. The Baltimore Memory Study. Am J Prev Med 2006; 31:455-63.^,²⁴24. Hanibuchi T, Kondo K, Nakaya T, Nakade M, Ojima T, Hirai H, et al. Neighborhood food environment and body mass index among Japanese older adults: results from the Aichi Gerontological Evaluation Study (AGES). Int J Health Geogr 2011; 10:43.^,²⁵25. Shiue I. Associated social factors of body mass index in adults and the very old in the UK. Int J Cardiol 2013; 168:543-5.. Few studies in Brazil have addressed neighborhood and obesity, and the samples have only included younger adults ²⁶26. Boing AF, Subramanian SV. The influence of area-level education on body mass index, waist circumference and obesity according to gender. Int J Public Health 2015; 60:727-36.. Since the country has sharp socioeconomic disparities and rapid population aging, it is essential to investigate environmental factors that can influence the occurrence of obesity in older Brazilians in order to support strategies for the promotion of healthy behaviors and to increase healthy life expectancy in this age group.

The aim of this study was thus to test the association between built environment, contextual income, and obesity in older adults in Florianópolis, Santa Catarina State, Brazil.

Methods

Study design and location

This was a cross-sectional study nested in a cohort of older residents in the city of Florianópolis, capital of Santa Catarina State (EpiFloripa Older Adults Study). The baseline was performed in 2009/2010, and the data for the current study were collected in 2013/2014. The city’s population in 2010 was 421,000, of whom 11.4% were older adults (60 years or older), and of these, 14% were considered very old (80 years or older) ²⁷27. Instituto Brasileiro de Geografia e Estatística. Sinopse do censo 2010 e resultados preliminares do universo. Rio de Janeiro: Instituto Brasileiro de Geografia e Estatística; 2011..

Sampling procedures and data collection

The study’s sample consisted of 1,705 older adults of both sexes, 60 years or older, non-institutionalized and residing within the city limits of Florianópolis. The sample size was estimated on the basis of known parameters for sampling calculations, using a two-stage cluster approach, the first consisting of census tracts and the second consisting of the households picked for interviews ²⁷27. Instituto Brasileiro de Geografia e Estatística. Sinopse do censo 2010 e resultados preliminares do universo. Rio de Janeiro: Instituto Brasileiro de Geografia e Estatística; 2011.. Further details on the sampling procedures have been published recently in an article on the study’s methodology ²⁸28. Confortin SC, Jayce I, Schneider C, Antes DL, Cembranel F, Ono LM, et al. Condições de vida e saúde de idosos: resultados do estudo de coorte EpiFloripa Idoso. Epidemiol Serv Saúde 2017; 26:305-17..

In 2013, all participants in the first wave were considered eligible. Addresses were updated by telephone, e-mail, or letter before the data collection. Deaths that occurred from 2009 to 2012 were checked using the state’s data from the Brazilian Mortality Information System (SIM). Losses were defined as individuals that were not located after four attempts (including at least one in the evening and one on weekends), hospitalized individuals, and those who had moved away from the city. Subjects that declined to answer the questionnaire by personal choice were considered refusals. When the refusal was voiced by telephone, the interviewer made one final attempt with a direct household visit.

Data were collected using netbooks for application of a standardized questionnaire, previously tested in a pilot study. The interviews were performed face-to-face at the older adults’ homes from November 2013 to November 2014. Data consistency was verified weekly, and quality control was done with an abridged questionnaire, via telephone, with 10% of the selected interviewees, using simple random sampling, considering the principle of equiprobability with low risk of selection bias ²⁹29. Friis RH, Sellers T. Epidemiology for public health practice. Burlington: Jones & Bartlett Publishers; 2013.. Kappa test was used to measure inter-observer reliability, after reapplication of eight randomly selected questions. The results indicate moderate to very good agreement, with values ranging from 0.51 to 0.94 (p < 0.001).

Outcome variables

The target outcomes for analysis were abdominal obesity and overall obesity, both dichotomized. Abdominal obesity was defined as waist circumference (WC) according to World Health Organization (WHO) guidelines ⁹9. World Health Organization. World health statistics: 2012. v. 27. Geneva: World Health Organization; 2012., with obesity in older males defined as WC greater than 102cm and in older females as WC greater than 88cm. WHO cutoff points for overall obesity ¹1. World Health Organization. Obesity: preventing and managing the global epidemic. Geneva: World Health Organization; 2000. (WHO Technical Report Series, 894). were also adopted, where body mass index (BMI) > 30kg/m² is considered obesity in both sexes.

Weight was measured with a calibrated portable scale (Britania, Joinville, Brazil), with a capacity of 150kg and accurate to 100g. Participants were weighed just once, barefoot and wearing light clothing. Height was measured twice with a tape measure stadiometer, accurate to 1mm. Subjects were measured in standing position, barefoot, with their feet together and their heels, buttocks, and head in contact with the stadiometer, head in the Frankfurt plane, arms handing loosely by their sides, and shoulders relaxed ³⁰30. Chumlea W, Guo S, Roche A, Steinbaugh M. Prediction of body weight for the nonambulatory elderly from anthropometry. J Am Diet Assoc 1988; 88:564-8.. WC was measured with a non-extensible anthropometric tape measure, 160cm long (Sanny, São Bernardo do Campo, Brazil), with resolution to 1mm, with the individual in standing position. The measurement was taken twice, and when there was a difference ≥ 1cm a third measurement was taken. The measurement was taken in the narrowest portion of the trunk below the last rib, identified by the examiner, after the subject had exhaled. For individuals without a visible waist, the reference was the midpoint between the iliac crest and the last rib. The examiner was positioned in front of the subject and kept the area for measurement free of clothing.

Exposure variables

The environmental variables were elaborated previously, using the ArcGIS 9.3 software (ArcMap) (Environmental Systems Research Institute, Redlands, USA; http://www.esri.com/software/arcgis/index.html), with the following data from the Florianópolis Institute of Urban Planning (IPUF): (a) street layout (urban layout); (b) blocks and lots; (c) land use; and (d) buildings ³¹31. Giehl MWC, Hallal PC, Weber CC, Schneider IJC, d'Orsi E. Built environment and walking behavior among Brazilian older adults: a population-based study. J Phys Act Health 2015; 13:617-24..

Elaboration of the environmental variables used editing and updating of IPUF data through georeferenced aerial photographs from 2010 and updated images available on Google Earth (https://www.google.com.br/intl/pt-BR/earth/) and Google Street View (https://www.google.com.br/intl/pt/streetview/). Additional socioeconomic and infrastructure information from around the households was used, published by the Brazilian Institute of Geography and Statistics (IBGE), from Brazil’s 2010 Population Census ²⁷27. Instituto Brasileiro de Geografia e Estatística. Sinopse do censo 2010 e resultados preliminares do universo. Rio de Janeiro: Instituto Brasileiro de Geografia e Estatística; 2011.. These data were available as tables and maps for each census tract, which represented the current study’s unit of analysis. Based on this, the following environmental variables were analyzed:

Contextual income: mean monthly nominal income of heads of permanent private households (with and without income);
Population density: number of inhabitants in the census tract divided by the tract’s area in square kilometers;
Percentage of public lighting in the census tract: this information was determined by direct observation by IBGE staffers, recording whether there was at least one public light post on the same or opposite side of the street from the household. This information was used to determine the percentage of public lighting in the census tract, dividing the total number of households with public lighting by the total number of households in the tract, multiplied by 100;
Percentage of paved streets in the census tract: existence of paving (public byway covered with asphalt, concrete, cobblestones, etc.) on the stretch in front of the household. Calculation: number of households with paving divided by total households, multiplied by 100;
Percentage of sidewalks in the census tract: existence of a sidewalk or walkway (concrete or paved) in front of the household. Calculation: number of households with sidewalks divided by total households, multiplied by 100;
Street density: area served by streets inside the tract, in square kilometers, divided by the tract’s total area;
Intersection density (street connectivity): number of intersections formed by four or more street segments, divided by the tract’s area in square kilometers, considering both the streets inside the tract and adjacent streets;
Mixed land use (entropy): calculated as the presence or absence of five types of land use (residential, commercial, recreational green areas, institutional, and others) in the tract, and defined by the following formula ³²32. Song Y, Rodríguez DA. The measurement of the level of mixed land uses: a synthetic approach. Chapel Hill: Carolina Transportation Program; 2005. (Carolina Transportation Program White Paper Series).:

-∑kpi*1n pi/(1n k)

where: p = proportion of land use, i = land use category, ln = natural logarithm, k = number of 141 uses. The entropy index varies from 0 to 1, where 0 indicates homogeneity (predominance of only type of land use) and 1 indicates heterogeneity (equal distribution of all land use categories);

Recreational green areas in the tract: public domain recreational green areas, e.g., playgrounds, gardens, squares, neighborhood parks, city parks, or metropolitan parks. Calculation: presence or absence of recreational green areas inside the tract (whether or not the area was contained totally within the tract);

Percentage of commerce in the tract: area classified as commercial divided by total land use area in the tract, multiplied by 100;

After the formulation, all the contextual exposure variables were grouped with the other individual variables in a single data bank using the command “merge”, with the census tract variable as the identifier.

Individual level adjustment variables

The individual adjustment variables were: sex (male, female), age bracket (60 to 69 years, 70 to 79, and 80 or older), schooling (≤ 4 years of school, 5 to 8, 9 to 11, and ≥ 12) and per capita income (calculated by dividing family income by the number of residents in the household and categorized in quartiles).

Data analysis

Initially, the interviewees’ addresses were updated in relation to the baseline, excluding those who had moved to different census tracts from the study’s sample. Descriptive analyses of the sample’s distribution considered the outcomes’ prevalence rates and respective 95% confidence intervals (95%CI) for each of the individual and contextual variables. Associations between environmental variables and outcomes were analyzed with multilevel logistic regression models, using all the contextual variables categorized in distribution tertiles. The choice of this analytical model was based on the observed values from the likelihood ratio test for comparison between models ³³33. Dupont WD. Statistical modeling for biomedical researchers: a simple introduction to the analysis of complex data. New York: Cambridge University Press; 2009..

The first level of analysis consisted of the individuals, with census tracts as the second level. First the null model was tested (with random interception, but without the exploratory variables) for each outcome, and after this stage, separate multilevel models were created for each contextual variable. Thus, first the crude models were tested for associations between each environmental characteristic and each outcome. Next, the adjusted models were tested for the individual-level variables (sex, age bracket, schooling, and income). No collinearity was observed between the exposure variables (VIF = 2.26), and all the models were stratified by sex, considering the significant results of the interaction analyses for this variable (p < 0.05). Post-estimation analyses were also performed for each of the models using two parameters - calculation of the predicted values and the likelihood ratio test. The first showed positive values for the outcomes in the absence of the models’ effect variation, and the second confirmed the null hypothesis for the observed coefficients, both indicating that the models adequately fit the data.

Multilevel models can be represented by the following equation, where Yi is the outcome coefficient, B0 the intercept, and Xi and Wj the individual and contextual exposure variables, respectively. Random effect is represented by the letter u and the model’s residuals by the letter e³⁴34. Wagner KJP, Boing AF, Subramanian SV, Hofelmann DA, d'Orsi E. Effects of neighborhood socioeconomic status on blood pressure in older adults. Rev Saúde Pública 2016; 50:78..

Yij=B0j+B1*X1ij+…+B5j*X5ij+eij

where:

B0j=γ00+γ0j*Wj+u0j;

Bij=γi0+γi1*Wj+u1j

For each model, the intra-class correlation coefficient (ICC) was calculated to estimate the total percentage variance of each outcome attributed to the differences between the census tracts. The formula for calculating ICC for logistic models is (variance of level 2/(variance of level 2 + (π^2/3))).

All analyses were performed with the Stata software, version 13.0 (StataCorp LP, College Station, USA) and considered the recalculated sampling weights according to the variables in which selective losses to follow-up were identified. Results with p < 0.05 were considered statistically significant.

Ethical aspects

The study was approved by the Ethics Research Committee of the Federal University of Santa Catarina (UFSC), under case review 352/2008 at baseline in 2009/2010, and the Certificate of Submission for Ethical Review (CAAE) n. 16731313.0.0000.0121 in the 2013/2014 wave. Participating older adults received orientation on the study’s objectives and signed the free and informed consent form. For older adults who were unable to sign the form, a legal guardian was asked to sign.

Results

In 2013/2014, 1,197 older adults were interviewed, or 70.2% of the original cohort. There was a selective loss to follow-up among older adults in the sample (from 2009/2010 to 2013/2014) in relation to the variables sex and age bracket. Men died more than women, but the percentage of refusals was higher in women. The 60-69-year age bracket showed the highest percentage of losses, while the 80-and-over bracket had the highest percentage of deaths. Considering health conditions, there was a higher absolute number of losses in older adults with overweight/obesity (9% of the sample), but the highest relative loss was in the group of normal-weight older adults (11% of the sample). As for socioeconomic variables, there was a higher loss of older adults from the second income quartile (1.7% of the sample).

Mean age of the older subjects was 73.9 years (standard deviation 7.2 years), with a higher proportion of women in the sample (65%). The largest share of the sample subjects were 70 to 79 years of age and had up to four years of schooling (42.5%). Median monthly per capita income was BRL 1,326.66 (USD 402 in current values) (interquartile interval = BRL 2,080.00). Prevalence of overall obesity was 17.3% in men and 34.8% in women. For abdominal obesity, women also showed higher prevalence rates than men, with 64.5% versus 36.7%, respectively.

Differences in the prevalence of overall and abdominal obesity were also observed between men and women according to age, schooling, and per capita income. In general, younger women and those with higher income and schooling showed higher percentages of overall and abdominal obesity. Meanwhile, the highest percentages in men were found in those with intermediate age and schooling and high income (Table 1).

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Table 1
Individual and contextual characteristics of the sample. EpiFloripa Older Adults Study, 2013/2014, Florianópolis, Santa Catarina State, Brazil.

Table 2 shows the results of multilevel logistic regression with abdominal obesity as the outcome. The values with the adjusted model showed that older women residing in places with intermediate mean income and higher percentage of paved streets showed lower odds of abdominal obesity. For older men, no significant association was observed. Table 3 shows the multilevel logistic regression with overall obesity as the outcome. In the adjusted model, intermediate mean income was associated with lower odds of obesity among women, while better street connectivity and intermediate percentage of local commerce were associated with lower odds of overall obesity in men.

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Table 2
Multilevel logistic regression analysis of contextual variables and abdominal obesity, according to sex. EpiFloripa Older Adults Study 2013/2014, Florianópolis, Santa Catarina State, Brazil.

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Table 3
Multilevel logistic regression analysis of contextual variables and overall obesity, according to sex. EpiFloripa Older Adults Study 2013/2014, Florianópolis, Santa Catarina State, Brazil.

Calculation of estimated ICC for the null models of the two outcomes (overall and abdominal obesity) ranged from 0% to 5.18% in both sexes. The adjusted models, after inclusion of the individual variables, did not substantially modify the observed ICC values in the null models, independently of the target outcome and sex.

Discussion

According to the study’s main results, for older women, census tracts with intermediate mean income were associated with lower odds of abdominal and overall obesity, and higher percentage of paved streets was associated with lower odds of abdominal obesity. For older men, better street connectivity and intermediate percentage of commerce were associated with lower odds of overall obesity.

Corroborating the current study’s results, other researchers have shown that neighborhoods with worse social and economic conditions (lower income and higher unemployment) are associated with higher odds of overall obesity in older women in England and in older adults of both sexes in the United States ¹⁹19. Bell JA, Hamer M, Shankar A. Gender-specific associations of objective and perceived neighborhood characteristics with body mass index and waist circumference among older adults in the English Longitudinal Study of Ageing. Am J Public Health 2014; 104:1279-86.^,²³23. Glass TA, Rasmussen MD, Schwartz BS. Neighborhoods and obesity in older adults. The Baltimore Memory Study. Am J Prev Med 2006; 31:455-63.. The mean income of the census tract generally represents its level of wealth and is related to the local infrastructure and supply of opportunities. Neighborhoods with better infrastructure tend to encourage healthier lifestyles, since they offer spaces for leisure and physical activity, which helps maintain adequate weight ¹⁸18. King AC, Sallis JF, Frank LD, Saelens BE, Cain K, Conway TL, et al. Aging in neighborhoods differing in walkability and income: associations with physical activity and obesity in older adults. Soc Sci Med 2011; 73:1525-33.. In addition, poorer neighborhoods generally present lower availability and/or accessibility of healthy foods such as fruits, vegetables, and greens, while offering a wider variety of high-calorie foods that contribute substantially to weight gain ¹⁴14. Pruchno R, Wilson-Genderson M, Gupta AK. Neighborhood food environment and obesity in community-dwelling older adults: individual and neighborhood effects. Am J Public Health 2014; 104:924-9.^,³⁵35. Renalds A, Smith TH, Hale PJ. A systematic review of built environment and health. Fam Community Health 2010; 33:68-78..

The significant association between intermediate mean income in the census tract and lower odds of obesity in older women may be due to the fact that the sample only included individuals from inside the city limits, where socioeconomic inequalities between census tracts may be smaller. At any rate, it is necessary to analyze other socioeconomic variables, such as employment and unemployment levels and inequality in income distribution (e.g., Gini coefficient) between the tracts, which have also been associated with worse health behaviors in the Brazilian population ³⁶36. Celeste RK, Fritzell J. The relationship between levels of income inequality and dental caries and periodontal diseases. Cad Saúde Pública 2011; 27:1111-20.^,³⁷37. Vettore MV, Amorim RA, Peres MA. Desigualdades sociais e doença periodontal no estudo SBBrasil 2010: abordagem multinível. Rev Saúde Pública 2013; 47 Suppl 3:29-39. and could help shed light on the observed association.

The observed associations between higher percentages of street paving and connectivity and lower odds of obesity also corroborate previous studies ¹⁵15. Troped PJ, Starnes HA, Puett RC, Tamura K, Cromley EK, James P, et al. Relationships between the built environment and walking and weight status among older women in three U.S. States. J Aging Phys Act 2014; 22:114-25.^,¹⁸18. King AC, Sallis JF, Frank LD, Saelens BE, Cain K, Conway TL, et al. Aging in neighborhoods differing in walkability and income: associations with physical activity and obesity in older adults. Soc Sci Med 2011; 73:1525-33.^,²⁰20. Frank LD, Andresen MA, Schmid TL. Obesity relationships with community design, physical activity, and time spent in cars. Am J Prev Med 2004; 27:87-96.. Unpaved streets with few sidewalks, with various route options, and low connectivity stimulate the use of transportation and tend to make older adults more sedentary and thus suffer higher odds of becoming obese ³⁸38. Frank L, Kerr J, Rosenberg D, King A. Healthy aging and where you live: community design relationships with physical activity and body weight in older Americans. J Phys Act Health 2010; 7 Suppl 1:S82-90.. Meanwhile, the higher percentage of local commerce reflects greater access to common destinations such as restaurants, supermarkets, shops, and services, which promotes commuting on foot and other active behaviors ¹³13. Tucker-Seeley RD, Subramanian SV, Li Y, Sorensen G. Neighborhood safety, socioeconomic status, and physical activity in older adults. Am J Prev Med 2009; 37:207-13.^,¹⁸18. King AC, Sallis JF, Frank LD, Saelens BE, Cain K, Conway TL, et al. Aging in neighborhoods differing in walkability and income: associations with physical activity and obesity in older adults. Soc Sci Med 2011; 73:1525-33.. The absence or low proportion of paved streets in neighborhoods can also contribute to a lower supply of services focused on the prevention of obesity, such as workout gyms and recreational clubs ³⁹39. Gao J, Fu H, Li J, Jia Y. Association between social and built environments and leisure-time physical activity among Chinese older adults: a multilevel analysis. BMC Public Health 2015; 15:1317..

The built environment is further capable of directly impacting the formation and maintenance of social ties between residents, since neighborhoods with relatively more public spaces and adequate paving provide greater opportunities for leisure and interaction between neighbors and thereby favor healthier lifestyles ⁴⁰40. McNeill LH, Kreuter MW, Subramanian SV. Social environment and physical activity: a review of concepts and evidence. Soc Sci Med 2006; 63:1011-22.. Nevertheless, the evidence between built environment and obesity is still limited and should be analyzed with caution. The current study did not identify significant associations with many of the target variables. One hypothesis that could explain this lack of more associations is that obesity is considered an outcome influenced more distally by the target variables from the built environment, as compared, for example, to physical activity ¹⁵15. Troped PJ, Starnes HA, Puett RC, Tamura K, Cromley EK, James P, et al. Relationships between the built environment and walking and weight status among older women in three U.S. States. J Aging Phys Act 2014; 22:114-25.^,⁴¹41. Cummins S, Curtis S. Understanding and representing "place" in health research: a relational approach. Soc Sci Med 2007; 65:1825-38.. Likewise, many of the explanations for the relationship between the built environment and obesity relate to concepts that involve local social and cultural aspects, which were also not measured directly in the exposures analyzed here.

The fact that better street connectivity only showed an association for older men may be due to gender differences in exposure to the neighborhood environment. In younger adulthood, it is common for women to interact more with their environment when compared to men, since they tend to perform multiple tasks that involve shopping, accompanying children to and from school, and more frequent involvement with physical and leisure-time activities ⁴²42. Humpel N, Owen N, Leslie E. Environmental factors associated with adults' participation in physical activity: a review. Am J Prev Med 2002; 22:188-99.. Meanwhile, older women spend more time on household activities as the result of retirement and lower participation in paid work activities ⁴³43. Banks J, Breeze E, Lessof C, Nazroo J, editors. Retirement, health and relationships of the older population in England. The 2004 English Longitudinal Study of Ageing (Wave 2). London: The Institute for Fiscal Studies; 2006.. In addition, with advancing age, women show lower prevalence of diseases (including obesity) and lower mortality rates ⁴⁴44. Chaimowicz F. Epidemiologia e o envelhecimento no Brasil. In: Freitas EV, organizador. Tratado de geriatria e gerontologia. Rio de Janeiro: Editora Guanabara Koogan; 2006. p. 89-105.^,⁴⁵45. Van Oyen H, Nusselder W, Jagger C, Kolip P, Cambois E, Robine JM. Gender differences in healthy life years within the EU: an exploration of the "health-survival" paradox. Int J Public Health 2013; 58:143-55. which could contribute to their longer survival and greater difficulties in maintaining healthy behaviors, which would include walking and social interaction in the neighborhood itself.

Although they were beyond the scope of this study, it is important to note the differences found in the prevalence rates of overall and abdominal obesity, where overall was nearly double that of abdominal in both sexes. These results are similar to those of other population studies in older Brazilians ⁴⁶46. Silveira EA, Kac G, Barbosa LS. Prevalência e fatores associados à obesidade em idosos residentes em Pelotas, Rio Grande do Sul, Brasil: classificação da obesidade segundo dois pontos de corte do índice de massa corporal. Cad Saúde Pública 2009; 25:1569-77.^,⁴⁷47. Linhares RS, Horta BL, Gigante DP, Dias-da-Costa JS, Olinto MTA. Distribuição de obesidade geral e abdominal em adultos de uma cidade no Sul do Brasil. Cad Saúde Pública 2012; 28:438-48. and underscore the importance of considering both indicators (BMI and WC) in the classification of obesity, since older adults with overall obesity can also present excess body fat and thus greater exposure to factors that determine morbidity and mortality ⁴⁸48. Choi KM, Cho HJ, Choi HY, Yang SJ, Yoo HJ, Seo JA, et al. Higher mortality in metabolically obese normal-weight people than in metabolically healthy obese subjects in elderly Koreans. Clin Endocrinol (Oxf) 2013; 79:364-70..

Another finding that indicates the interrelationship in the use of the two anthropometric indicators involves the fact that abdominal obesity only showed significant associations in women. There are known differences between the sexes in body fat patterns in older adults, with a greater tendency for women to accumulate central fat. In men, fat tends to concentrate more in peripheral areas of the body ⁴⁹49. Krause MP, Buzzachera CF, Hallage T, Santos ECR, Silva SG. Alterações morfológicas relacionadas à idade em idosos. Rev Bras Cineantropom Desempenho Hum 2006; 8:73-7.. These disparities indicate that both WC and BMI are relevant and complementary in the analysis of obesity, with WC more efficient for predicting risk of endocrine and metabolic diseases and BMI for identifying energy reserves and estimating total body fat ⁵⁰50. Anjos LA. Índice de massa corporal como indicador de estado nutricional de adultos: revisão da literatura. Rev Saúde Pública 1992; 26:431-6.^,⁵¹51. Micozzi MS, Harris TM. Age variations in the relation of body mass indices to estimates of body fat and muscle mass. Am J Phys Anthropol 1990; 81:375-9..

In addition, although a strong correlation exists between WC and BMI as indicators for estimating obesity, the correlation proves less intense in women than in men, since even with normal weight, women tend to accumulate more abdominal fat. Thus, although subtle, such differences could explain the loss of association between BMI and street paving in women ⁵²52. Zamboni M, Turcato E, Armellini F, Kahn HS, Zivelonghi A, Santana H, et al. Sagittal abdominal diameter as a practical predictor of visceral fat. Int J Obes Relat Metab Disord 1998; 22:655-60.. Meanwhile, for men, BMI was associated with street connectivity and intermediate commerce, while the same was not observed with WC. We believe that in addition to the reasons already cited, BMI, especially when analyzed in older adults, tends to suffer the heterogeneity that accompanies the aging process, which underscores the fact that it should not be used as the only measure of obesity in this age group ⁵³53. Landi F, Onder G, Gambassi G, Pedone C, Carbonin P, Bernabei R. Body mass index and mortality among hospitalized patients. Arch Intern Med 2000; 160:2641-4..

The current study’s strengths feature the fact that as far we know, this is the first study in Brazil that aimed to investigate the association in older adults between overall and abdominal obesity and different objective variables in the built environment. As for the chosen methodology, in addition to the high response rate, the use of directly measured BMI and WC contributed to the data’s quality, eliminating the inherent bias of self-reported outcomes. Likewise, the use of objective contextual variables obtained from the Geographic Information System (GIS) must have expressed the built environment in more detail. And although the cross-sectional design may have impacted the cause and effect relations, it can indicate the magnitude of associations and point to new hypotheses for future studies ⁵⁴54. Bastos JLD, Duquia RP. Um dos delineamentos mais empregados em epidemiologia: estudo transversal. Sci Med 2007; 17:229-32.. The potential limitations include the fact that the data were not originally collected to be associated with obesity, and that the dimension analyzed was the census tract, viewed in this study as representing the neighborhood. However, this measure may not have accurately represented the environment to which older adults were exposed.

Even with the few associations observed in the study, it is clear that the built environment exerts some influence on the prevalence of obesity in older adults. The fact that older adults are the fastest growing age group in Brazil and in the world 1 and the intense use that older adults make of the neighborhood environment ²¹21. Robert SA. Socioeconomic position and health: the independent contribution of community socioeconomic context. Annu Rev Sociol 1999; 25:489-516. highlight the importance of promoting policies to improve socioeconomic conditions and infrastructure in communities, aimed at better opportunities for older adults to maintain healthy habits where they live ⁵⁵55. Sun F, Norman IJ, While AE. Physical activity in older people: a systematic review. BMC Public Health 2013; 13:449.. New studies on this theme are necessary to investigate the long-term influence of living in favorable versus unfavorable environments for the prevention of obesity.

Acknowledgments

Thanks are due to the faculty of the Santa Catarina Federal Univeristy Graduate Studies Program in Public Health, the team involved in the EpiFloripa Older Adults study, and all the individuals who generously shared their time to participate in the study.

References

¹
World Health Organization. Obesity: preventing and managing the global epidemic. Geneva: World Health Organization; 2000. (WHO Technical Report Series, 894).
²
Gutiérrez-Fisac JL, León-Muñoz LM, Regidor E, Banegas J, Rodríguez-Artalejo F. Trends in obesity and abdominal obesity in the older adult population of Spain (2000-2010). Obes Facts 2013; 6:1-8.
³
Mitchell RJ, Lord SR, Harvey LA, Close JCT. Associations between obesity and overweight and risk of falls, health status and quality of life in the elderly. Aust N Z J Public Health 2014; 38:13-8.
⁴
de Groot LC, Verheijden MW, de Henauw S, Schroll M, van Staveren WA; SENECA Investigators. Lifestyle, nutritional status, health, and mortality in elderly people across Europe: a review of the longitudinal results of the SENECA study. J Gerontol A Biol Sci Med Sci 2004; 59:1277-84.
⁵
Tamakoshi A, Kawado M, Ozasa K, Tamakoshi K, Lin Y, Yagyu K, et al. Impact of smoking and other lifestyle factors on life expectancy among Japanese: findings from the Japan Collaborative Cohort (JACC) Study. J Epidemiol 2010; 20:370-6.
⁶
Pink B, Allbon P. The health and welfare of Australia's Aboriginal and Torres Strait Islander peoples 2008. Canberra: Australian Bureau of Statistics/Australian Institute of Health and Welfare; 2008. (ABS Catalogue, 4704.0/AIHW Catalogue, IHW 21).
⁷
Al Snih S, Graham JE, Kuo YF, Goodwin JS, Markides KS, Ottenbacher KJ. Obesity and disability: relation among older adults living in Latin America and the Caribbean. Am J Epidemiol 2010; 171:1282-8.
⁸
Instituto Brasileiro de Geografia e Estatística. Pesquisa Nacional de Saúde 2013. Rio de Janeiro: Instituto Brasileiro de Geografia e Estatística; 2014.
⁹
World Health Organization. World health statistics: 2012. v. 27. Geneva: World Health Organization; 2012.
¹⁰
Tchernof A, Després J-P. Pathophysiology of human visceral obesity: an update. Physiol Rev 2013; 93:359-404.
¹¹
Wu CY, Chou YC, Huang N, Chou YJ, Hu HY, Li CP. Association of body mass index with all-cause and cardiovascular disease mortality in the elderly. PLoS One 2014; 9:e102589.
¹²
Oliveira TC, Medeiros WR, Lima KC. Diferenciais de mortalidade por causas nas faixas etárias limítrofes de idosos. Rev Bras Geriatr Gerontol 2015; 18:85-94.
¹³
Tucker-Seeley RD, Subramanian SV, Li Y, Sorensen G. Neighborhood safety, socioeconomic status, and physical activity in older adults. Am J Prev Med 2009; 37:207-13.
¹⁴
Pruchno R, Wilson-Genderson M, Gupta AK. Neighborhood food environment and obesity in community-dwelling older adults: individual and neighborhood effects. Am J Public Health 2014; 104:924-9.
¹⁵
Troped PJ, Starnes HA, Puett RC, Tamura K, Cromley EK, James P, et al. Relationships between the built environment and walking and weight status among older women in three U.S. States. J Aging Phys Act 2014; 22:114-25.
¹⁶
Morland K, Wing S, Roux AD, Poole C. Neighborhood characteristics associated with the location of food stores and food service places. Am J Prev Med 2002; 22:23-9.
¹⁷
Booth KM, Pinkston MM, Poston WSC. Obesity and the built environment. J Am Diet Assoc 2005; 105(5 Suppl 1):S110-7.
¹⁸
King AC, Sallis JF, Frank LD, Saelens BE, Cain K, Conway TL, et al. Aging in neighborhoods differing in walkability and income: associations with physical activity and obesity in older adults. Soc Sci Med 2011; 73:1525-33.
¹⁹
Bell JA, Hamer M, Shankar A. Gender-specific associations of objective and perceived neighborhood characteristics with body mass index and waist circumference among older adults in the English Longitudinal Study of Ageing. Am J Public Health 2014; 104:1279-86.
²⁰
Frank LD, Andresen MA, Schmid TL. Obesity relationships with community design, physical activity, and time spent in cars. Am J Prev Med 2004; 27:87-96.
²¹
Robert SA. Socioeconomic position and health: the independent contribution of community socioeconomic context. Annu Rev Sociol 1999; 25:489-516.
²²
Berke EM, Koepsell TD, Moudon AV, Hoskins RE, Larson EB. Association of the built environment with physical activity and obesity in older persons. Am J Public Health 2007; 97:486-92.
²³
Glass TA, Rasmussen MD, Schwartz BS. Neighborhoods and obesity in older adults. The Baltimore Memory Study. Am J Prev Med 2006; 31:455-63.
²⁴
Hanibuchi T, Kondo K, Nakaya T, Nakade M, Ojima T, Hirai H, et al. Neighborhood food environment and body mass index among Japanese older adults: results from the Aichi Gerontological Evaluation Study (AGES). Int J Health Geogr 2011; 10:43.
²⁵
Shiue I. Associated social factors of body mass index in adults and the very old in the UK. Int J Cardiol 2013; 168:543-5.
²⁶
Boing AF, Subramanian SV. The influence of area-level education on body mass index, waist circumference and obesity according to gender. Int J Public Health 2015; 60:727-36.
²⁷
Instituto Brasileiro de Geografia e Estatística. Sinopse do censo 2010 e resultados preliminares do universo. Rio de Janeiro: Instituto Brasileiro de Geografia e Estatística; 2011.
²⁸
Confortin SC, Jayce I, Schneider C, Antes DL, Cembranel F, Ono LM, et al. Condições de vida e saúde de idosos: resultados do estudo de coorte EpiFloripa Idoso. Epidemiol Serv Saúde 2017; 26:305-17.
²⁹
Friis RH, Sellers T. Epidemiology for public health practice. Burlington: Jones & Bartlett Publishers; 2013.
³⁰
Chumlea W, Guo S, Roche A, Steinbaugh M. Prediction of body weight for the nonambulatory elderly from anthropometry. J Am Diet Assoc 1988; 88:564-8.
³¹
Giehl MWC, Hallal PC, Weber CC, Schneider IJC, d'Orsi E. Built environment and walking behavior among Brazilian older adults: a population-based study. J Phys Act Health 2015; 13:617-24.
³²
Song Y, Rodríguez DA. The measurement of the level of mixed land uses: a synthetic approach. Chapel Hill: Carolina Transportation Program; 2005. (Carolina Transportation Program White Paper Series).
³³
Dupont WD. Statistical modeling for biomedical researchers: a simple introduction to the analysis of complex data. New York: Cambridge University Press; 2009.
³⁴
Wagner KJP, Boing AF, Subramanian SV, Hofelmann DA, d'Orsi E. Effects of neighborhood socioeconomic status on blood pressure in older adults. Rev Saúde Pública 2016; 50:78.
³⁵
Renalds A, Smith TH, Hale PJ. A systematic review of built environment and health. Fam Community Health 2010; 33:68-78.
³⁶
Celeste RK, Fritzell J. The relationship between levels of income inequality and dental caries and periodontal diseases. Cad Saúde Pública 2011; 27:1111-20.
³⁷
Vettore MV, Amorim RA, Peres MA. Desigualdades sociais e doença periodontal no estudo SBBrasil 2010: abordagem multinível. Rev Saúde Pública 2013; 47 Suppl 3:29-39.
³⁸
Frank L, Kerr J, Rosenberg D, King A. Healthy aging and where you live: community design relationships with physical activity and body weight in older Americans. J Phys Act Health 2010; 7 Suppl 1:S82-90.
³⁹
Gao J, Fu H, Li J, Jia Y. Association between social and built environments and leisure-time physical activity among Chinese older adults: a multilevel analysis. BMC Public Health 2015; 15:1317.
⁴⁰
McNeill LH, Kreuter MW, Subramanian SV. Social environment and physical activity: a review of concepts and evidence. Soc Sci Med 2006; 63:1011-22.
⁴¹
Cummins S, Curtis S. Understanding and representing "place" in health research: a relational approach. Soc Sci Med 2007; 65:1825-38.
⁴²
Humpel N, Owen N, Leslie E. Environmental factors associated with adults' participation in physical activity: a review. Am J Prev Med 2002; 22:188-99.
⁴³
Banks J, Breeze E, Lessof C, Nazroo J, editors. Retirement, health and relationships of the older population in England. The 2004 English Longitudinal Study of Ageing (Wave 2). London: The Institute for Fiscal Studies; 2006.
⁴⁴
Chaimowicz F. Epidemiologia e o envelhecimento no Brasil. In: Freitas EV, organizador. Tratado de geriatria e gerontologia. Rio de Janeiro: Editora Guanabara Koogan; 2006. p. 89-105.
⁴⁵
Van Oyen H, Nusselder W, Jagger C, Kolip P, Cambois E, Robine JM. Gender differences in healthy life years within the EU: an exploration of the "health-survival" paradox. Int J Public Health 2013; 58:143-55.
⁴⁶
Silveira EA, Kac G, Barbosa LS. Prevalência e fatores associados à obesidade em idosos residentes em Pelotas, Rio Grande do Sul, Brasil: classificação da obesidade segundo dois pontos de corte do índice de massa corporal. Cad Saúde Pública 2009; 25:1569-77.
⁴⁷
Linhares RS, Horta BL, Gigante DP, Dias-da-Costa JS, Olinto MTA. Distribuição de obesidade geral e abdominal em adultos de uma cidade no Sul do Brasil. Cad Saúde Pública 2012; 28:438-48.
⁴⁸
Choi KM, Cho HJ, Choi HY, Yang SJ, Yoo HJ, Seo JA, et al. Higher mortality in metabolically obese normal-weight people than in metabolically healthy obese subjects in elderly Koreans. Clin Endocrinol (Oxf) 2013; 79:364-70.
⁴⁹
Krause MP, Buzzachera CF, Hallage T, Santos ECR, Silva SG. Alterações morfológicas relacionadas à idade em idosos. Rev Bras Cineantropom Desempenho Hum 2006; 8:73-7.
⁵⁰
Anjos LA. Índice de massa corporal como indicador de estado nutricional de adultos: revisão da literatura. Rev Saúde Pública 1992; 26:431-6.
⁵¹
Micozzi MS, Harris TM. Age variations in the relation of body mass indices to estimates of body fat and muscle mass. Am J Phys Anthropol 1990; 81:375-9.
⁵²
Zamboni M, Turcato E, Armellini F, Kahn HS, Zivelonghi A, Santana H, et al. Sagittal abdominal diameter as a practical predictor of visceral fat. Int J Obes Relat Metab Disord 1998; 22:655-60.
⁵³
Landi F, Onder G, Gambassi G, Pedone C, Carbonin P, Bernabei R. Body mass index and mortality among hospitalized patients. Arch Intern Med 2000; 160:2641-4.
⁵⁴
Bastos JLD, Duquia RP. Um dos delineamentos mais empregados em epidemiologia: estudo transversal. Sci Med 2007; 17:229-32.
⁵⁵
Sun F, Norman IJ, While AE. Physical activity in older people: a systematic review. BMC Public Health 2013; 13:449.

Publication Dates

Publication in this collection
10 May 2018

History

Received
11 Apr 2017
Reviewed
25 Sept 2017
Accepted
31 Oct 2017

Este é um artigo publicado em acesso aberto sob uma licença Creative Commons

[1] ¹
World Health Organization. Obesity: preventing and managing the global epidemic. Geneva: World Health Organization; 2000. (WHO Technical Report Series, 894).

[2] ²
Gutiérrez-Fisac JL, León-Muñoz LM, Regidor E, Banegas J, Rodríguez-Artalejo F. Trends in obesity and abdominal obesity in the older adult population of Spain (2000-2010). Obes Facts 2013; 6:1-8.

[3] ³
Mitchell RJ, Lord SR, Harvey LA, Close JCT. Associations between obesity and overweight and risk of falls, health status and quality of life in the elderly. Aust N Z J Public Health 2014; 38:13-8.

[4] ⁴
de Groot LC, Verheijden MW, de Henauw S, Schroll M, van Staveren WA; SENECA Investigators. Lifestyle, nutritional status, health, and mortality in elderly people across Europe: a review of the longitudinal results of the SENECA study. J Gerontol A Biol Sci Med Sci 2004; 59:1277-84.

[5] ⁵
Tamakoshi A, Kawado M, Ozasa K, Tamakoshi K, Lin Y, Yagyu K, et al. Impact of smoking and other lifestyle factors on life expectancy among Japanese: findings from the Japan Collaborative Cohort (JACC) Study. J Epidemiol 2010; 20:370-6.

[6] ⁶
Pink B, Allbon P. The health and welfare of Australia's Aboriginal and Torres Strait Islander peoples 2008. Canberra: Australian Bureau of Statistics/Australian Institute of Health and Welfare; 2008. (ABS Catalogue, 4704.0/AIHW Catalogue, IHW 21).

[7] ⁷
Al Snih S, Graham JE, Kuo YF, Goodwin JS, Markides KS, Ottenbacher KJ. Obesity and disability: relation among older adults living in Latin America and the Caribbean. Am J Epidemiol 2010; 171:1282-8.

[8] ⁸
Instituto Brasileiro de Geografia e Estatística. Pesquisa Nacional de Saúde 2013. Rio de Janeiro: Instituto Brasileiro de Geografia e Estatística; 2014.

[9] ⁹
World Health Organization. World health statistics: 2012. v. 27. Geneva: World Health Organization; 2012.

[10] ¹⁰
Tchernof A, Després J-P. Pathophysiology of human visceral obesity: an update. Physiol Rev 2013; 93:359-404.

[11] ¹¹
Wu CY, Chou YC, Huang N, Chou YJ, Hu HY, Li CP. Association of body mass index with all-cause and cardiovascular disease mortality in the elderly. PLoS One 2014; 9:e102589.

[12] ¹²
Oliveira TC, Medeiros WR, Lima KC. Diferenciais de mortalidade por causas nas faixas etárias limítrofes de idosos. Rev Bras Geriatr Gerontol 2015; 18:85-94.

[13] ¹³
Tucker-Seeley RD, Subramanian SV, Li Y, Sorensen G. Neighborhood safety, socioeconomic status, and physical activity in older adults. Am J Prev Med 2009; 37:207-13.

[14] ¹⁴
Pruchno R, Wilson-Genderson M, Gupta AK. Neighborhood food environment and obesity in community-dwelling older adults: individual and neighborhood effects. Am J Public Health 2014; 104:924-9.

[15] ¹⁵
Troped PJ, Starnes HA, Puett RC, Tamura K, Cromley EK, James P, et al. Relationships between the built environment and walking and weight status among older women in three U.S. States. J Aging Phys Act 2014; 22:114-25.

[16] ¹⁶
Morland K, Wing S, Roux AD, Poole C. Neighborhood characteristics associated with the location of food stores and food service places. Am J Prev Med 2002; 22:23-9.

[17] ¹⁷
Booth KM, Pinkston MM, Poston WSC. Obesity and the built environment. J Am Diet Assoc 2005; 105(5 Suppl 1):S110-7.

[18] ¹⁸
King AC, Sallis JF, Frank LD, Saelens BE, Cain K, Conway TL, et al. Aging in neighborhoods differing in walkability and income: associations with physical activity and obesity in older adults. Soc Sci Med 2011; 73:1525-33.

[19] ¹⁹
Bell JA, Hamer M, Shankar A. Gender-specific associations of objective and perceived neighborhood characteristics with body mass index and waist circumference among older adults in the English Longitudinal Study of Ageing. Am J Public Health 2014; 104:1279-86.

[20] ²⁰
Frank LD, Andresen MA, Schmid TL. Obesity relationships with community design, physical activity, and time spent in cars. Am J Prev Med 2004; 27:87-96.

[21] ²¹
Robert SA. Socioeconomic position and health: the independent contribution of community socioeconomic context. Annu Rev Sociol 1999; 25:489-516.

[22] ²²
Berke EM, Koepsell TD, Moudon AV, Hoskins RE, Larson EB. Association of the built environment with physical activity and obesity in older persons. Am J Public Health 2007; 97:486-92.

[23] ²³
Glass TA, Rasmussen MD, Schwartz BS. Neighborhoods and obesity in older adults. The Baltimore Memory Study. Am J Prev Med 2006; 31:455-63.

[24] ²⁴
Hanibuchi T, Kondo K, Nakaya T, Nakade M, Ojima T, Hirai H, et al. Neighborhood food environment and body mass index among Japanese older adults: results from the Aichi Gerontological Evaluation Study (AGES). Int J Health Geogr 2011; 10:43.

[25] ²⁵
Shiue I. Associated social factors of body mass index in adults and the very old in the UK. Int J Cardiol 2013; 168:543-5.

[26] ²⁶
Boing AF, Subramanian SV. The influence of area-level education on body mass index, waist circumference and obesity according to gender. Int J Public Health 2015; 60:727-36.

[27] ²⁷
Instituto Brasileiro de Geografia e Estatística. Sinopse do censo 2010 e resultados preliminares do universo. Rio de Janeiro: Instituto Brasileiro de Geografia e Estatística; 2011.

[28] ²⁸
Confortin SC, Jayce I, Schneider C, Antes DL, Cembranel F, Ono LM, et al. Condições de vida e saúde de idosos: resultados do estudo de coorte EpiFloripa Idoso. Epidemiol Serv Saúde 2017; 26:305-17.

[29] ²⁹
Friis RH, Sellers T. Epidemiology for public health practice. Burlington: Jones & Bartlett Publishers; 2013.

[30] ³⁰
Chumlea W, Guo S, Roche A, Steinbaugh M. Prediction of body weight for the nonambulatory elderly from anthropometry. J Am Diet Assoc 1988; 88:564-8.

[31] ³¹
Giehl MWC, Hallal PC, Weber CC, Schneider IJC, d'Orsi E. Built environment and walking behavior among Brazilian older adults: a population-based study. J Phys Act Health 2015; 13:617-24.

[32] ³²
Song Y, Rodríguez DA. The measurement of the level of mixed land uses: a synthetic approach. Chapel Hill: Carolina Transportation Program; 2005. (Carolina Transportation Program White Paper Series).

[33] ³³
Dupont WD. Statistical modeling for biomedical researchers: a simple introduction to the analysis of complex data. New York: Cambridge University Press; 2009.

[34] ³⁴
Wagner KJP, Boing AF, Subramanian SV, Hofelmann DA, d'Orsi E. Effects of neighborhood socioeconomic status on blood pressure in older adults. Rev Saúde Pública 2016; 50:78.

[35] ³⁵
Renalds A, Smith TH, Hale PJ. A systematic review of built environment and health. Fam Community Health 2010; 33:68-78.

[36] ³⁶
Celeste RK, Fritzell J. The relationship between levels of income inequality and dental caries and periodontal diseases. Cad Saúde Pública 2011; 27:1111-20.

[37] ³⁷
Vettore MV, Amorim RA, Peres MA. Desigualdades sociais e doença periodontal no estudo SBBrasil 2010: abordagem multinível. Rev Saúde Pública 2013; 47 Suppl 3:29-39.

[38] ³⁸
Frank L, Kerr J, Rosenberg D, King A. Healthy aging and where you live: community design relationships with physical activity and body weight in older Americans. J Phys Act Health 2010; 7 Suppl 1:S82-90.

[39] ³⁹
Gao J, Fu H, Li J, Jia Y. Association between social and built environments and leisure-time physical activity among Chinese older adults: a multilevel analysis. BMC Public Health 2015; 15:1317.

[40] ⁴⁰
McNeill LH, Kreuter MW, Subramanian SV. Social environment and physical activity: a review of concepts and evidence. Soc Sci Med 2006; 63:1011-22.

[41] ⁴¹
Cummins S, Curtis S. Understanding and representing "place" in health research: a relational approach. Soc Sci Med 2007; 65:1825-38.

[42] ⁴²
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Variables	n (%)	Abdominal obesity [% (95%CI)]		Overall obesity [% (95%CI)]
Variables	n (%)	Male	Female	Male	Female
Individuals
Sex
Male	419 (35.0)	36.8 (32.1; 41.5)	-	17.3 (13.6; 21.0)	-
Female	778 (65.0)	-	64.5 (61.0; 67.9)	-	34.8 (31.4; 38.2)
Age (years)
60-69	412 (34.4)	32.7 (25.2; 40.1)	63.6 (57.7; 69.6)	19.6 (13.3; 25.9)	38.4 (32.3; 44.4)
70-79	509 (42.5)	41.3 (33.9; 48.7)	69.1 (64.1; 74.1)	18.9 (13.0; 24.9)	38.2 (33.0; 43.4)
≥ 80	276 (23.1)	32.5 (22.3; 42.7)	56.8 (49.3; 64.3)	9.75 (3.3; 16.2)	22.6 (16.1; 29.0)
Schooling (years)
0-4	523 (43.8)	26.6 (22.3; 36.9)	66.3 (61.3; 71.2)	16.1 (10.1; 22.0)	36.4 (31.3; 41.4)
5-8	199 (16.2)	46.8 (34.2; 59.3)	62.6 (54.3; 70.9)	25.8 (14.8; 36.9)	30.0 (22.1; 37.9)
9-11	180 (15.0)	28.1 (16.3; 39.9)	68.0 (59.6; 76.5)	8.7 (1.3; 16.2)	37.8 (29.0; 46.6)
≥ 12	292 (24.4)	42.3 (34.0; 50.7)	59.4 (51.5; 67.4)	18.4 (11.8; 24.9)	33.1 (25.4; 40.8)
Per capita income
First quartile	-	31.2 (20.7; 41.6)	63.0 (56.4; 69.7)	11.9 (4.5; 19.2)	36.7 (29.9; 43.4)
Second quartile	-	31.5 (22.6; 40.3)	59.5 (52.0; 66.7)	19.8 (12.2; 27.4)	29.2 (22.3; 36.1)
Third quartile	-	44.4 (34.0; 54.8)	69.6 (63.0; 76.2)	22.5 (13.7; 31.2)	33.7 (26.9; 40.4)
Fourth quartile	-	38.0 (29.3; 46.7)	67.7 (60.4; 75.0)	14.9 (8.5; 21.3)	39.7 (32.0; 47.5)
Environment
Mean income, head of households (BRL)
818.00-2,052.00	551 (32.3)	30.4 (22.3; 38.5)	70.8 (64.9; 76.6)	16.3 (9.7; 22.8)	41.9 (35.5; 48.2)
2,052.00-3,607.87	666 (39.1)	35.5 (30.9; 46.0)	61.1 (55.6; 66.7)	17.5 (11.6; 23.4)	30.1 (24.8; 35.4)
> 3,607.87	488 (28.6)	39.3 (30.6; 48.0)	62.3 (55.9; 68.7)	18.2 (11.3; 25.1)	33.5 (27.2; 39.8)
Population density (inhabitants/km²)
356.37-3,028.07	603 (35.4)	39.5 (32.2; 46.9)	68.3 (62.6; 74.0)	17.0 (11.4; 22.7)	32.3 (26.7; 38.0)
3,028.07-9,319.06	608 (35.6)	31.5 (23.4; 39.6)	61.1 (55.3; 67.0)	16.8 (10.2; 23.4)	34.6 (28.8; 40.3)
≥ 9,319.06	494 (29.0)	36.7 (27.6; 45.8)	64.1 (57.7; 70.4)	18.3 (11.0; 25.7)	38.0 (31.6; 44.6)
Public lighting (%)
66.90-98.70	522 (36.6)	32.0 (23.8; 40.2)	65.1 (59.1; 71.2)	14.5 (8.27; 20.8)	37.5 (31.4; 43.7)
98.70-100.00	515 (30.2)	39.8 (30.9; 48.7)	59.4 (53.0; 65.9)	16.9 (10.1; 23.8)	31.8 (25.6; 38.0)
100.00	668 (39.2)	37.0 (29.5; 44.4)	67.8 (62.4; 73.2)	19.7 (13.6; 25.9)	34.8 (29.3; 40.4)
Paved street (%)
62.40-94.43	624 (36.6)	37.4 (29.7; 45.1)	66.2 (60.5; 71.8)	17.0 (11.0; 23.0)	34.9 (29.2; 40.7)
94.43-99.80	531 (31.1)	33.6 (25.0; 42.2)	62.8 (56.6; 69.0)	14.3 (7.9; 20.6)	35.9 (29.7; 41.1)
> 99.80	550 (32.3)	37.3 (29.0; 45.5)	64.2 (58.2; 70.2)	20.4 (13.5; 27.3)	33.6 (27.6; 39.5)
Sidewalks (%)
Up to 59.00	618 (36.2)	34.9 (27.2; 42.5)	66.4 (60.7; 72.1)	15.3 (9.5; 21.1)	32.8 (27.1; 38.5)
59.00-97.57	589 (34.6)	36.7 (29.9; 44.4)	67.2 (61.4; 72.9)	18.9 (12.6; 25.7)	36.2 (30.3; 42.2)
> 97.57	498 (29.2)	37.7 (28.4; 47.0)	59.3 (52.9; 65.7)	17.9 (10.6; 25.3)	35.5 (29.3; 41.7)
Street densidade (km²)
3.17-13.97	581 (34.1)	36.0 (28.2; 43.9)	64.9 (59.0; 70.7)	18.7 (12.3; 25.2)	32.2 (26.4; 37.9)
13.97-25.55	653 (38.3)	40.1 (32.2; 48.1)	65.5 (60.0; 71.0)	17.1 (11.0; 23.2)	26.5 (30.9; 42.2)
> 25.55	471 (27.6)	31.6 (23.0; 40.2)	62.6 (56.0; 69.2)	15.8 (9.0; 22.5)	35.8 (29.2; 42.4)
Street conectivity
Up to 3.64	607 (35.6)	39.2 (31.0; 47.5)	65.9 (60.2; 71.6)	23.7 (16.3; 31.0)	35.3 (29.6; 41.1)
3.64-30.94	633 (37.1)	36.2 (29.0; 43.5)	63.0 (57.3; 68.6)	14.6 (9.3; 20.0)	34.3 (28.7; 39.9)
> 30.94	465 (27.3)	32.3 (23.2; 41.5)	64.7 (58.1; 71.3)	13.7 (7.0; 20.4)	34.8 (28.2; 41.4)
Mixed land use (entropy)
0.01-0.49	503 (29.5)	38.2 (29.0; 47.3)	67.1 (60.9; 73.3)	21.3 (13.5; 29.1)	37.4 (31.0; 43.9)
0.49-0.59	582 (34.1)	29.7 (21.7; 37.6)	59.3 (53.5; 65.1)	13.3 (7.4; 19.2)	33.6 (28.0; 39.1)
> 0.59	620 (36.4)	40.0 (32.6; 47.4)	67.8 (62.1; 73.6)	17.8 (12.0; 23.7)	33.9 (27.9; 39.8)
Recreationl green areas
0.0000-0.0001	881 (51.7)	36.6 (29.6; 43.6)	64.4 (59.6; 69.2)	18.3 (12.6; 24.0)	36.8 (32.0; 41.6)
0.0001-0.4500	291 (17.0)	35.2 (24.0; 46.4)	61.4 (52.9; 69.9)	16.9 (8.1; 25.7)	32.5 (24.3; 40.7)
> 0.4500	533 (31.3)	36.4 (28.7; 44.0)	66.2 (60.2; 72.3)	16.3 (10.4; 22.2)	32.7 (26.7; 38.8)

Variables	Female		Male
	Crude	Adjusted *	Crude	Adjusted *
	OR (95%CI)	OR (95%CI)	OR (95%CI)	OR (95%CI)
Mean income in the census tract (BRL)
Low (818.00 < 2,052.00)	1.00	1.00	1.00	1.00
Medium (2,052.00-3,607.00)	0.65 (0.44; 0.96)	0.62 (0.41; 0.94)	1.36 (0.83; 2.24)	1.31 (0.77; 2.22)
High (≥ 3,607.00)	0.63 (0.42; 0.95)	0.63 (0.40; 1.00)	1.02 (0.59; 1.74)	0.85 (0.45; 1.52)
Population density (inhabitants/km²)
Low (356.37 < 3,028.07)	1.00	1.00	1.00	1.00
Medium (3,028.07 < 9,319.06)	0.86 (0.58; 1.26)	0.82 (0.55; 1.22)	0.70 (0.42; 1.16)	0.62 (0.37; 1.05)
High (≥ 9,319.06)	0.82 (0.55; 1.22)	0.85 (0.56; 1.29)	0.95 (0.56; 1.58)	0.86 (0.50; 1.48)
Paved street (%)
Low (62.40 < 94.43)	1.00	1.00	1.00	1.00
Medium (94.43 < 99.80)	0.96 (0.64; 1.42)	0.69 (0.47; 1.03)	0.79 (0.47; 1.35)	1.03 (0.58; 1.82)
High (≥ 99.80)	0.87 (0.59; 1.28)	0.66 (0.44; 0.99) *	1.00 (0.61; 1.65)	1.17 (0.67; 2.04)
Public lighting (%)
Low (66.90 < 98.69)	1.00	1.00	1.00	1.00
Medium (98.69 < 99.99)	0.85 (0.57; 1.28)	0.96 (0.63; 1.46)	1.27 (0.73; 2.22)	1.28 (0.72; 2.28)
High (100.00)	1.06 (0.72; 1.55)	1.09 (0.73; 1.63)	1.18 (0.70; 1.97)	1.10 (0.65; 1.88)
Sidewalks (%)
Low (0.00 < 59.00)	1.00	1.00	1.00	1.00
Medium (59.00 < 97.57)	1.10 (0.74; 1.62)	1.11 (0.74; 1.67)	1.00 (0.61; 1.64)	0.95 (0.57; 1.59)
High (≥ 97.57)	0.81 (0.55; 1.20)	0.87 (0.57; 1.34)	1.08 (0.63; 1.85)	1.02 (0.57; 1.82)
Street conectivity (km²)
Low (0.00 < 3.64)	1.00	1.00	1.00	1.00
Medium (3.64 < 30.94)	0.85 (0.58; 1.24)	0.87 (0.60; 1.29)	0.86 (0.53; 1.40)	0.74 (0.44; 1.23)
High (≥ 30.94)	0.96 (0.63; 1.44)	1.06 (0.68; 1.65)	0.74 (0.42; 1.29)	0.60 (0.33; 1.09)
Commerce in the tract (%)
Low (0.00 < 4.62)	1.00	1.00	1.00	1.00
Medium (4.62 < 12.98)	1.16 (0.78; 1.71)	1.21 (0.81; 1.81)	0.68 (0.40; 1.16)	0.71 (0.41; 1.22)
High (≥ 12.98)	0.83 (0.56; 1.23)	0.84 (0.56; 1.26)	0.80 (0.48; 1.34)	0.72 (0.42; 1.24)
Presence of recreational green areas
Não	1.00	1.00	1.00	1.00
Sim	1.08 (0.75; 1.55)	1.02 (0.70; 1.50)	1.10 (0.69; 1.76)	1.14 (0.71; 1.84)
Mixed land use (entropy)
Low (0.01 < 0.49)	1.00	1.00	1.00	1.00
Medium (0.49 < 0.59)	0.81 (0.55; 1.20)	0.81 (0.54; 1.21)	0.69 (0.40; 1.21)	0.66 (0.37; 1.17)
High (≥ 0.59)	1.10 (0.73; 1.66)	1.12 (0.74; 1.72)	1.02 (0.61; 1.71)	1.03 (0.61; 1.74)
Street density (km²)
Low (3.17 < 13.97)	1.00	1.00	1.00	1.00
Medium (13.97 < 25.55)	1.12 (0.77; 1.65)	1.21 (0.82; 1.80)	1.07 (0.65; 1.76)	0.96 (0.57; 1.60)
High (≥ 25.55)	0.95 (0.63; 1.42)	1.00 (0.65; 1.55)	0.82 (0.48; 1.39)	0.65 (0.36; 1.15)

Variables	Female		Male
	Crude	Adjusted *	Crude	Adjusted *
	OR (95%CI)	OR (95%CI)	OR (95%CI)	OR (95%CI)
Mean income in the census tract (BRL)
Low (818.00 < 2,052.00)	1.00	1.00	1.00	1.00
Medium (2,052.00-3,607.00)	0.52 (0.34; 0.81)	0.52 (0.33; 0.82)	1.30 (0.71; 2.79)	1.43 (0.75; 2.74)
High (≥ 3,607.00)	0.69 (0.45; 1.08)	0.70 (0.43; 1.15)	0.85 (0.42; 1.71)	1.08 (0.49; 2.36)
Population density (inhabitants/km²)
Low (356.37 < 3,028.07)	1.00	1.00	1.00	1.00
Medium (3,028.07 < 9,319.06)	1.25 (0.80; 1.94)	1.23 (0.78; 1.95)	1.04 (0.56; 1.94)	0.89 (0.47; 1.71)
High (≥ 9,319.06)	1.40 (0.88; 2.21)	1.46 (0.91; 2.36)	1.04 (0.54; 2.00)	1.11 (0.57; 2.17)
Paved street (%)
Low (62.40 < 94.43)	1.00	1.00	1.00	1.00
Medium (94.43 < 99.80)	1.14 (0.72; 1.80)	1.18 (0.73; 1.89)	0.79 (0.40; 1.54)	0.81 (0.41; 1.63)
High (≥ 99.80)	1.00 (0.64; 1.57)	1.05 (0.66; 1.70)	1.06 (0.57; 1.95)	1.18 (0.61; 2.26)
Public lighting (%)
Low (66.90 < 98.69)	1.00	1.00	1.00	1.00
Medium (98.69 < 99.99)	0.82 (0.51; 1.32)	0.86 (0.52; 1.41)	0.97 (0.48; 1.93)	1.07 (0.52; 2.21)
High (100.00)	0.95 (0.61; 1.48)	0.97 (0.61; 1.54)	1.09 (0.58; 2.05)	1.17 (0.60; 2.26)
Sidewalks (%)
Low (0.00 < 59.00)	1.00	1.00	1.00	1.00
Medium (59.00 < 97.57)	1.20 (0.77; 1.87)	1.27 (0.80; 2.02)	1.13 (0.61; 2.08)	1.28 (0.67; 2.43)
High (≥ 97.57)	1.31 (0.83; 2.06)	1.48 (0.91; 2.41)	0.98 (0.50; 1.95)	1.24 (0.59; 2.57)
Street conectivity (km²)
Low (0.00 < 3.64)	1.00	1.00	1.00	1.00
Medium (3.64 < 30.94)	0.82 (0.53; 1.27)	0.86 (0.55; 1.35)	0.55 (0.30; 0.99)	0.54 (0.29; 1.00)
High (≥ 30.94)	1.03 (0.64; 1.64)	1.13 (0.69; 1.87)	0.45 (0.21; 0.91)	0.43 (0.20; 0.94)
Commerce in the tract (%)
Low (0.00 < 4.62)	1.00	1.00	1.00	1.00
Medium (4.62 < 12.98)	0.77 (0.50; 1.20)	0.80 (0.51; 1.25)	0.45 (0.22; 0.89)	0.46 (0.23; 0.95)
High (≥ 12.98)	0.70 (0.45; 1.11)	0.69 (0.43; 1.11)	0.77 (0.42; 1.42)	0.95 (0.50; 1.79)
Presence of recreational green areas
Não	1.00	1.00	1.00	1.00
Sim	0.85 (0.51; 1.44)	0.83(0.49; 1.41)	0.92 (0.43; 1.96)	0.90 (0.41; 1.98)
Mixed land use (entropy)
Low (0.01 < 0.49)	1.00	1.00	1.00	1.00
Medium (0.49 < 0.59)	0.89 (0.56; 1.41)	0.90 (0.56; 1.44)	0.49 (0.25; 0.97)	0.52 (0.26; 1.05)
High (≥ 0.59)	0.92 (0.58; 1.47)	0.90 (0.55; 1.45)	0.61 (0.33; 1.14)	0.69 (0.33; 1.29)
Street density (km²)
Low (3.17 < 13.97)	1.00	1.00	1.00	1.00
Medium (13.97 < 25.55)	1.28 (0.83; 1.98)	1.33 (0.85; 2.09)	0.73 (0.39; 1.35)	0.68 (0.36; 1.29)
High (≥ 25.55)	1.31 (0.82; 2.10)	1.45 (0.88; 2.40)	0.74 (0.38; 1.43)	0.79 (0.39; 1.60)