Skip Navigation Links
Centers for Disease Control and Prevention
 CDC Home Search Health Topics A-Z

Preventing Chronic Disease: Public Health Research, Practice and Policy

View Current Issue
Issue Archive
Archivo de números en español








Emerging Infectious Diseases Journal
MMWR


 Home 

Volume 7: No. 3, May 2010

ORIGINAL RESEARCH
Socioeconomic Status and Prevalence of Obesity and Diabetes in a Mexican American Community, Cameron County, Texas, 2004-2007


TABLE OF CONTENTS


Translation available Este artículo en español
Print this article Print this article
E-mail this article E-mail this article:



Send feedback to editors Send feedback to editors
Download this article as a PDF Download this article as a PDF (526K)

You will need Adobe Acrobat Reader to view PDF files.


Navigate This Article
Abstract
Introduction
Methods
Results
Discussion
Acknowledgments
Author Information
References
Tables


Susan P. Fisher-Hoch, MD; Anne R. Rentfro, MSN, PhD; Jennifer J. Salinas, PhD; Adriana Pérez, PhD; H. Shelton Brown, PhD; Belinda M. Reininger, DrPH; Blanca I. Restrepo, PhD; J. Gaines Wilson, PhD; M. Monir Hossain, PhD; Mohammad H. Rahbar, PhD; Craig M. Hanis, PhD; Joseph B. McCormick, MD

Suggested citation for this article: Fisher-Hoch SP, Rentfro AR, Salinas JJ, Pérez A, Brown HS, Reininger BM, et al. Socioeconomic status and prevalence of obesity and diabetes in a Mexican American community, Cameron County, Texas, 2004-2007. Prev Chronic Dis 2010;7(3):A53. http://www.cdc.gov/pcd/issues/2010/
may/09_0170.htm
. Accessed [date].

PEER REVIEWED

Abstract

Introduction
Mexican Americans are at increased risk for obesity and diabetes. We established a cohort on the United States-Mexico border to determine the prevalence of obesity and diabetes in this Mexican American population and to see whether minor economic advantages had any effect on health.

Methods
We randomly selected and extensively documented 810 people aged 35 to 64 years. Weighted data were analyzed to establish prevalence of obesity and diabetes and other markers of poor health such as elevated glycated hemoglobin levels.

Results
Rates of obesity (body mass index ≥30 kg/m2) were 57% in the first (lower) of 4 socioeconomic strata by income and were 55.5% in the third (higher). People in the higher socioeconomic stratum were significantly less likely to have undiagnosed diabetes (2% vs 9%). Among people aged 55 to 64 years, rates of diabetes were significantly higher among those in the lower socioeconomic stratum than among those in the higher stratum. Rates of undiagnosed diabetes had similar differences. Approximately three-fourths of the respondents reported having no health insurance, and we found no difference between people in different socioeconomic strata.

Conclusion
Rates of obesity and diabetes in this border community are among the highest in the United States. Belonging to the lower socioeconomic stratum significantly increased the likelihood of having undiagnosed diabetes and, in patients too young to be eligible for Medicare, the overall risk of developing diabetes. Modest improvement in income has a beneficial effect on health in this racial/ethnic minority community.

Back to top

Introduction

Mexican Americans are at higher risk for obesity and diabetes than the general US population (1-5). The economic and social ramifications of these epidemics are substantial (6,7). In 2006, more than 20 million Americans were estimated to have type 2 diabetes, and nearly one-third of the cases were undiagnosed (8). By 2050, the number of US patients with diagnosed diabetes is projected to rise to 39 million (9). Race and ethnicity, encompassing genetics, culture, economics, and elements of the environment, are underlying risk factors for diabetes (9). In the United States, racial/ethnic minority populations, including Mexican Americans, have a higher risk of diabetes, but this tendency is confounded by socioeconomic status (SES) (10,11). Similarly, even though health in the United States, including diabetes control, improved in general from 1999 through 2006, this did not hold true in socioeconomically disadvantaged racial/ethnic minority populations, particularly before the age of eligibility for Medicare (≥65 years) (10,12).

Racial disparities measured in years of potential life lost from major diseases, including diabetes, are well documented (13). The influx of immigrants from Mexico has been in the forefront of a national debate over the past decade or more. What is often lost in this debate is the health status of Mexican Americans in the United States, and particularly on the United States-Mexico border where they are often the dominant ethnic group. Brownsville (Cameron County, Texas; 2006 population: 172,437 [14]) provides a unique environment to examine health disparities in Mexican Americans in the United States. This community provides an advance view of health outcomes due to demographic changes that are likely to spread to many parts of the country. In 2004, we began to recruit a cohort, now numbering 2,000, drawn from randomly selected households on the basis of 2000 Census tract data (15), with the purpose of establishing a “Framingham-like” cohort in this population. The Framingham cohort originated in 1948 as the Framingham Heart Study, consisting of a random sample of 5,209 adults from Framingham, Massachusetts, aged 30 to 62 years (16). This cohort has grown to serve numerous studies and supply risk factor data for common diseases. The primary objective of our study was to see what effect minor economic advantages might have on the prevalence of obesity and diabetes in a Mexican American population.

Back to top

Methods

Study design

After early discussions with and observations in our community, we decided in 2004 to establish the Cameron County Hispanic Cohort (CCHC). In this study, we randomly selected a subset of people (aged 35-64 years) in CCHC cohort households to determine the influence of SES on diabetes and obesity. By using a 2-stage stratified sampling design, we generated data from 810 people from a total population of 41,199 (55% women, 90% Hispanic).

Participants

From 2004 through 2007, we recruited 2,000 participants to the CCHC who are residents of Brownsville, Texas, which has 8 international crossing points to Matamoros, Mexico. We classified census tracts into 4 strata by income and targeted sampling on the first (lowest) and the third socioeconomic strata. For simplicity, we will call these “lower SES” and “higher SES.” Median annual household income was $17,830 or less for the lower SES stratum and $24,067 to $31,747 for the higher SES stratum (15). The resultant sampling frame from 47 census tracts was 1,579 inhabited census blocks (with a population of 136,366). From the 476 clusters (a cluster is a distinct census block unit in a specific census tract) in the tracts in the lower SES stratum, we selected 42 clusters by simple random sampling. In a similar way, from the 294 tracts in the higher SES stratum we selected 38 clusters. We sampled 11 tracts in the 42 clusters in the lower SES stratum and 11 tracts in the 38 clusters in the higher SES stratum. We omitted 1 in the higher SES stratum because it contained predominantly “winter Texans,” mostly retired winter visitors from the northern United States and Canada, most of whom are not Hispanic. Winter Texans typically cluster geographically and seasonally in rental housing complexes and parks for recreational vehicles (17). We invited all the households in the selected census blocks to participate in the study. Overall, 71% of households approached elected to participate, but more in the lower SES stratum did so (78% vs 63%, P = .03). We then selected 1 person randomly from each household to participate in this study.

The institutional review boards at the University of Texas Health Science Center and the University of Texas at Brownsville reviewed and approved the protocol. They also approved the informed consent forms, which included permission to collect and store de-identified data and specimens for this and other studies.

Main outcome measures

Two nurses and 4 field workers trained in good clinical practices in accordance with National Institutes of Health requirements, all bilingual and bicultural, conducted the study in Spanish and English. We asked participants to fast for at least 10 hours overnight before their visit to our clinical research unit, located centrally at Valley Baptist Medical Center in Brownsville. After confirming the duration of their fast, we obtained blood for clinical analyses and DNA. We rescheduled participants who had not fasted. We measured participants’ weight with their shoes removed by using a portable electronic scale and recorded the weight to the nearest 0.2 kg. Height was measured to the nearest 0.2 cm by using a stadiometer. We calculated body mass index (BMI) and determined waist circumference (visceral adiposity) at the level of the umbilicus, with participants in a standing position and breathing normally, to the nearest 0.2 cm. We measured blood pressure according to the protocol described in the National High Blood Pressure Education Program (18) and used the mean of measures 2 and 3 for analysis. We used a Glucostat analyzer (Model 27, YSI, Inc, Yellow Springs, Ohio) for blood glucose analysis. If we encountered unexpected results, such as elevated glucose in a participant not self-reporting diabetes, we asked the participant to return for a second visit to confirm the result. We discussed results with each participant. When we found abnormal results, we referred the participant to his physician or, if he had none, to a local federally qualified health center clinic. We froze whole blood for hemoglobin A1c (HbA1c) analysis (19) and transported white cells and plasma on ice to be archived for further laboratory analyses and future studies. We used enzyme-linked immunosorbent assays to determine insulin levels (Mercodia, Uppsala, Sweden).

Statistical analysis

We report results at the participant level. In the final sample, all participants were Hispanic, and 68% were female. This imbalance in the sample-generating mechanism needed to be adjusted in the analysis in order to generalize the results (eg, irrespective of sex), which we did by incorporating the sampling weights into our analysis. The sampling weights are the inverse probability of selection of each participant based on his or her SES stratum, census tract and block (cluster) of residence, and sex. Incorporating these sampling weights provides the correct statistical inference by giving a better estimate of standard error, and hence the confidence interval. In the sampling weight calculation, we made a post-ratio adjustment for the 2000 census population data. We also examined the data by ranking participants by household income and selecting the top and bottom quartiles to obtain a wider difference in household income than that provided by use of the census data. Thus, we compared the top 202 participants with the bottom 202 participants on the basis of household income.

We report results for the dependent variables of reported medical history and observed variables, including BMI, waist circumference, and fasting blood glucose and insulin. We used the homeostasis model assessment equation to determine insulin resistance (HOMA-IR = glucose (mg/dL)/18 × insulin (mU/L)/22.5) (20). Demographic covariates included age, sex, country of birth, country of birth of parents and grandparents, education, and employment status. First, we generated demographic and descriptive data to describe the sample. We compared weighted and unweighted analysis and determined that using the sample weights for the analysis was preferable, since they corrected for the lower response rate for men and the unemployed. We then developed a multiple logistic regression model to allow for the effects of potential confounders such as age, sex, and country of birth. Finally, we ranked the entire cohort by annual household income and repeated the analyses by using the bottom and top quartiles to see whether this would allow us to observe more subtle differences. We used SAS version 9.1 (SAS Institute, Inc, Cary, North Carolina) and Stata 10 SE (StataCorp LP, College Station, Texas). We made adjustments in the respective statistical packages for sampling design.

We used a geographic information system to visualize the spatial distribution of households by income quartile and the density of sampling. We geocoded households by using latitude and longitude coordinates collected by global positioning system, and crosschecked with the street addresses to ensure accuracy. We created maps and layouts with Environmental Systems Research Institute ArcMap v. 8.3 software (ESRI, Redlands, California).

Back to top

Results

Participation in the cohort in Brownsville did not significantly differ by SES stratum (Figure 1 and Table 1). The only substantial difference between the 2 socioeconomic strata was the proportion of participants who completed high school. Less than a fourth of the participants reported having private health insurance. A few (5%) were on Medicaid and a few others (5%) reported having Medicaid or Medicare combined with private managed care.

The map shows the location of each household included in the analysis. In general, people in the lowest quartile are in the north and east, while people in the third quartile are closest to the river in the south. These are shown in relation to 3 border crossings, several main roads, and the Rio Grande River.

Figure 1. Map of Brownsville, Texas, derived using geographic information systems and showing the distribution of the cohort across the city, Cameron County Hispanic Cohort, 2004-2007. People in the first quartile had annual household incomes of $17,830 or less, and people in the third quartile had annual household incomes of $24,067-$31,747. The inset box shows detail of 1 of the blocks randomly sampled.

More than half of the participants in both SES strata had BMI scores in the obese range (≥30 kg/m2) (Table 2). Slightly more participants in the higher SES stratum were morbidly obese (BMI ≥40 kg/m2), but the difference was not significant. Self-reported diabetes differed only slightly between strata, but we found significant differences between strata for undiagnosed diabetes. Nearly 1 in 10 of all participants in the lower SES stratum were informed through this study that they have diabetes. In both strata, mean HbA1c levels among participants with diabetes were 9.4%. In logistic regression models allowing for potential confounding variables, undiagnosed diabetes continued to be the only significant outcome associated with socioeconomic strata (Table 2).

The only significant difference in biological measurements by SES strata when using weighted data was for fasting blood insulin (Table 3). Results stratified by sex show significant differences between SES strata in women for fasting insulin and insulin resistance. Still, mean insulin resistance for both sexes was well above the upper limit of the normal range (3.15).

When we ranked these participants by annual household income, we found the mean household income of the fourth quartile to be $20,532 and of the first quartile to be $8,160. When we compared these quartiles, we found no differences in frequency of obesity or in mean BMI. However, consistent with what we observed using census tract quartiles, we found a significantly higher mean fasting blood glucose of 123.2 mg/dL (95% CI, 114.5-131.9 mg/dL; n = 204) in the first quartile compared with 108.0 mg/dL (95% CI, 101.3-114.5 mg/dL; n = 202) in the fourth quartile. We also observed a marked difference in prevalence of diabetes (diagnosed and undiagnosed), 21% (43/204) in the first quartile compared with 10% (20/202) in the fourth quartile (χ2 = 6.596, P < .01). We found no difference in mean insulin or insulin resistance levels between the 2 quartiles.

Age had a marked influence on the effect of SES. Rates of diabetes were significantly higher for people aged 55 to 64 years in the lower SES stratum compared with those in the higher SES stratum (Figure 2). There was a decrease in self-reported diabetes and an increase in undiagnosed diabetes, which was also age-dependent.

Line graph

Figure 2. Percentage of participants with diabetes, by age and by socioeconomic status, Cameron County Hispanic Cohort, 2004-2007. People in the first quartile had annual household incomes of $17,830 or less, and people in the third quartile had annual household incomes of $24,067-$31,747. Among people aged 55 to 64 years, the difference between people in the lower socioeconomic stratum compared with those in the higher stratum was significant at P < .05. [A tabular version of this figure is also available.]

Back to top

Discussion

In a largely uninsured racial/ethnic minority population on the urban United States-Mexico border, SES was associated with undiagnosed diabetes and development of diabetes. Despite the narrow range of income in this population, people in the lower SES stratum were significantly more likely to have undiagnosed diabetes and the risk of diabetes increased markedly with age. This adverse effect of lower SES stratum on health became starker when we compared the top and bottom quartiles of self-reported household incomes. However, we found no differences between strata in prevalence of obesity.

We found that women in the lower SES stratum were more likely to have elevated insulin resistance and fasting insulin levels compared with women in the higher SES stratum, but we did not observe similar differences for men, consistent with published observations (21,22). Mexican American women in the lower SES stratum may have less access to health care than do their counterparts in the higher SES stratum, or perhaps lifestyle differences between strata contribute to how women care for their own health.

National data may underestimate the prevalence of obesity and diabetes in border communities (1). Rates of diabetes in these communities were 1.4 times higher than those reported nationally for Mexican Americans aged 20 years or older (1) and nearly twice as high as in all Americans (aged 40-59 years) (1,3,23). Undiagnosed diabetes was also twice as high in our border population as nationally. Similarly, our rates of obesity were more than one and a half times the rate in Mexican Americans nationally (aged 40-59 years), and one-tenth of our women were morbidly obese (3). These excess rates offer a glimpse of the potential future health of people of Mexican origin residing in other parts of the United States.

Our study sample is not yet eligible for Medicare (age ≥65 years). In both SES strata, nearly 80% of participants reported that they had no medical coverage. These data highlight the need for prevention and intervention aimed at people aged 35 or older but younger than 65, who are most at risk and least likely to be able to afford health care. This population is at particular risk for expensive complications such as renal failure and amputations. Complications of diabetes reduce ability to work, exacerbating the socioeconomic vulnerability of this age group.

There were several limitations to our study. Despite intensive efforts, more women than men participated in the study; this was not unexpected in a community where most men are on hourly wages. We could not assess those randomly selected people who chose not to participate. Exclusion of the second and fourth SES strata weakens our estimates of prevalence. Our data raise issues of acculturation and immigration experience, but we did not collect data to distinguish those factors and SES. Though the population is largely Mexican in origin, participants in this study had lived in Brownsville an average of 16 years, making them long-term residents of the United States. Nevertheless, more than 70% elected to answer the questionnaires in Spanish. Residents in Brownsville access Mexican culture freely through media outlets and imported products in local retail and grocery stores; those who can also move freely across the border. In many ways, Brownsville more closely resembles its Mexican neighboring city, Matamoros, than its closest major US city, Corpus Christi. The process of acculturation to Brownsville may differ from that observed in the general US population. We plan to gather precise acculturation data in our future studies with this cohort to determine patterns in this community.

The strengths of our study are considerable in that we have recruited the first exclusively Mexican American cohort in a border city with extreme health disparities. With the support of our clinical research unit funded by the National Institutes of Health, we have been able to recruit and process participants in a standardized fashion, by using staff expert in good clinical practices and by using well-monitored data management and analysis processes. This enables us to report reliable data that can be used to plan for appropriate prevention and equitable health care for an underserved population.

The overall picture of health in this Mexican American population is poor. The rate of diabetes in Hispanics/Latinos is nearly twice that in whites, occurring at an earlier age and with higher rates of complications and death (2). In Mexican Americans on the United States-Mexico border, published rates of diabetes in rural communities are more than twice those in non-Hispanic whites (24). We show the same elevated risk in urban border populations. Furthermore, we demonstrate high rates of diabetes, particularly undiagnosed diabetes, in the poorest of our poor who have little or no access to health care through insurance. This presents a major economic burden on the community and on the health care system because it delays diagnosis and treatment until the disease is far more complex and costly to address. Intervention in the form of community-based participatory research will likely be essential to achieve sustainable solutions (25). A focus on early diagnosis and prevention of diabetes will be key to success in border health.

Back to top

Acknowledgments

We acknowledge the dedicated professionalism of our study personnel, particularly Elizabeth Braunstein, Julie Ramirez, Rocio Uribe, Blanca Ortiz, Jody Rodriguez, and Maria Lopez. We thank Gloria Sanchez and Pablo Sanchez for their excellent support in data management and analysis, Diana Gomez for her meticulous work in managing and processing specimens, and Christina Villarreal for her administrative support. We also thank the Valley Baptist Medical Center, Brownsville, for hosting our clinical research unit; their clinical laboratory for performing clinical assays; and Rose Gowen, MD, for her supervision of the clinical research unit. We thank Jennifer Gay and Cristina Barroso for their expert review of this manuscript and their helpful comments. We particularly thank our participants, the citizens of Brownsville who so generously and willingly gave and still give us their cooperation and time.

This work was supported by MD000170 P20 funded from the National Center on Minority Health and Health Disparities, the University of Texas Health Sciences Center, Houston, Center for Clinical and Translational Science CCTS-CTSA award 1U54RR023417-01 funded by the National Center for Research Resources, and the Centers for Disease Control and Prevention award RO1 DP000210-01.

Back to top

Author Information

Corresponding Author: Susan P. Fisher-Hoch, MD, Division of Epidemiology, University of Texas School of Public Health, Brownsville Campus, 80 Fort Brown, Brownsville, TX 78520. Telephone: 956-882-5167. E-mail: susan.p.fisher-hoch@uth.tmc.edu.

Author Affiliations: Anne R. Rentfro, J. Gaines Wilson, University of Texas at Brownsville, Brownsville, Texas; Jennifer J. Salinas, Belinda M. Reininger, Blanca I. Restrepo, Joseph B. McCormick, University of Texas Health Science Center, Houston, School of Public Health, Brownsville campus, Brownsville, Texas; Adriana Pérez, H. Shelton Brown, University of Texas Health Science Center, Houston, School of Public Health, Austin campus, Austin, Texas; M. Monir Hossain, Mohammad H. Rahbar, University of Texas School of Public Health and The Center for Clinical and Translational Sciences at The University of Texas Health Science Center, Houston, Houston, Texas; Craig M. Hanis, University of Texas Health Science Center, Houston, School of Public Health, Houston campus, Houston, Texas.

Back to top

References

  1. Cowie CC, Rust KF, Byrd-Holt DD, Eberhardt MS, Flegal KM, Engelgau MM, et al. Prevalence of diabetes and impaired fasting glucose in adults in the U.S. population: National Health and Nutrition Examination Survey 1999-2002. Diabetes Care 2006;29(6):1263-8.
  2. Umpierrez GE, Gonzalez A, Umpierrez D, Pimentel D. Diabetes mellitus in the Hispanic/Latino population: an increasing health care challenge in the United States. Am J Med Sci 2007;334(4):274-82.
  3. Ogden CL, Carroll MD, Curtin LR, McDowell MA, Tabak CJ, Flegal KM. Prevalence of overweight and obesity in the United States, 1999-2004. JAMA 2006;295(13):1549-55.
  4. Gregg EW, Cheng YJ, Narayan KM, Thompson TJ, Williamson DF. The relative contributions of different levels of overweight and obesity to the increased prevalence of diabetes in the United States: 1976-2004. Prev Med 2007;45(5):348-52.
  5. Harris MI, Flegal KM, Cowie CC, Eberhardt MS, Goldstein DE, Little RR, et al. Prevalence of diabetes, impaired fasting glucose, and impaired glucose tolerance in U.S. adults. The Third National Health and Nutrition Examination Survey, 1988-1994. Diabetes Care 1998;21(4):518-24.
  6. Runge CF. Economic consequences of the obese. Diabetes 2007;56(11):2668-72.
  7. Yach D, Stuckler D, Brownell KD. Epidemiologic and economic consequences of the global epidemics of obesity and diabetes. Nat Med 2006;12(1):62-6.
  8. Preventing chronic diseases: a vital investment. Geneva (CH): World Health Organization; 2005.
  9. Chronic disease prevention and health promotion: preventing diabetes and its complications. Atlanta (GA): Centers for Disease Control and Prevention. http://www.cdc.gov/chronicdisease/resources/publications/ fact_sheets/diabetes.htm. Accessed January 21, 2010.
  10. Florez JC, Price AL, Campbell D, Riba L, Parra MV, Yu F, et al. Strong association of socioeconomic status with genetic ancestry in Latinos: implications for admixture studies of type 2 diabetes. Diabetologia 2009;52(8):1528-36.
  11. Hanis CL, Ferrell RE, Barton SA, Aguilar L, Garza-Ibarra A, Tulloch BR, et al. Diabetes among Mexican Americans in Starr County, Texas. Am J Epidemiol 1983;118(5):659-72.
  12. McWilliams JM, Meara E, Zaslavsky AM, Ayanian JZ. Differences in control of cardiovascular disease and diabetes by race, ethnicity, and education: U.S. trends from 1999 to 2006 and effects of Medicare coverage. Ann Intern Med 2009;150(8):505-15.
  13. Wong MD, Shapiro MF, Boscardin WJ, Ettner SL. Contribution of major diseases to disparities in mortality. N Engl J Med 2002;347(20):1585-92.
  14. State and county quickfacts: Brownsville (city), Texas. US Census Bureau. http://quickfacts.census.gov/qfd/states/48/4810768.html. Accessed October 20, 2009.
  15. FactFinder. US Census Bureau. http://factfinder.census.gov/home/saff/main.html?_lang=en. Accessed October 20, 2009.
  16. Framingham heart study. http://www.framinghamheartstudy.org/participants/original.html. Accessed January 27, 2010.
  17. Winter Texan season. About.com: Texas travel, 2008. http://gotexas.about.com/od/wintertexans/a/WtrTexans.htm. Accessed February 5, 2009.
  18. National Heart, Lung, and Blood Institute. National High Blood Pressure Education Program. Department of Health and Human Services, National Institutes of Health, 2008. http://www.nhlbi.nih.gov/about/nhbpep/. Accessed February 5, 2009.
  19. Hanis CL. Genetics of NIDDM among Mexican Americans. In: Berg K, Boulyjenkov V, Christen Y, editors. Genetic approaches to noncommunicable diseases. Berlin (DE): Springer-Verlag; 1996. p. 65-77.
  20. Matthews DR, Hosker JP, Rudenski AS, Naylor BA, Treacher DF, Turner RC. Homeostasis model assessment: insulin resistance and beta-cell function from fasting plasma glucose and insulin concentrations in man. Diabetologia 1985;28(7):412-9.
  21. Loucks EB, Rehkopf DH, Thurston RC, Kawachi I. Socioeconomic disparities in metabolic syndrome differ by gender: evidence from NHANES III. Ann Epidemiol 2007;17(1):19-26.
  22. Sánchez-Vaznaugh EV, Kawachi I, Subramanian SV, Sánchez BN, Acevedo-Garcia D. Do socioeconomic gradients in body mass index vary by race/ethnicity, gender, and birthplace? Am J Epidemiol 2009;169(9):1102-12.
  23. Rosamond W, Flegal K, Friday G, Furie K, Go A, Greenlund K, et al. Heart disease and stroke statistics — 2007 update: a report from the American Heart Association Statistics Committee and Stroke Statistics Subcommittee [erratum in Circulation 2007;115(5):e172]. Circulation 2007;115(5):e69-171.
  24. Cohen SJ, Ingram M. Border health strategic initiative: overview and introduction to a community-based model for diabetes prevention and control. Prev Chronic Dis 2005;2(1). http://www.cdc.gov/pcd/issues/2005/jan/04_0081.htm. Accessed January 25, 2010.
  25. Bowman BA, Vinicor F. Toward prevention and control of type 2 diabetes: challenges at the U.S.-Mexico border and beyond. Prev Chronic Dis 2005;2(1). http://www.cdc.gov/pcd/issues/2005/jan/04_0119.htm. Accessed January 25, 2010.

Back to top

 



 

Tables

Return to your place in the textTable 1. Description of 810a People Aged 35-64 Years, by SESb, Cameron County Hispanic Cohort, Brownsville, Texas, 2004-2007
Characteristic Lower SESc Higher SESc P Valued
Participation, n (%) 350 (74.0) 460 (76.5) NA
Sex, n (%)
Women 232 (55.7) 319 (57.1) .04
Men 118 (44.3) 141 (42.9)
Place of birth, n (%)
Mexico 239 (71.1) 338 (74.4) <.001
United States 105 (28.9) 119 (25.6)
Place of birth for both parents, n (%)
Mexico 234 (88.3) 318 (87.7) .19
United States 38 (11.7) 43 (12.3)
Place of birth for all 4 grandparents, n (%)
Mexico 238 (95.5) 328 (94.6) .01
United States 12 (4.5) 14 (5.4)
Completed high school, n (%)
Yes 134 (35.3) 196 (45.3) <.001
No 214 (64.7) 264 (54.7)
Employed, n (%)
Yes 85 (60.5) 107 (59.0) .02
No 33 (39.5) 34 (41.0)
Health insurance, n (%)
Yes 91 (22.3) 92 (21.8) <.08
No 259 (77.7) 368 (78.7)
Age, mean (SD)
Women 49.1 (0.81) 48.9 (0.87) <.001
Men 47.6 (1.16) 48.4 (0.92) <.001

Abbreviations: SES, socioeconomic status; NA, not applicable; SD, standard deviation.
a Numbers may not total 810 because of missing data.
b People in the first quartile had annual household incomes of $17,830 or less (lower SES), and people in the third quartile had annual household incomes of $24,067-$31,747 (higher SES).
c Unweighted frequencies.
d χ2 Tests and percentages using weighted data.

Return to your place in the textTable 2. Prevalence by SES Quartilea and Odds Ratios from Logistic Regression Analysisb of Obesity and Diabetes, Cameron County Hispanic Cohort, Brownsville, Texas, 2004-2007
Characteristic Prevalence Odds Ratio
Lower SES (N = 350), n (%)c Higher SES (N = 460), n (%)c Univariate (95% CI) Multivariated (95% CI)
Obese (BMI ≥30) 189 (56.9) 253 (55.5) 0.97 (0.80-1.18) 1.00 (0.81-1.22)
Morbidly obese (BMI ≥40) 34 (7.7) 39 (8.3) 1.04 (0.82-1.32) 1.04 (0.79-1.28)
Self-reported diabetese 50 (14.0) 66 (15.1) 1.03 (0.67-1.58) 1.07 (0.73-1.59)
Undiagnosed diabetesf 23 (8.8) 16 (2.5) 0.55 (0.33-0.93) 0.54 (0.32-0.93)g

Abbreviations: SES, socioeconomic status; CI, confidence interval; BMI, body mass index.
a People in the first quartile had annual household incomes of $17,830 or less (lower SES), and people in the third quartile had annual household incomes of $24,067-$31,747 (higher SES).
b Reference group is higher SES.
c Unweighted frequencies and weighted percentages.
d Controlling for age, sex, country of birth, education, and employment status.
e Respondents answered yes to the question “Has a doctor ever told you you have diabetes?”
f Respondents answered no to the question “Has a doctor ever told you you have diabetes?” but had fasting blood glucose on 2 occasions ≥126 mg/dL.
g Significant at P < .05.

Return to your place in the textTable 3. Estimated Means of Anthropometric and Biological Variables Using Weighted Data, by SES Quartilea, Cameron County Hispanic Cohort, Brownsville, Texas, 2004-2007
Characteristic Lower SES (SD) Higher SES (SD) Mean Difference (95% CI)
Body mass index, kg/m2 31.7 (0.49) 31.4 (0.33) 0.26 (−0.91 to 1.43)
Women 32.8 (0.65) 32.3 (0.42) 0.50 (−1.02 to 2.03)
Men 30.3 (0.6) 30.3 (0.43) 0.02 (−1.42 to 1.47)
Waist circumference, cm 103.2 (1.02) 101.9 (0.90) 1.34 (−1.32 to 4.00)
Women 102.2 (1.19) 100.5 (1.18) 1.67 (−1.62 to 4.95)
Men 104.5 (1.48) 103.7 (0.97) 0.84 (−2.62 to 4.30)
Fasting blood glucose, mg/dL 118.1 (4.47) 112.5 (2.88) 5.61 (−4.82 to 16.03)
Women 112.3 (3.34) 111.2 (3.45) 1.11 (−8.30 to 10.53)
Men 125.5 (8.87) 114.3 (4.59) 11.16 (−8.41 to 30.73)
Fasting insulin, mU/L 16.4 (1.05) 13.6 (0.45) 2.78 (0.55 to 5.01)b
Women 17.5 (1.0) 14.1 (0.43) 3.45 (1.32 to 5.58)b
Men 15.0 (1.52) 13.0 (1.02) 1.99 (−1.59 to 5.57)
Insulin resistance ≤3.15 4.8 (0.44) 3.8 (0.20) 0.92 (−0.03 to 1.87)
Women 5.0 (0.44) 4.0 (0.24) 0.99 (0.01 to 1.97)b
Men 4.5 (0.54) 3.6 (0.38) 0.86 (−0.45 to 2.16)
Systolic blood pressure, mm/Hg 120.7 (1.54) 119.8 (0.67) 0.85 (−2.43 to 4.13)
Women 118.9 (1.49) 118.4 (0.96) 0.53 (−2.94 to 3.99)
Men 122.8 (2.45) 121.7 (1.32) 1.15 (−4.31 to 6.61)
Diastolic blood pressure, mm/Hg 73.6 (1.02) 73.7 (0.53) −0.07 (−2.33 to 2.19)
Women 71.7 (0.93) 71.6 (0.53) 0.12 (−1.99 to 2.22)
Men 76.1 (1.89) 76.6 (0.77) −0.46 (−4.46 to 3.54)

Abbreviation: SES, socioeconomic status; SD, standard deviation; CI, confidence interval.
a People in the first quartile had annual household incomes of $17,830 or less (lower SES), and people in the third quartile had annual household incomes of $24,067-$31,747 (higher SES).
b Significant at at P < .05.

Back to top

 




 



The findings and conclusions in this report are those of the authors and do not necessarily represent the official position of the Centers for Disease Control and Prevention.


 Home 

Privacy Policy | Accessibility

CDC Home | Search | Health Topics A-Z

This page last reviewed March 30, 2012

Centers for Disease Control and Prevention
National Center for Chronic Disease Prevention and Health Promotion
 HHS logoUnited States Department of
Health and Human Services