1 Department of Health Services, School of Public Health, University of California at Los Angeles, Los Angeles, CA
2 Center for Health Policy and Research, School of Public Health, University of California at Los Angeles, Los Angeles, CA
3 Department of Epidemiology, School of Public Health, University of California at Los Angeles, Los Angeles, CA
4 Department of Environmental Health Sciences, School of Public Health, University of California at Los Angeles, Los Angeles, CA
Reprint requests to Dr. Ninez A. Ponce, Department of Health Services, 31-254B CHS, School of Public Health, University of California at Los Angeles, Los Angeles, CA 90095-1772 (e-mail: nponce{at}ucla.edu).
Received for publication November 24, 2004. Accepted for publication March 7, 2005.
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ABSTRACT |
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air pollution; premature birth; socioeconomic factors
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INTRODUCTION |
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Researchers have begun to study the individual's neighborhood in addition to individual-level characteristics associated with preterm birth. While individual-level attributes are immutable or difficult to change, policies and interventions at the community level can influence neighborhood conditions associated with adverse health effects. Moreover, even if individual-level attributes are modifiable, such as earlier initiation of prenatal care and access to health insurance, this change has not resulted in considerable improvements in preterm birth rates over the past years (8). There is mounting evidence that, in addition to individual-level factors, the residential area or neighborhood may confer additional risks or provide benefits that affect birth outcomes (9
16
). However, most of these studies have focused on only the social, political, and economic conditions in a neighborhood, absent of measures depicting the physical environment that may exacerbate biologic and psychosocial stressors associated with preterm birth.
The call for a comprehensive examination of the physical and social environment was recently articulated by O'Neill et al. (17). They hypothesized that low socioeconomic status (SES) neighborhoods and communities may not only experience increased levels of air pollution but also have more vulnerable inhabitants who are more susceptible to these exposure effects because of compromised health status and a lack of resources, including adequate health care. Yet to date few studies have explicitly explored the interplay of individual characteristics and pollution exposure within neighborhoods with varying neighborhood socioeconomic resources.
In this spatial variation study, we examined preterm birth risk within a framework reflecting both the social and physical environments. We built on previous studies that have linked traffic-related pollution exposuremeasured by distance-weighted traffic density (DWTD)to preterm birth risk (18, 19
). "Space" was defined by the degree of neighborhood economic hardship (the social environment) and by distinct meteorologic seasonal conditions in Los Angeles that correlate strongly with traffic-related air pollution (the physical environment). We conceptualized an "adverse" social environment as neighborhoods with concentrated poverty, unemployment, and dependence on income from public assistance, whereas an adverse physical environment manifests as wintertime thermal inversions that trap motor vehicle pollutants. We explored whether and to what extent these adverse conditions in the social and physical environments might increase the susceptibility for preterm delivery among vulnerable women or potentially modify the effectiveness of protective factors such as health insurance.
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MATERIALS AND METHODS |
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Birth outcome
Preterm birth was a dichotomous outcome, specified as infants delivered at less than 37 completed weeks of gestation compared with all term infants.
Economic hardship stratifications
Economic hardship measures, such as poverty and unemployment rates, have been shown to be "implicated" in adverse birth outcomes. As a barometer of neighborhood disadvantage, economic hardship reflects poor levels of social resources that may be connected with the sequence of events that culminate in an adverse birth outcome (11, 20
). We therefore selected three federally defined "economic hardship" measures (unemployment, income from public assistance, and family poverty) to depict neighborhood SES (21
, 22
).
Neighborhoods were defined as census tracts (n = 863), a designation that captures homogeneous economic and demographic characteristics (12, 13
). For each census tract, we computed the percentages of unemployed persons in the civilian labor force, households with public assistance income, and families with income below the poverty line. We stratified the sample into high, middle, and low SES neighborhoods. Low SES neighborhoods were census tracts meeting all three criteria: greater than 10 percent unemployment, greater than 20 percent of families in poverty, and greater than 15 percent of individuals receiving public assistance. High SES neighborhoods were defined as meeting all of the following criteria: census tracts with 10 percent or less of the population unemployed, 20 percent or less of the families living in poverty, and 15 percent or less of the individuals receiving income from public assistance. Cutoff points for the low (high) SES neighborhoods correspond to neighborhoods above (below) the mean levels of each of these economic hardship indicators. The middle SES neighborhoods constituted the remaining census tracts (figure 1).
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Seasonal effects
We additionally conducted stratified analyses by third trimester season: women whose third trimesters fell during the winter months (NovemberApril) versus women whose third trimesters fell during the summer months (MayOctober). In Los Angeles County, the "winter" months (NovemberApril) correspond to a fall in temperature, ranging from 54 to 60°F (12.215.6°C), and the "summer" months (MayOctober) correspond to higher average temperatures, ranging from 63 to 73°F (17.222.8°C) (25). Higher local concentrations of primary exhaust particles and gases from traffic are expected to occur during the winter because of more stagnant air conditions and temperature inversions that limit the dilution and dispersion of emissions; summertime meteorology allows for more rapid mixing and dispersion of these pollutants. While ozone and secondary particles are more elevated in the summer because of increased sunlight's fueling photochemical reactions, we and others have not observed an effect of ozone on this outcome. We therefore infer that a more "adverse" localized physical environment occurs in the winter when carbon monoxide and primary particlespollutants directly emitted from vehicle tailpipesare accumulating near sources.
Our traffic-related pollution measure of interest, DWTD, could also be confounded by background ambient air pollution. We used air pollution data collected at 11 South Coast Air Quality Management District monitoring stations to determine annual average background concentrations of carbon monoxide, ozone, nitrogen dioxide, and particulate matter with a diameter of less than 10 µm for each subject's home (based on hourly measurements for gases and 24-hour average measurements taken every sixth day for the specified particulate matter); "background" is defined as pollutant concentrations after dispersion and transport away from sources, including roadways. Annual rather than seasonal averages were computed to represent background pollution levels experienced during the year the baby was born. Annual averages are more likely to reflect longer term true background levels of ambient air pollution over larger areas given exposure misclassification when extrapolating exposures for women living farther than 3.2 km from a station.
All models included covariates that have been previously identified as risk factors for preterm birth, including maternal age (categorized as <20, 2029, 3034, 35 years), maternal race/ethnicity (African American, White, Hispanic, other races), infant's sex, previous low birth weight or preterm infant, parity, and interval since previous livebirth. We used maternal education (08, 911, 12, 1315,
16 years), payment source for delivery (government insurance, private insurance, self-pay/uninsured), and initiation of prenatal care (during first trimester, after first trimester/never) as indicators of individual-level SES and protective factors. We included year-of-birth indicators to account for secular variations in preterm birth rates. Unfortunately, birth certificates from California do not contain data on smoking behavior during pregnancy.
Statistical methods
We fit six separate models to capture the interaction of individual covariates with neighborhood SES and season environments: 1) low SES/summer; 2) low SES/winter; 3) middle SES/summer; 4) middle SES/winter; 5) high SES/summer; and 6) high SES/winter. To examine whether our results were sensitive to residual confounding by unmeasured area-level factors, we fit two-level logistic models with a random intercept for each census tract. We fit these models using both empirical Bayesisan and "semi-Bayesian" procedures (26, 27
); for the latter, we chose a range of values for the second-level variance that reflected our prior beliefs about the variability in the random intercepts. Our results were robust to these different specifications (results available from authors); we therefore present the results from our one-level analysis.
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RESULTS |
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Women younger than 20 years of age compared with women aged 2030 years faced 2340 percent higher odds for preterm delivery in all season/SES strata except during the summer in high SES neighborhoods. Young mothers had the highest likelihood of delivering preterm in the low SES neighborhoods during winter (OR = 1.40, 95 percent CI: 1.19, 1.64). In general, women who delivered at 35 or more years of age also had higher odds (1765 percent) compared with the referent age group. Their greatest odds increase was observed in the low SES neighborhoods in winter (OR = 1.65, 95 percent CI: 1.35, 2.02).
A low level of education (fewer than 9 years compared with 12 years of schooling) increased the odds of a preterm delivery by 1923 percent, but only among women in low SES neighborhoods and in high SES neighborhoods in the summer. Attaining the highest educational level was protective only in the high SES neighborhoods.
Compared with no coverage, government health insurance (OR = 0.61, 95 percent CI: 0.39, 0.96), principally Medicaid, and private health coverage (OR = 0.50, 95 percent CI: 0.31, 0.79) had the strongest protective effect against preterm birth in low SES neighborhoods during winter. We found the opposite effect in high SES neighborhoods during winter: Women with government insurance had generally higher odds of preterm deliveries.
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DISCUSSION |
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We found that DWTD had the greatest adverse effect in the low SES areas during the winter season. Our findings also suggest that middle SES neighborhoods experienced an adverse effect in the summer and winter. However, we found no effect in high SES neighborhoods regardless of season. High SES neighborhoods might differ from low and middle SES neighborhoods with respect to a number of factors influencing exposure to a local pollution source such as traffic: 1) cars are newer and create less pollution in high SES neighborhoods, whereas low SES areas may be frequented by a greater percentage of older, high emitting gasoline or diesel vehicles; or 2) homes are newer, better insulated, equipped with air conditioning, and set back farther from the curb on larger residential lots so that pollution from highly trafficked roads does not affect the indoor environment as it does in low SES neighborhoods. Thus, one could argue that our traffic density measure does not reflect the same locally increased exposure from traffic at a home in high compared with low SES neighborhoods. On the other hand, conditions during the winter months seem to result in increased effect estimates only in low and middle SES areas. This may suggest a combination of greater vulnerability for women living in these neighborhoods and higher localized exposures from traffic exhaust, even when adjusting for general differences in air pollution levels measured at background stations.
Indeed, our results indicate that the susceptibility for preterm birth among vulnerable groups varied by neighborhood SES and season. As reported previously (15, 26
, 28
, 29
), we found that the odds of a preterm delivery were increased among African Americans, Hispanics, and younger or older mothers, with the biggest disparity in low and middle SES neighborhoods during winter. We found that African-American women face higher odds for preterm birth across all SES strata. However, in the more economically deprived neighborhoods, African-American women's increased odds of preterm delivery during winter suggest their added susceptibility to the changes in the conditions of the physical environment. Thus, for areas affected with the cumulative adverse effects of the social and physical environments, the implication of our study is that economic development programs need to be in tandem with environmental regulation to effectively reduce preterm births.
We found that the vulnerable groups, particularly African-American mothers, still faced increased odds of a preterm birth, despite living in high SES neighborhoods. This may be attributable to several unmeasured factors: 1) there may be race-based differential access to health services and other neighborhood resources that may be more disparate in high SES neighborhoods (27), or 2) individual-level social and cultural differences may result in variations in an individual's transformation of available neighborhood resources that lead to better birth outcomes (30
). Our study was not designed to identify the source of these neighborhood stressors, but our results suggest that social processes and their influence on a preterm birth outcome differ by neighborhood SES. This may indicate that a postulated biologic susceptibility for the outcome related to race and maturity/exhaustion of the maternal reproductive system is heightened when either the physical or the social environment is less supportive (8
).
Our findings concur with those from previous studies suggesting that education, prenatal care, and health insurance might mitigate the risk for preterm delivery (1, 31
33
). Lacking a high school diploma was associated with increased risk, but mostly in the low SES communities. We found a positive though weak association of the protective effect of high maternal education in the low and middle SES neighborhoods, perhaps because very few women (25 percent) had 16 or more years of schooling in these strata. Government and private health insurance, compared with the self-paying/uninsured, appeared to benefit women, but only in low, and not in high, SES neighborhoods. This suggests that in high SES neighborhoods, government insurance, principally Medicaid, acted as a marker for lower-income mothers: Relative to self-paying/uninsured women in the high SES neighborhoods, these women were financially disadvantaged. Members of more economically advantaged neighborhoods may have higher levels of education and can avail themselves of more choices in neighborhood resources, so that insurance coverage has less importance and consequently has less impact (34
). In contrast, in the low SES neighborhoods, women with government insurance may have been economically better off compared with the self-paying/uninsured women in their neighborhoods. In low SES neighborhoods, private coverage, like government insurance, conferred a protective effect. Although health insurance is clearly a marker for many unmeasured SES advantages, our results are suggestive that health insurance, whether government or private, appears to be effective only in the most economically deprived areas. This is consistent with the economic hypothesis that the marginal effect of health insurance in improving health outcomes diminishes in higher income areas because beneficial outcomes are already maximized (35
). Early initiation of prenatal care had a beneficial effect in all neighborhood settings and seasons, with no marked neighborhood SES gradient. Thus, the quality of prenatal care across different SES neighborhoods may be consistent across neighborhoods in its effectiveness in reducing preterm births. However, access may still be an issue since fewer women in the low and middle SES neighborhoods received prenatal care during the first trimester than in the high SES neighborhoods.
Study limitations include a potential bias arising from two sources in our final sample of study subjects. First, since the study sample included only 112 of the 269 Los Angeles ZIP codes, it may not be representative of the entire county. However, our results have focused policy implications because they are generalizable to many urban areas that are affected by traffic. Second, our inability to map all eligible subjects may have also resulted in exclusion of a higher proportion of cases than controls, but then our DWTD estimates would be biased toward the null.
We defaulted to census tracts as a plausible though admittedly imperfect definition of neighborhoods, but this is a methodological issue grappled with by neighborhood effects research in general (12, 36
). More importantly, our neighborhood SES measure of economic hardship reflected neighborhood economic conditions that may constrain a pregnant woman's choices and decisions, thereby influencing her pregnancy outcome. Our results are only suggestive of unobserved social processes that take place between the woman and her residential community. Increasingly, studies have attempted to evaluate previously unmeasured neighborhood dynamics through hypothesized neighborhood mechanisms, for example, perceived safety in a neighborhood associated with the level of maternal stress during pregnancy, and the social exchange/voluntarism/trust in a community that may reduce a woman's stress (11
, 37
). For a future analysis, we plan to link more recent birth record data in Los Angeles County to data from the population-based California Health Interview Survey 2003 (38
). This survey collected information on neighborhood social support and cohesion similar to the questions used by the Project on Human Development in Chicago Neighborhoods (39
). Another limitation of our analysis is the omission of relevant variables not collected in the California birth certificate data, such as maternal smoking during pregnancy. Our recent survey of 2,500 randomly selected women who gave birth during 2003 in the ZIP code areas we studied will provide the important information absent in our current analysis, including individual- and household-level information on maternal smoking, exposure to second hand smoke, occupation, commute, indoor/outdoor living patterns, and perceived discrimination.
We posited that, during winter, the physical environment is more adverse due to increased air pollution near traffic sources when winter thermal inversions trap exhaust (40, 41
). However, the localized physical environment may also be more adverse because infection rates are higher during the winter (16
, 42
, 43
). Wintertime pollution conditions may thus act indirectly or synergistically with infectious agents in increasing a pregnant woman's susceptibility to pollution-related reproductive failures and, consequently, preterm births (44
47
).
Finally, we cannot definitively rule out residual confounding by varying neighborhood characteristics that were unmeasured, such as the presence of a community health center in one neighborhood versus another. Future studies should consider measuring and accounting for supply-side resources on health and social services that may promote healthy pregnancies.
In conclusion, we confirmed that risk for preterm delivery is associated with individual and traffic-related pollution exposure factors previously shown to increase risk. More interestingly, these risks differed by neighborhood SES and by season. A woman's individual susceptibility to preterm delivery may be altered by the physical environment, the social and economic resources available to her, and her ability to transform these resources into beneficial birth outcomes. Reducing preterm births therefore warrants a concerted effort of social, economic, and environmental policies, focused not only on individual risk factors but also on reducing traffic-related air pollution, expanding health-care coverage, and improving neighborhood resources.
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ACKNOWLEDGMENTS |
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The authors thank Sander Greenland, Naihua Duan, Fei Yu, and Robert Nordyke for reviewing our conceptual framework and models and for providing statistical advice.
Conflict of interest: none declared.
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References |
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