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Demographic Inequities in Health Outcomes and Air Pollution Exposure in the Atlanta Area and its Relationship to Urban Infrastructure

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Abstract

Environmental burdens such as air pollution are inequitably distributed with groups of lower socioeconomic statuses, which tend to comprise of large proportions of racial minorities, typically bearing greater exposure. Such groups have also been shown to present more severe health outcomes which can be related to adverse pollution exposure. Air pollution exposure, especially in urban areas, is usually impacted by the built environment, such as major roadways, which can be a significant source of air pollution. This study aims to examine inequities in prevalence of cardiovascular and respiratory diseases in the Atlanta metropolitan region as they relate to exposure to air pollution and characteristics of the built environment. Census tract level data were obtained from multiple sources to model health outcomes (asthma, chronic obstructive pulmonary disease, coronary heart disease, and stroke), pollution exposure (particulate matter and nitrogen oxides), demographics (ethnicity and proportion of elderly residents), and infrastructure characteristics (tree canopy cover, access to green space, and road intersection density). Conditional autoregressive models were fit to the data to account for spatial autocorrelation among census tracts. The statistical model showed areas with majority African-American populations had significantly higher exposure to both air pollutants and higher prevalence of each disease. When considering univariate associations between pollution and health outcomes, the only significant association existed between nitrogen oxides and COPD being negatively correlated. Greater percent tree canopy cover and green space access were associated with higher prevalence of COPD, CHD, and stroke. Overall, in considering health outcomes in connection with pollution exposure infrastructure and ethnic demographics, demographics remained the most significant explanatory variable.

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Acknowledgements

NSF grant 1444745 – SRN: Integrated urban infrastructure solutions for environmentally sustainable, healthy, and livable cities.

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Authors and Affiliations

  1. Division of Environmental Health Sciences, University of Minnesota School of Public Health, Minneapolis, MN, USA

    Joseph L. Servadio

  2. Schools of Civil and Environmental Engineering, Georgia Institute of Technology, Atlanta, GA, USA

    Abiola S. Lawal & Josephine Bates

  3. School of City and Regional Planning, Georgia Institute of Technology, Atlanta, GA, USA

    Tate Davis & Nisha Botchwey

  4. Georgia Institute of Technology College of Design, Atlanta, GA, USA

    Armistead G. Russell

  5. Humphrey School of Public Affairs, University of Minnesota, Minneapolis, MN, USA

    Anu Ramaswami

  6. Graduate School of Information Science and Technology, Hokkaido University, Sapporo, Japan

    Matteo Convertino

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  1. Joseph L. Servadio
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  2. Abiola S. Lawal
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  3. Tate Davis
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  8. Nisha Botchwey
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Correspondence to Nisha Botchwey.

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Servadio, J.L., Lawal, A.S., Davis, T. et al. Demographic Inequities in Health Outcomes and Air Pollution Exposure in the Atlanta Area and its Relationship to Urban Infrastructure. J Urban Health 96, 219–234 (2019). https://doi.org/10.1007/s11524-018-0318-7

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