Veronica A Wang, Rima Habre, Patrick H Ryan, Brent A Coull, Soma Datta, Heike Luttmann-Gibson, Jeff Blossom, Allan C Just, Joel Schwartz, Jeff D Yanosky, Izzuddin M Aris, Aruna Chandran, Amii M Kress, Carrie Breton, Shohreh F Farzan, Carlos A Camargo, Donghai Liang, Assiamira Ferrera, Alicia K Peterson, Jean M Kerver, Catherine J Karr, Leslie D Leve, Dana Dabelea, Margaret R Karagas, Deborah H Bennett, Flory L Nkoy, Judy Aschner, T Michael O'Shea, Nathan Lothrop, Cindy T McEvoy, Emily A Knapp, Holly B Schuh, Rachel L Miller, Diane R Gold, Antonella Zanobetti
{"title":"ECHO联盟中环境空气污染与儿童哮喘发病率相关性的差异:一项美国范围内的多队列研究。","authors":"Veronica A Wang, Rima Habre, Patrick H Ryan, Brent A Coull, Soma Datta, Heike Luttmann-Gibson, Jeff Blossom, Allan C Just, Joel Schwartz, Jeff D Yanosky, Izzuddin M Aris, Aruna Chandran, Amii M Kress, Carrie Breton, Shohreh F Farzan, Carlos A Camargo, Donghai Liang, Assiamira Ferrera, Alicia K Peterson, Jean M Kerver, Catherine J Karr, Leslie D Leve, Dana Dabelea, Margaret R Karagas, Deborah H Bennett, Flory L Nkoy, Judy Aschner, T Michael O'Shea, Nathan Lothrop, Cindy T McEvoy, Emily A Knapp, Holly B Schuh, Rachel L Miller, Diane R Gold, Antonella Zanobetti","doi":"10.1097/EE9.0000000000000398","DOIUrl":null,"url":null,"abstract":"<p><strong>Background: </strong>Characterization of US sociodemographic disparities in air pollution respiratory effects has often been limited by lack of participant diversity, geography, exposure characterization, and small sample size.</p><p><strong>Methods: </strong>We included 34 sites comprising 23,234 children (born 1981-2021) from the Environmental influences on Child Health Outcomes (ECHO) Program with data on asthma diagnosis until age 10 (182,008 person-years). Predicted annual exposure to fine particulate matter (1988-2021), nitrogen dioxide (2000-2016), and ground ozone (2000-2016) were assigned based on residential histories. For each pollutant, we fitted time-varying Cox models adjusted for time trend, site, and several area- and individual-level sociodemographic features that were separately considered as modifiers via an interaction with exposure.</p><p><strong>Results: </strong>The hazard ratio of incident asthma by age 10 years was 1.19 (95% CI = 1.10, 1.28), 1.19 (95% CI = 1.05, 1.34), and 1.11 (95% CI = 1.01, 1.22) of an interquartile range increase in prior-year exposure to fine particulate matter (6.17 µg/m<sup>3</sup>), nitrogen dioxide (15.37 ppb), and ozone (6.87 ppb), respectively. For both fine particulate and nitrogen dioxide, children from areas with a higher proportion of Black residents or with a higher population density had greater pollution-associated risks of incident asthma. For ozone, asthma risks were enhanced in less dense areas.</p><p><strong>Conclusions: </strong>US efforts to mitigate childhood asthma risk by reducing air pollution would benefit from addressing root structural causes of vulnerability and susceptibility, including spatial patterning in air pollution sources and exposures as well as social and economic disadvantage.</p>","PeriodicalId":11713,"journal":{"name":"Environmental Epidemiology","volume":"9 4","pages":"e398"},"PeriodicalIF":3.8000,"publicationDate":"2025-06-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC12160752/pdf/","citationCount":"0","resultStr":"{\"title\":\"Disparities in the association of ambient air pollution with childhood asthma incidence in the ECHO consortium: A US-wide multi-cohort study.\",\"authors\":\"Veronica A Wang, Rima Habre, Patrick H Ryan, Brent A Coull, Soma Datta, Heike Luttmann-Gibson, Jeff Blossom, Allan C Just, Joel Schwartz, Jeff D Yanosky, Izzuddin M Aris, Aruna Chandran, Amii M Kress, Carrie Breton, Shohreh F Farzan, Carlos A Camargo, Donghai Liang, Assiamira Ferrera, Alicia K Peterson, Jean M Kerver, Catherine J Karr, Leslie D Leve, Dana Dabelea, Margaret R Karagas, Deborah H Bennett, Flory L Nkoy, Judy Aschner, T Michael O'Shea, Nathan Lothrop, Cindy T McEvoy, Emily A Knapp, Holly B Schuh, Rachel L Miller, Diane R Gold, Antonella Zanobetti\",\"doi\":\"10.1097/EE9.0000000000000398\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><strong>Background: </strong>Characterization of US sociodemographic disparities in air pollution respiratory effects has often been limited by lack of participant diversity, geography, exposure characterization, and small sample size.</p><p><strong>Methods: </strong>We included 34 sites comprising 23,234 children (born 1981-2021) from the Environmental influences on Child Health Outcomes (ECHO) Program with data on asthma diagnosis until age 10 (182,008 person-years). Predicted annual exposure to fine particulate matter (1988-2021), nitrogen dioxide (2000-2016), and ground ozone (2000-2016) were assigned based on residential histories. For each pollutant, we fitted time-varying Cox models adjusted for time trend, site, and several area- and individual-level sociodemographic features that were separately considered as modifiers via an interaction with exposure.</p><p><strong>Results: </strong>The hazard ratio of incident asthma by age 10 years was 1.19 (95% CI = 1.10, 1.28), 1.19 (95% CI = 1.05, 1.34), and 1.11 (95% CI = 1.01, 1.22) of an interquartile range increase in prior-year exposure to fine particulate matter (6.17 µg/m<sup>3</sup>), nitrogen dioxide (15.37 ppb), and ozone (6.87 ppb), respectively. For both fine particulate and nitrogen dioxide, children from areas with a higher proportion of Black residents or with a higher population density had greater pollution-associated risks of incident asthma. 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引用次数: 0
摘要
背景:由于缺乏参与者多样性、地理位置、暴露特征和小样本量,美国空气污染呼吸效应的社会人口差异特征常常受到限制。方法:我们纳入了来自环境影响儿童健康结局(ECHO)项目的34个地点,包括23234名儿童(1981-2021年出生),包括10岁前哮喘诊断数据(182008人年)。根据居住历史分配了细颗粒物(1988-2021)、二氧化氮(2000-2016)和地面臭氧(2000-2016)的预测年暴露量。对于每种污染物,我们拟合了随时间变化的Cox模型,调整了时间趋势、地点和几个区域和个人层面的社会人口特征,这些特征通过与暴露的相互作用被单独视为修饰因子。结果:10岁儿童哮喘发生的风险比分别为1.19 (95% CI = 1.10, 1.28)、1.19 (95% CI = 1.05, 1.34)和1.11 (95% CI = 1.01, 1.22),前一年暴露于细颗粒物(6.17µg/m3)、二氧化氮(15.37 ppb)和臭氧(6.87 ppb)的四分位数范围增加。就细颗粒物和二氧化氮而言,黑人居民比例较高或人口密度较高的地区的儿童与污染相关的突发哮喘风险更高。就臭氧而言,在密度较低的地区,哮喘风险增加。结论:美国通过减少空气污染来降低儿童哮喘风险的努力将受益于解决脆弱性和易感性的根本结构性原因,包括空气污染源和暴露的空间格局以及社会和经济劣势。
Disparities in the association of ambient air pollution with childhood asthma incidence in the ECHO consortium: A US-wide multi-cohort study.
Background: Characterization of US sociodemographic disparities in air pollution respiratory effects has often been limited by lack of participant diversity, geography, exposure characterization, and small sample size.
Methods: We included 34 sites comprising 23,234 children (born 1981-2021) from the Environmental influences on Child Health Outcomes (ECHO) Program with data on asthma diagnosis until age 10 (182,008 person-years). Predicted annual exposure to fine particulate matter (1988-2021), nitrogen dioxide (2000-2016), and ground ozone (2000-2016) were assigned based on residential histories. For each pollutant, we fitted time-varying Cox models adjusted for time trend, site, and several area- and individual-level sociodemographic features that were separately considered as modifiers via an interaction with exposure.
Results: The hazard ratio of incident asthma by age 10 years was 1.19 (95% CI = 1.10, 1.28), 1.19 (95% CI = 1.05, 1.34), and 1.11 (95% CI = 1.01, 1.22) of an interquartile range increase in prior-year exposure to fine particulate matter (6.17 µg/m3), nitrogen dioxide (15.37 ppb), and ozone (6.87 ppb), respectively. For both fine particulate and nitrogen dioxide, children from areas with a higher proportion of Black residents or with a higher population density had greater pollution-associated risks of incident asthma. For ozone, asthma risks were enhanced in less dense areas.
Conclusions: US efforts to mitigate childhood asthma risk by reducing air pollution would benefit from addressing root structural causes of vulnerability and susceptibility, including spatial patterning in air pollution sources and exposures as well as social and economic disadvantage.
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