Rural and Urban Differences in Air Quality, 2008-2012, and Community Drinking Water Quality, 2010-2015 - United States.

IF 37.3 1区 医学 Q1 PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH
Heather Strosnider, Caitlin Kennedy, Michele Monti, Fuyuen Yip
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A paucity of national standardized environmental data has hindered efforts to characterize differences in the physical aspects of urban and rural areas, such as air and water quality.</p><p><strong>Reporting period: </strong>2008-2012 for air quality and 2010-2015 for water quality.</p><p><strong>Description of system: </strong>Since 2002, CDC's National Environmental Public Health Tracking Program has collaborated with federal, state, and local partners to gather standardized environmental data by creating national data standards, collecting available data, and disseminating data to be used in developing public health actions. The National Environmental Public Health Tracking Network (i.e., the tracking network) collects data provided by national, state, and local partners and includes 21 health outcomes, exposures, and environmental hazards. 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引用次数: 90

Abstract

Problem/condition: The places in which persons live, work, and play can contribute to the development of adverse health outcomes. Understanding the differences in risk factors in various environments can help to explain differences in the occurrence of these outcomes and can be used to develop public health programs, interventions, and policies. Efforts to characterize urban and rural differences have largely focused on social and demographic characteristics. A paucity of national standardized environmental data has hindered efforts to characterize differences in the physical aspects of urban and rural areas, such as air and water quality.

Reporting period: 2008-2012 for air quality and 2010-2015 for water quality.

Description of system: Since 2002, CDC's National Environmental Public Health Tracking Program has collaborated with federal, state, and local partners to gather standardized environmental data by creating national data standards, collecting available data, and disseminating data to be used in developing public health actions. The National Environmental Public Health Tracking Network (i.e., the tracking network) collects data provided by national, state, and local partners and includes 21 health outcomes, exposures, and environmental hazards. To assess environmental factors that affect health, CDC analyzed three air-quality measures from the tracking network for all counties in the contiguous United States during 2008-2012 and one water-quality measure for 26 states during 2010-2015. The three air-quality measures include 1) total number of days with fine particulate matter (PM2.5) levels greater than the U.S. Environmental Protection Agency's (EPA's) National Ambient Air Quality Standards (NAAQS) for 24-hour average PM2.5 (PM2.5 days); 2) mean annual average ambient concentrations of PM2.5 in micrograms per cubic meter (mean PM2.5); and 3) total number of days with maximum 8-hour average ozone concentrations greater than the NAAQS (ozone days). The water-quality measure compared the annual mean concentration for a community water system (CWS) to the maximum contaminant level (MCL) defined by EPA for 10 contaminants: arsenic, atrazine, di(2-ethylhexyl) phthalate (DEHP), haloacetic acids (HAA5), nitrate, perchloroethene (PCE), radium, trichloroethene (TCE), total trihalomethanes (TTHM), and uranium. Findings are presented by urban-rural classification scheme: four metropolitan (large central metropolitan, large fringe metropolitan, medium metropolitan, and small metropolitan) and two nonmetropolitan (micropolitan and noncore) categories. Regression modeling was used to determine whether differences in the measures by urban-rural categories were statistically significant.

Results: Patterns for all three air-quality measures suggest that air quality improves as areas become more rural (or less urban). The mean total number of ozone days decreased from 47.54 days in large central metropolitan counties to 3.81 days in noncore counties, whereas the mean total number of PM2.5 days decreased from 11.21 in large central metropolitan counties to 0.95 in noncore counties. The mean average annual PM2.5 concentration decreased from 11.15 μg/m3 in large central metropolitan counties to 8.87 μg/m3 in noncore counties. Patterns for the water-quality measure suggest that water quality improves as areas become more urban (or less rural). Overall, 7% of CWSs reported at least one annual mean concentration greater than the MCL for all 10 contaminants combined. The percentage increased from 5.4% in large central metropolitan counties to 10% in noncore counties, a difference that was significant, adjusting for U.S. region, CWS size, water source, and potential spatial correlation. Similar results were found for two disinfection by-products, HAA5 and TTHM. Arsenic was the only other contaminant with a significant result. Medium metropolitan counties had 3.1% of CWSs reporting at least one annual mean greater than the MCL, compared with 2.4% in large central counties.

Interpretation: Noncore (rural) counties experienced fewer unhealthy air-quality days than large central metropolitan counties, likely because of fewer air pollution sources in the noncore counties. All categories of counties had a mean annual average PM2.5 concentration lower than the EPA standard. Among all CWSs analyzed, the number reporting one or more annual mean contaminant concentrations greater the MCL was small. The water-quality measure suggests that water quality worsens as counties become more rural, in regards to all contaminants combined and for the two disinfection by-products individually. Although significant differences were found for the water-quality measure, the odds ratios were very small, making it difficult to determine whether these differences have a meaningful effect on public health. These differences might be a result of variations in water treatment practices in rural versus urban counties.

Public health action: Understanding the differences between rural and urban areas in air and water quality can help public health departments to identify, monitor, and prioritize potential environmental public health concerns and opportunities for action. These findings suggest a continued need to develop more geographically targeted, evidence-based interventions to prevent morbidity and mortality associated with poor air and water quality.

农村和城市空气质量差异,2008-2012,和社区饮用水质量,2010-2015 -美国。
问题/状况:人们生活、工作和娱乐的场所可能导致不良健康结果的发展。了解不同环境中风险因素的差异有助于解释这些结果发生的差异,并可用于制定公共卫生计划、干预措施和政策。描述城乡差异的努力主要集中在社会和人口特征上。由于缺乏国家标准化环境数据,妨碍了对城市和农村地区的自然方面的差异,例如空气和水的质量进行描述的努力。报告期间:2008-2012年空气质量报告和2010-2015年水质报告。系统描述:自2002年以来,疾病预防控制中心的国家环境公共卫生跟踪项目与联邦、州和地方合作伙伴合作,通过制定国家数据标准、收集现有数据和传播用于制定公共卫生行动的数据来收集标准化的环境数据。国家环境公共卫生跟踪网络(即跟踪网络)收集国家、州和地方合作伙伴提供的数据,包括21项健康结果、暴露和环境危害。为了评估影响健康的环境因素,疾病预防控制中心分析了2008-2012年期间美国所有相邻县的跟踪网络中的三项空气质量指标,以及2010-2015年期间26个州的一项水质指标。三项空气质量指标包括:1)细颗粒物(PM2.5)水平高于美国环境保护署(EPA)国家环境空气质量标准(NAAQS) 24小时平均PM2.5水平的天数(PM2.5天数);2) PM2.5年平均环境浓度,单位为微克/立方米(mean PM2.5);3)最大8小时平均臭氧浓度大于NAAQS(臭氧日)的日数。水质测量将社区水系统(CWS)的年平均浓度与EPA规定的10种污染物的最大污染物水平(MCL)进行了比较:砷、阿特拉津、邻苯二甲酸二(2-乙基己基)酯(DEHP)、卤代乙酸(HAA5)、硝酸盐、过氯乙烯(PCE)、radium、三氯乙烯(TCE)、总三卤甲烷(TTHM)和铀。结果显示城乡分类方案:四个大都市(大中心大都市、大边缘大都市、中等大都市和小大都市)和两个非大都市(小城市和非核心)类别。使用回归模型来确定城乡类别之间的差异是否具有统计学意义。结果:所有三种空气质量测量的模式表明,随着地区变得更加农村(或更少城市),空气质量得到改善。臭氧平均总日数从中心大都市大县的47.54天下降到非核心县的3.81天,PM2.5平均总日数从中心大都市大县的11.21天下降到非核心县的0.95天。年平均PM2.5浓度从中心大城市县的11.15 μg/m3下降到非核心县的8.87 μg/m3。水质测量的模式表明,随着地区城市化程度的提高(或农村程度的降低),水质会有所改善。总体而言,7%的CWSs报告至少有一个年平均浓度高于所有10种污染物的MCL。这一比例从大型中心城市县的5.4%上升到非核心县的10%,在调整了美国地区、CWS规模、水源和潜在的空间相关性后,这一差异是显著的。两种消毒副产物HAA5和TTHM结果相似。砷是另一种影响显著的污染物。中等大都市县有3.1%的cws报告至少有一次的年平均高于MCL,而大型中心县的这一比例为2.4%。解释:非核心县(农村)的空气质量不健康的天数比中心大都市县少,可能是因为非核心县的空气污染源更少。各类县年均PM2.5浓度均低于EPA标准。在分析的所有CWSs中,报告一个或多个年平均污染物浓度高于MCL的CWSs数量较少。水质测量表明,就所有污染物的综合和两种消毒副产品而言,随着县越来越农村,水质恶化。尽管在水质测量中发现了显著差异,但比值比非常小,因此难以确定这些差异是否对公众健康产生有意义的影响。这些差异可能是农村和城市县水处理做法不同的结果。 公共卫生行动:了解农村和城市地区在空气和水质方面的差异有助于公共卫生部门识别、监测潜在的环境公共卫生问题,并确定优先次序和采取行动的机会。这些发现表明,继续需要制定更具地理针对性和基于证据的干预措施,以预防与空气和水质差有关的发病率和死亡率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Mmwr Surveillance Summaries
Mmwr Surveillance Summaries PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH-
CiteScore
60.50
自引率
1.20%
发文量
9
期刊介绍: The Morbidity and Mortality Weekly Report (MMWR) Series, produced by the Centers for Disease Control and Prevention (CDC), is commonly referred to as "the voice of CDC." Serving as the primary outlet for timely, reliable, authoritative, accurate, objective, and practical public health information and recommendations, the MMWR is a crucial publication. Its readership primarily includes physicians, nurses, public health practitioners, epidemiologists, scientists, researchers, educators, and laboratorians.
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