Abstract
Although the health effects of ambient ozone have been widely assessed, their tempo-spatial variations remain unclear. We selected 20 communities (ten each from southern and northern USA) based on the US National Morbidity, Mortality, and Air Pollution Study (NMMAPS) dataset. A generalized linear model (GLM) was used to estimate the season-specific association between each 10 ppb (lag0-2 day average) increment in daily 8 h maximum ozone concentration and mortality in every community. The results showed that in the southern communities, a 10 ppb increment in ozone was linked to an increment of mortality of −0.07%, −0.17%, 0.40% and 0.27% in spring, summer, autumn and winter, respectively. For the northern communities, the excess risks (ERs) were 0.74%, 1.21%, 0.52% and −0.65% in the spring, summer, autumn and winter seasons, respectively. City-specific ozone-related mortality effects were positively related with latitude, but negatively related with seasonal average temperature in the spring, summer and autumn seasons. However, a reverse relationship was found in the winter. We concluded that there were different seasonal patterns of ozone effects on mortality between southern and northern US communities. Latitude and seasonal average temperature were identified as modifiers of the ambient ozone-related mortality risks.
Highlights
Ozone is a key component in the troposphere and plays an important role in air quality, atmospheric oxidizing capacity, and climate change [1,2]
Assessing the seasonal and geographic variations of ozone effects on human health can provide additional information for making policy on ambient ozone control in a climate-changing environment where projections suggest a significant increase in ambient ozone by the year 2100 under RCP8.5 scenarios [7]
We used the NMMAPS dataset of the USA to assess the seasonal variations of ozone effects on mortality in southern and northern communities
Summary
Ozone is a key component in the troposphere and plays an important role in air quality, atmospheric oxidizing capacity, and climate change [1,2]. Especially in urban areas, mainly comes from photochemical reactions between oxides of nitrogen (NOx ) and volatile organic compounds (VOCs) in the presence of sunlight. In the past decades, associated with rapid urbanization and industrialization processes, increased anthropogenic emissions of NOx and VOCs has led to higher surface ozone concentration in some regions of the world [1,3,4,5,6]. The Intergovernmental Panel on Climate Change (IPCC) fifth assessment report in 2013 projected with high confidence that under the. Res. Public Health 2016, 13, 851; doi:10.3390/ijerph13090851 www.mdpi.com/journal/ijerph
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