Daily Mortality/Morbidity and Air Quality: Using Multivariate Time Series with Seasonally Varying Covariances
- DOI
- Language of the publication
- English
- Date
- 2022-01-21
- Type
- Article
- Author(s)
- Huang, Guowen
- Brown, Patrick E.
- Fu, Sze Hang
- Shin, Hwashin Hyun
- Publisher
- Oxford University Press
Abstract
We study the associations between daily mortality and short-term variations in the ambient concentrations of fine particulate matter (PM2.5), nitrogen dioxide (NO2) and ozone (O3) in four cities in Canada. First, a novel multivariate time series model within Bayesian framework is proposed for exposure assessment, where the response is a mixture of Gamma and Half-Cauchy distributions and the correlations between pollutants vary seasonally. A case-crossover design and conditional logistic regression model is used to relate exposure to disease data for each city, which then are combined to obtain a global estimate of exposure health effects allowing exposure uncertainty. The results suggest that every 10 ppb increase in O3 is associated with a 3.88% (95% credible interval [CI], 2.5%, 5.18%) increase in all-cause mortality, a 5.04% (2.84%, 7.43%) increase in circulatory mortality, a 7.87% (2.4%, 12.9%) increase in respiratory mortality, a 0.76% (0.19%, 1.35%) increase in all-cause morbidity and a 6.6% (0.58%, 12.7%) increase in respiratory morbidity. Similarly, every 10 ppb increase in NO2 is associated with a 2.13% (0.42%, 3.87%) increase in circulatory morbidity. The health impacts of PM2.5 are not found to be present once other pollutants are accounted for.
Plain language summary
Health Canada is responsible for assessing the health risks of ambient air pollution. For example, ground-level ozone, nitrogen dioxide and fine particulate matter have been the main air pollutants of interest investigated in order to provide guidance to the public on protecting their health from the adverse health effect of these three specified air pollutants. For health risks such as mortality and hospitalization, we prefer one model that sums the risks associated with the three air pollutants to three separate models for three pollutants. The latter approach [three separate models for three pollutants] does not fully represent the effect of the combined exposures on Canadians’ health due to interactions among the three air pollutants. In this study, we accounted for seasonally varying correlations among the three pollutants and predicted combined risks for the three pollutants. This study was conducted in collaboration with scientists from the University of Toronto.
Subject
- Health,
- Health and safety