Abstract
In time-series studies on the effect of particulate matter (PM) air pollution on an adverse health outcome, PM time-series data are often available from multiple monitoring stations. Published studies have combined the data from the multiple monitors using a simple or trimmed average. We investigate an alternative method of combining the data available from multiple PM-monitoring sites. This method uses time-series data to assign each PM monitor a weight. The weights are then used to combine the data from the multiple PM monitors into a single air pollution time series. The resulting model will identify important monitors for describing the relationship between PM and the adverse health outcome of interest. Subsequent investigations of why certain monitors are more informative than others may provide valuable information concerning the location of vulnerable subpopulations or locations where the meteorological and/or land-use conditions are better for assessing population exposure to PM. The new model is illustrated by applying it to actual data from Cook County, IL, USA and through a simulation study. Using the new model, for the Cook County data, it was found that two of the six monitors provided essentially as much information about the effect of PM on mortality as all six monitors combined. The simulation study suggests that the weights assigned to each monitor by the new model are appropriate, that is, that the model assigns the largest weight to the monitor most highly correlated with the underlying PM time series used to generate mortality
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References
Chock D.P., Winkler S.L., and Chen C. A study of the association between daily mortality and ambient air pollutant concentrations in Pittsburgh, Pennsylvania. J Air Waste Manage Assoc 2000: 50: 1481–1500.
Cifuentes L.A., Vega J., Kopfer K., and Lave L.B. Effect of the fine fraction of particulate matter versus the coarse mass and other pollutants on daily mortality in Santiago, Chile. J Air Waste Manage Assoc 2000: 50: 1287–1298.
Daniels M.J., Dominici F., Samet J.M., and Zeger S.L. Estimating particulate matter–mortality dose–response curves and threshold levels: an analysis of daily time-series for the 20 largest US cities. Am J Epidemiol 2000: 152: 397–406.
Goldberg M.S., Burnett R.T., Valois M.F., Flegel K., Bailar III J.C., Brook J., et al. Associations between ambient air pollution and daily mortality among persons with congestive heart failure. Environ Res 2003: 91: 8–20.
Ito K., Kinney P.L., and Thurston G.D. Variations in PM-10 concentrations within two metropolitan areas and their implications for health effects analyses. Inhal Toxicol 1995: 7: 735–745.
Jerrett M., Burnett R.T., Brook J., Kanaroglou P., Glovis C., Finkelstein N., and Hutchison B. Do socioeconomic characteristics modify the short term association between air pollution and mortality? Evidence from a zonal time series in Hamilton, Canada. J Epidemiol Commun Health 2004: 58: 31–40.
Kelsall J.E., Samet J.M., Zeger S.L., and Xu J. Air pollution and mortality in Philadelphia, 1974 to 1988. Am J Epidemiol 1997: 146: 750–762.
Klemm R.J., Mason Jr R.M., Heilig C.M., Neas L.M., and Dockery D.W. Is daily mortality associated specifically with fine particles? Data reconstruction and replication analyses. J Air Waste Manage Assoc 2000: 50: 1215–1222.
Kwon H.J., Cho S.H., Nyberg F., and Pershagen G. Effects of ambient air pollution on daily mortality in a cohort of patients with congestive heart failure. Epidemiology 2001: 12: 413–419.
Moolgavkar S.H. Air pollution and daily mortality in three US counties. Environ Health Perspect 2000: 108: 777–784.
O'Neill M.S., Loomis D., and Borja-Aburto V.H. Ozone, area social conditions, and mortality in Mexico City. Environ Res 2004: 94: 234–242.
Ostro B.D., Hurley S., and Lipsett M.J. Air pollution and daily mortality in the Coachella Valley, California: a study of PM10 dominated by coarse particles. Environ Res 1999: 81: 231–238.
Roberts S. An investigation of distributed lag models in the context of air pollution and mortality time series analysis. J Air Waste Manage Assoc 2005: 55: 273–282.
Roberts S. Combining data from multiple monitors in air pollution mortality time series studies. Atmos Environ 2003: 37: 3317–3322.
Roberts S., and Martin M.A. Investigating the mixture of air pollutants associated with adverse health outcomes. Atmos Environ 2006: 40: 984–999.
Roemer W.H., and van Wijnen J.H. Daily mortality and air pollution along busy streets in Amsterdam, 1987 to 1998. Epidemiology 2001: 12: 649–653.
Samet J.M., Dominici F., Curriero F.C., Coursac I., and Zeger S.L. Fine particulate air pollution and mortality in 20 US cities, 1987 to 1994. N Engl J Med 2000: 343: 1742–1749.
Smith R.L., Davis J.M., Sacks J., Speckman P., and Styer P. Regression models for air pollution and daily mortality: analysis of data from Birmingham, Alabama. Environmetrics 2000a: 11: 719–743.
Smith R.L., Spitzner D., Kim Y., and Fuentes M. Threshold dependence of mortality effects for fine and coarse particles in Phoenix, Arizona. J Air Waste Manage Assoc 2000b: 50: 1367–1379.
Stieb D.M., Judek S., and Burnett R.T. Meta-analysis of time-series studies of air pollution and mortality: effects of gases and particles and the influence of cause of death, age, and season. J Air Waste Manage Assoc 2002: 52: 470–484.
Styer P., McMillan N., Gao F., Davis J., and Sacks J. Effect of outdoor airborne particulate matter on daily death counts. Environ Health Perspect 1995: 103: 490–497.
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Roberts, S., Martin, M. A new approach for combining information available from multiple particulate air pollution monitors. J Expo Sci Environ Epidemiol 18, 88–94 (2008). https://doi.org/10.1038/sj.jes.7500597
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DOI: https://doi.org/10.1038/sj.jes.7500597
