Assessing the short term impact of air pollution on mortality: a matching approach

BackgroundThe opportunity to assess short term impact of air pollution relies on the causal interpretation of the exposure-response association. However, up to now few studies explicitly faced this issue within a causal inference framework. In this paper, we reformulated the problem of assessing the short term impact of air pollution on health using the potential outcome approach to causal inference. We considered the impact of high daily levels of particulate matter ≤10 μm in diameter (PM10) on mortality within two days from the exposure in the metropolitan area of Milan (Italy), during the period 2003–2006. Our research focus was the causal impact of a hypothetical intervention setting daily air pollution levels under a pre-fixed threshold.MethodsWe applied a matching procedure based on propensity score to estimate the total number of attributable deaths (AD) during the study period. After defining the number of attributable deaths in terms of difference between potential outcomes, we used the estimated propensity score to match each high exposure day, namely each day with a level of exposure higher than 40 μg/m3, with a day with similar background characteristics but a level of exposure lower than 40 μg/m3. Then, we estimated the impact by comparing mortality between matched days.ResultsDuring the study period daily exposures larger than 40 μg/m3 were responsible for 1079 deaths (90% CI: 116; 2042). The impact was more evident among the elderly than in the younger age classes. Exposures ≥ 40 μg/m3 were responsible, among the elderly, for 1102 deaths (90% CI: 388, 1816), of which 797 from cardiovascular causes and 243 from respiratory causes. Clear evidence of an impact on respiratory mortality was found also in the age class 65–74, with 87 AD (90% CI: 11, 163).ConclusionsThe propensity score matching turned out to be an appealing method to assess historical impacts in this field, which guarantees that the estimated total number of AD can be derived directly as sum of either age-specific or cause-specific AD, unlike the standard model-based procedure. For this reason, it is a promising approach to perform surveillance focusing on very specific causes of death or diseases, or on susceptible subpopulations. Finally, the propensity score matching is free from issues concerning the exposure-confounders-mortality modeling and does not involve extrapolation. On the one hand this enhances the internal validity of our results; on the other, it makes the approach scarcely appropriate for estimating future impacts.

[1]  J. Schwartz,et al.  Estimating Causal Associations of Fine Particles With Daily Deaths in Boston. , 2015, American journal of epidemiology.

[2]  Keying Ye,et al.  Applied Bayesian Modeling and Causal Inference From Incomplete-Data Perspectives , 2005, Technometrics.

[3]  P. Holland Statistics and Causal Inference , 1985 .

[4]  S. Vardoulakis,et al.  Health burdens of surface ozone in the UK for a range of future scenarios. , 2013, Environment international.

[5]  D B Rubin,et al.  Analyses that Inform Policy Decisions , 2012, Biometrics.

[6]  Dolores Catelan,et al.  Commuting-Adjusted Short-Term Health Impact Assessment of Airborne Fine Particles with Uncertainty Quantification via Monte Carlo Simulation , 2014, Environmental health perspectives.

[7]  Annibale Biggeri,et al.  The meta‐analysis of the Italian studies on short‐term effects of air pollution (MISA): old and new issues on the interpretation of the statistical evidences , 2007 .

[8]  Corwin M Zigler,et al.  Point: clarifying policy evidence with potential-outcomes thinking--beyond exposure-response estimation in air pollution epidemiology. , 2014, American journal of epidemiology.

[9]  J. Schwartz,et al.  Estimating Causal Effects of Local Air Pollution on Daily Deaths: Effect of Low Levels , 2016, Environmental health perspectives.

[10]  D. Rubin,et al.  The central role of the propensity score in observational studies for causal effects , 1983 .

[11]  S. Wood Generalized Additive Models: An Introduction with R , 2006 .

[12]  Kosuke Imai,et al.  Causal Inference With General Treatment Regimes , 2004 .

[13]  S. Greenland,et al.  Epidemiologic measures and policy formulation: lessons from potential outcomes , 2005, Emerging themes in epidemiology.

[14]  T STATEMEN,et al.  Revised Analyses of Time-Series Studies of Air Pollution and Health , 2003 .

[15]  Giovanna Berti,et al.  Short-term Associations between Fine and Coarse Particulate Matter and Hospitalizations in Southern Europe: Results from the MED-PARTICLES Project , 2013, Environmental health perspectives.

[16]  Scott L Zeger,et al.  On the equivalence of case-crossover and time series methods in environmental epidemiology. , 2007, Biostatistics.

[17]  Corwin M Zigler,et al.  Estimating causal effects of air quality regulations using principal stratification for spatially correlated multivariate intermediate outcomes. , 2012, Biostatistics.

[18]  N Künzli,et al.  Public-health impact of outdoor and traffic-related air pollution: a European assessment , 2000, The Lancet.

[19]  A. Biggeri,et al.  Health impact assessment of fine particle pollution at the regional level. , 2011, American journal of epidemiology.

[20]  M. Höfler,et al.  Causal inference based on counterfactuals , 2005, BMC medical research methodology.

[21]  Alan Y. Chiang,et al.  Generalized Additive Models: An Introduction With R , 2007, Technometrics.

[22]  M. Lipsitch,et al.  Negative Controls: A Tool for Detecting Confounding and Bias in Observational Studies , 2010, Epidemiology.

[23]  Manfred Neuberger,et al.  Reducing ambient levels of fine particulates could substantially improve health: a mortality impact assessment for 26 European cities , 2008, Journal of Epidemiology & Community Health.

[24]  Giovanni Parmigiani,et al.  Bayesian Effect Estimation Accounting for Adjustment Uncertainty , 2012, Biometrics.

[25]  Anu W. Turunen,et al.  Effects of long-term exposure to air pollution on natural-cause mortality: an analysis of 22 European cohorts within the multicentre ESCAPE project , 2014, The Lancet.

[26]  Nicholas I. Fisher,et al.  Statistical Analysis of Circular Data , 1993 .

[27]  Joel Schwartz,et al.  Estimating the Exposure–Response Relationships between Particulate Matter and Mortality within the APHEA Multicity Project , 2004, Environmental health perspectives.

[28]  Henrik Brønnum-Hansen,et al.  Population Dynamics and Air Pollution: The Impact of Demographics on Health Impact Assessment of Air Pollution , 2013, Journal of environmental and public health.

[29]  G. Imbens,et al.  The Propensity Score with Continuous Treatments , 2005 .

[30]  S. Goodman,et al.  Causal inference in public health. , 2013, Annual review of public health.

[31]  J Schwartz,et al.  Using Meta-Smoothing to Estimate Dose-Response Trends across Multiple Studies, with Application to Air Pollution and Daily Death , 2000, Epidemiology.

[32]  J. Thundiyil,et al.  Clearing the Air: A Review of the Effects of Particulate Matter Air Pollution on Human Health , 2011, Journal of Medical Toxicology.

[33]  Carl V Phillips,et al.  Epidemiologic Perspectives & Innovations Open Access the Missed Lessons of Sir Austin Bradford Hill , 2004 .

[34]  Corwin M Zigler,et al.  Causal Inference Methods for Estimating Long-Term Health Effects of Air Quality Regulations. , 2016, Research report.

[35]  G. S. Watson,et al.  A DISTRIBUTION-FREE TWO-SAMPLE TEST ON A CIRCLE, , 1964 .

[36]  Sascha O. Becker,et al.  Estimation of Average Treatment Effects Based on Propensity Scores , 2002 .

[37]  G. Imbens,et al.  Bias-Corrected Matching Estimators for Average Treatment Effects , 2002 .

[38]  A. Peters,et al.  Long-term air pollution exposure and cardio- respiratory mortality: a review , 2013, Environmental Health.

[39]  G. Imbens,et al.  Large Sample Properties of Matching Estimators for Average Treatment Effects , 2004 .

[40]  D. Rubin,et al.  Causal Inference for Statistics, Social, and Biomedical Sciences: An Introduction , 2016 .

[41]  B. Brunekreef,et al.  Effects of long-term exposure to traffic-related air pollution on respiratory and cardiovascular mortality in the Netherlands: the NLCS-AIR study. , 2009, Research report.

[42]  A. B. Hill The Environment and Disease: Association or Causation? , 1965, Proceedings of the Royal Society of Medicine.

[43]  Michael J Daniels,et al.  The National Morbidity, Mortality, and Air Pollution Study. Part III: PM10 concentration-response curves and thresholds for the 20 largest US cities. , 2004, Research report.

[44]  Els Goetghebeur,et al.  Comparison of causal effect estimators under exposure misclassification , 2010 .

[45]  B. Shepherd,et al.  GUIDO IMBENS, DONALD RUBIN, Causal Inference for Statistics, Social, and Biomedical Sciences: An Introduction. New York: Cambridge University Press. , 2016, Biometrics.

[46]  H Checkoway,et al.  A Case-Crossover Analysis of Particulate Matter Air Pollution and Out-of-Hospital Primary Cardiac Arrest , 2001, Epidemiology.