To determine if airborne particulates contribute to excess mortality, researchers have adopted multiple regression techniques to measure the effects of particulates on daily death counts (1,2). Other factors, such as extreme temperatures, can affect mortality, and regression techniques are used to adjust for these other known influences. Though many factors could be involved, research has generally limited attention to meteorological sources such as temperature and humidity. In some cases, other air pollution measures such as sulfur dioxide and ozone are included. The regression coefficient corresponding to a measure of particulate level is then interpreted as the effect of particulate pollution on mortality, accounting for stress from the other influences. If this coefficient is a statistically significant positive number, the conclusion is that mortality increases with increasing levels of particulates. This association is then elevated to a causal interpretation: particulates cause death, and researchers estimate that soot at levels well below the maximum set by federal law "kills up to 60,000 in U.S. each year" (3,4), and similar calculations "put the annual toll in England and Wales at 10,000" (5).Studies vary as to the particulate measures used and the locations analyzed. In the analyses presented here, we used PM1O, which specifies particulate matter with an aerodynamic diameter <10 pm (6). The current U.S. EPA standard is based on this measure. The locations we analyzed, Cook County, Illinois, and Salt Lake County, Utah, both have relatively long records of PM1O monitoring. The monitoring data are discussed in more detail in Methods.The data used in the analyses (meteorological conditions, particulate levels, death counts) are observational; that is, data that are measured and recorded without control or intervention by researchers. Deducing causal relationships from observational data is perilous. A practical approach described by Mosteller and Tukey (P) involves considerations beyond regression analysis. In particular, consideration should be given to whether the association between particulate levels and mortality is consistent across "settings," whether there are plausible common causes for elevated particulate levels and mortality, and whether the derived models reflect reasonable physical relationships.There is a high degree of association of PM1O with meteorology, and a high degree The results for Cook County and Salt Lake County show that the appearance and size of a PMIO effect is quite sensitive to model specification. In particular, the treatment of season affects the estimates of the PMIO effect. In Cook County, we found a significant interaction between the time of year and PM10. Using a standard Poisson regression model, we found that PMIO appears to be significantly associated with mortality in the spring and fall, but not in the winter and summer. Using a semi-parametric model (Appendix A), we found that only the months of May and September exhibit a particulate effect. In Salt Lake Count...
