Abstract
While fine particulate matter (PM(2.5)) has been associated with autism spectrum disorder (ASD), few studies focused on ultrafine particles (PM(0.1)). Given that fine and ultrafine particles can be highly correlated due to shared emission sources, challenges remain to distinguish their health effects. In a retrospective cohort of 318,371 mother-child pairs (4549 ASD cases before age 5) in Southern California, pregnancy average PM(2.5) and PM(0.1) were estimated using a California-based chemical transport model and assigned to residential addresses. The correlation between PM(2.5) and PM(0.1) was 0.87. We applied a two-step variance decomposition approach: first, decomposing PM(2.5) and PM(0.1) into the shared and unique variances using ordinary least squares linear regression (OLS) and Deming regression considering errors in both exposures; then assessing associations between decomposed PM(2.5) and PM(0.1) and ASD using Cox proportional hazard models adjusted for covariates. Prenatal PM(2.5) and PM(0.1) each was associated with increased ASD risk. OLS decomposition showed that associations were driven mainly by their shared variance, not by their unique variance. Results from Deming regression considering assumptions of measurement errors were consistent with those from OLS. This decomposition approach has potential to disentangle health effects of correlated exposures, such as PM(2.5) and PM(0.1) from common emissions sources.