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Long-term exposure to fine particle elemental components and mortality in Europe: results from six European administrative cohorts within the ELAPSE project
JournalArticle (Originalarbeit in einer wissenschaftlichen Zeitschrift)
ID
4651817
Author(s)
Rodopoulou, S.; Stafoggia, M.; Chen, J.; de Hoogh, K.; Bauwelinck, M.; Mehta, A. J.; Klompmaker, J. O.; Oftedal, B.; Vienneau, D.; Janssen, N. A. H.; Strak, M.; Andersen, Z. J.; Renzi, M.; Cesaroni, G.; Nordheim, C. F.; Bekkevold, T.; Atkinson, R.; Forastiere, F.; Katsouyanni, K.; Brunekreef, B.; Samoli, E.; Hoek, G.
Long-term exposure to fine particle elemental components and mortality in Europe: results from six European administrative cohorts within the ELAPSE project
Journal
The science of the total environment
Volume
809
Pages / Article-Number
152205
Keywords
Air pollution; Long-term exposure; Natural mortality; Particle components
Mesh terms
Air Pollutants, analysis; Air Pollution, analysis; Environmental Exposure, analysis; Europe, epidemiology; Humans; Particulate Matter, analysis
Abstract
Evidence for the association between long-term exposure to ambient particulate matter components and mortality from natural causes is sparse and inconsistent. We evaluated this association in six large administrative cohorts in the framework of the Effects of Low-Level Air Pollution: A Study in Europe (ELAPSE) project. We analyzed data from country-wide administrative cohorts in Norway, Denmark, the Netherlands, Belgium, Switzerland and in Rome (Italy). Annual 2010 mean concentrations of copper (Cu), iron (Fe), potassium (K), nickel (Ni), sulfur (S), silicon (Si), vanadium (V) and zinc (Zn) in fine particulate matter (PM2.5) were estimated using 100x100m Europe-wide hybrid land use regression models assigned to the participants' residential addresses. We applied cohort-specific Cox proportional hazard models controlling for area- and individual-level covariates to evaluate associations with natural mortality. Two pollutant models adjusting for PM2.5 total mass or nitrogen dioxide (NO2) were also applied. We pooled cohort-specific estimates using a random effects meta-analysis. We included almost 27 million participants contributing more than 240millionperson-years. All components except Zn were significantly associated with natural mortality [pooled Hazard Ratios (HRs) (95% CI): 1.037 (1.014, 1.060) per 5ng/m(3) Cu; 1.069 (1.031, 1.108) per 100ng/m(3) Fe; 1.039 (1.018, 1.062) per 50ng/m(3) K; 1.024 (1.006, 1.043) per 1ng/m(3) Ni; 1.036 (1.016, 1.057) per 200ng/m(3) S; 1.152 (1.048, 1.266) per 100ng/m(3) Si; 1.020 (1.006, 1.034) per 2ng/m(3) V]. Only K and Si were robust to PM2.5 or NO2 adjustment [pooled HRs (95% CI) per 50ng/m(3) in K: 1.025 (1.008, 1.044), 1.020 (0.999, 1.042) and per 100ng/m(3) in Si: 1.121 (1.039, 1.209), 1.068 (1.022, 1.117) adjusted for PM2.5 and NO2 correspondingly]. Our findings indicate an association of natural mortality with most components, which was reduced after adjustment for PM2.5 and especially NO2.
