Association of long-term exposure to local industry- and traffic-specific particulate matter with arterial blood pressure and incident hypertension

Long-term exposure to fine particulate matter (PM2.5) may lead to increased blood pressure (BP). The role of industry- and traffic-specific PM2.5 remains unclear. We investigated the associations of residential long-term source-specific PM2.5 exposure with arterial BP and incident hypertension in th...

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Bibliographic Details
Published in:International journal of hygiene and environmental health 2016-08, Vol.219 (6), p.527-535
Main Authors: Fuks, Kateryna B., Weinmayr, Gudrun, Hennig, Frauke, Tzivian, Lilian, Moebus, Susanne, Jakobs, Hermann, Memmesheimer, Michael, Kälsch, Hagen, Andrich, Silke, Nonnemacher, Michael, Erbel, Raimund, Jöckel, Karl-Heinz, Hoffmann, Barbara
Format: Article
Language:English
Subjects:
Aged
Air Pollutants - analysis
Arterial Pressure
Blood pressure
Environmental Exposure - analysis
Female
Germany - epidemiology
Humans
Hypertension
Hypertension - epidemiology
Incidence
Industrial emissions
Industry
Male
Middle Aged
Models, Theoretical
Motor Vehicles
Particulate matter
Particulate Matter - analysis
Prevalence
Prospective Studies
Source-specific air pollution
Traffic emissions
Vehicle Emissions - analysis
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Summary:Long-term exposure to fine particulate matter (PM2.5) may lead to increased blood pressure (BP). The role of industry- and traffic-specific PM2.5 remains unclear. We investigated the associations of residential long-term source-specific PM2.5 exposure with arterial BP and incident hypertension in the population-based Heinz Nixdorf Recall cohort study. We defined hypertension as systolic BP≥140mmHg, or diastolic BP≥90mmHg, or current use of BP lowering medication. Long-term concentrations of PM2.5 from all local sources (PM2.5ALL), local industry (PM2.5IND) and traffic (PM2.5TRA) were modeled with a dispersion and chemistry transport model (EURAD-CTM) with a 1km2 resolution. We performed a cross-sectional analysis with BP and prevalent hypertension at baseline, using linear and logistic regression, respectively, and a longitudinal analysis with incident hypertension at 5-year follow-up, using Poisson regression with robust variance estimation. We adjusted for age, sex, body mass index, lifestyle, education, and major road proximity. Change in BP (mmHg), odds ratio (OR) and relative risk (RR) for hypertension were calculated per 1μg/m3 of exposure concentration. PM2.5ALL was highly correlated with PM2.5IND (Spearman’s ρ=0.92) and moderately with PM2.5TRA (ρ=0.42). In adjusted cross-sectional analysis with 4539 participants, we found positive associations of PM2.5ALL with systolic (0.42 [95%-CI: 0.03, 0.80]) and diastolic (0.25 [0.04, 0.46]) BP. Higher, but less precise estimates were found for PM2.5IND (systolic: 0.55 [−0.05, 1.14]; diastolic: 0.35 [0.03, 0.67]) and PM2.5TRA (systolic: 0.88 [−1.55, 3.31]; diastolic: 0.41 [−0.91, 1.73]). We found crude positive association of PM2.5TRA with prevalence (OR 1.41 [1.10, 1.80]) and incidence of hypertension (RR 1.38 [1.03, 1.85]), attenuating after adjustment (OR 1.19 [0.90, 1.58] and RR 1.28 [0.94, 1.72]). We found no association of PM2.5ALL and PM2.5IND with hypertension. Long-term exposures to all-source and industry-specific PM2.5 were positively related to BP. We could not separate the effects of industry-specific PM2.5 from all-source PM2.5. Estimates with traffic-specific PM2.5 were generally higher but inconclusive.
ISSN:1438-4639
1618-131X
DOI:10.1016/j.ijheh.2016.05.008