HMOX1 and GST variants modify attenuation of FEF25-75% decline due to PM10 reduction.

Reduced exposure to particulate matter with a 50% cut-off aerodynamic diameter of 10 microm (PM(10)) attenuated age-related lung function decline in our cohort, particularly in the small airways. We hypothesised that polymorphisms in glutathione S-transferase (GST) and haem oxygenase-1 (HMOX1) genes, important for oxidative stress defence, modify these beneficial effects. A population-based sample of 4,365 adults was followed up after 11 yrs, including questionnaire, spirometry and DNA blood sampling. PM(10) exposure was estimated by dispersion modelling and temporal interpolation. The main effects on annual decline in forced expiratory flow at 25-75% of forced vital capacity (FEF(25-75%)) and interactions with PM(10) reduction were investigated for polymorphisms HMOX1 rs2071746 (T/A), rs735266 (T/A) and rs5995098 (G/C), HMOX1 (GT)(n) promoter repeat, GSTM1 and GSTT1 deletions, and GSTP1 p.Ile105Val, using mixed linear regression models. HMOX1 rs5995098, HMOX1 haplotype TTG and GSTP1 showed significant genetic main effects. Interactions with PM(10) reduction were detected: a 10 microg.m(-3) reduction significantly attenuated annual FEF(25-75%) decline by 15.3 mL.s(-1) only in the absence of HMOX1 haplotype ATC. Similarly, carriers of long (GT)(n) promoter repeat alleles or the GSTP1 Val/Val genotype profited significantly more from a 10 microg.m(-3) reduction (26.5 mL.s(-1) and 27.3 mL.s(-1) respectively) than non-carriers. Benefits of a reduction in PM(10) exposure are not equally distributed across the population but are modified by the individual genetic make-up determining oxidative stress defence.

Association between short term exposure to fine particulate matter and heart rate variability in older subjects with and without heart disease.

BACKGROUND: Short term increases in exposure to particulate matter (PM) air pollution are associated with increased cardiovascular morbidity and mortality. The mechanism behind this effect is unclear, although changes in autonomic control have been observed. It was hypothesised that increases in fine PM measured at the subjects' home in the preceding hour would be associated with decreased high frequency heart rate variability (HF-HRV) in individuals with pre-existing cardiac disease. METHODS: Two hundred and eighty five daily 20 minute measures of HRV (including a paced breathing protocol) were made in the homes of 34 elderly individuals with (n = 21) and without (n = 13) cardiovascular disease (CVD) over a 10 day period in Seattle between February 2000 and March 2002. Fine PM was continuously measured by nephelometry at the individuals' homes. RESULTS: The median age of the study population was 77 years (range 57-87) and 44% were male. Models that adjusted for health status, relative humidity, temperature, mean heart rate, and medication use did not find a significant association between a 10 microg/m3 increase in 1 hour mean outdoor PM2.5 before the HRV measurement and a change in HF-HRV power in individuals with CVD (3% increase in median HF-HRV (95% CI -19 to 32)) or without CVD (5% decrease in median HF-HRV (95% CI -34 to 36)). Similarly, no association was evident using 4 hour and 24 hour mean outdoor PM2.5 exposures before the HRV measurement. CONCLUSION: No association was found between increased residence levels of fine PM and frequency domain measures of HRV in elderly individuals.