Your search keyword '"Godri, Krystal J."' showing total 2 results

1. Respiratory Health Effects of Airborne Particulate Matter: The Role of Particle Size, Composition, and Oxidative Potential--The RAPTES Project.

Author

Strak, Maciej, Janssen, Nicole A. H., Godri, Krystal J., Gosens, Ilse, Mudway, Ian S., Cassee, Flemming R., Lebret, Erik, Kelly, Frank J., Harrison, Roy M., Brunekreef, Bert, Steenhof, Maaike, and Hoek, Gerard

Subjects

CARBON, COLLEGE students, CONFIDENCE intervals, RESEARCH methodology, METALS, NITROGEN oxides, OZONE, PARTICLES, QUESTIONNAIRES, REGRESSION analysis, RESEARCH funding, RESPIRATORY measurements, RESPIRATORY organs, STATISTICS, DATA analysis, ENVIRONMENTAL exposure, OXIDATIVE stress, PARTICULATE matter, PRE-tests & post-tests, VITAL capacity (Respiration), DATA analysis software, DESCRIPTIVE statistics

Abstract

Background: Specific characteristics of particulate matter (PM) responsible for associations with respiratory health observed in epidemiological studies are not well established. High correlations among, and differential measurement errors of, individual components contribute to this uncertainty. Objectives: We investigated which characteristics of PM have the most consistent associations with acute changes in respiratory function in healthy volunteers. Methods: We used a semiexperimental design to accurately assess exposure. We increased exposure contrast and reduced correlations among PM characteristics by exposing volunteers at five different locations: an underground train station, two traffic sites, a farm, and an urban background site. Each of the 31 participants was exposed for 5 hr while exercising intermittently, three to seven times at different locations during March-October 2009. We measured PM10, PM2.5, particle number concentrations (PNC), absorbance, elemental/organic carbon, trace metals, secondary inorganic components, endotoxin content, gaseous pollutants, and PM oxidative potential. Lung function [FEV1 (forced expiratory volume in 1 sec), FVC (forced vital capacity), FEF25-75 (forced expiratory flow at 25-75% of vital capacity), and PEF (peak expiratory flow)] and fractional exhaled nitric oxide (FENO) were measured before and at three time points after exposure. Data were analyzed with mixed linear regression. Results: An interquartile increase in PNC (33,000 particles/cm3) was associated with an 11% [95% confidence interval (CI): 5, 17%] and 12% (95% CI: 6, 17%) FENO increase over baseline immediately and at 2 hr postexposure, respectively. A 7% (95% CI: 0.5, 14%) increase persisted until the following morning. These associations were robust and insensitive to adjustment for other pollutants. Similarly consistent associations were seen between FVC and FEV1 with PNC, NO2 (nitrogen dioxide), and NOx (nitrogen oxides). Conclusions: Changes in PNC, NO2, and NOx were associated with evidence of acute airway inflammation (i.e., FENO) and impaired lung function. PM mass concentration and PM10 oxidative potential were not predictive of the observed acute responses. [ABSTRACT FROM AUTHOR]

Published

2012

2. Particulate Matter Oxidative Potential from Waste Transfer Station Activity.

Author

Godri, Krystal J., Duggan, Sean T., Fuller, Gary W., Baker, Tim, Green, David, Kelly, Frank J., and Mudway, Ian S.

Subjects

*CARDIOPULMONARY system, *PARTICULATE matter, *EMISSION control, *INDUSTRIAL wastes, *FLUID models in geophysics, *THRESHOLD limit values (Industrial toxicology), *GLUTATHIONE, *HEALTH risk assessment, *WASTE products

Abstract

Background: Adverse cardiorespiratory health is associated with exposure to ambient particulate matter (PM). The highest PM concentrations in London occur in proximity to waste transfer stations (WTS), sites that experience high numbers of dust-laden, heavy-duty diesel vehicles transporting industrial and household waste. Objective: Our goal was to quantify the contribution of WTS emissions to ambient PM mass concentrations and oxidative potential. Methods: PM with a diameter < 10 μm (PM10) samples were collected daily close to a WTS. PM10 mass concentrations measurements were source apportioned to estimate local versus background sources. PM oxidative potential was assessed using the extent of antioxidant depletion from a respiratory tract lining fluid model. Total trace metal and bioavailable iron concentrations were measured to determine their contribution to PM oxidative potential. Results: Elevated diurnal PM10 mass concentrations were observed on all days with WTS activity (Monday-Saturday). Variable PM oxidative potential, bioavailable iron, and total metal concentrations were observed on these days. The contribution of WTS emissions to PM at the sampling site, as predicted by microscale wind direction measurements, was correlated with ascorbate (r = 0.80; p = 0.030) and glutathione depletion (r = 0.76; p = 0.046). Increased PM oxidative potential was associated with aluminum, lead, and iron content. Conclusions: PM arising from WTS activity has elevated trace metal concentrations and, as a consequence, increased oxidative potential. PM released by WTS activity should be considered a potential health risk to the nearby residential community. [ABSTRACT FROM AUTHOR]

Published

2010