%0 Journal Article %J PLoS One %D 2022 %T Impact of acute temperature and air pollution exposures on adult lung function: A panel study of asthmatics. %A Evoy, Richard %A Laurel D Kincl %A Diana Rohlman %A Lisa M Bramer %A Holly Dixon %A Hystad, Perry %A Bae, Harold %A Michael L Barton %A Phillips, Aaron %A Miller, Rachel L %A Katrina M Waters %A Julie Herbstman %A Kim A Anderson %K Adult %K Air Pollution %K Asthma %K Bronchodilator Agents %K Environmental Exposure %K Humans %K Lung %K Temperature %X

BACKGROUND: Individuals with respiratory conditions, such as asthma, are particularly susceptible to adverse health effects associated with higher levels of ambient air pollution and temperature. This study evaluates whether hourly levels of fine particulate matter (PM2.5) and dry bulb globe temperature (DBGT) are associated with the lung function of adult participants with asthma.

METHODS AND FINDINGS: Global positioning system (GPS) location, respiratory function (measured as forced expiratory volume at 1 second (FEV1)), and self-reports of asthma medication usage and symptoms were collected as part of the Exposure, Location, and Lung Function (ELF) study. Hourly ambient PM2.5 and DBGT exposures were estimated by integrating air quality and temperature public records with time-activity patterns using GPS coordinates for each participant (n = 35). The relationships between acute PM2.5, DBGT, rescue bronchodilator use, and lung function collected in one week periods and over two seasons (summer/winter) were analyzed by multivariate regression, using different exposure time frames. In separate models, increasing levels in PM2.5, but not DBGT, were associated with rescue bronchodilator use. Conversely DBGT, but not PM2.5, had a significant association with FEV1. When DBGT and PM2.5 exposures were placed in the same model, the strongest association between cumulative PM2.5 exposures and the use of rescue bronchodilator was identified at the 0-24 hours (OR = 1.030; 95% CI = 1.012-1.049; p-value = 0.001) and 0-48 hours (OR = 1.030; 95% CI = 1.013-1.057; p-value = 0.001) prior to lung function measure. Conversely, DBGT exposure at 0 hours (β = 3.257; SE = 0.879; p-value>0.001) and 0-6 hours (β = 2.885; SE = 0.903; p-value = 0.001) hours before a reading were associated with FEV1. No significant interactions between DBGT and PM2.5 were observed for rescue bronchodilator use or FEV1.

CONCLUSIONS: Short-term increases in PM2.5 were associated with increased rescue bronchodilator use, while DBGT was associated with higher lung function (i.e. FEV1). Further studies are needed to continue to elucidate the mechanisms of acute exposure to PM2.5 and DBGT on lung function in asthmatics.

%B PLoS One %V 17 %P e0270412 %8 2022 %G eng %N 6 %R 10.1371/journal.pone.0270412 %0 Journal Article %J Environ Pollut %D 2018 %T Environmental and individual PAH exposures near rural natural gas extraction. %A Paulik, L Blair %A Kevin A Hobbie %A Diana Rohlman %A Brian W Smith %A Richard P Scott %A Laurel D Kincl %A Erin N Haynes %A Kim A Anderson %K Air Pollutants %K Air Pollution %K Environmental Exposure %K Environmental Monitoring %K Humans %K Linear Models %K Natural Gas %K Oil and Gas Fields %K Petroleum %K Polycyclic Aromatic Hydrocarbons %K Pyrenes %K Silicones %K Tandem Mass Spectrometry %X

Natural gas extraction (NGE) has expanded rapidly in the United States in recent years. Despite concerns, there is little information about the effects of NGE on air quality or personal exposures of people living or working nearby. Recent research suggests NGE emits polycyclic aromatic hydrocarbons (PAHs) into air. This study used low-density polyethylene passive samplers to measure concentrations of PAHs in air near active (n = 3) and proposed (n = 2) NGE sites. At each site, two concentric rings of air samplers were placed around the active or proposed well pad location. Silicone wristbands were used to assess personal PAH exposures of participants (n = 19) living or working near the sampling sites. All samples were analyzed for 62 PAHs using GC-MS/MS, and point sources were estimated using the fluoranthene/pyrene isomer ratio. ∑PAH was significantly higher in air at active NGE sites (Wilcoxon rank sum test, p < 0.01). PAHs in air were also more petrogenic (petroleum-derived) at active NGE sites. This suggests that PAH mixtures at active NGE sites may have been affected by direct emissions from petroleum sources at these sites. ∑PAH was also significantly higher in wristbands from participants who had active NGE wells on their properties than from participants who did not (Wilcoxon rank sum test, p < 0.005). There was a significant positive correlation between ∑PAH in participants' wristbands and ∑PAH in air measured closest to participants' homes or workplaces (simple linear regression, p < 0.0001). These findings suggest that living or working near an active NGE well may increase personal PAH exposure. This work also supports the utility of the silicone wristband to assess personal PAH exposure.

%B Environ Pollut %V 241 %P 397-405 %8 2018 Oct %G eng %R 10.1016/j.envpol.2018.05.010