Your search keyword '"Adragna, John"' showing total 7 results

1. Toxicological assessment of E-cigarette flavored E-liquids aerosols using Calu-3 cells: A 3D lung model approach

Author

Effah, Felix, Adragna, John, Luglio, David, Bailey, Alexis, Marczylo, Tim, and Gordon, Terry

Published

2023

2. Feasibility of low-cost particle sensor types in long-term indoor air pollution health studies after repeated calibration, 2019–2021

Author

Anastasiou, Elle, Vilcassim, M. J. Ruzmyn, Adragna, John, Gill, Emily, Tovar, Albert, Thorpe, Lorna E., and Gordon, Terry

Published

2022

3. Concentration and Composition in Subway Systems in the Northeastern United States

Author

Luglio, David G., Katsigeorgis, Maria, Hess, Jade, Kim, Rebecca, Adragna, John, Raja, Amna, Gordon, Colin, Fine, Jonathan, Thurston, George, Gordon, Terry, and Vilcassim, M.J. Ruzmyn

Subjects

Northeastern United States -- Environmental aspects, Air quality -- Health aspects, Particles -- Distribution -- Composition, Subways -- Environmental aspects -- Health aspects, Company distribution practices, Environmental issues, Health

Abstract

Objectives: The goals of this study were to assess the air quality in subway systems in the northeastern United States and estimate the health risks for transit workers and commuters. Methods: We report real-time and gravimetric [PM.sub.2.5] concentrations and particle composition from area samples collected in the subways of Philadelphia, Pennsylvania; Boston, Massachusetts; New York City, New York/New Jersey (NYC/NJ); and Washington, District of Columbia. A total of 71 stations across 12 transit lines were monitored during morning and evening rush hours. Results: We observed variable and high [PM.sub.2.5] concentrations for on-train and on-platform measurements during morning (from 0600 hours to 1000 hours) and evening (from 1500 hours to 1900 hours) rush hour across cities. Mean real-time [PM.sub.2.5] concentrations in underground stations were 779 [+ or -] 249, 548 [+ or -] 207, 341 [+ or -] 147,327 [+ or -] 136, and 112 [+ or -] 46.7 [micro]g/[m.sup.3] for the PATH-NYC/NJ; MTA- NYC; Washington, DC; Boston; and Philadelphia transit systems, respectively. In contrast, the mean real-time ambient [PM.sub.2.5] concentration taken above ground outside the subway stations of PATH-NYC/NJ; MTANYC; Washington, DC; Boston; and Philadelphia were 20.8[+ or -]9.3, 24.1[+ or -]9.3,12.01 [+ or -] 7.8,10.0[+ or -]2.7, and 12.6[+ or -] 12.6 [micro]g/[m.sup.3], respectively. Stations serviced by the PATH-NYC/NJ system had the highest mean gravimetric [PM.sub.2.5] concentration, 1,020 [micro]g/[m.sup.3], ever reported for a subway system, including two 1-h gravimetric [PM.sub.2.5] values of approximately 1,700 [micro]g/[m.sup.3] during rush hour at one PATH-NYC/NJ subway station. Iron and total carbon accounted for approximately 80% of the [PM.sub.2.5] mass in a targeted subset of systems and stations. Discussion: Our results document that there is an elevation in the [PM.sub.2.5] concentrations across subway systems in the major urban centers of Northeastern United States during rush hours. Concentrations in some subway stations suggest that transit workers and commuters may be at increased risk according to U.S. federal environmental and occupational guidelines, depending on duration of exposure. This concern is highest for the [PM.sub.2.5] concentrations encountered in the PATH-NYC/NJ transit system. Further research is urgently needed to identify the sources of [PM.sub.2.5] and factors that contribute to high levels in individual stations and lines and to assess their potential health impacts on workers and/or commuters. https://doi.org/10.1289/EHP7202, Introduction Subway systems are the veins and arteries of cities, moving people where they need to go. Their speed, accessibility, and affordability offer an alternative to often chaotic city streets. [...]

Published

2021

4. Feasibility of Low-Cost Particle Sensor Types in Long-Term Indoor Air Pollution Health Studies After Repeated Calibration Over a 2-Year Timeframe

Author

Anastasiou, Elle, primary, Vilcassim, M. J. Ruzmyn, additional, Adragna, John, additional, Gill, Emily, additional, Tovar, Albert, additional, Thorpe, Lorna E., additional, and Gordon, Terry, additional

Published

2021

5. PM2.5 Concentration and Composition in Subway Systems in the Northeastern United States

Author

Luglio, David G., primary, Katsigeorgis, Maria, additional, Hess, Jade, additional, Kim, Rebecca, additional, Adragna, John, additional, Raja, Amna, additional, Gordon, Colin, additional, Fine, Jonathan, additional, Thurston, George, additional, Gordon, Terry, additional, and Vilcassim, M.J. Ruzmyn, additional

Published

2021

6. Notes on Two Introduced Populations of the Italian Wall Lizard (Podarcis siculus) on Staten Island, New York

Author

Mendyk, Robert W., primary and Adragna, John, additional

Published

2014

7. PM 2.5 Concentration and Composition in Subway Systems in the Northeastern United States.

Author

Luglio DG, Katsigeorgis M, Hess J, Kim R, Adragna J, Raja A, Gordon C, Fine J, Thurston G, Gordon T, and Vilcassim MJR

Subjects

Environmental Monitoring, Humans, Particulate Matter analysis, Philadelphia, Air Pollutants analysis, Railroads

Abstract

Objectives: The goals of this study were to assess the air quality in subway systems in the northeastern United States and estimate the health risks for transit workers and commuters., Methods: We report real-time and gravimetric PM 2.5 concentrations and particle composition from area samples collected in the subways of Philadelphia, Pennsylvania; Boston, Massachusetts; New York City, New York/New Jersey (NYC/NJ); and Washington, District of Columbia. A total of 71 stations across 12 transit lines were monitored during morning and evening rush hours., Results: We observed variable and high PM 2.5 concentrations for on-train and on-platform measurements during morning (from 0600 hours to 1000 hours) and evening (from 1500 hours to 1900 hours) rush hour across cities. Mean real-time PM 2.5 concentrations in underground stations were 779 ± 249 , 548 ± 207 , 341 ± 147 , 327 ± 136 , and 112 ± 46.7   μ g / m 3 for the PATH-NYC/NJ; MTA-NYC; Washington, DC; Boston; and Philadelphia transit systems, respectively. In contrast, the mean real-time ambient PM 2.5 concentration taken above ground outside the subway stations of PATH-NYC/NJ; MTA-NYC; Washington, DC; Boston; and Philadelphia were 20.8 ± 9.3 , 24.1 ± 9.3 , 12.01 ± 7.8 , 10.0 ± 2.7 , and 12.6 ± 12.6   μ g / m 3 , respectively. Stations serviced by the PATH-NYC/NJ system had the highest mean gravimetric PM 2.5 concentration, 1,020   μ g / m 3 , ever reported for a subway system, including two 1-h gravimetric PM 2.5 values of approximately 1,700   μ g / m 3 during rush hour at one PATH-NYC/NJ subway station. Iron and total carbon accounted for approximately 80% of the PM 2.5 mass in a targeted subset of systems and stations., Discussion: Our results document that there is an elevation in the PM 2.5 concentrations across subway systems in the major urban centers of Northeastern United States during rush hours. Concentrations in some subway stations suggest that transit workers and commuters may be at increased risk according to U.S. federal environmental and occupational guidelines, depending on duration of exposure. This concern is highest for the PM 2.5 concentrations encountered in the PATH-NYC/NJ transit system. Further research is urgently needed to identify the sources of PM 2.5 and factors that contribute to high levels in individual stations and lines and to assess their potential health impacts on workers and/or commuters. https://doi.org/10.1289/EHP7202.

Published

2021