Assessment of the oxidative potential and oxidative burden from occupational exposures to particulate matter

Auteurs

Alan da Silveira Fleck, Université de MontréalFollow
Maximilien Debia, Université de MontréalFollow
Patrick Eddy Ryan, Université de Montréal
Caroline Couture, Université de MontréalFollow
Alison Traub, Ontario Centre for Atmospheric Aerosol Research, University of Toronto Engineering
Greg J. Evans, Southern Ontario Centre for Atmospheric Aerosol Research
Eva Suarthana, McGill University
Audrey Smargiassi, Université de Montréal

Type de document

Études primaires

Année de publication

2022

Langue

Anglais

Titre de la revue

Annals of Work Exposures and Health

Première page

379

Dernière page

391

Résumé

Oxidative potential (OP) is a toxicologically relevant metric that integrates features like mass concentration and chemical composition of particulate matter (PM). Although it has been extensively explored as a metric for the characterization of environmental particles, this is still an underexplored application in the occupational field. This study aimed to estimate the OP of particles in two occupational settings from a construction trades school. This characterization also includes the comparison between activities, sampling strategies, and size fractions. Particulate mass concentrations (PM_4-Personal, PM_4-Area, and PM_2.5-Area) and number concentrations were measured during three weeks of welding and construction/bricklaying activities. The OP was assessed by the ascorbate assay (OP^AA) using a synthetic respiratory tract lining fluid (RTLF), while the oxidative burden (OB^AA) was determined by multiplying the OPAA values with PM concentrations. Median (25^th–75^th percentiles) of PM mass and number concentrations were 900 (672–1730) µg m^–3 and 128 000 (78 000–169 000) particles cm^–3 for welding, and 432 (345–530) µg m^–3 and 2800 (1700–4400) particles cm^–3 for construction. Welding particles, especially from the first week of activities, were also associated with higher redox activity (OP^AA: 3.3 (2.3–4.6) ρmol min^–1 µg^–1; OB^AA: 1750 (893–4560) ρmol min^–1 m^–3) compared to the construction site (OP^AA: 1.4 (1.0–1.8) ρmol min^–1 µg^–1; OB^AA: 486 (341–695) ρmol min^–1 m^–3). The OP^AA was independent of the sampling strategy or size fraction. However, driven by the higher PM concentrations, the OB^AA from personal samples was higher compared to area samples in the welding shop, suggesting an influence of the sampling strategy on PM concentrations and OB^AA. These results demonstrate that important levels of OP^AA can be found in occupational settings, especially during welding activities. Furthermore, the OB^AA found in both workplaces largely exceeded the levels found in environmental studies. Therefore, measures of OP and OB could be further explored as metrics for exposure assessment to occupational PM, as well as for associations with cardiorespiratory outcomes in future occupational epidemiological studies.

Mots-clés

Oxydation, Oxidation, Évaluation de l'exposition, Exposure evaluation, Toxicologie, Toxicology, Poussière en suspension dans l'air, Airborne dust, Travaux de construction, Construction Work

Numéro de projet IRSST

2017-0007

Citation recommandée

da Silveira Fleck, A., Debia, M., Ryan, P. E., Couture, C., Traub, A., Evans, G. J., . . . Smargiassi, A. (2022). Assessment of the oxidative potential and oxidative burden from occupational exposures to particulate matter. Annals of Work Exposures and Health, 66(3), 379-391. https://doi.org/10.1093/annweh/wxab086