Reactions of ozone with human skin lipids: Sources of carbonyls, dicarbonyls, and hydroxycarbonyls in indoor air

• Published in: Proceedings of the National Academy of Sciences - PNAS Vol. 107; no. 15; pp. 6568 - 6575
• Main Authors: Wisthaler, Armin, Weschler, Charles J
• Format: Journal Article
• Language: English
• Published: United States National Academy of Sciences 13.04.2010; National Acad Sciences
• Series: Atmospheric Chemistry Special Feature
• Subjects: acetone; Air; Air Pollutants - analysis; Air Pollution, Indoor - analysis; ATMOSPHERIC CHEMISTRY SPECIAL FEATURE; Carbon - chemistry; Carbonyl compounds; Environmental Monitoring; esterification; Esters - chemistry; Experiments; Fatty acids; Female; Glass wool; Humans; in vivo studies; Indoor air pollution; Indoor air quality; Indoor environments; Ketones; Ketones - chemistry; Lipids; Lipids - chemistry; Male; Mass spectrometry; Mass Spectrometry - methods; mixing; Mixing ratios; Oxidation; Ozone; Physical Sciences; pollutants; Skin; Skin - drug effects; Skin - metabolism; spectroscopy; Squalene; surveys; Unsaturated fatty acids; Vapor phases; Volatility; Volatilization
• ISSN: 0027-8424; 1091-6490; 1091-6490
• DOI: 10.1073/pnas.0904498106

This study has used proton transfer reaction-mass spectrometry (PTR-MS) for direct air analyses of volatile products resulting from the reactions of ozone with human skin lipids. An initial series of small-scale in vitro and in vivo experiments were followed by experiments conducted with human subjects in a simulated office. The latter were conducted using realistic ozone mixing ratios ([almost equal to]15 ppb with occupants present). Detected products included mono- and bifunctional compounds that contain carbonyl, carboxyl, or α-hydroxy ketone groups. Among these, three previously unreported dicarbonyls have been identified, and two previously unreported α-hydroxy ketones have been tentatively identified. The compounds detected in this study (excepting acetone) have been overlooked in surveys of indoor pollutants, reflecting the limitations of the analytical methods routinely used to monitor indoor air. The results are fully consistent with the Criegee mechanism for ozone reacting with squalene, the single most abundant unsaturated constituent of skin lipids, and several unsaturated fatty acid moieties in their free or esterified forms. Quantitative product analysis confirms that squalene is the major scavenger of ozone at the interface between room air and the human envelope. Reactions between ozone and human skin lipids reduce the mixing ratio of ozone in indoor air, but concomitantly increase the mixing ratios of volatile products and, presumably, skin surface concentrations of less volatile products. Some of the volatile products, especially the dicarbonyls, may be respiratory irritants. Some of the less volatile products may be skin irritants.