Percutaneous Absorption of Polycyclic Aromatic Compounds from Fume Condensates of Paving and Built Up Roofing Asphalts

Paving and roofing workers can be exposed to low levels of polycyclic aromatic compounds (PACs) while working with asphalt at elevated temperatures via both the inhalation and dermal routes. Inhalation exposure date are readily available. However, dermal information is more complicated and not as we...

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Bibliographic Details
Published in:Polycyclic aromatic compounds 2020-08, Vol.40 (4), p.945-953
Main Authors: Roy, Timothy A., Kriech, Anthony J., Osborn, Linda V.
Format: Article
Language:English
Subjects:
Absorption
Anthracene
Aromatic compounds
Asphalt
Asphalt emissions
Asphalt fume condensates (AFCs)
Benzo(a)pyrene
BURA
Condensates
Diffusion cells
Epidermis
Exposure
Fluctuations
Fluoranthene
Fluorescence
Flux
Fumes
Headspace
High temperature
High-performance liquid chromatography
In vitro methods and tests
Inhalation
Liquid chromatography
Occupational exposure
PAC
Paving
Permeability
Permeability coefficient
Pyrene
Respiration
Risk assessment
Roofing
Skin
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Summary:Paving and roofing workers can be exposed to low levels of polycyclic aromatic compounds (PACs) while working with asphalt at elevated temperatures via both the inhalation and dermal routes. Inhalation exposure date are readily available. However, dermal information is more complicated and not as well-studied. Here we evaluate condensed fumes from four paving and four BURA asphalts for percutaneous absorption through human skin using in vitro studies. Test materials included eight asphalt (bitumen) fume condensates (AFCs) collected from the headspace above four paving and four Type III built up roofing asphalt (BURA) tanks, each proven to match worker breathing zone exposures. Sections of human cadaver skin were sliced with a dermatome to a thickness of 250-350 μm, one-inch circular pieces were mounted in Franz diffusion cells epidermis side up. Receptor fluids were sampled at intervals over 48 hr and the aliquots analyzed for PACs using HPLC with fluorescence detection to determine the dermal flux rates of anthracene, fluoranthene/pyrene, and total 3-6 ring PACs. For paving/BURA AFCs, respectively, the average (N = 4) concentrations (μg/g) were: anthracene, 50.6 (SD = 14)/27.2 (SD = 28); fluoranthene/pyrene, 66.5 (SD = 47)/83.2 (SD = 100); Ʃ3-6 ring PACs, 833 (SD = 302)/2191 (SD = 240). Dermal flux rates (ng/cm 2 /hr) were: anthracene, 4.4 (SD = 1.1)/1.9 (SD = 2.0); fluoranthene/pyrene, 3.8 (SD = 2.8)/3.6 (SD = 5.0); Ʃ3-6 ring PAC, 35 (SD = 14)/21 (SD = 15). The estimated dermal flux of benzo[a]pyrene B[a]P in paving AFCs ranged from 0.0006 to 0.007 ng/cm 2 /hr and for BURA AFCs from 0.016 to 0.19 ng/cm 2 /hr. The averaged experimentally determined permeability coefficient (Kp) for anthracene for all eight samples was 0.90 ± 0.13 × 10 −4  cm/hr (95% CI). Results show limited absorption of PACs across the skin in AFCs under the most conservative conditions (occluded/infinite dose). Dermal flux results can be used to support dermal exposure and risk assessments for asphalt emissions.
ISSN:1040-6638
1563-5333
DOI:10.1080/10406638.2018.1509362