Linking a dermal permeation and an inhalation model to a simple pharmacokinetic model to study airborne exposure to di(n-butyl) phthalate

Six males clad only in shorts were exposed to high levels of airborne di(n-butyl) phthalate (DnBP) and diethyl phthalate (DEP) in chamber experiments conducted in 2014. In two 6 h sessions, the subjects were exposed only dermally while breathing clean air from a hood, and both dermally and via inhal...

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Bibliographic Details
Published in:Journal of exposure science & environmental epidemiology 2017-11, Vol.27 (6), p.601-609
Main Authors: Lorber, Matthew, Weschler, Charles J, Morrison, Glenn, Bekö, Gabriel, Gong, Mengyan, Koch, Holger M, Salthammer, Tunga, Schripp, Tobias, Toftum, Jørn, Clausen, Geo
Format: Article
Language:English
Subjects:
631/1647/767/2202
631/92/436/1729
704/172/169/895
Adult
Air Pollutants - urine
Breathing
Computer simulation
Denmark
Dibutyl Phthalate - urine
Diethyl phthalate
Environmental Exposure - analysis
Environmental Monitoring - methods
Environmental Pollutants - urine
Epidemiology
Excretion
Exposure
Humans
Indoor air pollution
Inhalation
Male
Mathematical models
Medicine
Medicine & Public Health
Metabolites
Middle Aged
Modelling
Original
original-article
Penetration
Pharmacokinetics
Pharmacology
Phthalates
Predictions
Respiration
Skin
Skin Absorption
Time Factors
Urine
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Summary:Six males clad only in shorts were exposed to high levels of airborne di(n-butyl) phthalate (DnBP) and diethyl phthalate (DEP) in chamber experiments conducted in 2014. In two 6 h sessions, the subjects were exposed only dermally while breathing clean air from a hood, and both dermally and via inhalation when exposed without a hood. Full urine samples were taken before, during, and for 48 h after leaving the chamber and measured for key DnBP and DEP metabolites. The data clearly demonstrated high levels of DnBP and DEP metabolite excretions while in the chamber and during the first 24 h once leaving the chamber under both conditions. The data for DnBP were used in a modeling exercise linking dose models for inhalation and transdermal permeation with a simple pharmacokinetic model that predicted timing and mass of metabolite excretions. These models were developed and calibrated independent of these experiments. Tests included modeling of the “hood-on” (transdermal penetration only), “hood-off” (both inhalation and transdermal) scenarios, and a derived “inhalation-only” scenario. Results showed that the linked model tended to duplicate the pattern of excretion with regard to timing of peaks, decline of concentrations over time, and the ratio of DnBP metabolites. However, the transdermal model tended to overpredict penetration of DnBP such that predictions of metabolite excretions were between 1.1 and 4.5 times higher than the cumulative excretion of DnBP metabolites over the 54 h of the simulation. A similar overprediction was not seen for the “inhalation-only” simulations. Possible explanations and model refinements for these overpredictions are discussed. In a demonstration of the linked model designed to characterize general population exposures to typical airborne indoor concentrations of DnBP in the United States, it was estimated that up to one-quarter of total exposures could be due to inhalation and dermal uptake.
ISSN:1559-0631
1559-064X
DOI:10.1038/jes.2016.48