Development and evaluation of two-parameter linear free energy models for the prediction of human skin permeability coefficient of neutral organic chemicals

Phthalates are multifunctional chemicals that are used in a variety of consumer products including cosmetic and personal care products. This study aims at determining phthalate levels in cosmetic and personal care products obtained from the Canadian market. Overall 252 products including 98 baby care products were collected at retail stores in several provinces across Canada in year 2007. These products included fragrances, hair care products (hair sprays, mousses, and gels), deodorants (including antiperspirants), nail polishes, lotions (body lotions and body creams), skin cleansers, and baby products (oils, lotions, shampoos and diaper creams). Samples were extracted with different organic solvents, depending on the types of the products, followed by gas chromatography-mass spectrometry (GC-MS) analysis. Of the 18 investigated phthalates, diethyl phthalate (DEP), dimethyl phthalate (DMP), diisobutyl phthalate (DiBP), di-n-butyl phthalate (DnBP) and di(2-ethylhexyl) phthalate (DEHP) were detected. The detection frequencies were in the following order: DEP (103 out of 252 products)>DnBP (15/252)>DiBP (9/252)>DEHP (8/252)>DMP (1/252). DEP was detected in almost all types of surveyed products with the highest levels (25,542 μg/g, equal to 2.6%) found in fragrances. DnBP was largely present in nail polish products with the highest concentration of 24,304 μg/g (2.4%). DnBP was also found in other products such as hair sprays, hair mousses, skin cleansers and baby shampoos at much lower concentrations (36 μg/g and less). Levels of other detected phthalates were generally low in the products. Based on these values, daily dermal exposure dosage to five phthalates was estimated for three age groups, female adults (60 kg); toddlers (0.5-4 years) and infants (0-6 months), through the use of cosmetic and personal care products. The exposure estimation, however, was based on existing products use pattern data, instead of probabilistic model based population use distribution. For female adults, the maximal daily exposure of 78 μg/kg bw/d was determined for DEP. The maximal daily exposure was much lower for the other four phthalates (DEHP, 0.82 μg/kg bw/d; DnBP, 0.36 μg/kg bw/d; and DMP, 0.03 μg/kg bw/d). The exposure for DiBP was not calculated due to its very low levels (<10 μg/g) in products. Toddlers and infants in this case had a maximal daily exposure to DEP of 20 and 42 μg/kg bw/d, respectively. Crown Copyright © 2011. Published by Elsevier Inc. All rights reserved.

This paper critically examines indoor exposure to semivolatile organic compounds (SVOCs) via dermal pathways. First, it demonstrates that--in central tendency--an SVOC's abundance on indoor surfaces and in handwipes can be predicted reasonably well from gas-phase concentrations, assuming that thermodynamic equilibrium prevails. Then, equations are developed, based upon idealized mass-transport considerations, to estimate transdermal penetration of an SVOC either from its concentration in skin-surface lipids or its concentration in air. Kinetic constraints limit air-to-skin transport in the case of SVOCs that strongly sorb to skin-surface lipids. Air-to-skin transdermal uptake is estimated to be comparable to or larger than inhalation intake for many SVOCs of current or potential interest indoors, including butylated hydroxytoluene, chlordane, chlorpyrifos, diethyl phthalate, Galaxolide, geranyl acetone, nicotine (in free-base form), PCB28, PCB52, Phantolide, Texanol and Tonalide. Although air-to-skin transdermal uptake is anticipated to be slow for bisphenol A, we find that transdermal permeation may nevertheless be substantial following its transfer to skin via contact with contaminated surfaces. The paper concludes with explorations of the influence of particles and dust on dermal exposure, the role of clothing and bedding as transport vectors, and the potential significance of hair follicles as transport shunts through the epidermis. Human exposure to indoor pollutants can occur through dietary and nondietary ingestion, inhalation, and dermal absorption. Many factors influence the relative importance of these pathways, including physical and chemical properties of the pollutants. This paper argues that exposure to indoor semivolatile organic compounds (SVOCs) through the dermal pathway has often been underestimated. Transdermal permeation of SVOCs can be substantially greater than is commonly assumed. Transport of SVOCs from the air to and through the skin is typically not taken into account in exposure assessments. Yet, for certain SVOCs, intake through skin is estimated to be substantially larger than intake through inhalation. Exposure scientists, risk assessors, and public health officials should be mindful of the dermal pathway when estimating exposures to indoor SVOCs. Also, they should recognize that health consequences vary with exposure pathway. For example, an SVOC that enters the blood through the skin does not encounter the same detoxifying enzymes that an ingested SVOC would experience in the stomach, intestines, and liver before it enters the blood. © 2012 John Wiley & Sons A/S.