The effects of perchlorate on thyroidal gene expression are different from the effects of iodide deficiency.

Perchlorate (ClO4⁻), which is a ubiquitous and persistent ion, competitively interferes with iodide (I) accumulation in the thyroid, producing I deficiency (ID), which may result in reduced thyroid hormone synthesis and secretion. Human studies suggest that ClO4⁻ presents little risk in healthy individuals; however, the precautionary principle demands that the sensitive populations of ID adults and mothers require extra consideration. In an attempt to determine whether the effects on gene expression were similar, the thyroidal effects of ClO4⁻ (10 mg/kg) treatment for 14 d in drinking water were compared with those produced by 8 wk of ID in rats. The thyroids were collected (n = 3 each group) and total mRNA was analyzed using the Affymetrix Rat Genome 230 2.0 GeneChip. Changes in gene expression were compared with appropriate control groups. The twofold gene changes due to ID were compared with alterations due to ClO4⁻ treatment. One hundred and eighty-nine transcripts were changed by the ID diet and 722 transcripts were altered by the ClO4⁻ treatment. Thirty-four percent of the transcripts changed by the I-deficient diet were also altered by ClO4⁻ and generally in the same direction. Three specific transporter genes, AQP1, NIS, and SLC22A3, were changed by both treatments, indicating that the membrane-specific changes were similar. Iodide deficiency primarily produced alterations in retinol and calcium signaling pathways and ClO4⁻ primarily produced changes related to the accumulation of extracellular matrix proteins. This study provides evidence that ClO4⁻, at least at this dose level, changes more genes and alters different genes compared to ID.

A review of transcriptomics in cutaneous chemical exposure.

Monitoring gene expression profiles in the skin using microarrays has become a useful approach to enhance the understanding of dermal function, toxicologic mechanisms, and risk assessment. With respect to cutaneous chemical exposure, there are few transcriptomic studies in the published literature, and these often differ in experimental design and availability of raw data. An assessment of multiple microarray data sets could be advantageous for identifying potential redundant biological mechanisms or genes associated with dermal responses to chemical exposure. As in vivo cutaneous chemical exposure models can vary, extrapolations from analyzing multiple cross-species microarray data sets could aid in identifying a general set of pathways or genes that could guide future study direction and evaluation of dermal toxicologic assessments and potential therapeutic intervention. This review provides a summary of studies in the open literature that utilize transcriptomics in assessing the molecular responses in chemical-exposed skin with an intent of determining whether biomarkers could be identified and the potential for future meta-analyses.

Transcriptional changes in porcine skin at 7 days following sulfur mustard and thermal burn injury.

Severe cutaneous injuries continue to result from exposure to sulfur mustard [bis(2-chloroethyl)sulfide; HD] and thermal burns. Microarray analysis was utilized in this study to evaluate transcriptional changes in porcine skin assessing the underlying repair mechanisms of HD and thermal injury involved in wound healing. Four ventral abdominal sites on each of 4 weanling swine were exposed to 400 microL undiluted HD or a heated brass rod (70 degrees C) for 8 minutes and 45-60 seconds, respectively. At 7 days postexposure, skin samples were excised and total RNA was isolated, labeled, and hybridized to Affymetrix GeneChip (Santa Clara, CA, USA) Porcine Genome Arrays (containing 20,201 genes). Based on the gene expression patterns in HD- and thermal-exposed skin at 7 days, the transcriptional profiles do not differ greatly. HD and thermal exposures promoted similar changes in transcription, where 270 and 283 transcripts were increased with HD and thermal exposures, respectively. Both exposures promoted decreases in 317 and 414 transcripts, respectively. Of the significantly increased transcripts, at least 77% were commonly expressed in both HD- and thermal-exposed skin, whereas at least 67% of decreased transcripts were common between both exposure types. Six of the top 10 biological functions were common to HD and thermal injury in which 9 canonical pathways were shared. The present study illustrates the similarities found between HD and thermal injury with respect to transcriptional response and wound healing and identifies specific genes (CXCL2, CXCR4, FGFR2, HMOX1, IGF1, PF4, PLAU, PLAUR, S100A8, SPP1, and TNC) that may be useful as potential therapeutic targets to promote improved wound healing.

Transcriptional responses associated with sulfur mustard and thermal burns in porcine skin.

In military and civilian environments, serious cutaneous damage can result from thermal burns or exposure to the blistering agent sulfur mustard [bis (2-chloroethyl) sulfide; HD]. Similar therapies have historically been used to treat cutaneous thermal and HD injuries; however, the underlying molecular mechanisms of tissue damage and wound healing may differ between the types of burns. Using microarray analysis, this study assessed the transcriptional responses to cutaneous HD and thermal injury at 48 hours post-exposure to identify molecular networks and genes associated with each type of skin injury. Ventral abdominal sites on each of 4 weanling swine were exposed to 400 mul of undiluted HD or a heated brass rod (70 degrees C) for 8 minutes and 45-60 seconds, respectively. At 48 hours post-exposure, total RNA was isolated from excised skin samples and hybridized to Affymetrix GeneChip Porcine Genome Arrays (containing 20,201 genes). Both HD and thermal exposure promoted significant transcriptional changes where 290 and 267 transcripts were increased and 197 and 707 transcripts were decreased with HD and thermal exposure, respectively. HD- and thermal-injured skin expressed 149 increased and 148 decreased common transcripts. Comparison of the 10 most significantly changed biological functions for HD and thermal exposures identified 7 overlapping functional groups. Canonical pathways analysis revealed 15 separate signaling pathways containing transcripts associated with both HD and thermal exposure. Within these pathways, 5 transcripts (CXCR4, FGFR2, HMOX1, IL1R1, and TLR4) were identified as known targets for existing phase II/III clinical trial or Food and Drug Administration (FDA)-approved drugs. This study is the first to directly assess transcriptional changes in porcine skin subjected to HD or thermal injury over the same time period.

Gene expression analysis of bromine-induced burns in porcine skin.

Bromine is an industrial chemical that is irritating to the skin and causes cutaneous burns. An important factor in selecting or developing an effective treatment is to understand the underlying molecular mechanisms of tissue damage and wound healing. This study used a weanling swine burn model and microarray analysis to evaluate the effect of exposure length and sampling times on the transcriptional changes in response to cutaneous bromine injury. Ventral abdominal sites (N=4/treatment group) were exposed to 600microL undiluted bromine for 45 s or 8 min. At 24 h and 7d post-exposure, total RNA from skin samples was isolated, processed, and hybridized to Affymetrix GeneChip Porcine Genome Arrays. Expression analysis revealed that bromine exposure duration appeared to have less effect on the transcript changes than the sampling time. The percent transcripts changed at 24h were similar (30%) whether having a 45 s or 8 min bromine exposure; percent transcripts changed at 7d were also similar (62%) regardless of exposure length. However, only 13-14% of the transcripts were similar when comparing samples analyzed at 24h and 7d. Ingenuity Pathways Analysis (IPA) revealed six common biological functions among the top 10 functions of each experimental group, while canonical pathway analysis revealed 11 genes that were commonly shared among 24 significantly altered signaling pathways. Additionally, there were 11 signaling pathways in which there were no commonly shared transcripts. The present study is an initial assessment of the transcriptional responses to cutaneous bromine exposure identifying molecular networks and genes that could serve as targets for developing therapeutics for bromine-induced skin injury.

In vitro dermal absorption rate testing of certain chemicals of interest to the Occupational Safety and Health Administration: summary and evaluation of USEPA's mandated testing.

In 2004, the United States Environmental Protection Agency (USEPA) published a final test rule in the US Federal Register requiring in vitro dermal penetration rate testing for selected industrial chemicals. The test rule described procedures for determining a permeability coefficient (Kp) and two short-term dermal absorption rates at 10 and 60min using human cadaver skin mounted in an in vitro diffusion cell model. According to the USEPA announcement, the selected chemicals were to be spiked with their radiolabeled form and tested in either water, isopropyl myristate (IPM) or neat depending on their physical character at room temperature, their aqueous solubility, their potential to damage the skin and their ability to achieve the study endpoints as prescribed. Overall, and for the majority of chemicals, the short-term absorption rates were higher at 10min than at 60min and the portion of applied dose remaining in the skin at the end of the exposure period was greater than the portion of dose that had penetrated through the skin and was detected in the receptor solution. In contrast to this, the amount of chemical in the receptor solution at study termination for the Kp (steady-state) experiments was greater than the amount remaining in the skin. For the Kp experiments, which lasted from 2 to 48h, a majority of skins exposed to neat chemical exhibited a reduced barrier function. However, integrity was mostly unaltered for skins from the short-term experiments and Kp experiments using chemicals applied either in water or IPM. Quantitative structure activity relationship (QSAR) model-predicted Kp values were in fair agreement with experimental data for those chemicals that were applied in a water vehicle when the integrity of the skin was not compromised. However, QSAR-derived Kp values were not predictive for those chemicals when applied in IPM vehicle or neat. Absorption predictions, based on the measured Kp and steady-state flux data for chemicals applied in water or neat, respectively, were comparable to measured values at both 10 and 60min. Kp data for chemicals applied in water and the flux values for neat chemicals will be useful for making estimates of skin absorption in occupational settings. Kp measurements for chemicals applied in IPM vehicle are not envisioned to provide useful data for estimating the risk from dermal exposure to chemicals in the workplace. When available, in vitro dermal flux measurements should be combined with toxicity information in order to improve the utility of chemical skin notations.

Skin penetration and lag times of neat and aqueous diethyl phthalate, 1,2-dichloroethane and naphthalene.

Cutaneous exposures to occupational chemicals may cause toxic effects. For any chemical, the potential for systemic toxicity from dermal exposure depends on its ability to penetrate the skin. Most laboratory studies measure chemical penetration from an aqueous solution through isolated human or laboratory animal skin, although most exposures are not from pure aqueous solutions. The US EPA Interagency Testing Committee (ITC) mandated by the Toxic Substances Control Act, has required industry to measure the in vitro penetration of 34 chemicals in their pure or neat form (if liquid). The goal of the present study was to measure skin permeability and lag time for three neat chemicals of industrial importance, representing the general types of chemicals to be studied by the ITC (non-volatile liquids, volatile liquids, and solids), and to examine interlaboratory variation from these studies. Steady state fluxes and lag times of diethyl phthalate (DEP, slightly volatile), 1,2-dichloroethane (DCE, highly volatile), and naphthalene (NAP, solid) were studied in two different laboratories using different analytical methods. One lab also measured fluxes and lag times from saturated aqueous vehicle. Static diffusion cells, dermatomed hairless guinea pig skin, and gas chromatography were used to measure skin penetration. In the two laboratories, the steady state fluxes (mean+/-SD; microg cm(-2)hour(-1)) of DEP applied neat were: 11.8+/-4.1 and 23.9+/-7.0; fluxes of DCE (neat) were 6280+/-1380 and 3842+/-712; fluxes of NAP from powder were 30.4+/-2.0 and 7.5+/-4.7. Compared with neat fluxes measured in the same laboratory, flux from saturated aqueous solution was higher with DEP (1.9 x) but lower with DCE (0.17 x) and NAP (0.45 x). The three chemicals studied including a dry powder, demonstrate the potential for significant dermal penetration.

Gene expression and target tissue dose in the rat epidermis after brief JP-8 and JP-8 aromatic and aliphatic component exposures.

Exposures of jet propulsion fuel 8 (JP-8) to human and laboratory animal skin have resulted in skin irritation. JP-8 is a mixture of aromatic and aliphatic hydrocarbons, which in some cases have also been shown to be irritating to the skin. In an attempt to determine if aromatic or aliphatic components could mimic the JP-8-induced gene expression response, we exposed rats to JP-8, undecane (UND), tetradecane (TET), trimethylbenzene (TMB), and dimethylnaphthalene (DMN) for 1 h and examined the epidermis to characterize the gene expression response. We also measured the concentrations of the JP-8 components in the epidermis with gas chromatography/mass spectrometry after 1-h exposures to JP-8 and pure components to determine if differences in potency could be identified. Changes in gene expression, compared to sham treatment, were studied with microarray techniques and analyzed for changes in gene ontology categories. UND and TMB exposures caused the greatest number of changes in transcript levels compared to DMN and TET. When only the specific functional and signaling pathways that were changed by JP-8 were considered, these pathways were nearly all activated by the components, but to different extents. After pure component exposures, the epidermal concentrations of the components showed no significant differences, although the differences in magnitude of either total or pathway-specific gene expression differed by a factor of 10-fold. We conclude that no single component that we studied mimicked the gene expression resulting from the JP-8 exposure but that UND had the most similar responses. These data suggest that there are differences in potency between the four components studied.

Effects of brief cutaneous JP-8 jet fuel exposures on time course of gene expression in the epidermis.

The jet fuel jet propulsion fuel 8 (JP-8) has been shown to cause an inflammatory response in the skin, which is characterized histologically by erythema, edema, and hyperplasia. Studies in laboratory animal skin and cultured keratinocytes have identified a variety of changes in protein levels related to inflammation, oxidative damage, apoptosis, and cellular growth. Most of these studies have focused on prolonged exposures and subsequent effects. In an attempt to understand the earliest responses of the skin to JP-8, we have investigated changes in gene expression in the epidermis for up to 8 h after a 1-h cutaneous exposure in rats. After exposure, we separated the epidermis from the rest of the skin with a cryotome and isolated total mRNA. Gene expression was studied with microarray techniques, and changes from sham treatments were analyzed and characterized. We found consistent twofold increases in gene expression of 27 transcripts at 1, 4, and 8 h after the beginning of the 1-h exposure that were related primarily to structural proteins, cell signaling, inflammatory mediators, growth factors, and enzymes. Analysis of pathways changed showed that several signaling pathways were increased at 1 h and that the most significant changes at 8 h were in metabolic pathways, many of which were downregulated. These results confirm and expand many of the previous molecular studies with JP-8. Based on the 1-h changes in gene expression, we hypothesize that the trigger of the JP-8-induced, epidermal stress response is a physical disruption of osmotic, oxidative, and membrane stability which activates gene expression in the signaling pathways and results in the inflammatory, apoptotic, and growth responses that have been previously identified.

Characterization of the skin penetration of a hydrocarbon-based weapons maintenance oil.

Break-Free CLP is a commercial petroleum-based liquid used for cleaning, lubricating, and protecting firearms that is used in the United States by military personnel, police, and individual gun owners for maintaining a wide variety of firearms. According to its material safety data sheet (MSDS), Break-Free CLP is predominately polyalphaolefin oil but also contains dibasic ester and isoparaffinic hydrocarbons; all of these ingredients are known to induce skin irritation in laboratory animals. Studies completed in our labs found that repeated topical application of Break-Free CLP to the backs of CD-1 mice produced evidence of systemic effects. Studies were conducted to characterize the dermal penetration of Break-Free CLP in mouse, rat, and pig skin to provide insight on possible factors or causes of skin irritation and systemic effects observed in previous studies. Mouse skin was 37 times more permeable to Break-Free CLP than pig skin and 6 times more permeable than rat skin. Flux measurements from static diffusion cells showed an inverse correlation with mouse, rat, and pig skin thickness. The concentration of Break-Free CLP in mouse skin was 4.5 times higher than the amount found in rat skin and about 17 times higher than the amount absorbed by pig skin. These results support the idea that Break-Free CLP causes skin irritation and systemic effects in the mouse by both penetrating through and accumulating in the skin. The findings for rat and pig skin are probably most representative of Break-Free CLP flux into and through unprotected human skin and suggest that dermal toxicity studies in CD-1 mice overestimate the risk to humans. These results, nevertheless, suggest that persons handling or using Break-Free CLP should protect the skin from possible exposure.

Local and systemic toxicity of JP-8 from cutaneous exposures.

Jet propellant-8 (JP-8) jet fuel is a version of commercial jet fuel, Jet A, and is a complex mixture of primarily aliphatic (but also aromatic) hydrocarbons that varies in composition from batch to batch. There is potential for dermal exposure to jet fuels with personnel involved in aircraft refueling and maintenance operations as well as ground personnel. Cutaneous exposures have the potential to cause skin irritation, sensitization or skin cancer. JP-8 has been shown to be irritating and causes molecular changes in the skin of laboratory animals. The mechanisms of some of these effects have been investigated in intact skin and cultured skin cells. Hydrocarbons have also been shown to cause skin cancer with repeated application to the skin. Additionally, there is concern about systemic toxicity from dermal exposures to jet fuels, such as JP-8. Assessing risks from systemic absorption of hydrocarbon components is complex because most of the components are present in the mixture in small quantities (less than 1%). The effect of the fuel as a vehicle, different rates of penetration through the skin and different target organ toxicities all complicate the assessment of the hazards of cutaneous exposures. The purpose of this manuscript is to review studies of local and systemic toxicity of JP-8.

The cytotoxicity of volatile JP-8 jet fuel components in keratinocytes.

In vitro models are being used to evaluate the toxic and irritating effects of JP-8, a kerosene-based jet fuel. JP-8 components are volatile, which makes in vitro studies difficult to evaluate dose-response relationships due to changes in chemical dosimetry caused by evaporation from the exposure medium. An in vitro approach testing volatile chemical toxicity that we have recently developed was used to evaluate the toxicity of the JP-8 components m-xylene, 1-methylnaphthalene (1-MN), and n-nonane in keratinocytes. Partition coefficients were measured and used to estimate the chemical concentration in the keratinocytes. The EC50 for m-xylene and 1-MN decreased significantly (P < or = 0.05) at 1, 2, and 4h. For n-nonane, no significant decreases in the EC50 values were observed over time; marginal cytotoxicity of n-nonane in keratinocytes was observed at 1h. Within 4h, about 75-90% of each volatile chemical was observed to be lost from the exposure medium when tissues were exposed in unsealed 24-well plates. This decrease resulted in significantly higher medium chemical concentrations needed to obtain EC50 values when compared to tissues exposed in sealed vials. This study demonstrates that chemical evaporation during in vitro exposures can significantly affect toxicological endpoint measurements. Ultimately, relating target cell chemical concentration to cellular responses in vitro could be used in determining an equivalent external dose using a biologically-based mathematical model.

Gene expression in rat skin induced by irritating chemicals.

Occupational skin disease is the second most significant cause of occupational disease, after accidents. Irritation from occupational chemicals such as solvents, hydrocarbons, and surfactants are one cause of this disease. Gene expression studies provide useful information about normal processes in the skin and responses of the skin to exogenous chemicals. We exposed rats, cutaneously, to sodium lauryl sulfate (SLS, 1% and 10% aqueous solution), m-xylene (pure liquid), and d-limonene (pure liquid) for 1 h and measured transcriptional responses at the end of the exposure and 3 h later for comparison with untreated skin samples. Total skin RNA was isolated and analyzed using the Affymetrix RatTox U34 array. Using the Affymetrix software, we found that 234 of approximately 850 genes were detected as present in at least 80% of the normal skin samples. The largest number of these genes was related to metabolism, oxidative/cellular stress, and signal transduction. Limonene caused the largest change in mRNA levels with a total of 34 increased transcripts and 4 decreased transcripts. Xylene treatment resulted in 6 increased transcripts and 14 decreased transcripts, while 10% SLS caused 5 transcripts to increase and 17 to decrease. Only two transcripts were observed to change in skin following a 1% SLS exposure. Sodium lauryl sulfate transcript changes increased with dose and were maximum at 4 h. Limonene transcript changes were more numerous at 1 h than at 4 h. The observed differences may reflect different mechanisms of irritation.

The effect of m-xylene on cytotoxicity and cellular antioxidant status in rat dermal equivalents.

Exposure of the skin to volatile organic chemicals (VOCs) can lead to irritation, inflammation and cytotoxicity. Since VOCs are used in industrial, commercial and military applications, concern is mounting with respect to VOC safe exposure limits. Although traditional toxicological assessment of VOCs has utilized animal models, the use of alternative in vitro models is becoming more widespread. We have previously developed a sealed exposure system that prevents chemical loss through evaporation and enables calculation of target cell chemical dose. The present study utilized this in vitro exposure method to assess m-xylene-induced cytotoxicity and antioxidant status in dermal equivalents (dermal fibroblasts in a collagen matrix). At the end of a 1- or 4-h exposure, cytotoxicity was measured using the MTT assay and the EC50 values determined were 1481 +/- 88 and 930 +/- 33, respectively. Decreases in cellular thiols and catalase activity were observed, which occurred in a time and dose-dependent manner. Treatment of dermal equivalents with the antioxidants N-acetylcysteine (NAC) and catalase provided some protection against m-xylene-induced cytotoxicity. When compared to m-xylene exposures, treatment with either 1.0 or 5.0 mM NAC led to increases in the EC50 values at 1 and 4 h. Increases in these EC50 values ranged from 1.22- to 1.32-fold at 1 h and 1.27- to 1.54-fold at 4 h. Although treatment with catalase (1000 U/ml) led to a 1.35-fold increase in cell viability at 1 h, no significant differences were observed at either 1 or 4 h when compared to dermal equivalents exposed to m-xylene alone. These results suggest that exposure to m-xylene leads to a time- and dose-dependent decrease in cellular antioxidants and that cellular thiols may provide protection against the cytotoxic properties of m-xylene.

Molecular and histological responses in rat skin exposed to m-xylene.

Solvents, surfactants, cutting fluids, hydrocarbons, and oils cause skin irritation by incompletely understood mechanisms. This study examined histological and molecular changes in rodent skin caused by brief topical exposures to m-xylene. At 0, 1, 2, 4, and 6 h after 1-h exposure, skin samples were removed and analyzed for histopathological changes and interleukin-1 alpha (IL-1 alpha) and inducible nitric oxide synthase (iNOS) protein levels. Histopathological changes (epidermal-dermal separation and granulocyte infiltration) and increases in IL-1 alpha and iNOS protein expression occurred during our observation period. IL-1 alpha levels increased by 80% immediately after exposure and iNOS levels increased about 60% 4 hours after exposure. Our study demonstrates that dermal exposure to m-xylene promotes IL-1 alpha and iNOS production in skin and these proteins may serve as early indicators of skin irritation.

Improved method for in vitro assessment of dermal toxicity for volatile organic chemicals.

Cell culture methods are being developed to assess the dermal toxicity (irritancy and corrosion) of chemicals. These in vitro methods are being validated to categorize chemicals as irritating or non-irritating to humans. Currently, these cell culture tests are useful to assist in the ranking of chemicals for irritancy, but they are not useful for quantitative risk assessment for two reasons. First, for volatile chemicals the amount of chemical in the media that the cells are exposed to may decrease with exposure time. Also, effective concentrations such as EC(50) and IC(50) are reported as the concentrations in the media not the skin tissue/cells. We have developed an in vitro approach for dermal toxicity testing of volatile chemicals that avoids these problems. Using sealed vials lacking a headspace, dermal equivalents (dermal fibroblasts in a collagen matrix) were exposed to culture medium containing a test chemical (m-xylene) and compared to a traditional open well culture system. We found that about 90% of the m-xylene was lost from the open well plates and the viability was 4-6 times greater than in the closed system. Partition coefficients were measured and used to estimate the m-xylene concentration in the fibroblasts. The EC(50) for m-xylene in the dermal equivalents was 833.13+/-35.33 microg m-xylene per gram of fibroblasts. This method will provide an effective approach to relate target cell chemical concentration to cellular responses. Based on this method, a biologically-based mathematical model could be used to determine an equivalent external dose for a specific toxic end point.

Methods for assessing risks of dermal exposures in the workplace.

The skin as a route of entry for toxic chemicals has caused increasing concern over the last decade. The assessment of systemic hazards from dermal exposures has evolved over time, often limited by the amount of experimental data available. The result is that there are many methods being used to assess safety of chemicals in the workplace. The process of assessing hazards of skin contact includes estimating the amount of substance that may end up on the skin and estimating the amount that might reach internal organs. Most times, toxicology studies by the dermal route are not available and extrapolations from other exposure routes are necessary. The hazards of particular chemicals can be expressed as "skin notations", actual exposure levels, or safe exposure times. Characterizing the risk of a specific procedure in the workplace involves determining the ratio of exposure standards to an expected exposure. The purpose of this review is to address each of the steps in the process and describe the assumptions that are part of the process. Methods are compared by describing their strengths and weaknesses. Recommendations for research in this area are also included.

Skin absorption and human risk assessment.

A common practice is to assume that percutaneous absorption does not significantly contribute to total bioavailability and therefore, absorption through other routes is more important to human risk assessment. The skin can represent a significant barrier to absorption, but some substances are absorbed to a significant extent. Since there is a potential for percutaneous penetration that is not consistent between species or substances, the assessment of the potential contribution of total body burden from dermal exposures should be considered. This review briefly discusses some theories, practices, and factors that affect percutaneous absorption with an emphasis on how percutaneous absorption evaluations apply to human risk assessment.

Assessment of dermal absorption and penetration of components of a fuel mixture (JP-8).

Occupational and environmental multi-chemical exposures are extremely common. Methods for assessment of the risks from dermal exposures to complex mixtures vary depending on the information available. The composition of a volatile mixture (such as JP-8 jet fuel) can change radically, depending on the phase of the mixture - vapor, liquid or aerosol. Assessing the absorption (into the skin) and penetration (through the skin) of components of the mixture can reduce uncertainty in the risk assessment process. Permeability coefficients of the 12 individual components that could be detected to penetrate the skin could be used to assess the toxicity of each individual component in the JP-8. The penetration of each of these components is related to and can be predicted from molecular weight and octanol water partition coefficients of that component. The composition of the components that penetrate the skin would be different from the composition of JP-8 because the permeability of the components differs by two orders of magnitude. Concentrations of the aliphatic chemicals found in the skin correlated well with carbon number. The JP-8 jet fuel is used as an example of how component data on absorption and penetration can be integrated into an assessment (McDougal et al., Toxicol Sci 2000; 55: 247-255). The component approach shows promise for estimating systemic toxicity of mixtures. Local toxicity (irritation, sensitization, etc.) may be better understood in the future when quantitative information becomes available about the duration and magnitude of chemical exposures required to cause local effects.