Toxicity of volatile organic compounds (VOCs) mixtures using human derived cells (original) (raw)
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A novel in vitro exposure technique for toxicity testing of selected volatile organic compounds
Journal of Environmental Monitoring, 2006
Exposure to vapours of volatile chemicals is a major occupational and environmental health concern. Toxicity testing of volatile organic compounds (VOCs) has always faced significant technological problems due to their high volatility and/or low solubility. The aim of this study was to develop a practical and reproducible in vitro exposure technique for toxicity testing of VOCs. Standard test atmospheres of xylene and toluene were generated in glass chambers using a static method. Human cells including: A549-lung derived cell lines, HepG2-liver derived cell lines and skin fibroblasts, were grown in porous membranes and exposed to various airborne concentrations of selected VOCs directly at the air/liquid interface for 1 h at 37 °C. Cytotoxicity of test chemicals was investigated using the MTS (3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2H-tetrazolium) and NRU (neutral red uptake) assays following 24 h incubation. Airborne IC 50 (50% inhibitory concentration) values were determined using dose response curves for xylene (IC 50 = 5350 ± 328 ppm, NRU; IC 50 = 5750 ± 433 ppm, MTS in skin fibroblast) and toluene (IC 50 = 10500 ± 527 ppm, NRU; IC 50 = 11200 ± 1044 ppm, MTS in skin fibroblast). Our findings suggest that static direct exposure at the air/liquid interface is a practical and reproducible technique for toxicity testing of VOCs. Further, this technique can be used for inhalational and dermal toxicity studies of volatile chemicals in vitro as the exposure pattern in vivo is closely simulated by this method.
Cellular reactions to long-term volatile organic compound (VOC) exposures
Scientific Reports, 2016
Investigations of cellular processes initiated by volatile organic compounds (VOCs) are limited when modelling realistic long-term exposure scenarios at low concentrations. Exposure to indoor VOCs is associated with a range of adverse effects, but data on molecular changes at regulatory threshold limits are lacking. Activity analysis of VOC in vitro can be a valuable complement to inhalation toxicological evaluations. We developed an exposure platform that generates a stable VOC atmosphere and allows the exposure of cells for longer periods. Using formaldehyde as a model analyte, air-liquid interface cultured A549 lung epithelial cells were exposed to critical concentrations of 0.1 and 0.5 ppm for 3 days. Owing to the lack of known exposure biomarkers, we applied a genome-wide transcriptional analysis to investigate cellular responses at these sublethal concentrations. We demonstrate a minor overlap of differentially expressed transcripts for both treatment concentrations, which can...
Chemical research in toxicology, 2014
A recently developed hanging drop air exposure system for toxicity studies of volatile chemicals was applied to evaluate the cell viability of lung carcinoma A549 cells after 1 and 24 h of exposure to benzene, toluene, ethylbenzene, and xylenes (BTEX) as individual compounds and as mixtures of four or six components. The cellular chemical concentrations causing 50% reduction of cell viability (EC50) were calculated using a mass balance model and came to 17, 12, 11, 9, 4, and 4 mmol/kg cell dry weight for benzene, toluene, ethylbenzene, m-xylene, o-xylene, and p-xylene, respectively, after 1 h of exposure. The EC50 decreased by a factor of 4 after 24 h of exposure. All mixture effects were best described by the mixture toxicity model of concentration addition, which is valid for chemicals with the same mode of action. Good agreement with the model predictions was found for benzene, toluene, ethylbenzene, and m-xylene at four different representative fixed concentration ratios after 1...
Inhalation toxicology, 2018
A cell culture exposure system (CCES) was developed to expose cells established at an air-liquid interface (ALI) to volatile chemicals. We characterized the CCES by exposing indigo dye-impregnated filter inserts inside culture wells to 125 ppb ozone (O) for 1 h at flow rates of 5 and 25 mL/min/well; the reaction of O with an indigo dye produces a fluorescent product. A 5-fold increase in fluorescence at 25 mL/min/well versus 5 mL/min/well was observed, suggesting higher flows were more effective. We then exposed primary human bronchial epithelial cells (HBECs) to 0.3 ppm acrolein for 2 h at 3, 5, and 25 mL/min/well and compared our results against well-established in vitro exposure chambers at the U.S. EPA's Human Studies Facility (HSF Chambers). We measured transcript changes of heme oxygenase-1 (HMOX1) and interleukin-8 (IL-8), as well as lactate dehydrogenase (LDH) release, at 0, 1, and 24 h post-exposure. Comparing responses from HSF Chambers to the CCES, differences were on...
Review: Endogenously Produced Volatiles forIn VitroToxicity Testing Using Cell Lines
Applied In Vitro Toxicology, 2018
Due to the *86,000 chemicals registered under the Toxic Substances Control Act and increasing ethical concerns regarding animal testing, it is not economically or technically feasible to screen every registered chemical for toxicity using animal-based toxicity assays. To address this challenge, regulatory agencies are investigating high-throughput screening in vitro methods to increase speed of toxicity testing, while reducing the overall cost. One approach for rapid toxicity testing currently being investigated is monitoring of volatile emissions produced by cell lines in culture. Such a metabolomics approach would measure gaseous emissions from a cell line and determine if such gaseous metabolites are altered upon exposure to a xenobiotic. Herein, we describe the history and rationale of monitoring endogenously produced volatiles for identification of pathologic conditions, as well as emerging applications in toxicity testing for such an approach.
Approaches for assessing health risks from complex mixtures in indoor air: a panel overview
Environmental Health Perspectives, 1991
Critical to a more definitive human health assessment ofthe potential health risks from exposure to complex mixtures in indoor air is the need for a more definitive clinical measure and etiology ofthe helath effects ofcomplex mixtures. This panel overview highlights six of the eight presentations of the conference panel discussion and features a number of the major topical areas of indoor air concern. W. G. Meggs assessed clinical research priorities with primary focus on the role of volatile organic chemicals in human health, recognizing the areas where definitive data are lacking. By recognizing many types of chemical sensitivity, it may be possible to design studies that can illuminate the mechanisms by which chemical exposure may cause disease. The critically important topic of multiple chemical sensitivity was discussed by N. A. Ashford, who identified four high risk groups and defined the demographics of these groups. P. A. Schulte addressed the issue of biological markers of susceptibility with specific considerations of both m ethodologia and societal aspects that may be operative in the ability to detect innate or inborne differences between individuals and populations. Three case studies were reviewed. H. Anderson discussed the past and present priorities from a public health perspective, focusing on those issues dealing with exposures to environmental tobacco smoke and formaldehyde off-gassing from materials used in mobile home construction. J. J. Osborne described several case studies involving wood smoke exposure to children, with emphasis on the significantly greater occurrence ofchronic respiratory symptoms and acute chest illness for children from homes heated with woodburning stoves. D. W. Sepkovic focused on the use of a specific nicotine metabolite, cotinine, as a biomarker ofenvironmental tobacco smoke uptake in controlled studies.
An efficient approach to study the toxicological effects of complex mixtures
Experimental and Toxicologic Pathology, 2008
In vitro studies in the field of inhalation toxicology suffer a number of problems due to the difficulties in exposing cells of the respiratory tract directly to inhalable substances in a way that is comparable to the in vivo situation. The most promising approach is based on a biphasic cell culture technique, where cells are grown on microporous membranes at an air-liquid interface. In this way, the cells can be nutrified from the basal side of the membrane whereas the apical part with the cultivated cells is in direct contact with the test atmosphere, meaning gaseous and/or particulate compounds. This type of exposure requires (1) a special exposure device and conditions, (2) a close contact between the cultivated cells and the inhalable substances without the interference of medium as well as (3) precise control of the pollutant levels. Exposure of cells under these conditions results in dose-dependent reactions with regard to cyto-and genotoxicity or cell activation associated, for example, with the release of bioactive mediators. Such an experimental approach is not only suitable for cultivated cells, but it can also be used in a modified Ames assay for the detection of mutagenicity by exposing bacteria to gaseous compounds or complex mixtures. This is not only true under laboratory conditions but can also be achieved under real indoor situations.
Archives of Toxicology, 1996
The objective of the present study was to compare the influence of various binary mixtures containing ethylbenzene (EBZ), toluene (TOL) or xylene (XYL) administered by inhalation, with the influence exerted by a ternary mixture, on the kinetics of these solvents in blood. Groups of four rats were exposed for 4 h to TOL, XYL and EBZ, singly or in combination. The concentration of TOL, XYL and EBZ in blood was measured at various times (5, 30, 60, 90 and 120 min) following the end of exposure and the areas under the blood concentration curves (AUC) were calculated. Results showed that exposures to binary and ternary mixtures resulted in significantly higher (P(0.05) blood concentrations of unchanged solvents as a result of metabolic interaction between these solvents. When the comparison was based on individual solvents, there was no difference between effect exerted by the ternary mixture and the binary mixtures, except for one. However, a comparison based on the total concentration of unchanged solvents disclosed that exposure to the ternary mixture resulted in greater interactive effects (3.17-fold increase) than exposures to binary mixtures (1.97-fold increase), whereas four out of six binary mixtures produced higher total levels of unchanged solvents in blood compared to the ternary mixture. This study shows that the greater risk of toxicity often thought to be associated with exposures to complex mixtures should not only be related to the magnitude of interactive effects among components (i.e., degree of mutual metabolic interaction) resulting from combined exposures, but also should take into account, as is universally recognized, the internal total dose of toxic chemicals in target organs/tissues.
Journal of Chromatography B, 2015
Humans are continuously exposed to volatile organic compounds (VOCs) as these chemicals are ubiquitously present in most indoor and outdoor environments. In order to assess recent exposure to VOCs for population-based studies, VOCs are measured in the blood of participants. This work describes an improved method to detect 12 VOCs by head-space solid-phase microextraction gas chromatography coupled with isotope-dilution mass spectrometry in selected reaction monitoring mode (SPME-GC-MS/MS). This method was applied to the analysis of trihalomethanes, styrene, trichloroethylene, tetrachloroethylene and BTEX (benzene, toluene, ethylbenzene, m-xylene, p-xylene, o-xylene) in a population-based biomonitoring study (Canadian Health Measures Survey). The method showed good linearity (>0.990) in the range of 0.010-10 g/L and detection limits between 0.007 and 0.027 g/L, precision better than 25% and good accuracy (±25%) based on proficiency testing materials. Quality Control data among runs over a 7 month period showed %RSD between 14 and 25% at low levels (∼0.03 g/L) and between 9 and 23% at high levels (∼0.4 g/L). The method was modified to analyze samples from a pharmacokinetic study in which 5 healthy volunteers were exposed to single, binary and quaternary mixtures of CTEX (chloroform, ethylbenzene, toluene and m-xylene), thus the expected concentration in blood was 1 order of magnitude higher than those found in the general population. The method was modified by reducing the sample size (from 3 g to 0.5 g) and increasing the upper limit of the concentration range to 395 g/L. Good linearity was found in the range of 0.13-395 g/L for toluene and ethylbenzene and 0.20-609 g/L for m/p-xylene. Quality control data among runs over the period of the study (n = 13) were found to vary between 7 and 25%.
Biological monitoring for exposure to volatile organic compounds (VOCs) (IUPAC Recommendations 2000
Pure and Applied Chemistry, 2000
Republication or reproduction of this report or its storage and/or dissemination by electronic means is permitted without the need for formal IUPAC permission on condition that an acknowledgment, with full reference to the source, along with use of the copyright symbol ©, the name IUPAC, and the year of publication, are prominently visible. Publication of a translation into another language is subject to the additional condition of prior approval from the relevant IUPAC National Adhering Organization.