A ready-to-use integrated in vitro skin corrosion and irritation testing strategy using EpiSkin™ model in China.

The need of in vitro alternative methods has been increasing in toxicology research as well as in cosmetic industry in China recently. Following the establishment of China EpiSkin™ skin corrosion and irritation testing methods, both as stand-alone in vitro tests according to Organization for Economic Co-operation and Development (OECD) TG 431 and TG 439, the present study aims to evaluate the use of these two methods within the Integrated Approach on Testing and Assessment (IATA). The IATA, adopted by OECD as Guidance Document 203, provides guidance on the integration of existing and new data in a modular approach for classification and labelling of chemicals according to Globally Harmonized System of classification and labeling of chemicals (GHS) issued by the United Nations (UN). By applying bottom-up and top-down integrated testing strategies to a set of 60 chemicals representing various chemicals classes (organic acid/base/neutral, inorganic acid/base/salt, and surfactant) and physical states (liquid and solid), the results demonstrated that both strategies reached a high overall accuracy of 83.3% to distinguish non-classified, Category 2, Category 1B/1C and Category 1A according to UN GHS, identically. In conclusion, the integration of China EpiSkin™ skin corrosion and irritation testing data into either bottom-up or top-down strategy allows accurate assessment of potential skin hazard of chemicals. It brings a future extension of application of alternative methods and implementation of alternative testing strategies in China.

Dermo-epidermal organotypic cultures for in vitro evaluation of skin irritation and corrosion.

In recent years, in-vitro skin models for chemical hazard identification have been developed. Most of them consist only of human keratinocytes, neglecting the contribution of other skin constituents. Cultures containing the dermal and epidermal component provide an attractive system to investigate, in a more realistic model, toxicological responses, which represents a distinct advantage over keratinocytes-based models that do not mimic faithfully the in vivo environment. This study aimed to validate dermo-epidermal organotypic cultures (ORGs) as a platform to perform irritation and corrosion tests. Skin models were constructed by seeding keratinocytes on fibroblast-containing fibrin gels. After 21 days, the ORGs were evaluated histologically, and the irritant and corrosion potential was determined by means of viability measurements (MTT assay) and cytokine release, according to 431 and 439 OECD tests guidelines. Skin models showed similar histological characteristics to native skin and were able to classify different substances with high accuracy, showing their applicability to skin irritation and corrosion tests. Although cytokines release seems to be chemical-dependent, a tendency was observed, leading to the improvement of the prediction capacity. Nevertheless, further studies should be done to reduce variability in order to increase prediction capacity.

Differences in classification for skin corrosion/irritation in EU and Ukraine: Case study of alternative (in vitro and in silico) methods application for classification of pesticide active ingredient imazamox.

In Ukraine Globally Harmonized System of classification of chemicals has not been implemented yet. In this article we analyze differences between GHS/CLP classification systems and Hygienic Classification of Pesticides by the Degree of Hazard currently in force in Ukraine in respect of approach and criteria for classification of effects on skin. As a case study, we conducted in silico modelling of herbicide imazamox using skin irritation/corrosion modules of ToxTree. The prediction of ToxTree was "Not Corrosive to skin". Then skin irritation and skin corrosion in vitro tests (OECD TGs 439, 431) were conducted. Classification of this substance based on in vitro and in vivo results according to GHS/CLP was the same, while it was not possible based on in vitro results to assign certain hazard class of Ukrainian classification due to difference in its and GHS/CLP criteria. However, ongoing process of harmonization of Ukrainian legislation with EU will give opportunity not only use alternative methods, but also adopt most recent advances and incorporate data from non-animal methods directly into classification criteria.

Development of an in vitro corrosion/irritation prediction assay using the EpiDerm skin model.

A validation of the in vitro skin corrosion method using the EpiDerm skin model was performed using 12 recommended chemicals. All chemicals were correctly classified by OECD test guideline 431. In order to predict corrosion and/or irritation potential, additional compound exposure times and IL-1alpha measurements were included in a tiered testing approach. Four exposure times were performed followed by MTT (viability) and IL-1alpha measurement. This allowed classification of corrosive chemicals (OECD guideline 431) and those likely to be severe irritants. If the chemical was found to be corrosive or a severe irritant, no further experimental work was performed, otherwise a second experiment was performed using three further exposure times (same endpoints). The second experiment provided information on whether the chemical was likely to be a moderate/mild irritant. If the chemical was negative following both experiments, it was predicted as non-corrosive/non-irritating. A total of 12 chemicals were tested in the irritation or combined assay (five non-irritants, seven irritants). Specificity (% non-irritants concurring with EU classification) was 60% (MTT) and 100% (MTT+IL-1alpha). Sensitivity (% irritants concurring with EU classification) was 86% (MTT) and 86% (MTT+IL-1alpha). Accuracy (% chemicals correctly identified) was 75% (MTT) and 92% (MTT+IL-1alpha).

Evaluation of SARs for the prediction of eye irritation/corrosion potential: structural inclusion rules in the BfR decision support system.

The proposed REACH regulation within the European Union (EU) aims to minimise the number of laboratory animals used for human hazard and risk assessment while ensuring adequate protection of human health and the environment. One way to achieve this goal is to develop non-testing methods, such as (quantitative) structure-activity relationships ([Q]SARs), suitable for identifying toxicological hazard from chemical structure and physicochemical properties alone. A database containing data submitted within the EU New Chemicals Notification procedure was compiled by the German Bundesinstitut für Risikobewertung (BfR). On the basis of these data, the BfR built a decision support system (DSS) for the prediction of several toxicological endpoints. For the prediction of eye irritation and corrosion potential, the DSS contains 31 physicochemical exclusion rules evaluated previously by the European Chemicals Bureau (ECB), and 27 inclusion rules that define structural alerts potentially responsible for eye irritation and/or corrosion. This work summarises the results of a study carried out by the ECB to assess the performance of the BfR structural rulebase. The assessment included: (a) evaluation of the structural alerts by using the training set of 1341 substances with experimental data for eye irritation and corrosion; and (b) external validation by using an independent test set of 199 chemicals. Recommendations are made for the further development of the structural rules in order to increase the overall predictivity of the DSS.

Assessment of the human epidermis model SkinEthic RHE for in vitro skin corrosion testing of chemicals according to new OECD TG 431.

Based on two successfully completed ECVAM validation studies for in vitro skin corrosion testing of chemicals, the National Co-ordinators of OECD Test Guideline Programme endorsed in 2002 two new test guidelines: TG 430 'Transcutaneous Electrical Resistance assay' and TG 431 'Human Skin Model Test'. To allow all suitable in vitro human reconstructed (dermal or epidermal) models to be used for skin corrosion testing, the OECD TG 431 defines general and functional conditions that the model must meet before it will be routinely used for skin corrosion testing. In addition, the guideline requires correct prediction of 12 reference chemicals and assessment of intra- and inter-laboratory variability. To show that the OECD TG 431 concept works, in 2003 ZEBET tested several chemicals from the ECVAM validation trials on the SkinEthic reconstituted human epidermal (RHE) model. Based on knowledge that reconstructed human skin models perform similarly in toxicological studies, it was decided to adopt the validated EpiDerm skin corrosion test protocol and prediction model to the SkinEthic model. After minor technical changes, classifications were obtained in concordance with those reported for the validated human skin models EPISKIN and EpiDerm. To allow adequate determination of inter-laboratory reproducibility, a blind trial was conducted in three laboratories -- ZEBET (D), Safepharm (UK) and BASF (D), in which the 12 endorsed reference chemicals were tested. Results obtained with the SkinEthic epidermal model were reproducible, both within and between laboratories, and over time. Concordance between the in vitro predictions of skin corrosivity potential obtained with the SkinEthic model and the predictions obtained with the accepted tests of OECD TG 430 and TG 431 was very good. The new test was able to distinguish between corrosive and non-corrosive reference chemicals with an accuracy of 93%.

Epidermal-skin-test 1,000 (EST-1,000)--a new reconstructed epidermis for in vitro skin corrosivity testing.

The determination of a possible corrosive or irritative potential of certain products and ingredients is necessary for their classification and labeling requirements. Reconstructed skin as a model system provides fundamental advantages to single cell culture testing and leads to promising results as shown by different validation studies (for review: Fentem, J.H., Botham, P.A., 2002. ECVAM's activities in validating alternative tests for skin corrosion and irritation. ATLA 30(Suppl. 2), 61-67). In this study we introduce our new reconstructed epidermis "Epidermal-Skin-Test" (EST-1,000). This fully grown epidermis consists of proliferating as well as differentiating keratinocytes. EST-1,000 shows a high comparability to normal human skin as shown by histological and immunohistochemical data. Characteristic markers (KI-67, CK 1/10/5/14, transglutaminase, collagen IV, involucrin, beta 1 integrin) can be identified easily. The main focus of this work was to characterize EST-1,000 especially with respect to its barrier function by testing several substances of known corrosive potential. Skin corrosion was detected by the cytotoxic effect of the substances on a reconstructed epidermis after short-term application to the stratum corneum. The effect was determined by standard MTT assay and accompanying histological analysis. Hence EST-1,000 shows a very high predictive potential and closes the gap between animal testing and the established full-thickness model Advanced-Skin-Test 2,000 (AST-2,000) (Noll, M., Merkle, M.-L., Kandsberger, M., Matthes, T., Fuchs, H., Graeve, T., 1999. Reconstructed human skin (AST-2,000) as a tool for pharmaco-toxicology. ATLA 27, 302).

[Criteria for classifying chemical substances according to toxicity: carcinogens, irritants, corrosives, allergens, fetotoxins and those absorbed through the skin]. / Zasady klasyfikacji substancji chemicznych pod katem dzialania toksycznego: rakotwórczego, drazniacego, zracego, uczulajacego, fetotoksycznego oraz wchlaniania przez skóre.

The authors reviewed and presented the criteria used to classify the toxic effects of chemicals such as carcinogenic, irritation, corrosive, allergic, and fetotoxicity, as well as dermal absorption of chemical agents. The criteria for assigning symbols to the Polish list of chemical MAC values has not as yet been determined. Following the analysis it may be concluded that all chemical compounds, which satisfy the requirements should be indexed on the MAC list.

Evaluation of a human patch test for the identification and classification of skin irritation potential.

Current regulations require that the skin irritation/corrosion potential of new chemicals is assessed in the rabbit Draize test, although there are opportunities to use alternative methods to identify the most aggressive materials. Previously, we have proposed that it is possible to employ a strategy that avoids the use of animals and at the same time delivers a more relevant assessment of skin irritation/corrosion potential. The approach is to identify corrosive materials in vitro and then proceed to human volunteer testing for skin irritation. In this study, the human 4-h patch test, its interpretation, and results with 29 test materials are presented. Using 14 materials not classified as "Irritating to skin" by EU criteria, 13 classified as "Irritating to skin" by suppliers, and 2 as "Corrosive - causes burns", it is demonstrated that, by evaluating these on human skin in vitro and in vivo, a significant proportion are either over-classified or under-classified. In conclusion, we are convinced that by application of the approach described in detail here, it is possible to avoid the use of animals, whilst at the same time obtaining an assessment of skin irritation/corrosion potential that is more relevant to man, and which, if required, may be used directly for classification and labelling of substances and preparations within the European Union.