SkinEthic HCE Time-to-Toxicity on solids: A test method for distinguishing chemicals inducing serious eye damage, eye irritation and not requiring classification and labelling.

This study describes the development of a Time-to-Toxicity approach for solids (TTS) based on the SkinEthic™ HCE tissue construct, capable to distinguish chemicals that do not require classification for serious eye damage/eye irritation (No Cat.) from chemicals that require classification for eye irritation (Cat. 2), and serious eye damage (Cat. 1). Briefly, the time-to-toxicity of 69 solids was evaluated by exposing SkinEthic™ HCE tissue constructs to the test chemical for two different time periods (30-min, and 120-min). Based on the viability observed for the different exposure periods, a classification was assigned. The within laboratory reproducibility in terms of concordance in classifications (3 UN GHS categories), based on a set of 48 solids, was 93.7%. Furthermore, 73.6% Cat. 1 (N = 24), 55.6% Cat. 2 (N = 15) and 72.2% No Cat. (N = 30) were correctly identified with the SkinEthic™ HCE TTS test method. This study provides evidence that the SkinEthic™ HCE Time-to-Toxicity method (multiple exposure times) can distinguish Cat. 2 solids from Cat. 1 solids. This is an added value compared to the SkinEthic™ HCE EITS method (single exposure time) that can distinguish No Cat. chemicals from chemicals that do require classification and labelling for eye irritation/serious eye damage (Cat. 2/Cat. 1).

The EyeIRR-IS assay: Development and evaluation of an in vitro assay to measure the eye irritation sub-categorization of liquid chemicals.

Several alternative methods have been developed and regulatory adopted by OECD as in vitro alternatives to the Draize eye irritation assay either to detect chemicals not requiring classification (No Category) or inducing serious damage to the eye (Category 1) but none are sensitive enough to identify chemicals inducing reversible eye effects (category 2) which are categorised by default. Therefore, the discriminatory power of a genomic approach applied to the SkinEthic™ Human Corneal Epithelium (HCE) model was investigated to allow subcategorization capacity according to UN GHS classification. An algorithm based on gene expression modulation on a training (62) and a test (31 liquids) chemical set, tested neat and at 30%was evaluated in an assay called EyeIRR-IS. Its accuracy prediction to distinguish Cat1/Cat2 from No Cat was 95% with a specificity of 89% and a sensitivity of 98%. For subcategorization into the 3 GHS classes the accuracy reached 84% with 94% Cat1, 67% Cat2 and 89% No Cat correctly predicted. No Cat.1 chemicals were underestimated as negative with a majority of misclassified Cat2 over predicted as Cat 1. In conclusion, the performance of the assay suggests its added value in a defined approach for liquids to replace the Draize assay.

Development of the SkinEthic HCE Time-to-Toxicity test method for identifying liquid chemicals not requiring classification and labelling and liquids inducing serious eye damage and eye irritation.

This study describes the development of a Time-to-Toxicity approach for liquids (TTL) based on the SkinEthic™ HCE tissue construct, capable to distinguish chemicals that do not require classification for serious eye damage/eye irritation (No Cat.) from chemicals that require classification for eye irritation (Cat. 2), and serious eye damage (Cat. 1). Briefly, the Time-to-Toxicity of 56 liquids was evaluated by exposing SkinEthic™ HCE tissue constructs to the test chemical for three different time periods (5-min, 16-min, and 120-min). Based on the viability observed for the different exposure periods, a classification was assigned. The within laboratory reproducibility in terms of concordance in classifications (3 UN GHS categories), based on a set of 50 liquids, was 80.0%. Furthermore, 84.3% Cat. 1 (N = 17), 79.4% Cat. 2 (N = 21) and 72.2% No Cat. (N = 18) were correctly identified with the SkinEthic™ HCE TTL test method. This study provides evidence that the SkinEthic™ HCE Time-to-Toxicity method (multiple exposure times) is capable of distinguishing Cat. 2 liquids from Cat. 1 liquids. This is an advantage compared to the SkinEthic™ HCE EITL method (single exposure time) that can distinguish No Cat. chemicals from chemicals that do require classification and labelling for eye irritation/serious eye damage (Cat. 2/Cat. 1).

SkinEthic™ HCE Eye Irritation Test: Similar performance demonstrated after long distance shipment and extended storage conditions.

Assessment of ocular irritation risk is an international regulatory requirement in the safety evaluation of products. In response to this need, L'Oréal developed the SkinEthic™ Human Corneal Epithelium (HCE) Eye Irritation Test (EIT) that has been included in OECD Test Guideline 492. SkinEthic™ HCE EIT is able to correctly and reliably identify chemicals not requiring classification versus labelling for eye irritation or serious eye damage according to UN GHS. In an effort to promote its global use, the performance of the method was evaluated after long-distance shipment and compared to European shipment conditions. Results obtained by Cosmos Technical Center (Japan) after extended tissues transit were compared to results obtained in L'Oréal (France). Thirty-nine out of 40 blinded chemicals, representing different functional chemical classes, were consistently classified in both laboratories. The SkinEthic™ HCE EIT test method was also evaluated for its performance after extended storage of the tissues. The performance was in agreement with the values reported in OECD TG 492, with an overall accuracy of 87.1% (based on 119 chemicals), sensitivity of 95.5% and specificity of 73.5%. The reliability and relevance of SkinEthic™ HCE EIT test method after long-distance shipment and extended storage remain in agreement with regulatory validation criteria.

PrPTSE distribution in a primate model of variant, sporadic, and iatrogenic Creutzfeldt-Jakob disease.

Human prion diseases, such as Creutzfeldt-Jakob disease (CJD), are neurodegenerative and fatal. Sporadic CJD (sCJD) can be transmitted between humans through medical procedures involving highly infected organs, such as the central nervous system. However, in variant CJD (vCJD), which is due to human contamination with the bovine spongiform encephalopathy (BSE) agent, lymphoreticular tissue also harbors the transmissible spongiform encephalopathy-associated prion protein (PrP(TSE)), which poses a particularly acute risk for iatrogenic transmission. Two blood transfusion-related cases are already documented. In addition, the recent observation of PrP(TSE) in spleen and muscle in sCJD raised the possibility that peripheral PrP(TSE) is not limited to vCJD cases. We aimed to clarify the peripheral pathogenesis of human TSEs by using a nonhuman primate model which mimics human diseases. A highly sensitive enzyme-linked immunosorbent assay was adapted to the detection of extraneural PrP(TSE). We show that affected organs can be divided into two groups. The first is peripheral organs accumulating large amounts of PrP(TSE), which represent a high risk of iatrogenic transmission. This category comprises only lymphoreticular organs in the vCJD/BSE model. The second is organs with small amounts of PrP(TSE) associated with nervous structures. These are the muscles, adrenal glands, and enteric nervous system in the sporadic, iatrogenic, and variant CJD models. In contrast to the first set of organs, this low level of tissue contamination is not strain restricted and seems to be linked to secondary centrifugal spread of the agent through nerves. It might represent a risk for iatrogenic transmission, formerly underestimated despite previous reports of low rates of transmission from peripheral organs of humans to nonhuman primates (5, 10). This study provides an additional experimental basis for the classification of human organs into different risk categories and a rational re-evaluation of current risk management measures.

Homogeneous time-resolved fluorescence assay for identifying p53 interactions with its protein partners, directly in a cellular extract.

The p53 protein is a tumor suppressor that protects the organism against malignant consequences of DNA damage. Interaction of p53 with numerous cellular or viral proteins regulates its functional activity either positively or negatively. An approach leading to identification of such protein interactions directly in a cell extract could be of help in the development of screening assays to search for drugs acting on p53 in its cellular environment, either by disrupting its association with inhibitory proteins or by increasing its affinity for activating proteins. We show that the homogeneous time-resolved fluorescence (HTRF) assay based on the time-resolved amplified cryptate emission (TRACE) technology allows identification of such an interaction by simply adding a mixture of two labeled monoclonal antibodies, directly in a cellular extract. We validate this assay by studying p53/SV40-LTAg interactions. The antibodies directed against genuine p53 and SV40-LTAg epitopes were labeled with europium cryptate (donor) and XL665, a crosslinked allophycocyanin (acceptor), respectively. We demonstrated that a nonradiative energy transfer occurs between labeled antibodies only when p53 interacts with SV40-LTag, which opens up the possibility of extending this approach to other p53 partners to search for drugs that restore p53 tumor-suppressor activity.