In vitro assessment of eye irritancy using the Reconstructed Human Corneal Epithelial SkinEthic HCE model: application to 435 substances from consumer products industry.

The 7th amendment of the EU Cosmetics Directive led to the ban of eye irritation testing for cosmetic ingredients in animals, effective from March 11th 2009. Over the last 20years, many efforts have been made to find reliable and relevant alternative methods. The SkinEthic HCE model was used to evaluate the in vitro eye irritancy potential of substances from a cosmetic industry portfolio. An optimized protocol based on a specific 1-h treatment and a 16-h post-treatment incubation period was first assessed on a set of 102 substances. The prediction model (PM) based on a 50% viability cut-off, allowed to draw up two classes (Irritants and Non-Irritants), with good associated sensitivity (86.2%) and specificity (83.5%). To check the robustness of the method, the evaluated set was expanded up to 435 substances. Final performances maintained a high level and were characterized by an overall accuracy value > 82% when using EU or GHS classification rules. Results showed that the SkinEthic HCE test method is a promising in vitro tool for the prediction of eye irritancy. Optimization datasets were shared with the COLIPA Eye Irritation Project Team and ECVAM experts, and reviewed as part of an ongoing progression to enter an ECVAM prospective validation study for eye irritation.

Transcriptional profiling defines the effects of nickel in human epidermal keratinocytes.

Nickel is a ubiquitous and virtually unavoidable environmental pollutant and occupational hazard, but its molecular and cellular effects are not well understood. Human epidermal keratinocytes are the sentinel and the primary target for nickel. We treated with nickel salts skin equivalents containing differentiating epidermal keratinocytes grown on air-liquid interface in standard cell culture conditions. We identified the transcriptional profiles affected by nickel in reconstructed human epidermis (RHE) using DNA microarrays. The Ni-regulated genes were determined at two time points, immediate-early, 30 min after treatment, and late, at 6 h. Using in silico data analysis, we determined that 134 genes are regulated by nickel; of these, 97 are induced and 37 suppressed. Functional categories of regulated genes suggest that Ni inhibits apoptosis, promotes cell cycle and induces synthesis of extracellular matrix proteins and extracellular proteases. Importantly, Ni also regulates a set of secreted signaling proteins, inducing VEGF, amphiregulin, PGF, GDF15, and BST2, while suppressing IL-18, galectin-3, and LITAF. These secreted proteins may be important in Ni-caused allergic reactions. Ni induced inhibitors of the NFkappaB signaling pathway, and suppressed its activators. Correspondingly, NFkappaB binding sites were found to be overrepresented in the Ni-suppressed genes, whereas cFOS/AP1 binding sites were common in the Ni-induced genes. Significant parallels were found between the Ni-regulated genes and the genes regulated by TGFbeta, EGF, glucocorticoids, or Oncostatin-M. The comprehensive identification of Ni-regulated genes in human epidermal equivalents significantly advances our understanding of the molecular effects of nickel in skin.