Development of a Reconstructed Human Epidermis (RHE) as platform to in vitro assays: irritation, sensitization, atopic dermatitis and photoimmunosuppression

The development of new in vitro skin models and new methodologies follows a global trend in search for reductions or replacement of animal testing. In this context, Reconstructed Human Epidermis kits (RHE) are presented as a promising platform in the search for alternative methods to animal use, and some models are validated for skin irritation and corrosion in vitro tests. However, in countries such as Brazil, who face customs issues and loss of material due to perishability, making it challenging and even compromising the importation of these kits for use by industries and laboratories. In contrast, the development of an RHE model is presented as a technological breakthrough and gain of autonomy for these countries. Thus, in Chapter 1 we explored the development of a national model of RHE (USP-RHE) that meet international requirements described in OECD TG 439. The developed model presented a well-differentiated epidermis and met the quality parameters, for instance, histology, viability, and barrier function as well as the functionality expressed in the capacity of screening between irritants and nonirritants, with 85.7 % of specificity, 100 % of sensitivity and 91.7% of accuracy in comparision to in vivo UN GHS classification from Local limph node assay (LLNA). In chapter 2, monocytic THP-1 cell line, as monolayers, were able to distinguish between sensitizers and non-sensitizers by expression of CD86, CD54, and IL-8 release. In this model, functional RHE and THP-1 were used in a cross-talking, and thus an immunocompetent RHE (RHEI) was generated. The RHEI has distinguished satisfactorily between sensitizers and non-sensitizers through CD86 and CD54 expression that was larger and more sensitive in this model. The release of IL-8 was also evaluated in RHEI, however, did not demonstrate to be a good parameter for this evaluation, unlike IL-1α, which satisfactorily distinguished sensitizers from non-sensitizers, but was not able to hierarchize them. In chapter 3, we evaluated the role of Th2-related cytokines and plasma membrane cholesterol depletion (CD) in the development of atopic dermatitis (AD) morphological and molecular characteristics in an in vitro model of RHE. The results showed that combination of IL-4, IL-13 and IL-25 in combination with CD can reproduce the major features of AD in vitro. In Chapter 4, we sought to evaluate the ultraviolet radiation-induced immunosuppressive effects in RHE. The tests were performed at different times. However, it was not possible to observe such effects. The results are justified by the absence of IL-10 release by RHEI, for example, and show a limitation of RHEI for rating inactivation of the immune response. In this work, we conclude that it was possible to obtain a competitive RHE similar to the validated international models that can be used as a platform for irritation and skin sensitization tests, besides being a platform for the study of atopic dermatitis. Using this model is possible to explore the activation of immune system, which makes it promising as a platform for the evaluation of immune response in vitro. We conclude, therefore, that the objectives have been met as well as it is offering an open source protocol for breeding by other laboratories, thus offering the RHE model developed here for future validation tests. (AU)