Construction of Three-Dimensional Dermo-Epidermal Skin Equivalents Using Cell Coating Technology and Their Utilization as Alternative Skin for Permeation Studies and Skin Irritation Tests.

Abstract

In vitro generated human skin equivalents are generating interest as promising tools in basic study, as alternatives to animal testing, and for clinical applications in regenerative medicine. For prediction of skin irritation and corrosion, three-dimensional human skin equivalents consisting of differentiated human keratinocytes (KCs) have been developed and some models have been internationally accepted. However, more delicate assessments using full-thickness skin models, such as skin sensitization tests, cannot be performed due to the lack of a dermis containing fibroblasts or appendages. In a previous study, we developed dermo-epidermal human skin equivalents (DESEs) using a cell coating technique, which employs cell surface coating by layer-by-layer assembled extracellular matrix (ECM) films. The DESEs with dermis consisting of normal human dermal fibroblasts (NHDFs) and epidermis consisting of human KCs were easily fabricated by using this technology. In this study, the constructed DESEs were evaluated as an alternative skin for skin permeation and irritation tests. A good relationship of permeability coefficient of chemicals was observed between the DESEs and human skin data. We investigated whether the DESEs, a new in vitro skin model, are capable of identifying skin irritant and nonirritant substances among 20 reference chemicals. It was confirmed that the DESEs are applicable to skin irritation testing as defined in the European Centre for the Validation of Alternative Methods (ECVAM) Performance Standard (OECD Test Guideline 439). We further studied the construction of DESEs with density-controlled blood capillary networks using human umbilical vein endothelial cells (HUVECs). The results suggest that DESEs allowing incorporation of skin appendages are more promising alternatives to animal testing and can be applied to the design of physiologically relevant in vitro skin models.