Human skin equivalents are an excellent tool to study the effect of moisturizers on the water distribution in the stratum corneum.

In this study, the mode of action of moisturizers on the level of water in the stratum corneum was studied using cryo-scanning electron microscopy. As model for dry skin, we used human skin equivalents (HSEs) generated at 93% or 60% relative humidity (RH). During the generation of the HSEs, the moisturizers were applied during a period of maximal 2 weeks.

Generation of human skin equivalents under submerged conditions-mimicking the in utero environment.

In this study we generated human skin equivalents (HSEs) under submerged conditions mimicking the aqueous in utero environment and investigated the morphology and differentiation process of the formed epidermis. Further, the skin barrier, which resides in the stratum corneum (SC), was characterized by its lipid content, hydration level, and natural moisturizing factor level. The submerged HSEs showed comparable tissue morphology and similar expression of several differentiation markers and SC lipid composition compared with HSEs grown at the air-liquid interface and native human skin.

Effect of synthetic vernix biofilms on barrier recovery of damaged mouse skin.

The aim of this work was to investigate whether topical application of synthetic biofilms supports and accelerates the recovery of the murine skin barrier, disrupted by sequential tape stripping. Therefore, various biofilms were applied topically on disrupted mouse skin to determine which formulation could improve barrier function, as was observed previously for the natural biofilm vernix caseosa (VC). The biofilms [i.

Mimicking vernix caseosa--preparation and characterization of synthetic biofilms.

The multiple protecting and barrier-supporting properties of the creamy, white biofilm vernix caseosa (VC) before and after birth suggest that a VC biomimetic could be an innovative barrier cream for barrier-deficient skin. The aim of this study was the rational design and preparation of synthetic biofilms mimicking the unique composition and properties of natural VC. Hexagonal, highly hydrated hyperbranched polyglycerol microgel particles (30 microm in diameter) were embedded in a synthetic lanolin-based lipid mixture using a micromixer.

Skin barrier disruption by acetone: observations in a hairless mouse skin model.

To disrupt the barrier function of the skin, different in vivo methods have been established, e.g., by acetone wiping or tape-stripping.