Development of a novel in vitro strategy to understand the impact of shaving on skin health: combining tape strip exfoliation and human skin equivalent technology

Introduction: The removal of unwanted hair is a widespread grooming practice adopted by both males and females. Although many depilatory techniques are now available, shaving remains the most common, despite its propensity to irritate skin. Current techniques to investigate the impact of shaving regimes on skin health rely on costly and lengthy clinical trials, which hinge on recruitment of human volunteers and can require invasive biopsies to elucidate cellular and molecular-level changes. Methods: Well-characterised human skin equivalent technology was combined with a commonplace dermatological technique of tape stripping, to remove cellular material from the uppermost layer of the skin (stratum corneum). This method of exfoliation recapitulated aspects of razor-based shaving in vitro, offering a robust and standardised in vitro method to study inflammatory processes such as those invoked by grooming practices. Results: Tape strip insult induced inflammatory changes in the skin equivalent such as: increased epidermal proliferation, epidermal thickening, increased cytokine production and impaired barrier function. These changes paralleled effects seen with a single dry razor pass, correlated with the number of tape strips removed, and were attenuated by pre-application of shaving foam, or post-application of moisturisation. Discussion: Tape strip removal is a common dermatological technique, in this study we demonstrate a novel application of tape stripping, to mimic barrier damage and inflammation associated with a dry shave. We validate this method, comparing it to razor-based shaving in vitro and demonstrate the propensity of suitable shave- and skin-care formulations to mitigate damage. This provides a novel methodology to examine grooming associated damage and a platform for screening potential skin care formulations

Tetra-2,3-pyrazinoporphyrazines with externally appended pyridine rings. 17. Photosensitizing properties and cellular effects of ZnII octacationic and ZnII/PtII hexacationic macrocycles in aqueous media: Perspectives of multimodal anticancer potentialities

The photosensitizing activity of two multiply charged porphyrazine derivatives, i.e. the ZnII species [(CH3)8LZn]8+ and the ZnII/PtII heterobimetallic complex [(PtCl2)(CH3)6LZn]6+ (neutralized byI- ions; L = tetrakis-2,3-[5,6-di(2-pyridyl)pyrazino]porphyrazinato dianion) has been examined in the water medium in the presence of SDS under experimental conditions in which the two species are present exclusively in their monomeric form. The determined quantum yield values (ΦΔ) for both complexes, of interest in photodynamic therapy (PDT), are 2.3–2.5 higher than that of the aluminium compound PcAlSmix (Photosens®) used as the reference standard, an encouraging result for the application of the two cationic species as anticancer curative drugs in PDT. Investigation was also extended to explore the cellular effects on the melanoma C8161 and the oral squamous carcinoma CA-1 cell lines like viability, cellular uptake, cell death modality and cell cycle distribution experiments. The IC50 values for the ZnII and ZnII/PtII cations are consistently lower than those of the reference standard, thus the degree of efficiency as anticancer agents being in the order octacation ≫ hexacation > PcAlSmix. A large prevalence of apoptosis with respect to necrosis is observed for both charged complexes. Thus, all achieved information from photoactivity and in vitro tests in water solution further enhance perspectives for the application of the two ZnII cation [(CH3)8LZn]8+ and the related ZnII/PtII analog [(PtCl2)(CH3)6LZn]6+ as potential bi-multimodal anticancer drugs. © 201