A new eco-friendly and water-resistant sunscreen agent: Lecithin-based multilamellar liposomes.

BACKGROUND: UV skin exposure is an important matter of public health, as the worldwide rising prevalence of skin cancers indicates. However, a wide majority of commercially available sunscreens are responsible for ocean ecosystem damages such as coral reef degradation and phytoplankton mortality. AIMS: To answer the urge for new eco-friendly UV filters, we studied the use of lecithin-based multilamellar liposomes (MLLs) of controlled size and elasticity as a bio-sourced and biodegradable alternative to classic sunscreens. These parameters control allows different skin layers targeting. METHODS: The performance of two different MLLs compositions and a commercially available SPF50+ water-resistant liposomal sunscreen was compared on skin explants. SC-MLLs target the stratum corneum and Epi-MLLs the whole epidermis. Preparations were applied prior to skin irradiation. Their efficiencies were evaluated histologically (hematoxylin and eosin staining plus cyclobutane pyrimidine dimer [CPD] immunostaining) and by skin barrier quality assessment (trans-epithelial electrical resistance). Adhesiveness to the skin was also investigated. RESULTS: Altogether, ex vivo results indicate MLLs offer a solar protection as effective as a SPF50+ water-resistant liposomal sunscreen but with a better skin adhesiveness and an improved skin barrier function. CONCLUSION: Lecithin-based MLLs of controlled physicochemical parameters can be used as a new eco-friendly and water-resistant agent for solar protection. The stratum corneum targeted action of SC-MLLs appears to be more interesting, as SC-MLLs exhibit an overall better performance than Epi-MLLs at a lower cost. The skin barrier improvement showcased could be of interest to people suffering from dry skin or skin barrier impairment related disease.

What is the fate of multi-lamellar liposomes of controlled size, charge and elasticity in artificial and animal skin?

Multi-lamellar liposomes (MLLs), prepared by shearing a lamellar phase composed of lipids (phosphatidylcholine) and surfactant (Tween 80®), were designed to control their size, charge and elasticity, the key parameters known to influence liposomes penetration through skin. Their size was tuned by the water content of the sheared lamellar phase, and by the surfactant-to-lipid ratio as was their elasticity. Their charge was varied by the incorporation of DPPG and DOTAP to confer a high negative or positive zeta potential, respectively. Couples of MLLs differing solely in one physicochemical parameter, the others kept constant, were compared to discriminate the influence of the key parameters on their penetration through a synthetic membrane, Strat-M™. Using confocal Raman microscopy, the kinetics of MLLs penetration was established for 40 h using a Franz cell dispositive under non-occlusive conditions. From these comparisons, we showed that their transversal diffusion cannot be predicted by one sole parameter but depends on a combination of their physicochemical characteristics that were enlightened. Two types of liposomes designed for topic and systemic diffusion and tested on dog-excised skin exhibited the predicted behavior. Eventually, a mechanism supported by complementary TEM analysis is proposed to shed light on MLLs skin penetration.

A new bio-inspired route to metal-nanoparticle-based heterogeneous catalysts.

Onion-type multilamellar vesicles are made of concentric bilayers of organic surfactant and are mainly known for their potential applications in biotechnology. They can be used as microreactors for the spontaneous and controlled production of metal nanoparticles. This process does not require any thermal treatment and, hence, it is also attractive for material sciences such as heterogeneous catalysis. In this paper, silver-nanoparticle-based catalysts are prepared by transferring onion-grown silver nanoparticles onto inorganic supports. The resulting materials are active in the total oxidation of benzene, attesting that this novel bio-inspired concept is promising in inorganic catalysis.