Development and characterization of novel 1-(1-Naphthyl)piperazine-loaded lipid vesicles for prevention of UV-induced skin inflammation.

1-(1-Naphthyl)piperazine (1-NPZ) has shown promising effects by inhibiting UV radiation-induced immunosuppression. Ultradeformable vesicles are recent advantageous systems capable of improving the (trans)dermal drug delivery. The aim of this study was to investigate 1-NPZ-loaded transethosomes (NPZ-TE) and 1-NPZ-loaded vesicles containing dimethyl sulfoxide (NPZ-DM) as novel delivery nanosystems, and to uncover their chemopreventive effect against UV-induced acute inflammation. Their physicochemical properties were evaluated as follows: vesicles size and zeta potential by dynamic and electrophoretic light scattering, respectively; vesicle deformability by pressure driven transport; rheological behavior by measuring viscosity and I-NPZ entrapment yield by HPLC. In vitro topical delivery studies were performed in order to evaluate the permeation profile of both formulations, whereas in vivo studies sought to assess the photoprotective effect of the selected formulation on irradiated hairless mice by measuring myeloperoxidase activity and the secretion of proinflammatory cytokines. Either NPZ-TE or NPZ-DM exhibited positive results in terms of physicochemical properties. In vitro data revealed an improved permeation of 1-NPZ across pig ear skin, especially by NPZ-DM. In vivo studies demonstrated that NPZ-DM exposure was capable of preventing UVB-induced inflammation and blocking mediators of inflammation in mouse skin. The successful results here obtained encourage us to continue these studies for the management of inflammatory skin conditions that may lead to the development of skin cancers.

In vitro and in vivo topical delivery studies of tretinoin-loaded ultradeformable vesicles.

INTRODUCTION: Ultradeformable vesicles are highly promising tools to enhance the percutaneous transport of different drugs such as tretinoin across the skin barrier and also to increase the formulation stability at absorption site and reduce the drug induced irritation. METHODS: Topical delivery of tretinoin-loaded ultradeformable vesicles (tretinoin-UDV) was evaluated concerning different studies, such as: the release and permeation profiles (tape stripping); skin penetration (fluorescence analysis); induced electrical changes in skin barrier properties; cytotoxicity (Trypan Blue assay) and skin irritation in in vivo conditions (Draize test). The novel formulation performance was also compared to a commercial tretinoin formulation regarding in vivo studies. RESULTS: It was obtained a sustained and controlled drug release, as expected for UDV formulation. In addition, a dermal delivery was observed regarding the permeation study since it was not detected any drug amount in the receptor phase after 24h. Nile Red-UDV stained intensively mostly in the stratum corneum, corroborating the tape stripping results. Tretinoin-UDV decreased skin resistance, suggesting its ability to induce skin barrier disruption. Finally, the formulation vehicle (empty UDV) and tretinoin-UDV were not toxic under in vitro and in vivo conditions, at least, at 5×10(-3)mg/mL and 0.5mg/mL of tretinoin, respectively. CONCLUSION: Tretinoin-UDV is a promising delivery system for tretinoin dermal delivery without promoting skin irritation (unlike other commercial formulations), which is quite advantageous for therapeutic purpose.

Novel tretinoin formulations: a drug-in-cyclodextrin-in-liposome approach.

PURPOSE: The aims of this experimental work were the incorporation and full characterization of the system Tretinoin-in-dimethyl-beta-cyclodextrin-in-ultradeformable vesicles (Tretinoin-CyD-UDV) and Tretinoin-in-ultradeformable vesicles (Tretinoin-UDV). METHODS: The Tretinoin-CyD complex was prepared by kneading and the UDV by adding soybean phosphatidylcholine (SPC) to Tween® 80 followed by an appropriate volume of sodium phosphate buffer solution to make a 10%-20% lipid suspension. The resulting suspension was brought to the final mean vesicles size, of approximately 150 nm, by sequential filtration. The physicochemical characterization was based on: the evaluation of mean particle size and polydispersity index (PI) measured by photon correlation spectroscopy (PCS) and atomic force microscopy (AFM) topographic imaging; zeta potential (ζ-potential) and the SPC concentration determined by Laser-Doppler anemometry and an enzymatic-colorimetric test, respectively. The quantification of the incorporated Tretinoin and its chemical stability (during preparation and storage) was assayed by a HPLC at 342 nm. RESULTS: It was possible to obtain the system Tretinoin-CyD-UDV. The mean vesicle size was the most stable parameter during experiments time course. AFM showed that Tretinoin-CyD-UDV samples were very heterogeneous in size, having three distinct subpopulations, while Tretinoin-UDV samples had only one homogeneous size population. The results of the ζ-potential measurements have shown that vesicle surface charge was low, as expected, presenting negative values. The incorporation efficiency was high, and no significant differences between Tretinoin-CyD-UDV and Tretinoin-UDV were observed. However, only Tretinoin-UDV with 20% lipid concentration formulation remained chemically stable during the evaluation period. CONCLUSION: According to our results, Tretinoin-UDV with 20% lipid concentration seems to be a better approach than Tretinoin-CyD-UDV, attending to the higher chemical stability.