In Vitro Cytotoxicity and Cellular Uptake of Tamoxifen Citrate-Loaded Polymeric Micelles.

The main intent of this treatise was to encapsulate tamoxifen citrate (TMXC) into polymeric micellar delivery system and evaluate the influence of TMXC-loaded micelles as a promising carrier on the in vitro cytotoxicity and cellular uptake of TMXC in treatment of breast cancer. Different formulae of polymeric micelles loaded with TMXC using mixtures of different Pluronic polymers were fabricated by thin-film hydration method and evaluated for morphology, drug entrapment efficiency, particle size, surface charge, in vitro liberation of TMXC, uptake by cancer cell lines, and cytotoxic effect against breast cancer cell lines such as MCF-7. The optimal TMXC-loaded micelles exhibited nano-sized particles and entrapped about 89.09 ± 4.2% of TMXC. In vitro liberation study revealed an extended TMXC escape of about 70.23 ± 5.9% over a period of 36 h. The optimized TMXC-loaded micelles formula showed enhanced cellular uptake of TMXC by 2.28 folds and showed a significant cytotoxic effect with MCF-7 breast cancer cells compared to TMXC solution. The obtained yield proposed that Pluronic micelles could be a promising potential delivery system for anticancer moieties.

In vitro and in vivo evaluation of cubosomal nanoparticles as an ocular delivery system for fluconazole in treatment of keratomycosis.

The objective of the present study was to enhance ocular antifungal activity of fluconazole (FCZ) in treatment of keratomycosis through incorporation into cubosomal nanoparticles. FCZ-loaded cubosomal dispersions were prepared by emulsification method according to 23 full factorial design. Design-Expert® software was used to study the effects of different formulation factors on properties of FCZ-loaded cubosomal dispersions and select the optimal formulation. Eight FCZ-loaded cubosomal dispersions were prepared and were in vitro and in vivo evaluated. In vitro, the results revealed that the optimum formula exhibited a mean particle size of 48.17 ± 0.65 nm and entrapped 85.70 ± 2.56% of FCZ. The ex vivo permeation study confirmed a two-fold enhancement in FCZ permeation through rabbit cornea compared to aqueous FCZ solution. Furthermore, in vivo ocular tolerance and histopathological studies proved the efficacy and safety FCZ-loaded cubosomal dispersion in treatment of induced keratomycosis in rats compared to aqueous FCZ solution after topical ocular application. In conclusion, the obtained results indicated that cubosomes could be promising ocular drug delivery system for enhancing antifungal activity of FCZ in treatment of fungal keratitis in rats. Graphical abstract.