Mucoadhesive Chitosan Composite Sponge as a Carrier for ß-Sitosterol Cubosomes for Thermal Burn Treatment.

Our study aimed to explore the potential of using nanostructured lipid carriers (NLCs) to enhance the topical administration of ß-sitosterol, a bioactive that is poorly soluble in water. Here, we have taken advantage of the unique characteristics that cubosomes have to provide as a drug delivery system. These characteristics include a large surface area, thermal stability, and the capacity to encapsulate molecules that are hydrophobic, amphiphilic, and hydrophilic. The cubosomal formulation was optimized by building a central composite design. The optimum dispersion exhibited a particle size of 88.3 nm, a zeta potential of -43, a polydispersity index of 0.358, and drug entrapment of 95.6%. It was composed of 15% w/w oleic acid and 5% w/w pluronic F127. The optimized cubosome dispersion was incorporated into a sponge formulation. The optimized cubosome sponge achieved a higher drug release compared with the cubosome dispersion. The SEM micrograph of the selected sponge showed that it has an interwoven irregular fibrous lamellar structure with low density and high porosity. The in-vivo data revealed that topical application of the ß-sitosterol cubosomal sponge showed significant higher wound closure percentage relative to the ß-sitosterol product (Mebo)®.

Optimization of topical curcumin spanlastics for melanoma treatment.

The aim of the study was to enhance curcumin skin permeability through the preparation of spanlastics. Spanlastics were prepared using the ethanol injection technique through a central composite design using Span 60 concentration (X1), edge activator type (X2), and its concentration (X3) as the independent variables. The spanlastics were characterized for particle size (PS), encapsulation efficiency (EE), and dissolution efficiency (%DE24h). Formulae with the highest desirability (FN1 and FN2) were prepared and further characterized. They were elastic, spherical, nonirritant, and compatible with the used excipients. They had particle sizes of 147 and 198 nm, encapsulation efficiencies of 84.00% and 89.63%, zeta potential values of -45.50 and -39.10 mV, permeation enhancement ratios of 11.51 and 8.34 folds, and amounts retained of 7.25 and 10.44 µg/cm2 after 24 h, respectively. Formulae FN1 and FN2 showed cytotoxic effects after 48 h on human melanoma A375 with IC50 of 10.9 and 75.6 µg/mL, respectively. They increased the apoptotic effect confirming the success of the spanlastics to be a potential delivery for melanoma treatment.

Spanlastics nanovesicular ocular insert as a novel ocular delivery of travoprost: optimization using Box-Behnken design and in vivo evaluation.

Currently, travoprost is a synthetic prostaglandin F2α analogue used in the treatment of glaucoma, it is delivered by eye drop solution. Due to its very low bioavailability and patient non-compliance, the objective of the current study was to enhance its bioavailability, and prolong its release Spanlastic nano-vesicles gels were designed and optimized using Box-Behnken design. The optimized spanlastic nano-vesicles gel exhibited the lowest particle size (PS), polydispersity index (PDI) and the highest zeta potential (ZP), encapsulation efficiency (EE) and mucoadhesive strength was fabricated into spanlastic nano-vesicles ocular insert by solvent casting. In vivo studies showed enhanced bioavailability of travoprost spanlastic nano-vesicles gel and ocular insert compared to the marketed eye drops (travoswix®), as proven by their higher Cmax and AUC0-∞, in addition to being nonirritant to ocular surfaces. However, spanlastic nano-vesicles ocular insert showed more prolonged effect than spanlastic nano-vesicles gel. According to our study, it can be suggested that travoprost spanlastic nano-vesicles ocular insert is a novel ocular delivery system for glaucoma treatment.

Alfuzosin hydrochloride-loaded low-density gastroretentive sponges: development, in vitro characterization and gastroretentive monitoring in healthy volunteers via MRI.

The current work aimed to develop low-density gastroretentive sponges loaded with alfuzosin HCl (ALF) to sustain the rate of drug release, improve its oral bioavailability and deliver it to the main site of absorption. Sponges were developed, according to a 23 full factorial design, by compression of the lyophilized ALF-loaded hydroxypropylmethylcellulose (HPMC) or chitosan (CH) solutions. The influences of the polymer type, grade and concentration on the appearance, topography, porosity, density, in vitro ALF release, floating behavior, swelling, erosion, and mucoadhesive potential of the developed sponges were explored. Based on the desirability value, the best achieved system was selected. The gastroretentive potential of this system was evaluated in healthy male volunteers via MRI. Soft and flexible sponges were developed. They were characterized with interconnecting pores and channels and had excellent floating properties with respect to floating lag time and duration. Compared to HPMC-based sponges, CH-based ones exhibited higher porosity, larger pore diameters, lower bulk densities, higher drug release rates, larger swelling ratios, faster erosion rates and better mucoadhesive properties. MRI of magnetite-loaded best-achieved CH-based system (F8) ascertained the development of a promising gastroretentive system; exhibiting a gastric residence period of at least 5 h.