Sugar-based colloidal nanocarriers for topical meglumine antimoniate application to cutaneous leishmaniasis treatment: Ex vivo cutaneous retention and in vivo evaluation.

The leishmaniases are a group of diseases caused by protozoan parasites from Leishmania species. Effectiveness therapies for cutaneous leishmaniasis (CL), the most common form, are still needed to be developed since the available drugs such as meglumine antimoniate (MA) present severe adverse reactions. Here, we develop and characterize maltodextrin polymeric colloidal nanocarriers containing MA (PCN-MA) for topical CL treatment. PCN-MA is composed of 5 to 8% maltodextrin, 0.3% NaCl, 1% MA in 21% of water as aqueous-internal phase, containing or no 3% Kolliphor® P-188, and 10% SF1540 dispersed in a silicone-based external phase. It formed a colloidal system dispersed in silicone with high encapsulation efficiency (87% to 92%) and composite spherical-shaped particles with the smooth and regular surface within the nanosized scale, which was confirmed by scanning electron microscopy (SEM) and dynamic light scattering (DLS) analysis. Ex vivo cutaneous retention studies using pig ears skin on Franz diffusion cells revealed that the MA cutaneous retention is improved when delivered by PCN. Topical PCN-MA evaluation in murine leishmaniasis model showed similar efficacy than the intraperitoneal injection of the reference medicine (Glucantime®) regarding parasite titer reduction and superior healing activity in terms of collagen area deposition. Our results suggest that this sugar-based PCN is a promising agent for topical delivery of meglumine antimoniate.

Multifunctional nanoemulsions for intraductal delivery as a new platform for local treatment of breast cancer.

Considering that breast cancer usually begins in the lining of the ducts, local drug administration into the ducts could target cancers and pre-tumor lesions locally while reducing systemic adverse effects. In this study, a cationic bioadhesive nanoemulsion was developed for intraductal administration of C6 ceramide, a sphingolipid that mediates apoptotic and non-apoptotic cell death. Bioadhesive properties were obtained by surface modification with chitosan. The optimized nanoemulsion displayed size of 46.3 nm and positive charge, properties that were not affected by ceramide encapsulation (0.4%, w/w). C6 ceramide concentration necessary to reduce MCF-7 cells viability to 50% (EC50) decreased by 4.5-fold with its nanoencapsulation compared to its solution; a further decrease (2.6-fold) was observed when tributyrin (a pro-drug of butyric acid) was part of the oil phase of the nanocarrier, a phenomenon attributed to synergism. The unloaded nanocarrier was considered safe, as indicated by a score <0.1 in HET-CAM models, by the high survival rates of Galleria mellonella larvae exposed to concentrations ≤500 mg/mL, and absence of histological changes when intraductally administered in rats. Intraductal administration of the nanoemulsion prolonged drug localization for more than 120 h in the mammary tissue compared to its solution. These results support the advantage of the optimized nanoemulsion to enable mammary tissue localization of C6 ceramide.

Co-encapsulation of paclitaxel and C6 ceramide in tributyrin-containing nanocarriers improve co-localization in the skin and potentiate cytotoxic effects in 2D and 3D models.

Considering that tumor development is generally multifactorial, therapy with a combination of agents capable of potentiating cytotoxic effects is promising. In this study, we co-encapsulated C6 ceramide (0.35%) and paclitaxel (0.50%) in micro and nanoemulsions containing tributyrin (a butyric acid pro-drug included for potentiation of cytotoxicity), and compared their ability to co-localize the drugs in viable skin layers. The nanoemulsion delivered 2- and 2.4-fold more paclitaxel into viable skin layers of porcine skin in vitro at 4 and 8h post-application than the microemulsion, and 1.9-fold more C6 ceramide at 8h. The drugs were co-localized mainly in the epidermis, suggesting the nanoemulsion ability for a targeted delivery. Based on this result, the nanoemulsion was selected for evaluation of the nanocarrier-mediated cytotoxicity against cells in culture (2D model) and histological changes in a 3D melanoma model. Encapsulation of the drugs individually decreased the concentration necessary to reduce melanoma cells viability to 50% (EC50) by approximately 4- (paclitaxel) and 13-fold (ceramide), demonstrating an improved nanoemulsion-mediated drug delivery. Co-encapsulation of paclitaxel and ceramide further decreased EC50 by 2.5-4.5-fold, and calculation of the combination index indicated a synergistic effect. Nanoemulsion topical administration on 3D bioengineered melanoma models for 48h promoted marked epidermis destruction, with only few cells remaining in this layer. This result demonstrates the efficacy of the nanoemulsion, but also suggests non-selective cytotoxic effects, which highlights the importance of localizing the drugs within cutaneous layers where the lesions develop to avoid adverse effects.

Monoolein-alginate beads as a platform to promote adenosine cutaneous localization and wound healing.

Alginate beads containing the polar lipid monoolein were developed as a strategy to manage wet wounds by providing improved uptake of excess exudate while releasing adenosine locally for promotion of healing. To obtain monoolein-containing beads, the lipid was mixed with almond oil (2:1w/w), and emulsified within the alginate aqueous dispersion, followed by ionotropic gelation in CaCl2 solution. Compared to alginate-only, monoolein-alginate systems were 1.44-fold larger, their swelling ability was 1.40-fold higher and adenosine cumulative release was approximately 1.30-fold lower (at 24h). Monoolein-alginate beads were considered safe for topical application as demonstrated by the absence of changes on the viability of reconstructed skin equivalents compared to PBS. Smaller amounts of adenosine were delivered by the beads into and across damaged porcine skin (created by an incisional wound) compared to the drug aqueous solution, and cutaneous localization was favored. More specifically, the beads increased the viable skin layer/receptor phase delivery ratio by approximately 4-fold at 12h post-application. Considering the wide range of adenosine physiological effects and the importance of skin localization for its use in wound healing, these results demonstrate the potential of monoolein-containing beads for localized drug delivery and management of wet wounds.

Potential of Non-aqueous Microemulsions to Improve the Delivery of Lipophilic Drugs to the Skin.

In this study, non-aqueous microemulsions were developed because of the challenges associated with finding pharmaceutically acceptable solvents for topical delivery of drugs sparingly soluble in water. The formulation irritation potential and ability to modulate the penetration of lipophilic compounds (progesterone, α-tocopherol, and lycopene) of interest for topical treatment/prevention of skin disorders were evaluated and compared to solutions and aqueous microemulsions of similar composition. The microemulsions (ME) were developed with BRIJ, vitamin E-TPGS, and ethanol as surfactant-co-surfactant blend and tributyrin, isopropyl myristate, and oleic acid as oil phase. As polar phase, propylene glycol (MEPG) or water (MEW) was used (26% w/w). The microemulsions were isotropic and based on viscosity and conductivity assessment, bicontinuous. Compared to drug solutions in lipophilic vehicles, MEPG improved drug delivery into viable skin layers by 2.5-38-fold; the magnitude of penetration enhancement mediated by MEPG into viable skin increased with drug lipophilicity, even though the absolute amount of drug delivered decreased. Delivery of progesterone and tocopherol, but not lycopene (the most lipophilic compound), increased up to 2.5-fold with MEW, and higher amounts of these two drugs were released from MEW (2-2.5-fold). Both microemulsions were considered safe for topical application, but MEPG-mediated decrease in the viability of reconstructed epidermis was more pronounced, suggesting its higher potential for irritation. We conclude that MEPG is a safe and suitable nanocarrier to deliver a variety of lipophilic drugs into viable skin layers, but the use of MEW might be more advantageous for drugs in the lower range of lipophilicity.