Self-emulsifying drug delivery systems: Design of a novel vaginal delivery system for curcumin.

AIM: The aim of this study was to develop a vaginal self-emulsifying delivery system for curcumin being capable of spreading, of permeating the mucus gel layer and of protecting the drug being incorporated in oily nanodroplets towards mucus interactions and immobilization. METHODS: The emulsifying properties of curcumin loaded SEDDS containing 30% Cremophor RH40, 20% Capmul PG-8, 30% Captex 300, 10% DMSO and 10% tetraglycol (SEDD formulation A) as well as 25% PEG 200, 35% Cremophor RH40, 20% Captex 355, 10% Caprylic acid and 10% Tween 80 (SEDD formulation B) after diluting 1+2 with artificial vaginal fluid were characterized regarding droplet size and zeta potential. Collagen swelling test was used to examine the irritation potential of SEDDS. Additionally to mucus binding studies, permeation studies in the mucus were performed. Furthermore, spreading potential of the novel developed formulations was compared with a commercial available o/w cream (non-ionic hydrophilic cream) on vaginal mucosa. RESULTS: SEDDS displayed a mean droplet size between 38 and 141nm and a zeta potential of -0.3 to -1.6mV. The collagen swelling test indicated no significant irritation potential of both formulations over 24h. An immediate interaction of unformulated curcumin with the mucus was determined, whereas both SEDDS facilitated drug permeation through the mucus layer. Formulation B showed a 2.2-fold improved transport ratio of curcumin compared to SEDD formulation A. In comparison to the vaginal cream, SEDD formulation A and B were able to spread over the vaginal mucosa and cover the tissue to a 17.8- and 14.8-fold higher extent, respectively. CONCLUSION: According to these results, SEDDS seems to be a promising tool for vaginal application.

Mucus permeating thiomer nanoparticles.

The aim of this study was to develop and evaluate a novel mucoadhesive drug delivery system based on thiolated poly(acrylic acid) nanoparticles exhibiting mucolytic properties to enhance particle diffusion into deeper mucus regions before adhesion. Mediated by a carbodiimide, cysteine and the mucolytic enzyme papain were covalently attached to poly(acrylic acid) via amide bond formation. The conjugates were co-precipitated with calcium chloride in order to obtain papain modified (PAA-pap) and thiolated nanoparticles (PAA-cys) as well as particles containing both conjugates (PAA-cys-pap). The nanoparticulate systems were characterized regarding particle size distribution and zeta potential. Particle transport was investigated by diffusion studies across intestinal mucus using two different techniques. Furthermore, mucoadhesive properties of all particles were evaluated via rheological measurements. Results demonstrated that all nanoparticles were in a size range of 158-214 nm and showed negative zeta potentials. Due to the presence of papain, the PAA-cys-pap particles were capable of cleaving mucoglycoprotein substructures and consequently exhibited a 2.0-fold higher penetration into the mucus layer in comparison with PAA-cys particles. Within the rheological studies, an 1.9-fold increase in mucoadhesion could be achieved for the nanoparticulate system based on thiolated PAA compared to papain modified particles (PAA-pap). Therefore, the newly developed particulate system (PAA-cys-pap) is characterized by mucoadhesive as well as mucolytic properties. The combination of both effects - mucus-permeating and mucoadhesive properties - might be a promising strategy for the development of oral drug delivery systems to overcome the mucus barrier and providing a prolonged residence time close to the absorption membrane.

Thiolated nanocarriers for oral delivery of hydrophilic macromolecular drugs.

It was the aim of this study to investigate the effect of unmodified as well as thiolated anionic poly(acrylic acid) (PAA) and cationic chitosan (CS) utilized in free-soluble form and as nanoparticulate system on the absorption of the hydrophilic compound FD4 across intestinal epithelial cell layer with and without a mucus layer. Modifications of these polymers were achieved by conjugation with cysteine to PAA (PAA-Cys) and thioglycolic acid to CS (CS-TGA). Particles were prepared via ionic gelation and characterized based on their amount of thiol groups, particle size and zeta potential. Effects on the cell layer concerning absorption enhancement, transepithelial electrical resistance (TEER) and cytotoxicity were investigated. Permeation enhancement was evaluated with respect to in vitro transport of FD4 across Caco-2 cells, while mucoadhesion was indirectly examined in terms of adsorption behaviour when cells were covered with a mucus layer. Lyophilized particles displayed around 1000 µmol/g of free thiol groups, particle sizes of less than 300 nm and a zeta potential of 18 mV (CS-TGA) and -14 mV (PAA-Cys). Cytotoxicity studies confirmed that all polymer samples were used at nontoxic concentrations (0.5% m/v). Permeation studies revealed that all thiolated formulations had pronounced effects on the paracellular permeability of mucus-free Caco-2 layers and enhanced the permeation of FD4 3.0- to 5.3-fold. Moreover, polymers administered as particles showed a higher permeation enhancement than their corresponding solutions. However, the absorption-enhancing effect of each thiolated formulation was significantly (p<0.05) reduced when cells were covered with mucus layer. In addition, all formulations were able to decrease the TEER of the cell layer significantly (p<0.05). Therefore, both thiolated polymers as nanoparticulate delivery systems represent a promising tool for the oral administration of hydrophilic macromolecules.

Development of a dosage form for accelerated release.

PURPOSE: It was the aim of this study to develop an oral capsule delivery system capable of rapidly ejecting the incorporated payload in the small intestine. METHODS: The capsule consists of four parts: a reaction mixture comprising of a basic and a corresponding acidic component, a plunger necessary to separate the reaction mixture from the inserted ingredients, capsule cap and body (made out of ethylcellulose (EC)), where at the bottom of the body a semipermeable filter membrane is mounted. As soon as water permeates through the membrane, the reaction mixture dissolves and carbon dioxide (CO2) is released resulting in a high speed liberation of inserted compounds onto the intestinal mucosa. Several filter membranes were investigated regarding water influx, capillary force and water retention capacity. CO2 release of sodium hydrogen carbonate (NaHCO3) was examined in presence of several acidic components in different morphological forms (powder, lyophilisate and granule) and the amount of CO2 liberation out of prepared capsules was determined. Furthermore, release of enteric coated capsules was tested within 0.1M HCl and 100mM phosphate buffer pH 6.8. RESULTS: The rank order regarding membrane permeability was determined to be: cellulose acetate with a pore diameter of 12-15 µm>4-12 µm cellulose acetate>8 µm cellulose nitrate>8-12 µm cellulose acetate. NaHCO3 in combination with tartaric acid in form of a granule could be identified as the most promising reaction mixture with the highest amount of released CO2 compared to all other reaction mixture combinations. Stability of enteric coated capsules in HCl and a spontaneous release in phosphate puffer could be demonstrated within in vitro release studies. CONCLUSION: In light of these results, the developed releasing system seems to be a promising tool for an accelerated delivery of several incorporated excipients.