Chitosan oligosaccharide enhances binding of nanostructured lipid carriers to ocular mucins: Effect on ocular disposition.

The objective of the study was to assess the effect of enhanced mucoadhesion of a cationic mucoadhesive nanostructured lipid carrier (NLC) on its ocular disposition after topical administration. The NLC was made mucoadhesive by surface coating with chitosan oligosaccharide (COS), a low molecular weight derivate of chitosan which is more suitable for drug delivery applications as compared to the native chitosan. The NLC was characterised by surface evaluating techniques like SANS and XPS for confirming coating of COS over the surface of NLC. In order to assess the effect of COS coating on in vivo ocular mucoadhesion, coumarin loaded NLC were topically administered to rats and the sagittal sections of the eyes were imaged using confocal microscopy. The COS coated NLC were seen to adhere more around the ocular surface than the uncoated NLC during the 4-h study. The improved ocular retention for COS-NLC reflected on the content of Etoposide within the eye, which showed a higher concentration of Etoposide, as compared to the uncoated NLC. The NLC was also assessed for any ocular irritancy in rabbits and repeat dose toxicity in rats and found to be relatively non-irritant and non-toxic as compared to appropriate controls. Thus, the study asserts that to achieve higher concentration of therapeutics within the eye, the formulations like NLC are not just required to be permeating but also retentive on the surface of the eye to achieve appreciable concentrations.

Liposils: An effective strategy for stabilizing Paclitaxel loaded liposomes by surface coating with silica.

The present work aims at improving stability of paclitaxel (PTX) loaded liposomes by its coating with silica on the surface by a modified sol-gel method. Effect of various components of liposomes such as phosphatidylcholine to cholesterol ratio (PC:CH), PTX and stearylamine on entrapment efficiency (% EE) and particle size were systematically investigated and optimized using central composite design on Design-Expert®. The optimized liposomes were utilized as a template for silica coating to prepare surface coated PTX liposils. Physical stability of liposomes and liposils was evaluated with Triton X-100 and the results indicated that liposils were much more stable as compared to liposomes and the same has been reiterated in stability study performed over 6 months. In vitro cytotoxicity study on B16F10 tumor cells showed cytotoxicity of PTX liposils was not significantly different than PTX liposomes, whereas both were less cytotoxic as compared to the commercial Taxol®. In vivo pharmacokinetics on rats, exhibited increased T1/2 of liposils when compared to liposomes and Taxol®, thus releasing the drug over a longer duration. The enhanced physicochemical stability as well as controlled release of PTX in liposils developed in this study could be an effective alternative to Taxol® and PTX liposomes.

Development and Evaluation of Chitosan Microparticles Based Dry Powder Inhalation Formulations of Rifampicin and Rifabutin.

BACKGROUND: The lung is the primary entry site and target for Mycobacterium tuberculosis; more than 80% of the cases reported worldwide are of pulmonary tuberculosis. Hence, direct delivery of anti-tubercular drugs to the lung would be beneficial in reducing both, the dose required, as well as the duration of therapy for pulmonary tuberculosis. In the present study, microsphere-based dry powder inhalation systems of the anti-tubercular drugs, rifampicin and rifabutin, were developed and evaluated, with a view to achieve localized and targeted delivery of these drugs to the lung. METHODS: The drug-loaded chitosan microparticles were prepared by an ionic gelation method, followed by spray-drying to obtain respirable particles. The microparticles were evaluated for particle size and drug release. The drug-loaded microparticles were then adsorbed onto an inhalable lactose carrier and characterized for in vitro lung deposition on an Andersen Cascade Impactor (ACI) followed by in vitro uptake study in U937 human macrophage cell lines. In vivo toxicity of the developed formulations was evaluated using Sprague Dawley rats. RESULTS: Both rifampicin and rifabutin-loaded microparticles had MMAD close to 5 µm and FPF values of 21.46% and 29.97%, respectively. In vitro release study in simulated lung fluid pH 7.4 showed sustained release for 12 hours for rifampicin microparticles and up to 96 hours for rifabutin microparticles, the release being dependent on both swelling of the polymer and solubility of the drugs in the dissolution medium. In vitro uptake studies in U937 human macrophage cell line suggested that microparticles were internalized within the macrophages. In vivo acute toxicity study of the microparticles in Sprague Dawley rats revealed no significant evidence for local adverse effects. CONCLUSION: Thus, spray-dried microparticles of the anti-tubercular drugs, rifampicin and rifabutin, could prove to be an improved, targeted, and efficient system for treatment of tuberculosis.