Hybrid nanospheres and vesicles based on pectin as drug carriers.

A novel strategy was developed to prepare nanospheres and vesicles as drug carriers. The drug-loaded pectin nanospheres and vesicles were fabricated in aqueous media containing Ca2+ and CO3(2-) ions under very mild conditions, which did not involve any surfactant. Through adjusting the preparation conditions, nanosized drug delivery systems with diverse morphologies, that is, nanospheres and vesicles, could be obtained. This technique could offer good control over the morphology and the size of nanospheres and vesicles. The morphologies of the aggregates were observed by environmental scanning electron microscopy and transmission electron microscopy. 5-Fluorouracil (5-FU), an antineoplastic drug, was encapsulated in the nanospheres and vesicles, and the in vitro drug release at different pH values was investigated. With the presence of Ca2+ and CO3(2-) ions in the pectin-based nanospheres/vesicles, the release of the low molecular weight drug could be effectively sustained from the highly hydrolyzed polysaccharide-based drug delivery systems.

Sustained release of antineoplastic drugs from chitosan-reinforced alginate microparticle drug delivery systems.

Alginate based microparticle drug delivery systems were prepared for the sustained release of antineoplastic drugs. Two drugs, 5-fluorouracil (5-FU) and tegafur, were encapsulated into the microparticles. The drug loaded microparticles were fabricated using a very convenient method under very mild conditions, i.e., directly shredding the drug loaded beads into microparticles in a commercial food processor. The mean sizes of the obtained microparticles were between 100 and 200 microm. To effectively sustain the drug release, alginate microparticles were reinforced by chitosan during gelation. The drug release from the chitosan-reinforced alginate microparticles was obviously slower than that from the unreinforced microparticles. The effect of the reinforcement conditions on the drug release property of the microparticles was studied, and the optimized concentration of chitosan solution for reinforcement was identified. The effects of drug feeding concentration and pH value of the release medium on the drug release were investigated.