An experimental study of the antitumour effect of bleomycin hydrochloride microcapsules

The encapsulation of bleomycin within chitosan based polymeric vesicles does not alter its biodistribution

Polymeric vesicles have recently been developed from an amphiphilic chitosan derivative--palmitoyl glycol chitosan. Their potential as a drug delivery system was evaluated using the anti-cancer compound bleomycin as a model drug. Palmitoyl glycol chitosan (GCP41) was synthesised by conjugation of palmitoyl groups to glycol chitosan. Bleomycin-containing vesicles (669 nm diameter) were prepared from a mixture of GCP41 and cholesterol by remote loading. The vesicles were imaged by freeze-fracture electron microscopy and their in-vitro stability tested. Incubation of the larger vesicles with plasma in-vitro led to a reduction of mean size by 49%, a reaction not seen with control sorbitan monostearate niosomes (215 nm in size). They also showed a higher initial drug release (1 h), but GCP41 and sorbitan monostearate vesicles retained 62% and 63% of the encapsulated drug after 24h, respectively. The biodistribution of smaller vesicles (290 nm) prepared by extrusion through a 200-nm filter was also studied in male Balb/c mice. Encapsulation of bleomycin into polymeric vesicles did not significantly alter the pharmacokinetics of biodistribution of bleomycin in male Balb/c mice although plasma and kidney levels were slightly increased. It is concluded that the extruded GCP41 vesicles break down in plasma in-vivo and hence are unlikely to offer any therapeutic advantage over the free drug.

Tumoricidal effect of controlled-release polymeric needle devices containing adriamycin HCl in tumor-bearing mice

Controlled-release polymeric needle devices containing adriamycin HCL (ADH) were investigated by an in vitro dissolution study in normal saline solution and an in vivo antitumor activity in C3H mice bearing mammary carcinoma and nude mice bearing brain tumor. HPMC was used as a release rate regulator. The ADH released from needle devices was controlled by the types of polymer used and the addition of HPMC. EVA needle devices exhibit a zero order release behavior better than that of PLA needle devices. Tumor growth was markedly inhibited by treatment with needle devices after locally inserted into the solid tumor. The rank of antitumor activity of the needle devices is EVA greater than PLA greater than EVA-HPMC greater than PLA-HPMC. No significant changes in body weight of mice after treatment were found in treated groups as compared to controlled groups. The preliminary results of our study suggest that needle device dosage form shows a controlled release behavior and may be applicable as a drug carrier for delivery of antitumor drug in cancer chemotherapy.