Chretien C, Chaumeil J C
R&D Galénique, AGEPS, Faculté de Sciences Pharmaceutiques et Biologiques, Université Paris 5, 4 avenue de l'Observatoire, 75270 Paris cedex 06, France.
Int J Pharm. 2005 Nov 4;304(1-2):18-28. doi: 10.1016/j.ijpharm.2005.06.030. Epub 2005 Sep 13.
Macroporous microspheres were impregnated with calcium alginate to encapsulate fluorescein isothiocyanate-labeled dextran (FITC-dextran) and control its release. The detailed study of the impregnation process lead to its optimization: the quantity of alginate in the impregnated microspheres and the FITC-dextran encapsulation efficiency were increased. FITC-dextran diffused out of the impregnated microspheres in a slow rate in deionised water, while in presence of sodium ions, its release rate was increased as a consequence of the progressive swelling and erosion of calcium alginate. Release studies from different formulations of impregnated microspheres were performed in a continuous flow apparatus. The release profiles were composed of a slow release phase explained by the progressive erosion of calcium alginate and a faster release phase related to eroded impregnated microspheres. Therefore, the delayed release by microspheres induced by impregnation would permit the delivery of their payload at the vascular occlusion site, limit the amount of drug lost in the systemic circulation and improve the therapy.
将大孔微球用海藻酸钙浸渍,以包封异硫氰酸荧光素标记的葡聚糖(FITC - 葡聚糖)并控制其释放。对浸渍过程的详细研究实现了其优化:浸渍微球中海藻酸盐的量以及FITC - 葡聚糖的包封效率均有所提高。FITC - 葡聚糖在去离子水中以缓慢的速率从浸渍微球中扩散出来,而在存在钠离子的情况下,由于海藻酸钙的逐渐溶胀和侵蚀,其释放速率增加。在连续流动装置中对不同配方的浸渍微球进行了释放研究。释放曲线由海藻酸钙逐渐侵蚀所解释的缓慢释放阶段和与侵蚀的浸渍微球相关的较快释放阶段组成。因此,通过浸渍诱导微球实现的延迟释放将允许在血管闭塞部位递送其负载物,限制在体循环中损失的药物量并改善治疗效果。