PURPOSE: To improve chemotherapy protocols of lymphoid malignancies, by using polymeric and lipid microparticles as controlled delivery systems of dexamethasone, part of all combined chemotherapy protocols for its strong-inducing effect on malignant lymphoblasts. METHODS: Polymeric microparticles were prepared by the oil-in-water-emulsion cosolvent evaporation method, andlipid microparticles by spray drying. Their cytotoxic effects on GC-sensitive PC12 cells and GC-resistant PC3 cells were characterized by cell proliferation and apoptosis assays. RESULTS: Both elaboration methods rendered optimal-sized microparticles for parenteral administration with high drug loading. In vitro assays showed sustained dexamethasone release from polymeric microparticles over a month, whereas 100% dexamethasone release from lipid microparticles was achieved within 24 h. Similar PC12 cell death to that obtained with dexamethasone solution administered every 48 h was achieved with dexamethasone polymeric microparticles in 26-days assays. Dexamethasone solution and loaded polymeric microparticles induced apoptosis around 15.8 and 19.9%, respectively, after 2 days of incubation. Lipid microparticles increased further apoptosis induction in PC12 cells and, unlike dexamethasone solution and polymeric microparticles, showed antiproliferative effects on PC3 cells. CONCLUSIONS: Dexamethasone polymeric microparticles constitute an alternative to current dexamethasone administration systems in combined chemotherapy, whereas dexamethasone lipid microparticles represent a potential tool to revert glucocorticoid resistance.
PURPOSE: To improve chemotherapy protocols of lymphoid malignancies, by using polymeric and lipid microparticles as controlled delivery systems of dexamethasone, part of all combined chemotherapy protocols for its strong-inducing effect on malignant lymphoblasts. METHODS: Polymeric microparticles were prepared by the oil-in-water-emulsion cosolvent evaporation method, andlipid microparticles by spray drying. Their cytotoxic effects on GC-sensitive PC12 cells and GC-resistant PC3 cells were characterized by cell proliferation and apoptosis assays. RESULTS: Both elaboration methods rendered optimal-sized microparticles for parenteral administration with high drug loading. In vitro assays showed sustained dexamethasone release from polymeric microparticles over a month, whereas 100% dexamethasone release from lipid microparticles was achieved within 24 h. Similar PC12 cell death to that obtained with dexamethasone solution administered every 48 h was achieved with dexamethasone polymeric microparticles in 26-days assays. Dexamethasone solution and loaded polymeric microparticles induced apoptosis around 15.8 and 19.9%, respectively, after 2 days of incubation. Lipid microparticles increased further apoptosis induction in PC12 cells and, unlike dexamethasone solution and polymeric microparticles, showed antiproliferative effects on PC3 cells. CONCLUSIONS:Dexamethasone polymeric microparticles constitute an alternative to current dexamethasone administration systems in combined chemotherapy, whereas dexamethasonelipid microparticles represent a potential tool to revert glucocorticoid resistance.
Authors: J Annelies E Polman; Jennifer E Welten; Danny S Bosch; Robert T de Jonge; Judit Balog; Silvère M van der Maarel; E Ronald de Kloet; Nicole A Datson Journal: BMC Neurosci Date: 2012-10-03 Impact factor: 3.288