Formulation and characterisation of primaquine loaded liposomes prepared by a pH gradient using experimental design.

The effect of different formulation factors (lipid type, cholesterol, charge, internal buffer capacity, drug-to-lipid incubation ratio) on the encapsulation efficiency and size of primaquine liposomes (SUV's) in response to a pH gradient was investigated by a fractional factorial screen ing design. Three of the factors (charge, internal buffer capacity, drug -to-lipid incubation ratio) were further studied in a Box--Behnken optimisation design. The lipid type was the most important parameter followed by the drug-to-lipid incubation ratio, buffer capacity, cholesterol and charge. Several of the interactions wer e important. In the optimisation design a robust region with high encapsulation efficiency (>95%) was obtained for DSPC: 33.33 mol% cholesterol-liposomes at high internal citrate concentration (200 mM) by maintaining the drug-to-lipid incubation ratio below 0.15:1 (mol:mol) and varying the charge incorporation between 2 and 10%. In order to achieve long-term stability and sterility, the liposomes were lyophilised followed by gamma irradiation. The pH gradient was maintained during this treatment with little chemical degradation of the substances. The final preparation consisted of three separate vials with lyophilised liposomes, solid state primaquine and hydration medium.

Toxicity of gamma irradiated liposomes. 1. In vitro interactions with blood components.

Gamma irradiation is a potential technique for sterilisation of liposome suspensions. Unfortunately, gamma irradiation may result in chemical degradation of the phospholipids and the toxicological aspects have to be considered. The effects of liposome composition and gamma irradiation on the interactions of the liposomes with the hemostatic mechanisms (hemolysis, aggregation and coagulation) were studied. Non-irradiated liposome suspensions showed no hemolysis of erythrocytes. After irradiation, up to 3.1% hemolysis was measured. Least hemolysis was observed with irradiated liposomes composed of unsaturated or charged phospholipids. The negatively charged DSPG-liposomes (both non-irradiated and irradiated) induced aggregation of platelets as observed by the spectrophotometric method. However, no aggregates were seen in the microscope or measured by the aggregometer. Negatively charged liposomes also affected the coagulation cascade where prolonged coagulation times were measured. Irradiation of the liposome suspensions resulted in even longer coagulation times. The prolonged coagulation times correlated to some extent with the measured binding and depletion of calcium from plasma by the negatively charged liposomes.

Toxicity of gamma irradiated liposomes. 2. In vitro effects on cells in culture.

In this study, the effects of liposome composition and gamma irradiation on their interactions with cell cultures were studied. The cytotoxicity test and the growth inhibition test clearly revealed toxic effects of liposomes composed of unsaturated phospholipids and gamma irradiation of these preparations enhanced their toxic effects. The murine fibroblast cell-line L 929 was less affected compared to the macrophage cell-line RAW 264 with a higher endocytic capacity. On the other hand, both gamma irradiated and non-irradiated liposomes composed of saturated phospholipids were non-toxic for the cells and irradiation did not affect their drug delivery properties. Hence, it seems that gamma irradiation is appropriate for sterilisation of these liposomes.