The degradation of liposomes in blood circulation is important in regulating the releasing rate of encapsulated compounds. In this study, the effect of liposome size--one of the principal determining factors in liposome disposition--on their degradation in serum/blood was evaluated quantitatively both in vitro and in vivo. In the in vitro study, the time courses of the degradation of liposomes in fresh rat serum were measured continuously using 5(6)-carboxyfluorescein (CF) as an aqueous phase marker and were described by the kinetic model with the lag time (tau), first order degradation rate constant (k), and the maximum degradation (alpha). Both k and alpha increased with the increase of liposome size, which indicated a higher affinity of larger liposomes for complement activation. In the in vivo study, the degradation of liposomes was evaluated sensitively by a first order degradation rate constant (kd) in blood circulation. The kd was obtained by kinetically modeling the liposome degradation in vivo using 3H-inulin as an aqueous phase marker. The size dependent kd correlated well with the hepatic uptake clearance, which suggests an underlying complement activation mechanism common to both degradation and hepatic uptake of liposomes. There was a good correlation in the degradation rate constant between in vitro and in vivo trials. These kinetic analyses validate the quantitative evaluation of liposome degradation in blood circulation and provide a useful way to predict the degradation of liposomes in vivo from in vitro experiments.
The purpose of this study is to propose a new method for quantitative evaluation of liposome degradation in serum. The time course of liposome degradation in rat serum was monitored continuously, using 6(5)-carboxyfluorescein as an aqueous phase marker. The degradation curves exhibited three characteristic phases: lag time, degradation, and plateau. This curve was described by a kinetic model with three parameters: lag time (tau), first-order degradation rate constant (k), and maximum degradation (alpha). The rate and extent of the degradation of liposomes were evaluated separately in terms of k and alpha, respectively. The effects of size and concentration of liposomes on their degradation kinetics were examined using this method. Both k and alpha increased with increasing liposomal size. The increased affinity of larger liposomes for complement was suggested to increase both k and alpha. On the other hand, alpha decreased with increasing liposomal concentration without altering k. The decreased extent of degradation was considered to result from the depletion of complement components. There was no significant effect of size and concentration of liposomes on tau. Quantitative evaluation of the rate and extent of degradation of liposomes will provide deeper insights into the interaction between liposomes and serum components, and basic information on liposomes as potential drug carriers.
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