In vitro targeting of acoustically reflective immunoliposomes to fibrin under various flow conditions.

We have previously demonstrated the development of acoustically reflective liposomes as a novel ultrasound contrast agent, that can be conjugated to antibodies for site specific acoustic enhancement of pathologically altered vascular tissue. The liposomes are echogenic due to the lipid composition, without gas entrapment, and have a size of less than one micron (Alkan-Onyuksel et al., 1996). When conjugated to anti-fibrinogen antibodies, the liposomes have the ability to attach to fibrin coated surfaces and thrombi in vitro as demonstrated by scanning electron microscopy and ultrasound imaging (Demos et al., 1997a). Anti-fibrinogen liposomes were shown to attach to fibrous atheroma and thrombi in a Yucatan miniswine model of induced atherosclerosis whereas liposomes conjugated to anti-intercellular adhesion molecule-1 (anti-ICAM-1) were demonstrated to target early stage atherosclerotic plaques (Demos et al., 1997b). The purpose of this study is to evaluate the binding characteristics of anti-fibrinogen liposomes in vitro under a variety of flow conditions in order to optimize the targeting ability of the immunoliposomes. Radiolabeled anti-fibrinogen liposomes were applied to fibrin coated filter paper and placed in a flow circuit under controlled flow conditions. Flow conditions were altered to study the effects of different shear stresses, temperature, plasma flow and pulsatile flow on the retention of liposomes to fibrin after set time periods. The retention of liposomes conjugated to polyclonal and monoclonal antibodies as well as Fab fragments made from monoclonal antibodies were compared. The binding characteristics of liposomes conjugated to different quantities of polyclonal antibodies were analyzed. At physiological shear stress of 1.5 N/m2 (15 dynes/cm2) over 70% of the liposomes remained attached to fibrin after two hours. A smaller and greater portion of the liposomes remained attached at higher and lower shear stresses respectively. Plasma components and temperature had no effect on liposomal retention whereas pulsatile flow resulted in a slight reduction in binding. Monoclonal antibodies showed a slight trend of reduced retention to fibrin over time as compared with polyclonal antibodies and Fab fragments. The quantity of antibody conjugated to the liposomes plays a role in liposome retention as demonstrated by the reduction in liposome retention caused by reducing the quantity of antibody conjugated to the liposomes. Anti-fibrinogen liposomes were retained to the fibrin surface to a large extent under all flow conditions likely to occur in vivo and therefore can provide site specific ultrasound contrast for a long enough time period to allow for imaging after injection.