In Vivo Behaviour of Homologous Urea‐Soluble 131 I‐Fibrin and 125 I‐Fibrinogen in Rabbits: the Effect of Fibrinolysis Inhibition

S ummary . The in vivo behaviour of urea‐soluble fibrin monomer (FM) was compared with that of fibrinogen in rabbits. Purified rabbit 125 I‐fibrinogen was injected into 36 unanaesthetized rabbits. Three days later the rabbits received either purified rabbit 131 I‐FM 1 mg/kg body weight, which corresponds to c 1% of the circulating plasma fibrinogen pool or 131 I‐fibrinogen, or buffered urea only. The distribution volume of FM was 43.4±6.9 ml/kg and of fibrinogen 43.5±7.7 ml/kg (mean±SD). The elimination curve of urea‐soluble FM as represented by the clottable 131 I‐radioactivity, plotted on a semi‐logarithmic paper, consisted of an initial steep decay within the first 6 h and a slow flattening of the slope 6 to 24 h after injection of FM. Although a terminal single‐exponential slope, as observed in fibrinogen elimination, could not be computed for the 24 h following FM injection the mean half‐life time of the last segment of the clottable‐radioactivity curve, between 12 h and 24 h, was 12 h. Within 24 h a mean of 83.5% of the injected FM were removed from the circulating blood. The elimination characteristics of fibrinogen were not influenced by the injected FM. Control experiments showed that buffered 3.0 M urea, the solvent of FM, does not influence distribution volume and elimination of 125 I‐fibrinogen. The distribution of 131 I as well as 125 I‐radioactivities in organs representing FM and fibrinogen respectively did not differ from each other. Elevated levels of 131 I‐radioactivity, however, were found in the urine after FM injection suggesting an accelerated elimination of FM in comparison to fibrinogen. Fibrinolysis inhibition with high doses of aprotinin did not significantly reduce the urinary excretion of 131 I‐radioactivity representing breakdown of FM. Furthermore, inhibition of the fibrinolytic system had no influence on the elimination characteristics of either fibrinogen or FM. In order to explain the results obtained in this study the following theory is proposed. Intravenously injected FM forms complexes with fibrinogen and fibrinolytic degradation products. The complexes continuously increase in size until they dissociate into fibrin oligomers and carrier proteins. The oligomers are eliminated whereas the carrier proteins recycle.