Kinetic characterization of a saturable pathway for rapid clearance of circulating fibrin monomer.

The mechanism of clearance of circulating fibrin monomer was investigated in rabbits through (1) study of decay in plasma concentrations of 125I-labeled monomers with variant fibrinopeptide content and (2) concurrent analysis of decay of the monomers relative to coinjected 131I-fibrinogen. Under the conditions employed, essentially all of the fibrin became distributed in a soluble form in plasma and decayed independently of the coinjected fibrinogen. Among the species of fibrin studied, monomer lacking fibrinopeptide A alone (alpha-fibrin) underwent very rapid clearance by a saturable mechanism that was not evident in relatively sluggish clearance of monomer lacking either fibrinopeptide B alone (beta-fibrin) or both fibrinopeptides A and B (alpha beta-fibrin). Decay of alpha-fibrin conformed with a kinetic mechanism involving first-order permeation of the fibrin into extravascular space at a rate equivalent to that of permeation of fibrinogen; unlike fibrinogen, however, the alpha-fibrin underwent immediate absorption in parallel with permeation (t1/2 = 2.6 hours) at doses below an apparent saturating level of 3 mg/kg. At doses near the absorptive limit, the uptake accompanying permeation diminished as in a second-order kinetic mechanism, and at very high doses the plasma decay of the alpha-fibrin approached that of fibrinogen. The beta- and alpha beta-fibrins also permeated extravascular space in parallel with fibrinogen, but absorption proceeded sluggishly (t1/2 = 11 and 16 hours, respectively) at low doses and did not change with increasing dose. The uniquely rapid and saturable clearance of alpha-fibrin is suggested to involve uptake through the fibrin aggregation site that is blocked by fibrinopeptide A in fibrinogen and beta-fibrin and by tight binding to fibrinogen in soluble complexes formed by alpha beta-fibrin. A corollary of this hypothesis is that rapid uptake depends on dissociability of fibrin complexes for access to the aggregation site, a mechanism that is just the converse of uptake through aggregation.