Abstract
Coagulation kinetics are well established for purified blood proteases or human plasma clotting isotropically. However, less is known about thrombin generation kinetics and transport within blood clots formed under hemodynamic flow. Using microfluidic perfusion (wall shear rate, 200 s-1) of corn trypsin inhibitor-treated whole blood over a 250-μm long patch of type I fibrillar collagen/lipidated tissue factor (TF; ∼1 TF molecule/μm2), we measured thrombin released from clots using thrombin-antithrombin immunoassay. The majority (>85%) of generated thrombin was captured by intrathrombus fibrin as thrombin-antithrombin was largely undetectable in the effluent unless Gly-Pro-Arg-Pro (GPRP) was added to block fibrin polymerization. With GPRP present, the flux of thrombin increased to ∼0.5 × 10-12 nmol/μm2-s over the first 500 s of perfusion and then further increased by ∼2-3-fold over the next 300 s. The increased thrombin flux after 500 s was blocked by anti-FXIa antibody (O1A6), consistent with thrombin-feedback activation of FXI. Over the first 500 s, ∼92,000 molecules of thrombin were generated per surface TF molecule for the 250-μm-long coating. A single layer of platelets (obtained with αIIbβ3 antagonism preventing continued platelet deposition) was largely sufficient for thrombin production. Also, the overall thrombin-generating potential of a 1000-μm-long coating became less efficient on a per μm2 basis, likely due to distal boundary layer depletion of platelets. Overall, thrombin is robustly generated within clots by the extrinsic pathway followed by late-stage FXIa contributions, with fibrin localizing thrombin via its antithrombin-I activity as a potentially self-limiting hemostatic mechanism.
Highlights
Human thrombin is a multifunctional protease central to coagulation by its enzymatic cleavage of platelet PAR1 and PAR4 receptors [1], cleavage of fibrinogen to fibrin monomer [2], generation of Factor XIIIa (FXIIIa)2 [3, 4], and feedback
A wall thrombin flux of 10Ϫ11 nmol/m2-s is required for platelet-free plasma to form a three-dimensional fibrin network [44], which is the fibrin structure that is usually observed in whole blood thrombi formed on the surface with collagen and tissue factor (TF) at venous shear rates [5]
Within 1 s, the thrombin concentration was high over the entrance due to the release of soluble thrombin from the bottom boundary; there was no significant thrombin yet reaching the outlet
Summary
To our knowledge there has been no direct quantitative measurement of thrombin flux from a growing thrombus under hemodynamic flow This lack of measurement may be due to the limited sensitivity of immunoassays to detect released thrombin in the stable complex of thrombin-antithrombin (TAT) as released thrombin would be severely diluted in macroscopic flow systems with ml/min-scale perfusion. We measure thrombin flux from TF bearing collagen surface and aggregated platelets at a venous shear rate in a human whole blood microfluidic thrombosis assay by collecting effluent at the outlet of the microfluidic system and subsequently measuring TAT complex concentration with enzyme linked immunosorbent assay (ELISA)
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