RESUMEN
Factor X (FX)-deficiency is a rare bleeding disorder manifesting a bleeding tendency caused by low FX activity levels. We aimed to explore the use of fitusiran (an investigational siRNA that silences antithrombin expression) to increase thrombin generation and the in vivo hemostatic potential under conditions of FX-deficiency. We therefore developed a novel model of inducible FX-deficiency, generating mice expressing <1% FX activity and antigen (f10low-mice). Compared to control f10WT-mice, f10low-mice had 6- and 4-fold prolonged clotting times in Prothrombin Time- and activated Partial Prothrombin Time-assays, respectively (p<0.001). Thrombin generation was severely reduced, irrespective whether tissue factor or factor XIa was used as initiator. In vivo analysis revealed near-absent thrombus formation in a laser-induced vessel injury-model. Furthermore, in two distinct bleeding models, f10low-mice displayed an increased bleeding tendency compared to f10WT-mice. In the tail-clip assay blood loss was increased from 12±16 microliter to 590±335 microliter (p<0.0001). In the saphenous vein puncture (SVP)-model, the number of clots generated was reduced from 19±5 clots/30 min for f10WT-mice to 2±2 clots/30 min (p<0.0001) for f10low-mice. In both models, bleeding was corrected upon infusion of purified FX. Treatment of f10low-mice with fitusiran (2x10 mg/kg at one-week interval) resulted in 17±6% residual antithrombin activity and increased thrombin generation (4-fold and 2-3-fold increase in endogenous thrombin potential and thrombin peak, respectively). In the SVP-model, the number of clots was increased to 8±6 clots/30 min (p=0.0029). Altogether, we demonstrate that reduction of antithrombin levels is associated with improved hemostatic activity under conditions of FX-deficiency.
RESUMEN
Recombinant factor VIII (rFVIII), rFVIIIFc and emicizumab are established treatment options in the management of hemophilia A. Each has its unique mode of action, which can influence thrombin generation kinetics and therefore also the kinetics of thrombin substrates. Such differences may potentially result in clots with different structural and physical properties. A starting observation of incomplete wound closure in a patient on emicizumab-prophylaxis led us employ a relevant mouse model in which we noticed that emicizumab-induced clots appeared less stable compared to FVIII-induced clots. We thus analyzed fibrin formation in vitro and in vivo. In vitro fibrin formation was faster and more abundant in the presence of emicizumab compared to rFVIII/rFVIIIFc. Furthermore, the time-interval between the initiation of fibrin formation and factor XIII activation was twice as long for emicizumab compared to rFVIII/rFVIIIFc. Scanning-electron microscopy and immunofluorescent spinning-disk confocal-microscopy of in vivo generated clots confirmed increased fibrin formation in the presence of emicizumab. Unexpectedly, we also detected a different morphology between rFVIII/rFVIIIFc- and emicizumab-induced clots. Contrary to the regular fibrin-mesh obtained with rFVIII/rFVIIIFc, fibrin-fibers appeared to be fused into large patches upon emicizumabtreatment. Moreover, fewer red blood cells were detected in regions where these fibrin patches were present. The presence of highly-dense fibrin-structures associated with a diffuse fiber-structure in emicizumab-induced clots was also observed when using superresolution imaging. We hypothesize that the modified kinetics of thrombin, fibrin and factor XIIIa generation contribute to differences in structural and physical properties between clots formed in the presence of FVIII or emicizumab.
