Hemostatic potential of recombinant von Willebrand factor and standard or pegylated extended half-life recombinant factor VIII on thrombus formation under high shear flow.

BACKGROUND: Von Willebrand factor (VWF) and factor VIII (FVIII) complex play a pivotal role in hemostasis. A deficiency or defect of VWF causes von Willebrand disease (VWD). Recombinant (r)VWF product has proved to be effective for hemostatic treatment of VWD, but limited information is available on their role in moderating thrombus formation under flow condition. We aimed to assess thrombus formation in the presence of rVWF combined with rFVIII or pegylated-extended half-life rFVIII (peg-EHL-rFVIII) in VWD whole blood under high shear flow. METHODS: Perfusion chamber experiments under high shear (2,500 s- 1) combined with immunostaining were performed using patient's whole blood with type 1 VWD, mixed with rVWF (Vonvendi®; 1.6 IU/mL), rFVIII or peg-EHL-rFVIII (Advate® or Adynovate®; 1.0 IU/mL), or both. Similar experiments were also conducted with clinical medical devices (T-TAS®). RESULTS: The addition of rFVIII did not augment thrombus formation assessed by surface coverage (SC) and thrombus height (TH), whereas rVWF enhanced these parameters (SC 19.1 ± 1.1% vs. 30.1 ± 4.1%, TH 2.2 ± 0.14 µm vs. 3.6 ± 0.40 µm, respectively). The co-presence of rVWF/rFVIII was comparable to plasma-derived VWF/FVIII (Confact®, VWF:FVIII ratio = 1.6:1.0) for increasing thrombogenicity in SC (32.5 ± 4.3% vs. 38.7 ± 5.5%) and in TH (5.0 ± 0.60 µm vs. 5.5 ± 0.64 µm), respectively. The pre-incubation time with rVWF and rFVIII appeared to have a little effect on the size of thrombus. Peg-EHL-rFVIII mediated thrombus formation to similar extent as rFVIII in the co-presence of rVWF. Similar results were obtained even with T-TAS. Immunostaining demonstrated that rFVIII and peg-EHL-rFVIII were similarly co-localized with rVWF in formed thrombi, indicating that pegylation did not interfere with molecular complexes. CONCLUSION: The effects of high-level rVWF and peg-EHL-rFVIII on thrombus formation were comparable to conventional therapeutic products in a patient's whole blood with VWD under high shear flow.

Emicizumab enhances thrombus formation in vitro under high shear flow conditions in whole blood from patients with type 1 and type 3 von Willebrand disease.

INTRODUCTION: Type 1 and type 3 von Willebrand disease (VWD) are caused by partial and complete, quantitative deficiency of von Willebrand factor (VWF), respectively, and factor (F)VIII/VWF complex concentrates are used for haemostatic treatment. Emicizumab, mimics activated FVIII, reduces bleeding in haemophilia A patients. The effects of emicizumab on haemostasis in both types of VWD remain to be fully established, however. AIM: To examine the effects of emicizumab on thrombogenesis in type 1 and type 3 VWD. PATIENTS/METHODS: Perfusion chamber experiments under high shear conditions (2500 s-1 ) combined with immunostaining were performed using whole blood samples from patients with type 1 (VWF:Ag 25 U/dl) and type 3 VWD (<1.0 U/dl). RESULTS: The addition of FVIII (1 U/ml) to type 1 blood did not affect thrombus formation, whilst supplementation with VWF (1.6 U/ml) or FVIII/VWF (1 U/ml/1.6 U/ml) enhanced thrombogenesis to a similar extent. FVIII/VWF promoted thrombus formation significantly more than VWF alone, however, in type 3 blood. Emicizumab (100 µg/ml) augmented thrombus formation in type 3 blood compared to FVIII, and this potency seemed to be somewhat greater than that of VWF. Surface coverage of formed thrombus in type 3 VWD was less than that in type 1 VWD, but thrombus height was comparable in both. The addition of emicizumab to type 3 blood enhanced thrombin generation and fibrin formation compared to control IgG. CONCLUSION: Emicizumab promoted mechanisms of thrombus formation in vitro in type 3 and type 1 VWD, suggesting the possibility of alternative therapeutic protocols in these patients.

Emicizumab improves thrombus formation of type 2A von willebrand disease under high shear condition.

INTRODUCTION: Type 2A von Willebrand disease (VWD) is common in type-2 group caused by qualitative deficiency of von Willebrand factor (VWF). Emicizumab is a bispecific antibody that mimics activated factor VIII (FVIIIa) cofactor function, and emicizumab prophylaxis substantially reduces bleeding in patients with haemophilia A. It is unknown whether emicizumab affects thrombus formation in type 2A VWD characterized by not only low FVIII levels but also the impaired platelet adhesion and aggregation. AIM: To examine the coagulant potential of emicizumab in type 2A VWD. PATIENTS/METHODS: Perfusion chamber experiments combined with immunostaining were performed using whole blood from 5 patients with type 2A VWD under high shear condition (2500 s-1 ). RESULTS: The addition of FVIII to type 2A VWD whole blood did not augment thrombus formation, whilst supplementation with VWF or FVIII/VWF enhanced. FVIII appeared to contribute to thrombus height rather than surface coverage. The addition of emicizumab enhanced thrombus formation in type 2A VWD compared with FVIII, but this potency was less than the presence of VWF. The effect on thrombus formation mediated by emicizumab appeared to be more rapid than that by FVIII for non-requirement of activation step of FVIII, whilst that by FVIII showed more impact on thrombus formation at the late phase. CONCLUSION: Emicizumab-induced enhancing effects of thrombus formation, independent on VWF, may be useful as an alternative therapy for type 2A VWD patients. These results supported a critical role for the FVIII-VWF complex facilitating thrombus formation under high shear.

Factor (F)VIII/VIIa enhances global haemostatic function in the co-presence of bypassing agents and FVIII among patients with haemophilia A with inhibitor.

Bypassing therapy is essential for the haemostatic management of patients with haemophilia A with inhibitor (PWHA-inh), but the therapeutic effects are inconsistent. We previously reported that activated prothrombin complex concentrates (aPCC) activated factor (F)VIIIin vitro, and was mediated mainly by the activated FVII (FVIIa) contained in aPCC. We have extended those studies to assess global coagulation in whole blood from 18 PWHA-inh in the co-presence of aPCC and FVIII using Ca2+ -triggered rotational thromboelastometry. The clot times (CTs) in the presence of both aPCC (0·05 iu/ml) and recombinant (r)FVIII (1 iu/ml) ex vivo were shortened compared to the aPCC alone (P < 0·01). These enhancing effects of rFVIII were observed, irrespective of recognizing inhibitor epitopes; however, the clot formation time and 'α'-angle were not significantly different. In samples from 7 PWHA-inh post-infusion of aPCC (70-80 iu/kg), only the CTs were shortened in the presence of rFVIIIex vivo compared to its absence (P < 0·05), indicating that the enhanced activity centred on the initiation phase of coagulation. Furthermore, experiments in the co-presence of rFVIIa and rFVIII demonstrated that FVIII accelerated only the CTs. We concluded that FVIII/FVIIa-related coagulation mechanism enhanced global haemostatic function by the co-presence of bypassing agents and FVIII in PWHA-inh.

Analysis of the role of von Willebrand factor, platelet glycoprotein VI-, and α2ß1-mediated collagen binding in thrombus formation.

Rare missense mutations in the von Willebrand factor (VWF) A3 domain that disrupt collagen binding have been found in patients with a mild bleeding phenotype. However, the analysis of these aberrant VWF-collagen interactions has been limited. Here, we have developed mouse models of collagen-binding mutants and analyzed the function of the A3 domain using comprehensive in vitro and in vivo approaches. Five loss-of-function (p.S1731T, p.W1745C, p.S1783A, p.H1786D, A3 deletion) and 1 gain-of-function (p.L1757A) variants were generated in the mouse VWF complementary DNA. The results of these various assays were consistent, although the magnitude of the effects were different: the gain-of-function (p.L1757A) variant showed consistent enhanced collagen binding whereas the loss-of-function mutants showed variable degrees of functional deficit. We further analyzed the impact of direct platelet-collagen binding by blocking glycoprotein VI (GPVI) and integrin α2ß1 in our ferric chloride murine thrombosis model. The inhibition of GPVI demonstrated a comparable functional defect in thrombosis formation to the VWF(-/-) mice whereas α2ß1 inhibition demonstrated a milder bleeding phenotype. Furthermore, a delayed and markedly reduced thrombogenic response was still evident in VWF(-/-), GPVI, and α2ß1 blocked animals, suggesting that alternative primary hemostatic mechanisms can partially rescue the bleeding phenotype associated with these defects.

Emicizumab Augments Thrombus Formation in Whole Blood from Patients with Hemophilia A under High Shear Flow Conditions.

BACKGROUND: Emicizumab is a bispecific antibody to factor (F) IXa and FX that mimics the FVIIIa cofactor function. Emicizumab prophylaxis markedly decreases bleeding episodes in patients with hemophilia A (PwHAs), irrespective of the presence of FVIII inhibitors. However, thrombotic microangiopathy (TMA) was reported when repeated high doses of activated prothrombin complex concentrates (aPCC) were concomitantly used with emicizumab. Although bypassing agents (BPAs) are vital in the hemostatic treatment for PwHAs with inhibitors, the mechanism of emicizumab-related TMA remains unclear. AIM: To assess the risk of excessive thrombus formation associated with BPAs and emicizumab under high shear conditions. METHODS: Perfusion flow-chamber experiments under high shear conditions were performed using whole blood from PwHAs in the presence of emicizumab without or together with FVIII or BPAs ex vivo. RESULTS: Emicizumab (100 µg/mL) added ex vivo to whole blood from PwHAs improved defective thrombus formation in a similar manner to that observed with the addition of recombinant FVIII at the early phase, while FVIII continued to be important at the later stages. aPCC (1.2 U/mL equivalent to 100 U/kg) or recombinant FVIIa (1.1 µg/mL; equivalent to 90 µg/kg) together with emicizumab further promoted platelet interactions and fibrin formation ex vivo but did not induce excessive thrombus formation. CONCLUSION: Emicizumab enhanced thrombin generation at local sites and improved defective hemostasis in whole blood from PwHAs under high shear conditions. Simple concomitant use of BPAs with emicizumab did not mediate excessive thrombus formation and remains an option for hemostatic management of emicizumab-treated PwHAs with inhibitors.

Activated factor VIII-mimicking effect by emicizumab on thrombus formation in type 2N von Willebrand disease under high shear flow conditions.

INTRODUCTION: Type 2N von Willebrand disease (2NVWD) is characterized by a mild to moderate reduction in plasma levels of factor (F)VIII associated with defective binding of von Willebrand factor (VWF) to FVIII and accelerated proteolysis and clearance of FVIII. The clinical phenotype in 2NVWD is often indistinguishable from mild/moderate hemophilia (H)A. Emicizumab is a bispecific antibody to FIX/FIXa and FX/FXa that mimics FVIIIa cofactor function, and emicizumab prophylaxis significantly reduces bleeding events in patients with severe HA. AIM: We investigated the potential benefits of emicizumab in the hemostatic management of 2NVWD. PATIENTS/METHODS: Perfusion chamber experiments were performed using whole blood from three 2NVWD patients with different clinical phenotypes (bleeding scores: 0, 6 and 20; mutations: p.R816W, p.R816W, and p.R365X/p.T791M, respectively). Furthermore, the impact of specific FVIII-VWF interactions on thrombus formation was investigated. RESULTS: Defective thrombus formation that correlated with bleeding phenotype was evident in these 2NVWD patients. Emicizumab improved surface coverage and thrombus height in all cases. Multi-color immunostaining of thrombi further demonstrated that emicizumab enhanced thrombin generation and fibrin formation. The addition of FVIII alone to 2NVWD whole blood did not augment thrombus formation, while supplementation with FVIII/VWF complex enhanced platelet-fibrin interactions. Furthermore, an anti-FVIII monoclonal antibody known to interrupt the release of FVIIIa from VWF depressed these effects. CONCLUSIONS: Emicizumab-induced enhancing effects of thrombus formation, independent on VWF, might be useful as an alternative therapy for 2NVWD patients. The extent of FVIII-VWF interaction should be optimal to deliver and release FVIII/FVIIIa on the activated platelet surface.

Shear stress and platelet-induced tensile forces regulate ADAMTS13-localization within the platelet thrombus.

BACKGROUND: The multimeric glycoprotein von Willebrand factor (VWF) mediates platelet adhesion and aggregation at the site of vessel injury. The adhesive activity of VWF is influenced by its multimer length which is regulated by the metalloprotease ADAMTS13. The ability of ADAMTS13 to regulate platelet thrombus growth in a shear-dependent manner has been described, however, the mechanistic basis of this action has not been well characterized. METHODS: We developed an mCherry-tagged murine ADAMTS13 protein and utilized an ex vivo flow chamber system to visualize the localization of ADAMTS13 within the platelet thrombus under different conditions of shear. Using this system, we also assessed the influence of platelet-mediated tensile force on ADAMTS13 localization within the thrombus using gain-of-function GPIb binding and loss-of-function GPIIbIIIa binding mutants in VWF/ADAMTS13 DKO mice. RESULTS: ADAMTS13 was visualized on the growing platelet thrombus under very high shear using ADAMTS13-mcherry. ADAMTS13-mCherry localized particularly at the top portion of the thrombus and reduced thrombus size as it grew to occlusion. At the pathological high shear of 7500 s-1, platelet-mediated tensile force, involving GPIb but not GPIIbIIIa receptors, influenced localization of ADAMTS13 to the thrombus under conditions of shear. CONCLUSIONS: Tensile force applied on VWF produced by shear stress and platelet GPIb binding has a crucial role in ADAMTS13 activity at the site of thrombus formation. These results suggest that ADAMTS13 activity at the site of platelet thrombus formation is regulated by a shear stress and platelet-dependent feedback mechanism to prevent vessel occlusion and pathological thrombosis.

Global coagulation function assessed by rotational thromboelastometry predicts coagulation-steady state in individual hemophilia A patients receiving emicizumab prophylaxis.

Emicizumab is a bispecific antibody to factor (F) IX/IXa and FX/FXa, which mimics FVIIIa cofactor function. Emicizumab prophylaxis significantly decreases bleeding events for patients with hemophilia A (PwHA). However, global hemostatic monitoring in emicizumab-treated PwHA remains poorly investigated. Using rotational thromboelastometry (ROTEM), we evaluated coagulation potentials of whole blood samples from seven emicizumab-treated PwHA who participated in ACE001JP/ACE002JP studies. Dose-dependent coagulation-enhancing effects of emicizumab to whole blood from PwHA mixed with an anti-FVIII C2 antibody in vitro were evident by non-activated ROTEM analysis (NATEM). The relationship between FVIII levels and NATEM parameters in PwHA not participating in the clinical trials demonstrated that CT + CFT inversely correlated with FVIII levels. These parameters were defined as NATEM-based grading of coagulation potential; 'T1' (FVIII < 1 IU/dL), 'T2' (1 ≤ , < 12 IU/dL) and 'T3' (12 ≤ , < 60 IU/dL). Coagulation function in emicizumab-treated PwHA was determined to be 'T2' or 'T3,' and was dependent on plasma emicizumab concentration. Improvement of NATEM-based grades corresponded with significant reduction of bleeding episodes, except for target joints, and differences were due to the time to reach the coagulation-steady state in individual patients. The NATEM analysis may be useful for intra- and inter-individual evaluation of coagulation function in emicizumab-treated PwHA.

Visual evaluation of blood coagulation during mural thrombogenesis under high shear blood flow.

Mural thrombus generation at sites of damaged vessel walls is essential for both physiological haemostasis and pathological intravascular thrombosis. While thrombi are established by the concerted action of platelet aggregation and blood coagulation, most previous in vitro coagulation assays have evaluated fibrin clot formation in a closed stirring situation that lacks blood cells including platelets. We describe here a modified flow chamber system, established originally for platelet functional studies, that enables real-time observation of intra-thrombus fibrin accumulation during platelet thrombogenesis under flow conditions. Analysis by confocal laser scanning microscopy during perfusion of whole blood anticoagulated to various extents revealed that the size and shape of mural thrombi can depend on the intra-thrombus fibrin development under high shear rate conditions. These observations were confirmed by perfusion of heparinized blood or blood from haemophilia patients with or without addition of activated factor VII. Thus, our experimental system provides visual evidence supporting the concept of "cell-based coagulation under whole blood flow", which might be the most physiologically relevant model of comprehensive thrombogenicity in vivo to date. This system promises to help formulate strategies for haemostatic management of congenital coagulation disorders as well as for antithrombotic therapy targeting fatal arterial thrombosis.

Highly elevated plasma level of von Willebrand factor accelerates the formation of platelet thrombus under high shear stress in plasma with deficient ADAMTS13 activity.

Upshaw-Schulman syndrome (USS) is a thrombo-hemorrhagic disease caused by congenital deficiency of ADAMTS13 due to ADAMTS13 gene mutations. USS is characterized by repeated episodes of thrombocytopenia and microangiopathic hemolytic anemia that respond dramatically to infusions of fresh frozen plasma. There are two phenotypic expressions of USS: one is the early-onset type and the other, the late-onset type, is asymptomatic during childhood with the first bout of thrombotic thrombocytopenic purpura (TTP) developing after adolescence or during adulthood. We found that gravida with the latter phenotype developed thrombocytopenia and hemolytic anemia during the second or third trimesters, often followed by thrombotic microangiopathies (TMAs). These phenomena suggest that elevated plasma von Willebrand Factor (VWF) might be crucial because plasma levels of VWF antigen usually increase by 200-500% during this period of gestation. Here, we performed platelet function assays using a mixture of anti-coagulated blood from normal volunteers, human VWF, anti-ADAMTS13 monoclonal antibody A10, and purified plasma-derived ADAMTS13 to investigate the effect of plasma VWF levels on platelet thrombus formation in the context of deficient ADAMTS13. In vitro studies showed that mural thrombus formation and platelet aggregation under high shear stress were markedly augmented by increasing the amounts of exogenously added VWF when ADAMTS13 activity was deficient, as may be the case in the in vivo circulation of gravida with USS. These results suggest that highly elevated plasma VWF might accelerate platelet thrombus formation not only in the circulation but also on the surface of vascular endothelial cells in the setting of ADAMTS13 deficiency in USS.

Cilostazol down-regulates the height of mural platelet thrombi formed under a high-shear rate flow in the absence of ADAMTS13 activity.

Cilostazol is an anti-platelet drug that reversibly inhibits phosphodiesterase III (PDE-III), which is ubiquitously expressed in platelets and various tissues. PDE-III converts cyclic adenosine monophosphate (cAMP) to 5'-AMP and up-regulates the intracellular concentration of cAMP, a potent inhibitor of platelet aggregation. Unlike other anti-platelet drugs, cilostazol is unique because patients receiving this drug do not have a significantly prolonged bleeding time, but the reasons for this difference are still unknown. In this study, we have examined how cilostazol inhibits platelet thrombus formation using anti-coagulated normal whole blood in which the platelets were labeled with a fluorescent dye in comparison with the anti-GPIIb/IIIa agent, tirofiban. We used an in vitro assay to examine mural platelet thrombus growth on a collagen surface under a high-shear rate flow in the absence of ADAMTS13 activity. These experimental conditions mimic the blood flow in patients with thrombotic thrombocytopenic purpura. Using this model, we clearly determined that cilostazol down-regulates the height of mural platelet thrombi formed on a collagen surface in a dose-dependent manner, without affecting the surface coverage. The concentration of cilostazol used in this study was relatively high (60-120 µM) compared to clinically relevant concentrations (1-3 µM), which may be due to the in vivo synergistic effects of PDE-III present in other tissues aside from platelets. Cilostazol does not affect the initial formation of platelet thrombi, but does inhibit the height of thrombi. These results showed a sharp contrast to tirofiban, and address why cilostazol does not significantly prolong bleeding time, despite its strong anti-platelet activity.

Antithrombotic properties of pravastatin reducing intra-thrombus fibrin deposition under high shear blood flow conditions.

In addition to lowering cholesterol, the 3-hydroxyl-3-methylglutaryl coenzyme A reductase inhibitors (statins) have a range of pleiotropic effects that help reduce the risk of adverse cardiovascular events. We sought to understand the molecular mechanisms by which statins could exert anti-platelet actions under physiologic whole blood flow conditions. Using an in vitro perfusion chamber system, we examined the anti-platelet effects of pravastatin under whole blood flow conditions with high or low shear rates. We determined that pravastatin significantly suppressed platelet activation-dependent procoagulant activity, decreasing P-selectin membrane expression, tissue factor accumulation, and thrombin binding within platelet thrombi generated on a von Willebrand factor-surface under high shear rate conditions. These effects resulted in reductions of intra-thrombus fibrin deposition. These antithrombotic properties of pravastatin, which were comparable to those of atorvastatin, could be abrogated by mevalonate. Our experimental approach revealed a novel mechanism mediating the anti-platelet action of statins. Shear rate-dependent antithrombotic activity may explain the favourable effect of pravastatin on the reduction in cardiovascular events that typically occur in vivo under whole blood flow conditions with high shear rates.

Functional imaging of shear-dependent activity of ADAMTS13 in regulating mural thrombus growth under whole blood flow conditions.

The metalloprotease ADAMTS13 is assumed to regulate the functional levels of von Willebrand factor (VWF) appropriate for normal hemostasis in vivo by reducing VWF multimer size, which directly represents the thrombogenic activity of this factor. Using an in vitro perfusion chamber system, we studied the mechanisms of ADAMTS13 action during platelet thrombus formation on a collagen surface under whole blood flow conditions. Inhibition studies with a function-blocking anti-ADAMTS13 antibody, combined with immunostaining of thrombi with an anti-VWF monoclonal antibody that specifically reflects the VWF-cleaving activity of ADAMTS13, provided visual evidence for a shear rate-dependent action of ADAMTS13 that limits thrombus growth directly at the site of the ongoing thrombus generation process. Our results identify an exquisitely specific regulatory mechanism that prevents arterial occlusion under high shear rate conditions during mural thrombogenesis.