An in vitro pharmacodynamic spiking study of befovacimab, a tissue factor pathway inhibitor monoclonal antibody, in blood samples from patients with severe FVIII deficiency.

INTRODUCTION: Tissue factor pathway inhibitor (TFPI) is an endogenous protein that inhibits the extrinsic (tissue factor) pathway and negatively regulates thrombin production during coagulation. Inhibiting TFPI may become a useful target for haemophilia drug development to allow greater thrombin generation without use of the intrinsic (contact) pathway. AIMS: The in vitro effects of befovacimab, a humanized TFPI neutralizing antibody, were studied in whole blood and plasma samples from patients with severe FVIII deficiency. METHODS: Blood and plasma obtained from participants was supplemented in vitro with befovacimab (0.5, 1, 5, 10 and 100 nM) or recombinant factor VIII (rFVIII) 5-, 10- and 40% and analysed using rotational thromboelastometry (ROTEM), thrombin generation assay (TGA) and the dilute prothrombin time (dPT) assay. The in vitro coagulation effects of befovacimab were compared to samples supplemented with rFVIII. RESULTS: Befovacimab induced consistent pro-coagulant responses in ROTEM parameters including reduction in clotting times and increases in α-angle; induced reductions in dPT clotting time; and improvements in TGA parameters (reduced lag time and increased thrombin generation parameters). There was a modest concentration-dependent response generally from 0.5- to 10 nM, after which, the pharmacodynamic effect plateaued through the 100 nM concentration. Befovacimab concentrations of 5 to 10 nM showed pro-coagulant activity comparable to blood samples supplemented with rFVIII 10-40%. CONCLUSIONS: Befovacimab has modest dose-response effects from 0.5 to 10 nM with minimal improvement with higher concentrations. In vitro befovacimab blood concentrations of 5 to 10 nM had pro-coagulant effects similar to blood supplemented with rFVIII 10- to 40%.

Marstacimab, a tissue factor pathway inhibitor neutralizing antibody, improves coagulation parameters of ex vivo dosed haemophilic blood and plasmas.

INTRODUCTION: Tissue factor pathway inhibitor (TFPI) is an endogenous inhibitor of the extrinsic pathway that negatively regulates thrombin production during coagulation. Under haemophilic conditions, where the intrinsic coagulation pathway is impaired, inhibition of TFPI may improve clotting. AIM: We investigated the ex vivo effects of a human TFPI neutralizing antibody, marstacimab (previously PF-06741086), in coagulation assays including rotational thromboelastometry (ROTEM), thrombin generation assay (TGA) and the dilute prothrombin time (dPT) assay, performed in haemophilic whole blood and plasmas. We compared the effects of marstacimab to the effects of recombinant coagulation factors and investigated the reproducibility of marstacimab in restoring haemostasis by comparing its effect in whole blood collected from the same study participants on differing days. METHODS: Citrated whole blood and plasmas obtained from haemophilia participants were supplemented ex vivo with vehicle, marstacimab, recombinant FVIII (rFVIII) or recombinant factor IX (rFIX) and analysed in ROTEM, TGA and the dPT assay using low tissue factor concentrations to trigger coagulation. RESULTS: Marstacimab induced pro-coagulant responses in ROTEM parameters including reduction in clotting times and increases in angle. Similarly, participant plasmas supplemented with marstacimab exhibited improvements in TGA parameters, including reduced lag times, increased peak thrombin concentrations and reductions in dPT clotting time. Concentrations of marstacimab tested showed activity comparable to addition of rFVIII or rFIX and were reproducible. CONCLUSIONS: These studies show the ex vivo potency of marstacimab in restoring haemostasis in whole blood and plasmas from haemophilia participants and comparability to ex vivo reconstitution with recombination coagulation factors.

Evaluating the thrombin generation profiles of four different rFVIII products in FVIII-deficient plasma using FIXa and FXIa activation.

INTRODUCTION: The thrombin generation assay (TGA) can be used to monitor factor replacement therapy in patients with haemophilia. The TGA assay is typically performed using tissue factor as the reaction activator; however, activating with FIXa or FXIa can enhance assay sensitivity when FVIII < 1%. AIMS: To evaluate the sensitivity of the TGA when FIXa (5 nmol/L) and FXIa (0.22 nmol/L) are used to activate the assay in platelet-poor plasma and to compare these data to the one-stage and chromogenic assays. METHODS: Plasma from 10 severe FVIII-deficient subjects was supplemented with FVIII (0%, 0.1%, 0.4%, 1.2%, 4%, 11% and 33%), using either Novo Eight® , Advate® , Eloctate® , turoctocog alfa pegol or a control standard. The one-stage and chromogenic assays quantified the FVIII levels. The TGA assay was activated using either FIXa or FXIa. RESULTS: Both FIXa- and FXIa-activated TGA were sensitive across FVIII concentrations, with intra-assay coefficient of variation (CV) < 10%. The FXIa-activated assay had 25% CV at the lowest level of FVIII compared to 10% CV with FIXa activation. There were strong correlations between the FIXa- and FXIa-activated TGA tests (R2  = 0.9912) and between the one-stage and chromogenic assays (R2  = 0.9469). However, there were poor relationships between the TGA tests and one-stage and chromogenic assays. CONCLUSIONS: Both FIXa- and FXIa activation results in similar TGA profiles across a FVIII range of 0.1%-33%; however, FIXa activation was more robust at the lowest levels of FVIII compared with FXIa activation.

Overcoming delayed in-vitro response to rFVIIa: effects of rFVIIa and rFVIIa analogue (vatreptacog alfa) concentration escalation in whole blood assays.

In a previous pharmacokinetic/pharmacodynamic study in nonbleeding hemophilia patients, variability in laboratory response to recombinant factor VIIa (rFVIIa) 90 µg/kg was noted, and the patients were described as delayed or rapid laboratory responders based on time to clot formation. The current study determined whether in-vitro experiments could reproduce previous in-vivo findings; whether the delayed laboratory response to rFVIIa 90 µg/kg is improved by spiking with high-dose rFVIIa or rFVIIa analogue (vatreptacog alfa); whether a dose-response is observed with our method. In-vitro experiments were conducted in our previous patient cohort using rFVIIa 1.28 and 3.84 µg/ml and vatreptacog alfa 0.28 and 0.56 µg/ml. Whole blood studies were conducted using the Hemodyne Hemostasis Analysis System (platelet contractile force, clot elastic modulus, force onset time) and rotational thromboelastometry (clotting time, maximum clot firmness). Spiking with rFVIIa 1.28 µg/ml showed the same distribution of delayed and rapid laboratory response as observed previously. Increasing in-vitro rFVIIa concentrations improved the coagulation parameters; however, there remained delayed and rapid responders. Vatreptacog alfa improved the coagulation parameters at all concentrations tested, and the 0.56 µg/ml concentration normalized the force onset time, platelet contractile force, clot elastic modulus and clotting time parameters. A dose-response was observed with both assays. There was good agreement between the laboratory responses obtained after intravenous administration of rFVIIa 90 µg/kg and in-vitro spiking studies. Escalating rFVIIa and vatreptacog alfa concentrations improved coagulation parameters in all patients compared to rFVIIa 1.28 µg/ml. Vatreptacog alfa produced more pronounced coagulation effects at lower concentrations than rFVIIa; and the 0.56 µg/ml concentration completely normalized responses in all patients.

Factor VIIa analog has marked effects on platelet function and clot kinetics in blood from patients with hemophilia A.

To evaluate the hemostatic effects of NN1731 and rFVIIa, an ex-vivo study in hemophilia patients used the Hemodyne Hemostasis Analysis System (HAS) to measure platelet contractile force (PCF), clot elastic modulus (CEM), and force onset time (FOT), and the Haemoscope Thrombelastograph (TEG) to measure reaction time (R), kinetics time (K), and maximum amplitude (MA). Blood samples from 10 healthy volunteers and 10 Factor VIII-deficient patients of varying severity (mild, moderate, severe), were spiked with rFVIIa and NN1731 (both 0.64 and 1.28 microg/ml, respectively) and analyzed to characterize platelet function and clot kinetics. There was wide variability in the rFVIIa response. NN1731 had greater and more consistent effects on PCF, CEM, FOT, R, and K relative to rFVIIa, in all hemophilia groups. The lowest NN1731 concentration (0.64 microg/ml) shortened R and FOT, and increased CEM and PCF more than rFVIIa 1.28 microg/ml. NN1731 normalized clotting parameters equivalent to values obtained in healthy volunteers. FOT and R were highly correlated (r = 0.96). No correlation was observed between CEM and MA. NN1731 produced less variable, more pronounced and predictable ex-vivo hemostatic effects on PCF, CEM, FOT, R and K than rFVIIa in all hemophilia groups. HAS and TEG assays provided similar estimates of FOT and R, however CEM appeared to be more sensitive than MA to changes in clot firmness.