Effective reversal of edoxaban-associated bleeding with four-factor prothrombin complex concentrate in a rabbit model of acute hemorrhage.

BACKGROUND: Edoxaban is an oral, selective direct factor Xa inhibitor approved in Japan for venous thromboembolism prevention after orthopedic surgery. Data are lacking regarding reversal strategies for edoxaban; this study assessed whether four-factor prothrombin complex concentrate (Beriplex/Kcentra; CSL Behring GmbH, Marburg, Germany) can effectively reverse its effects on hemostasis using a previously described rabbit model. METHODS: The study comprised assessments of thrombin generation in vitro, pharmacokinetic parameters, and edoxaban reversal in vivo. In a blinded in vivo stage, a standardized kidney incision was performed in animals (n = 11 per group) randomized to receive vehicle + saline, edoxaban (1,200 µg/kg) + saline, or edoxaban (1,200 µg/kg) + four-factor prothrombin complex concentrate (50 IU/kg). Animals were monitored for treatment impact on hemostasis and coagulation parameters. Data are median (range). Statistical tests were adjusted for multiple testing. RESULTS: Edoxaban administration increased blood loss (30 [2 to 44] ml) and time to hemostasis (23 [8.5 to 30.0] min) compared with the control group (3 [1 to 8] ml and 3 [2.0 to 5.0] min, respectively). Biomarkers of coagulation (prothrombin time, activated partial thromboplastin time, whole blood clotting time) and thrombin generation parameters (e.g., peak thrombin, endogenous thrombin potential, lag time) were also affected by edoxaban. Administration of four-factor prothrombin complex concentrate significantly reduced time to hemostasis (to 8 [6.5 to 14.0] min, observed P < 0.0001) and total blood loss (to 9 [4 to 22] ml, observed P = 0.0050) compared with the edoxaban + saline group. Of the biomarkers tested, prothrombin time, whole blood clotting time, and endogenous thrombin potential correlated best with clinical parameters. CONCLUSION: In a rabbit model of hemostasis, four-factor prothrombin complex concentrate administration significantly decreased edoxaban-associated hemorrhage.

Evaluation of the prothrombotic potential of four-factor prothrombin complex concentrate (4F-PCC) in animal models.

OBJECTIVES: Acquired coagulopathy may be associated with bleeding risk. Approaches to restore haemostasis include administration of coagulation factor concentrates, but there are concerns regarding potential prothrombotic risk. The present study assessed the prothrombotic potential of four-factor prothrombin complex concentrate (4F-PCC) versus activated PCC (aPCC) and recombinant factor VIIa (rFVIIa), using three preclinical animal models. METHODS: The first model was a modified Wessler model of venous stasis-induced thrombosis in rabbit, focusing on dilutional coagulopathy; the second model employed the same system but focused on direct oral anticoagulant reversal (i.e. edoxaban). The third model assessed the prothrombotic impact of 4F-PCC, aPCC and rFVIIa in a rat model of ferric chloride-induced arterial thrombosis. RESULTS: In the first model, thrombi were observed at aPCC doses ≥10 IU/kg (therapeutic dose 100 IU/kg) and rFVIIa doses ≥50 µg/kg (therapeutic dose 90 µg/kg), but not 4F-PCC 50 IU/kg (therapeutic dose 50 IU/kg). The impact of 4F-PCC (up to 300 IU/kg) on thrombus formation was evident from 10 minutes post-administration, but not at 24 hours post-administration; this did not change with addition of tranexamic acid and/or fibrinogen concentrate. 4F-PCC-induced thrombus formation was lower after haemodilution versus non-haemodilution. In the second model, no prothrombotic effect was confirmed at 4F-PCC 50 IU/kg. The third model showed lower incidence of thrombus formation for 4F-PCC 50 IU/kg versus aPCC (50 U/kg) and rFVIIa (90 µg/kg). CONCLUSIONS: These results suggest that 4F-PCC has a low thrombotic potential versus aPCC or rFVIIa, supporting the clinical use of 4F-PCC for the treatment of coagulopathy-mediated bleeding.

Tissue distribution of rIX-FP after intravenous application to rodents.

BACKGROUND: Hemophilia B is caused by coagulation factor IX (FIX) deficiency. Recombinant fusion protein linking coagulation FIX with recombinant albumin (rIX-FP; Idelvion® ) is used for replacement therapy with an extended half-life. A previous quantitative whole-body autoradiography (QWBA) study investigating the biodistribution of rIX-FP indicated equal biodistribution, but more prolonged tissue retention compared with a marketed recombinant FIX product. OBJECTIVES: To complete and confirm the QWBA study data by directly measuring rIX-FP protein and activity levels in tissues following intravenous (i.v.) administration to normal rats and FIX-deficient (hemophilia B) mice. METHODS: After i.v. administration of rIX-FP at a dose of 2000 IU/kg, animals were euthanized at specific time points up to 72 hours postdosing. Subsequently, plasma and various tissues, which were selected based on the previous QWBA results, were harvested and analyzed for FIX antigen levels using an ELISA (both species) or an immunohistochemistry method (mice only), as well as for FIX activity levels (mice only) using a chromogenic assay. RESULTS: In rats, rIX-FP distributed extravascularly into all tissues analyzed (ie, liver, kidney, skin and knee) with peak antigen levels reached between 1 and 7 hours postdosing. In hemophilia B mice, rIX-FP tissue distribution was comparable to rats. FIX antigen levels correlated well with FIX activity readouts. CONCLUSIONS: Our results confirm QWBA data showing that rIX-FP distributes into relevant target tissues. Importantly, it was demonstrated that rIX-FP available in tissues retains its functional activity and can thus facilitate its therapeutic activity at sites of potential injury.

Characterization of the coagulation deficit in porcine dilutional coagulopathy and substitution with a prothrombin complex concentrate.

BACKGROUND: In this study, we used a porcine model to investigate whether impaired coagulation and severe arterial or venous bleeding could be normalized by substitution with a prothrombin complex concentrate (PCC), Beriplex P/N, containing coagulation factors II, VII, IX, and X. METHODS: Dilutional coagulopathy was induced in anesthetized pigs by fractionated blood withdrawal (approximately 65% of total volume), followed by erythrocyte retransfusion and volume substitution with a total of 1000 mL of hydroxyethyl starch (Infukoll 6%). Animals were randomized to no treatment, treatment with placebo, or treatment with 35 U/kg PCC. Arterial (spleen incision) or venous (bone injury) bleeding was inflicted. Thromboelastometry, hematology, and coagulation tests were performed at baseline, after dilution, and after study treatments had been administered and injury inflicted. The primary end-point was postinjury time to hemostasis. RESULTS: Hemodilution resulted in a decrease in coagulation factor concentrations to approximately 35% and prolonged prothrombin time. Platelet numbers decreased from approximately 400,000 to approximately 100,000/microL, and aggregation and adhesion were impaired. PCC effectively substituted the deficient prothrombin factors (II, VII, IX, and X) and normalized the prolonged prothrombin time. After spleen injury, PCC significantly reduced time to hemostasis versus dilutional control (median, 35 vs 82.5 min; P < 0.0001), and produced a nonsignificant trend towards reduction in blood loss (mean, 275 vs 589 mL). PCC also significantly reduced time to hemostasis (median, 27 vs 97 min; P < 0.0011) and blood loss (mean, 71 vs 589 mL; P < 0.0017) after bone injury. CONCLUSIONS: Dilutional coagulopathy produced a generalized decrease in coagulation factors and impaired platelet function. Substitution with PCC effectively normalized coagulation and significantly improved hemostasis after venous and arterial bleeding.

Correlation of coagulation markers and 4F-PCC-mediated reversal of rivaroxaban in a rabbit model of acute bleeding.

INTRODUCTION: Rivaroxaban is an oral, selective direct factor Xa inhibitor approved for several indications in patients at risk of thrombotic events. One limitation of its clinical use is the lack of data pertaining to its reversal in situations where urgent response is critical (e.g. acute bleeding events or emergency surgery). MATERIALS AND METHODS: This study assessed the effectiveness of a four-factor prothrombin complex concentrate (4F-PCC; Beriplex(®)/Kcentra(®)) for the reversal of rivaroxaban-associated bleeding in an in vivo rabbit model, and evaluated the correlations between in vitro coagulation parameters and haemostasis in vivo. RESULTS: Administration of single intravenous doses of rivaroxaban (150-450 µg/kg) resulted in increased and prolonged bleeding following standardised kidney incision. Pre-incision treatment with 4F-PCC (25-100 IU/kg) resulted in a dose-dependent reversal of rivaroxaban (150 and 300 µg/kg)-associated increases in time to haemostasis and blood loss; no reversal was seen at the highest rivaroxaban dose (450 µg/kg). Of the in vitro biomarkers tested, thrombin generation and whole-blood clotting time correlated well with in vivo measures of 4F-PCC-mediated effects. Thrombin generation was highly reagent-dependent, with the assay initiated using the phospholipid-only reagent being the most predictive of effective haemostasis in vivo. CONCLUSIONS: In summary, in a rabbit model of acute bleeding, treatment with 4F-PCC reduced bleeding to control levels following rivaroxaban 150 µg/kg and 300 µg/kg administration.

The effect of fibrinogen concentrate administration on coagulation abnormalities in a rat sepsis model.

Disseminated intravascular coagulation is a disorder that affects the function of the clotting system and is frequently associated with sepsis or septic shock. One of its leading symptoms is the decrease in circulating fibrinogen. We investigated the effect of fibrinogen concentrate (Haemocomplettan P) on fibrinogen plasma levels, coagulation parameters and mortality in a rat model of sepsis-induced disseminated intravascular coagulation. The disseminated intravascular coagulation was characterized by elevated thrombin-antithrombin complex and a sharp drop in circulating fibrinogen. Coagulation abnormalities were evaluated by thrombelastography. Plasma fibrinogen levels decreased from 2.06 +/- 0.2 to 0.16 +/- 0.1 g/l following administration of bacterial lipopolysaccharide. Thrombelastographic measurements revealed a concurrent decrease in maximum amplitude and an increase in reaction time. Treatment with fibrinogen concentrate (Haemocomplettan P, 25-200 mg/kg body weight intravenously) resulted in a statistically significant dose-dependent increase in fibrinogen plasma levels and amelioration of the measured coagulation abnormalities. Fibrinogen plasma concentrations were restored to normal levels when 200 mg/kg body weight fibrinogen concentrate was administered. A significant decrease in sepsis-induced mortality was observed in animals treated with Haemocomplettan P.

Thrombotic safety of prothrombin complex concentrate (Beriplex P/N) for dabigatran reversal in a rabbit model.

INTRODUCTION: In vivo animal data have shown prothrombin complex concentrate (PCC) to be effective in preventing bleeding induced by excessive plasma levels of the direct thrombin inhibitor dabigatran. This animal model study was designed to determine the risk of thrombosis associated with administration of a PCC (Beriplex P/N) to reverse dabigatran-induced bleeding. MATERIALS AND METHODS: Anesthetized rabbits were treated with initial 0, 75, 200 or 450 µg kg(-1) dabigatran boluses followed by continuous infusions to maintain elevated plasma dabigatran levels. At 15 min after the start of dabigatran administration, PCC doses of 0, 50 or 300 IU kg(-1) were administered. Thereafter, coagulation in an arteriovenous (AV) shunt was evaluated and histopathologic examination for thrombotic changes performed. Venous thrombosis was also assessed in a modified Wessler model. RESULTS: At the suprapharmacologic dose of 300 IU kg(-1), PCC increased thrombus weight during AV shunting, but this effect could be prevented by dabigatran at all tested doses. AV shunt occlusion after PCC administration was delayed by 75 µg kg(-1) dabigatran and abolished by progressively higher dabigatran doses. High-dose treatment with 300 IU kg(-1) PCC resulted in histologically evident low-grade pulmonary thrombi; however, that effect could be blocked by dabigatran in a dose-dependent manner (p=0.034). In rabbits treated with high-dose PCC, dabigatran inhibited thrombus formation during venous stasis. PCC effectively reversed dabigatran-induced bleeding. CONCLUSIONS: In this animal study, thrombosis after PCC administration could be prevented in the presence of dabigatran. PCC reversed dabigatran-induced excessive bleeding while retaining protective anticoagulatory activity of dabigatran.