Darexaban has high sensitivity in the prothrombin time clotting test

Mechanistic Basis for the Differential Effects of Rivaroxaban and Apixaban on Global Tests of Coagulation

Rivaroxaban and apixaban are both small molecules that reversibly inhibit factor Xa. Compared with rivaroxaban, apixaban has minimal effects on the prothrombin time and activated partial thromboplastin time. To investigate this phenomenon, we used a factor Xa-directed substrate in a buffer system. Although rivaroxaban and apixaban inhibited factor Xa with similar K _i values at equilibrium, kinetic measurements revealed that rivaroxaban inhibited factor Xa up to 4-fold faster than apixaban ( p  < 0.001). Using a discontinuous chromogenic assay to monitor thrombin production by prothrombinase in a purified system, rivaroxaban was 4-fold more potent than apixaban (K _i values of 0.7 ± 0.3 and 2.9 ± 0.5 nM, respectively; p  = 0.02). Likewise, in thrombin generation assays in plasma, rivaroxaban prolonged the lag time and suppressed endogenous thrombin potential to a greater extent than apixaban. To characterize how the two inhibitors differ in recognizing factor Xa, inhibition of prothrombinase was monitored in real-time using a fluorescent probe for thrombin. The data were fit using a mixed-inhibition model and the individual association and dissociation rate constants were determined. The association rates for the binding of rivaroxaban to either free factor Xa or factor Xa incorporated into the prothrombinase complex were 10- and 1,193-fold faster than those for apixaban, respectively, whereas dissociation rates were about 3-fold faster. Collectively, these findings suggest that rivaroxaban and apixaban differ in their capacity to inhibit factor Xa and provide a plausible explanation for the observation that rivaroxaban has a greater effect on global tests of coagulation than apixaban.

Plasma factor Xa inhibition can predict antithrombotic effects of oral direct factor Xa inhibitors in rabbit atherothrombosis models

We evaluated the relationship between antithrombotic effects and pharmacodynamic (PD) marker changes produced by the novel factor (F)Xa inhibitors darexaban (YM150) and rivaroxaban in a rabbit model of plaque disruption-induced arterial thrombosis. Animals were subjected to catheter-induced endothelial denudation via the femoral artery followed by a two-week high-cholesterol diet. Plaque disruption was induced by balloon angioplasty, and then stasis was achieved by ligation at the distal side of the injured segment. Darexaban and rivaroxaban were administered orally 1 hour (h) before and 9 h after plaque disruption, and their antithrombotic effects were evaluated 24 h after the initiation of ligation. Prothrombin time (PT), activated partial thromboplastin time (APTT), and plasma FXa activity were measured using blood samples collected before and 1 h after administration. Darexaban and rivaroxaban significantly reduced thrombus formation. The thrombus weight obtained in the 30 mg/kg darexaban group was comparable to that in the 1 mg/kg rivaroxaban group (2.17 ± 0.63 and 3.23 ± 1.64 mg, respectively, vs. 8.01 ± 1.08 mg in the control group). Plasma FXa activity correlated with the antithrombotic effects of darexaban and rivaroxaban, while PT only correlated with those of darexaban. Our findings suggest that the degree of plasma FXa inhibition may be useful for predicting antithrombotic effects of darexaban and rivaroxaban in arterial thrombosis. PT may also be useful in evaluating antithrombotic effects of darexaban in particular.

Clinical Pharmacokinetics, Pharmacodynamics, Safety and Tolerability of Darexaban, an Oral Direct Factor Xa Inhibitor, in Healthy Elderly Japanese Subjects

The clinical pharmacokinetics, pharmacodynamics, safety and tolerability of darexaban after single and multiple once-daily doses of 60, 120, and 240 mg in healthy elderly Japanese subjects were assessed. Following oral administration, darexaban was rapidly and extensively metabolized to darexaban glucuronide, which is an active glucuronide metabolite. Plasma concentrations of darexaban glucuronide increased with dose, and Cmax and AUC increased dose-dependently after both single and repeated doses. Cumulative urinary excretion of darexaban glucuronide up to 24 hours after repeated doses ranged from 28.59% to 36.50%. PT-INR, aPTT, and FXa activity were prolonged or decreased dose-dependently after both single and repeated doses of darexaban. The time-profile of pharamcodynamic parameters closely followed the time-concentration profile of darexaban glucuronide. Five adverse events occurred in the present study (4: darexaban [16.7%]; 1: placebo [8.3%]), all of which were mild in severity and required no treatment.

Darexaban: anticoagulant effects in mice and human plasma in vitro, antithrombotic effects in thrombosis and bleeding models in mice and effects of anti-inhibitor coagulant complex and recombinant factor VIIa

Here, we investigated the anticoagulant effects of darexaban in mice and human plasma in vitro, effects of darexaban in thrombosis and bleeding models in mice, and reversal effects of anti-inhibitor coagulant complex (ACC) and recombinant factor VIIa (rFVIIa) on anticoagulant effects of darexaban. In mice, darexaban inhibited FXa activity in plasma with an ED50 value of 24.8 mg/kg. Both darexaban and warfarin prolonged prothrombin time (PT) at 3 mg/kg and 0.3 mg/kg/day, respectively. PT and activated partial thromboplastin time (aPTT) prolonged by darexaban were dose-dependently reversed by intravenously-administered rFVIIa, significantly so at 1 mg/kg. In a pulmonary thromboembolism (PE) mouse model, both darexaban and warfarin dose-dependently reduced the mortality rate, significantly so at 10 mg/kg and 3 mg/kg/day, respectively. In a FeCl3-induced venous thrombosis (VT) mouse model, darexaban (0.3-10 mg/kg) dose-dependently decreased the thrombus protein content, significantly so at doses of 3 mg/kg or higher. In a tail-transection mouse model, darexaban had no significant effect on the amount of blood loss at doses up to 10 mg/kg, while warfarin showed a dose-dependent increase in blood loss, significantly so from 1 mg/kg/day. Darexaban and its metabolite darexaban glucuronide significantly prolonged PT and aPTT in human plasma in vitro, and while rFVIIa concentration-dependently reversed the prolonged PT in this plasma, ACC dose-dependently reversed both PT and aPTT changes prolonged by darexaban. Taken together, these results suggest that darexaban has a potential to be an oral anticoagulant with a better safety profile than warfarin, and that rFVIIa and ACC may be useful as antidotes to darexaban in cases of overdose.