In-vitro profile and ex-vivo anticoagulant activity of the direct thrombin inhibitor dabigatran and its orally active prodrug, dabigatran etexilate

Dabigatran is a reversible and selective, direct thrombin inhibitor (DTI) undergoing advanced clinical development as its orally active prodrug, dabigatran etexilate. This study set out to determine the molecular potency and anticoagulant efficacy of dabigatran and its prodrug dabigatran etexilate. This was achieved through enzyme inhibition and selectivity analyses, surface plasmon resonance studies, platelet aggregation, thrombin generation and clotting assays in vitro and ex vivo. These studies demonstrated that dabigatran selectively and reversibly inhibited human thrombin (Ki: 4.5 nM) as well as thrombin-induced platelet aggregation (IC(50): 10 nM), while showing no inhibitory effect on other platelet-stimulating agents. Thrombin generation in platelet-poor plasma (PPP), measured as the endogenous thrombin potential (ETP) was inhibited concentration-dependently (IC(50): 0.56 microM). Dabigatran demonstrated concentration-dependent anticoagulant effects in various species in vitro, doubling the activated partial thromboplastin time (aPTT), prothrombin time (PT) and ecarin clotting time (ECT) in human PPP at concentrations of 0.23, 0.83 and 0.18 microM, respectively. In vivo, dabigatran prolonged the aPTT dose-dependently after intravenous administration in rats (0.3, 1 and 3 mg/kg) and rhesus monkeys (0.15, 0.3 and 0.6 mg/kg). Dose- and time-dependent anticoagulant effects were observed with dabigatran etexilate administered orally to conscious rats (10, 20 and 50 mg/kg) or rhesus monkeys (1, 2.5 or 5 mg/kg), with maximum effects observed between 30 and 120 min after administration, respectively. These data suggest that dabigatran is a potent, selective thrombin inhibitor and an orally active anticoagulant as the prodrug, dabigatran etexilate.     

Effects of the oral, direct thrombin inhibitor dabigatran on five common coagulation assays

Pancreatic cancer is known to be associated with VTE, but contemporary rates of incidental and symptomatic VTE events and their association with mortality are incompletely understood. We conducted a retrospective cohort study of consecutive pancreatic adenocarcinoma patients at the University of Rochester from 2006-2009. Data were analysed using a Cox model with time-dependent covariates. A total of 1,151 radiologic exams of 135 patients were included. Forty-seven patients (34.8%) experienced VTE including 12 pulmonary emboli (PE), 28 deep-vein thromboses (DVTs) and 47 visceral vein events. Incidental events comprised 33.3% of PEs, 21.4% of DVTs and 100% of visceral VTE. Median (95% CI) conditional survival beyond three months was 233 (162-322) more days for those without VTE, which was significantly greater than 12 (3-60) days for those with DVT as first event (p<0.0001) and 87 (14-322) days with visceral first events (p=0.022). In multivariate analysis, DVT (HR 25, 95% CI 10-63, p <0.0001), PE (HR 8.9, 95% CI 2.5-31.7, p = 0.007) and incidental visceral events (HR 2.6, 95% CI 1.6-4.2, p =0.0001) were all associated with mortality, though anticoagulants reduced these risks by 70% (26-88%, p = 0.009). In conclusion, VTE occurs in over one-third of contemporary pancreatic cancer patients and, whether symptomatic or incidental, is strongly associated with worsened mortality. The role of anticoagulation in treating incidental or visceral VTE warrants further study.     

Effect of activated prothrombin complex concentrate or recombinant factor VIIa on the bleeding time and thrombus formation during anticoagulation with a direct thrombin inhibitor

Melagatran is the active form of the oral, direct thrombin inhibitor H 376/95. In several animal models of thrombosis, the antithrombotic properties of melagatran have been demonstrated, without any increase in experimental bleeding. However, as with all anticoagulants, in emergency situations, reversal of the anticoagulation may be necessary. In this study, increasing doses of activated prothrombin complex concentrate (APCC, Feiba) or recombinant factor VIIa (r-F VIIa, NovoSeven) were superimposed on high doses of melagatran, or saline, in anaesthetised rats. The haemostatic effect was evaluated in two bleeding time models and a potential prothrombotic effect was evaluated in an arterial thrombosis model. Compared with melagatran alone (0.5 micromol/kg/h), Feiba in doses of > or =25 U/kg significantly shortened the prolonged bleeding time and reduced blood loss. In addition, Feiba > or =50 U/kg when added to melagatran (2 micromol/kg/h), significantly reduced bleeding time. No potentiation of thrombus formation was observed when Feiba was added to melagatran, compared with controls. NovoSeven at high doses (2-10 mg/kg) produced a nonsignificant trend in reduction of blood loss and with the highest dose (10 mg/kg) producing only a mild nonsignificant reduction in bleeding time. The prolonged prothrombin time (PT) and the ecarin clotting time (ECT) were more effectively shortened by Feiba than by NovoSeven. In contrast, whole blood clotting time (WBCT) was more effectively shortened by NovoSeven than by Feiba. Activated partial thromboplastin time (APTT) was shortened by NovoSeven but was prolonged by Feiba. Thrombin-antithrombin (TAT) complex formation was increased in a dose-dependent fashion more effectively by Feiba than by NovoSeven. Conclusion: Feiba (APCC) reversed prolonged bleeding time and blood loss in rats treated with high doses of melagatran and compared with the control group thrombus formation was not potentiated. NovoSeven (r-F VIIa) at high doses had less pronounced effects on blood loss and bleeding times compared with Feiba.     

Effects of agents, used to treat bleeding disorders, on bleeding time prolonged by a very high dose of a direct thrombin inhibitor in anesthesized rats and rabbits

Melagatran is the active form of the oral, direct thrombin inhibitor, H 376/95, that is under evaluation in clinical trials for the prevention and treatment of thromboembolism. In this study, a single dose, calculated on body weight basis, of antifibrinolytic treatment, factor VIIa, factor VIII with and without von Willebrand factor (vWF), factor IX, activated (APCC) or nonactivated (PCC) prothrombin complex concentrates was given intravenously to rats and rabbits, in an attempt to reverse the prolonged bleeding time during intensive anticoagulation with melagatran (2 micromol/kg/h). The doses used were at or above human therapeutic doses. The cutaneous tail bleeding time in the rat, as well as the ear incision bleeding time and cuticle bleeding time, and the blood loss in the rabbit were used for evaluation of the hemostatic effects of these agents. In vivo Feiba (APCC) and Prothromplex-T (PCC) shortened the prolonged cutaneous bleeding times in rats (P<.05); Feiba and Autoplex (APCC) shortened the cutaneous bleeding times in rabbits (P<.05). In contrast, Prothromplex-T prolonged bleeding times and blood loss in the rabbits (P<.05). Ex vivo Feiba, Autoplex and NovoSeven (rF VIIa) significantly (P<.05) shortened the prolonged whole blood clotting time (WBCT). Prothromplex-T significantly prolonged WBCT, activated clotting time (ACT) and activated partial thromboplastin time (APTT). Feiba, Autoplex, and Prothromplex-T increased thrombin generation measured as increased thrombin-antithrombin complex (TAT) formation. In conclusion, APCCs were found to be the most effective agents for reversing bleeding time induced by a very high plasma concentration of melagatran. APCC and recombinant activated factor FVII (rF VIIa) effectively shortened the prolonged WBCT. Thus, stimulating thrombin generation with the use of APCC may counteract the anticoagulant effect observed with a very high dose of a thrombin inhibitor.     

The direct thrombin inhibitor melagatran and its oral prodrug H 376/95: intestinal absorption properties, biochemical and pharmacodynamic effects

Suboptimal gastrointestinal absorption is a problem for many direct thrombin inhibitors. The studies presented herein describe the new oral direct thrombin inhibitor H 376/95, a prodrug with two protecting residues added to the direct thrombin inhibitor melagatran. Absorption properties in vitro: H 376/95 is uncharged at intestinal pH while melagatran is charged. H 376/95 is 170 times more lipophilic (octanol water partition coefficient) than melagatran. As a result, the permeability coefficient across cultured epithelial Caco-2 cells is 80 times higher for H 376/95 than for melagtran. Pharmacokinetic studies in healthy volunteers: H 376/95 is converted to melagatran in man. Oral bioavailability, measured as melagatran in plasma, is about 20% after oral administration of H 376/95, which is 2.7-5.5 times higher than after oral administration of melagatran. The variability in the area under the drug plasma concentration vs. time curve (AUC) is much smaller with oral H 376/95 (coefficient of variation 20%) than with oral melagatran (coefficient of variation 38%). Pharmacodynamic properties: H 376/95 is inactive towards human alpha-thrombin compared with melagatran [inhibition constant (K(i)) ratio, 185 times], a potential advantage for patients with silent gastrointestinal bleeding. In an experimental thrombosis model in the rat, oral H 376/95 was more effective than the subcutaneous low molecular weight heparin dalteparin in preventing thrombosis. Conclusion: By the use of the prodrug principle, H 376/95 endows the direct thrombin inhibitor melagatran with pharmacokinetic properties required for oral administration without compromising the promising pharmacodynamic properties of melagatran.     

In vitro and in vivo studies of AT-1362, a newly synthesized and orally active inhibitor of thrombin

AT-1362 was found to be a potent, selective, and competitive inhibitor of thrombin, with a Ki value of 6.7 nM. In a rat model of venous thrombosis induced by partial stasis and endothelial disruption, the ID(50) values (a dose required to obtain 50% inhibition of thrombus formation over each vehicle group) of AT-1362 and argatroban were 0.03 mg/kg i.v. plus 0.5 microg/kg/minute and 0. 13 mg/kg i.v. plus 8.7 microg/kg/minute, respectively, and the antithrombotic effect of AT-1362 without prolongation of bleeding time lasted for 2 hours and disappeared 4 hours after oral administration of 30 mg/kg. In the rat tail transection model, the BT(2) values (a dose causing two-fold prolongation of the bleeding time over each vehicle group) of AT-1362 and argatroban were 0.56 mg/kg i.v. plus 9.3 microg/kg/minute and 1.1 mg/kg i.v. plus 73.3 microg/kg/minute, respectively. The reduction of thrombus formation and the prolongation of bleeding time were correlated with an ex vivo activated partial thromboplastin time (APTT) for both drugs. AT-1362 at 0.3 mg/kg i.v. plus 5 microg/kg/minute and argatroban at 0.6 mg/kg i.v. plus 40 microg/kg/minute significantly (p<0.05 and p<0.01, respectively) improved the vessel patency in a FeCl(2)-induced carotid artery thrombosis model in rats. These results suggest that AT-1362 may be a potent antithrombotic agent for the treatment of thrombotic diseases.     

The pharmacodynamics and pharmacokinetics of the oral direct thrombin inhibitor ximelagatran and its active metabolite melagatran: a mini-review

Ximelagatran (Exanta, AstraZeneca) is a novel, oral direct thrombin inhibitor (oral DTI) that is rapidly converted to melagatran, its active form, following absorption. Melagatran has been shown to be a potent, rapidly binding, competitive inhibitor of human alpha-thrombin that inhibits both thrombin activity and generation. Melagatran also effectively inhibits both free and clot-bound thrombin. Melagatran has a wide therapeutic interval that enables it to be administered safely across a wide range of doses with no increased risk of bleeding, in contrast with warfarin whose narrow therapeutic window necessitates monitoring of its pharmacodynamic effect. Although melagatran has all the pharmacodynamic properties required of a new antithrombotic agent, low oral bioavailability that is even further reduced by the concomitant intake of food precludes its development as an oral agent. It was this that propelled the development of its prodrug, ximelagatran, which is 170 times more lipophilic than melagatran and uncharged at intestinal pH. Ximelagatran is therefore much better than melagatran at penetrating the gastrointestinal barrier and, as a consequence, has sufficient bioavailability (20%) for oral administration. Moreover, its pharmacokinetic properties following oral administration are stable and reproducible, with no food interactions and a low potential for drug-drug interactions. These properties allow ximelagatran to be administered twice daily according to a fixed dose regimen without coagulation monitoring. As a consequence of its favourable pharmacokinetic and pharmacodynamic properties, ximelagatran is currently undergoing full-scale clinical development for the prophylaxis and treatment of thromboembolic disorders.     

Antithrombotic and bleeding effects of a new synthetic direct thrombin inhibitor and of standard heparin in the rabbit

This study reports on the anticoagulant, antithrombotic and bleeding effects of a new synthetic direct thrombin inhibitor (SDTI) in comparison with standard heparin (SH). The anticoagulant effect was determined with the thrombin clotting time (TCT) and the activated partial thromboplastin time (APTT). SDTI was more potent than SH in prolonging the TCT, but as potent as SH in prolonging the APTT. The antithrombotic effect was determined using a modified Wessler model in the rabbit, either 30 min after a continuous IV infusion of increasing doses or at various times after a single SC injection (20 mg/kg). After continuous IV infusion of 187 micrograms/kg/h of SDTI and of 60 micrograms/kg/h of SH, significant thrombus prevention effects were obtained (59 and 57% respectively). Increasing the dose of SDTI up to 3000 micrograms/kg/h did not significantly improve the antithrombotic effect. After SC injection, a significant antithrombotic effect was observed for 12 h with SDTI but for more than 24 h with SH. The bleeding effect was studied using the rabbit ear model 15 min after a continuous infusion of 7.5 and 15 mg/kg/h: the amounts of blood loss were dose-dependent and comparable for SDTI and SH. These studies also indicated that SDTI possesses a considerable shorter half-life in comparison with SH. Accordingly, the ex vivo concentrations generated after continuous IV infusion or SC injection of the same dose were higher for SH than for the SDTI.     

Comparison of the effect of edoxaban,a direct factor Xa inhibitor,with a direct thrombin inhibitor,melagatran, and heparin on intracerebral hemorrhage induced by collagenase in rats

Introduction

Intracerebral hemorrhage (ICH) is a major clinical concern with anticoagulation therapy. The effect of a new oral direct FXa inhibitor, edoxaban, was determined in a rat model of ICH and compared with a direct thrombin inhibitor, melagatran, and heparin.

Methods

To induce ICH, 0.1 U collagenase type VII was injected into the striatum of male Wistar rats under anesthesia with thiopental or halothane. Immediately after ICH induction, edoxaban, melagatran, or heparin were infused intravenously. Five hours after ICH induction, the brain was removed and ICH size was measured. To estimate the margin of safety, antithrombotic effects were evaluated in a rat venous thrombosis model.

Results

Edoxaban at 6 mg/kg/h significantly increased ICH volume (1.8-fold) and prolonged prothrombin time (PT) 2.8-fold compared to the vehicle group. No deaths were observed with edoxaban. Melagatran at 1 mg/kg/h increased ICH volume at 1 mg/kg/h (2.8-fold) with 6.1-fold PT prolongation. At 3 mg/kg/h, all rats died due to severe ICH (3.9-fold). Heparin at both 100 and 500 U/kg/h significantly increased ICH. At 500 U/kg/h, 5 out of 8 rats died. The doses required for 50% inhibition of thrombosis of edoxaban, melagatran, and heparin were 0.045 mg/kg/h, 0.14 mg/kg/h, and 55 U/kg/h, respectively. The safety margins between antithrombotic and ICH exacerbation effects of these anticoagulants were 133, 7.1, and 1.8, respectively.

Conclusion

The safety margin of edoxaban was wider than that of melagatran or heparin. These results suggest that edoxaban may be preferable from the perspective of ICH exacerbation risk.     

Discovery of glycyrrhetinic acid as an orally active,direct inhibitor of blood coagulation factor xa

Introduction

Factor Xa (FXa) plays an important role in blood coagulation. This study investigated glycyrrhetinic acid, a small molecule derived from Chinese herbs, and whether it has a direct inhibitory effect on FXa to display its anticoagulant activity.

Materials and Methods

Enzyme activities of FXa, plasmin, trypsin and thrombin, inhibition of FXa enzyme kinetics and plasma clotting time by glycyrrhentinic acid were performed in vitro. A rat tail-bleeding model and a rat venous stasis model were also used to evaluate in vivo tail-bleeding time and thrombus formation, respectively.

Results

Glycyrrhetinic acid in vitro directly inhibited FXa uncompetitivly with IC₅₀ of 32.6 ± 1.24 μmol/L, and displayed 2-, 14- and 20-fold selectivity for FXa when compared to plasmin, thrombin and trypsin, respectively. The plasma clotting time was increased in a dose-dependent manner. The prothrombin time doubled (PT₂), when the concentration of glycyrrhetinic acid reached 2.02 mmol/L. During in vivo experiments intragastric administration of glycyrrhetinic acid caused a dose-dependent reduction in thrombus weight on the rat venous stasis model (all P < 0.05). 50 mg/kg glycyrrhetinic acid resulted in 34.8% of venous thrombus weight lost, compared to the control. In addition, 200, 300 and 400 mg/kg doses of glycyrrhetinic acid caused a moderate hemorrhagic effect in the rat tail-bleeding model by prolonging bleeding time 1.1-, 1.5- and 1.9-fold compared to the control, respectively.

Conclusions

Glycyrrhetinic acid is a direct inhibitor of FXa that is effective by oral administration, and with further research could be used to treat blood coagulation disorders.     

The inhibitory effect of melagatran, the active form of the oral direct thrombin inhibitor ximelagatran, compared with enoxaparin and r-hirudin on ex vivo thrombin generation in human plasma

INTRODUCTION: The effect of the oral direct thrombin inhibitor (DTI) ximelagatran (Exanta, AstraZeneca) on the endogenous thrombin potential (ETP) of activated plasma was investigated ex vivo using a thrombin generation assay and compared with recombinant (r)-hirudin and enoxaparin. MATERIALS AND METHODS: 120 healthy male volunteers were randomized to one of six treatment groups (n=20 in each): oral ximelagatran (15, 30, or 60 mg), intravenous r-hirudin (0.4 mg/kg bolus, 0.15 mg/kg/h infusion for 2 h, followed by 0.075 mg/kg/h infusion for 2 h), subcutaneous enoxaparin (100 IU/kg), or control (tap water administered orally). Venous blood was collected predose and at 2, 4, and 10 h postdosing. Thrombin generation was triggered by the addition of tissue factor to platelet-poor plasma, and the ETP and time to peak thrombin generation were measured. RESULTS AND CONCLUSIONS: A significant and dose-dependent reduction in ETP was observed 2 and 4 h after the administration of ximelagatran 30 mg (70.3% of predose, 95% confidence intervals 63.0-78.5, P<0.0001 at 2 h) and 60 mg (49.8%, 43.2-57.4, P<0.0001 at 2 h), r-hirudin (19.5%, 10.1-37.6, P<0.0001 at 2 h), and enoxaparin (34.2%, 21.4-54.7, P<0.0001 at 2 h). Ximelagatran (30 mg, 3.79 min, 3.52-4.08 at 2 h), r-hirudin (6.23 min, 4.93-7.86 at 2 h), and enoxaparin (4.68 min, 3.30-6.64 at 2 h) also delayed the lag phase before the thrombin generation burst compared to placebo (2.92 min, 2.71-3.25 at 2 h). The oral DTI ximelagatran, in its active form melagatran, is a potent thrombin inhibitor that efficiently decreases ETP and delays the generation of thrombin in plasma in this ex vivo model.     

In vitro comparison of dabigatran, unfractionated heparin, and low-molecular-weight heparin in preventing thrombus formation on mechanical heart valves

Introduction

Lifelong oral anticoagulation (OAC) therapy is required for the prevention of thromboembolic events after implantation of an artificial heart valve. Thromboembolism and anticoagulant-related bleedings account for ≈ 75% of all complications experienced by heart valve recipients (2-9% of patients per year). The present study investigated the efficacy of dabigatran, a new direct thrombin inhibitor for oral use, as compared to unfractionated heparin (UFH) and low-molecular-weight heparin (LMWH) in preventing thrombus formation on mechanical heart valves in vitro.

Material and Methods

Blood (230 ml) from healthy young male volunteers was anticoagulated either by dabigatran (1 μmol/l), UFH (150 IU), or LMWH (100 IU). Mechanical heart valve prostheses were placed in an in vitro thrombosis tester and exposed to the anticoagulated blood samples under continuous circulation at a rate of 75 beats per minute.

Results

In whole blood with no anticoagulant, the apparatus completely clotted in 15-20 minutes. When blood was treated with dabigatran, the mean thrombus weight was 164 ± 55 mg, in the UFH group 159 ± 69 mg, and in the LMWH group 182 ± 82 mg (p-value: 0.704). Electron microscopy showed no significant difference in thrombus formation in any group.

Conclusisons

Dabigatran was as effective as UFH and LMWH in preventing thrombus formation on mechanical heart valves in our in vitro investigation. Thus, we hypothesize that dabigatran etexilate might potentially be a useful and competitive orally administered alternative to UFH and LMWH for recipients of alloplastic heart valve prostheses.     

Administration of a small molecule tissue factor/factor VIIa inhibitor in a non-human primate thrombosis model of venous thrombosis: effects on thrombus formation and bleeding time

INTRODUCTION: Pharmacological treatment of deep vein thrombosis (DVT) in the future may target inhibitors of specific procoagulant proteins. This study used a non-human primate model to test the effect of PHA-798, a specific inhibitor of the tissue factor/Factor VIIa complex (TF/VIIa), on venous thrombus formation. MATERIALS AND METHODS: PHA inhibits the TF/VIIa complex with an IC(50) of 13.5 nM (K(i) 9 nM) and is more than 2000-fold selective for the TF/VIIa complex with respect to IC(50)s for factor Xa and thrombin. In the model, a thrombogenic surface was introduced into the vena cava of a primate, and the amount of thrombus accumulated after 30 min was determined. RESULTS: PHA-798 reduced thrombus formation on the thrombogenic surface in a dose-dependent manner (56+/-1.9% and 85+/-0.3% inhibition with 100 and 200 microg/kg/min PHA-798, respectively) indicating that the model is sensitive to TF/VIIa inhibition. Treatment with 1 mg/kg intravenous (IV) acetyl salicylic acid (ASA) resulted in only a slight (4-12%), non-significant inhibition of thrombus formation. However, the combination of 100 microg/kg/min PHA-798 and 1 mg/kg ASA resulted in an 89% inhibition of thrombus formation. Additionally, while ASA alone increased bleeding time (BT) from 3.3 min at baseline to 4.6 min following treatment, addition of PHA-798 (100 microg/kg/min) to ASA did not significantly increase the BT further (4.7 min). CONCLUSIONS: The results of this study indicate that inhibition of TF/VIIa may be safe and effective for the prevention of the proprogation of venous thrombosis and that the combination of ASA and PHA may provide increased efficacy with little change in safety.     

Anticoagulant action of melagatran, the active form of the oral direct thrombin inhibitor ximelagatran, in umbilical cord and adult plasma: an in vitro examination

INTRODUCTION:This study was performed to compare the anticoagulant activity of melagatran, the active form of the oral direct thrombin inhibitor ximelagatran, in umbilical cord plasma with that in adult plasma. In contrast with the most frequently administered anticoagulants, the heparins, melagatran acts independently of antithrombin (AT). As a consequence, administration of melagatran is of special interest in neonates, who have physiologically low levels of AT. MATERIALS AND METHODS: Plasma samples were activated under high (as used in standard clotting assays) and low (more comparable with the physiological milieu) coagulant challenge. In the absence of melagatran, adult plasma clotted significantly faster than umbilical cord plasma under high coagulant challenge. Conversely, under low coagulant challenge, clotting of adult plasma was significantly delayed compared with umbilical cord plasma. For both high and low coagulant challenges, clotting times increased and prothrombin fragment 1.2 and thrombin-antithrombin (TAT) formation decreased with melagatran in a concentration-dependent fashion in umbilical cord and adult plasma. With increasing melagatran concentrations, the quotient between prothrombin fragment 1.2 and TAT formation increased in adult and umbilical cord plasma under both high and low coagulant challenges. RESULTS AND CONCLUSIONS: Our in vitro results cannot be directly extrapolated to clinical efficacy, but assessing the degree of inhibition of thrombin generation may be a useful surrogate for selecting effective doses of ximelagatran for in vivo studies in neonates with thromboembolic complications.     

Antithrombotic effects and bleeding time of thrombin inhibitors and warfarin in the rat.

Warfarin limits the synthesis of y-glutamyl carboxylated forms of coagulation factors, factor II, factor VII, factor IX, and factor X, protein C, and protein S and as a result impairs the function of these proteins. In contrast, direct inhibitors of thrombin only affect one enzyme in the coagulation cascade. The aim of this study was to investigate the antithrombotic effect and the slope of the dose-response curves of the multifactorial coagulation inhibitor warfarin in comparison with the single factor low-molecular-weight thrombin inhibitors melagatran and inogatran. An arterial thrombosis model in rats was used, and vessel damage was induced by topical application of ferric chloride to the carotid artery. The slopes of the dose-response curves were 3.6, 1.8, 1.1, and 1.2, for warfarin, heparin, inogatran, and melagatran, respectively. For warfarin the antithrombotic effect increased from 23% to 81% when the dose was doubled. In contrast, 10-fold increases in the doses of inogatran and melagatran were necessary to obtain a similar increase in antithrombotic effect. The doses needed to obtain 80% antithrombotic effect for heparin, warfarin, and melagatran were investigated in a tail transection bleeding model. For heparin, this dose significantly prolonged the bleeding time and the blood loss; for warfarin, only the total bleeding time was increased while for melagatran there was no increase in bleeding. We conclude that, thrombin inhibitors affecting only one enzyme in the coagulation cascade seem preferable to inhibitors affecting multiple enzymes, such as warfarin, due to shallower dose-response curves and a wider therapeutic interval.     

Inhibition of thrombin generation by the oral direct thrombin inhibitor ximelagatran in shed blood from healthy male subjects

Ximelagatran, an oral direct thrombin inhibitor, whose active form is melagatran, was studied using a model of thrombin generation in humans. Healthy male volunteers (18 per group) received ximelagatran (60 mg p.o.), dalteparin (120 IU/kg s.c.) or a control (water p.o.). Shed blood, collected after incision of the forearm with standardised bleeding time devices at pre-dose, and at 2, 4 and 10 h post-dosing, was analysed for markers of thrombin generation. Statistically significant reductions (p < 0.05) in levels of prothrombin fragment 1+2 (F1+2) and thrombin-antithrombin complex (TAT) in shed blood were detected at 2 and 4 h post-dosing in both the ximelagatran and dalteparin groups. Shed blood F1+2 and TAT levels had returned to pre-dose levels at 10 h post-dosing. Using a shed blood model, we demonstrate that the reversible thrombin inhibitor melagatran and, therefore, oral administration of ximelagatran, inhibits thrombin generation in humans after acute activation of coagulation.     

Cost-effectiveness of dabigatran etexilate for the prevention of stroke and systemic embolism in atrial fibrillation in Taiwan

Background

Economic evaluation of dabigatran, a new anti-antithrombotic agent, is done mostly in Western countries. It remains to be seen whether dabigatran will be cost effective in a practice environment where warfarin is significantly underused and the costs of both warfarin and international normalized ration INR monitoring are cheap.

Methods

We performed a cost-effectiveness analysis with a Markov model to evaluate the value of dabigatran to prevent stroke and systemic embolism in patients with atrial fibrillation (AF) in Taiwan. Dabigatran was given through sequential dosing, where patients < 80 years old received 150 mg of dabigatran twice a day and the dosage was reduced to 110 mgs for patients ≥ 80 years old. Dabigatran was compared with warfarin under two scenarios: the “real-world adjusted-dose warfarin” assuming all AF patients eligible for warfarin were given the medication and maintained at the INR observed in routine clinical practice in Taiwan, and the “real-world prescribing behaviour” similar to the treatment with antithrombotics in real-world practice in Taiwan, where eligible patients could receive warfarin, aspirin, or no treatment.

Results

The percentage of AF patients who received warfarin, aspirin or no treatment in Taiwan was 16%, 62% and 22%, respectively. The event rates of ischemic stroke per 100 patient-years were 4.5, 8.0, and 6.0 for sequential dabigatran, real-world prescribing behaviour and real-world warfarin use, respectively. The incremental cost-effectiveness ratio was $280 US per quality-adjusted-year (QALY) in the real-world prescribing scenario and $10,551 US/QALY in real-word warfarin use.

Conclusions

Dabigatran was highly cost-effective in a clinical practice setting where warfarin has been significantly underused.     

Effects of prothrombin fragments on thrombin, on thrombin formation, and separation, and separation from Ac-globulin (factor V).

Bovine prothrombin fragment 2 (profragment 2) and prethrombin 1 were found in normal oxalated bovine plasma after extensive adsorption with barium carbonate. This implies continuous physiological utilization of prothrombin. Ac-globulin-profragment 2 complex was isolated from plasma by the method of Dombrose and Seegers. This purified complex dissociated at pH 7.2 in a buffer consisting of 0.15 M NaCl in 0.15 M phosphate buffer. The two proteins were separated by ultrafiltration. The profragment 2 passed through the filter while the Ac-globulin (Factor V) was retained in pure form. Purified bovine profragment 2 enhanced esterase activity of thrombin and retarded the clotting function, thus producing a large esterase/coagulation ratio in prethrombin 1 activation mixtures. Inhibition of the thrombin-fibrinogen reaction by profragment 2 must be taken into account in some assays for prothrombin or prethrombin 1. If profragment 2 is not bound in the activation mixture of a prothrombin assay, a low thrombin titer may be recorded. Contrary to a previous conclusion reached in this laboratory, there is no enzyme with only esterase activity in the following degradation sequence: Prothrombin → Prethrombin 1 → Prethrombin 2 → Thrombin. The esterase enhancement of thrombin and its coagulation inhibition by profragment 2 were neutralized by additions of purified Ac-globulin or by specific antibodies to profragment 2. The procoagulant or anticoagulant properties of purified bovine prothrombin fragment 1 (profragment 1) were studied. For that purpose, purified bovine profragment 1 was incubated with purified Ac-globulin, purified autoprothrombin C (Factor Xa), crude “cephalin,” and calcium ions. Due to profragment 1, the procoagulant function of the mixture diminished when tested against purified prothrombin as substrate, but the procoagulant function increased when tested against purified prethrombin 1 as substrate. Thus, depending upon conditions, profragment 1 can function as a procoagulant or as an anticoagulant.