A specific inhibitor of factor Xa, DX-9065a, exerts effective protection against experimental tumor induced disseminated intravascular coagulation in rats

(+)-2S-2-[4-[[(35S)-1-acetimidoyl-3-pyrrolidinyl]oxy]phenyl]-3-[7- amidino-2-napthyl]propanoic acid hydrochloride pentahydrate (DX-9065a) is an antithrombin III-independent, selective inhibitor of activated blood coagulation factor X (FXa). We investigated the protective effects of DX-9065a against tumor-bearing experimental disseminated intravascular coagulation (DIC) induced by the inoculation of AH-109A cells into rats. DX-9065a was subcutaneously administered at doses of 0.03 and 0.1 mg/kg/hour through an osmotic pump transplanted immediately after the inoculation of the tumor cells during the observation period. Platelet count decreased 12 days after the inoculation, concomitant with an increase in the thrombin-antithrombin III complex and fibrin and fibrinogen degradation products. Doses of 0.03 and 0.1 mg/kg/hour of DX-9065a significantly inhibited the decrease in plasma fibrinogen concentration and platelet count 13 days after the inoculation, respectively. These findings suggest that direct, selective inhibition of FXa by DX-9065a improves the hypercoagulable state induced by the progress of solid tumor.     

DX-9065a, an orally active factor Xa inhibitor, does not facilitate haemorrhage induced by tail transection or gastric ulcer at the effective doses in rat thrombosis model.

DX-9065a is an antithrombin III (AT III)-independent and selective inhibitor of activated blood coagulation factor X (FXa). We evaluated the effects of DX-9065a and warfarin on bleeding time and blood loss in rat tail transection model and on blood loss in hydrochloride (HCl)-induced rat gastrointestinal haemorrhage model. The blood loss was determined by measuring the haemoglobin content in saline immersed with transected tail or hematin chloride content in the gaster after HCl administration. DX-9065a or warfarin was administered orally at 1 h or 15-21 h before the haemorrhagic stimuli, respectively. The dose required for 50% inhibition of thrombus formation (ID50) was 21 mg/kg for DX-9065a and 0.75 mg/kg for warfarin in a copper wire-inserted arteriovenous (AV) shunt model. In contrast to DX-9065a (10 or 30 mg/kg), warfarin (0.75 mg/kg) significantly prolonged the bleeding time. In rat tail transection model, the blood loss for the control group was 102+/-41 microl at 20 min after the transection. While warfarin (0.75 mg/kg) facilitated the blood loss about 5 times as much as the control, DX-9065a (10 or 30 mg/kg) did not. In rat gastrointestinal model, the blood loss for the control group was 15.9+/-5.6 microl at 15 min after HCl administration. In contrast to DX-9065a (10 or 30 mg/kg), warfarin (0.75 mg/kg) increased the blood loss about twice as much as the control. Thus, compared with warfarin, DX-9065a only increased bleeding time or blood loss to a minor extent in the doses tested. These observations suggest that direct inhibition of FXa could be preferable to warfarin in the suppression of thrombosis without haemorrhagic complications.     

Effective inhibition of experimental metastasis and prolongation of survival in mice by a potent factor Xa-specific synthetic serine protease inhibitor with weak anticoagulant activity

Clinical and experimental evidence suggests that the blood coagulation system is involved in the dissemination of malignant tumors. Consequently, anticoagulant agents have been tested as metastasis suppressors in experimental models. Recently, we have found a close correlation between factor Xa (FXa)-specificity of a series of synthetic serine protease inhibitors and their anti-metastatic potential in a murine T-cell lymphoma metastasis model. Interference of such inhibitors with blood-coagulation may represent a major experimental and clinical obstacle. Here, we test anti-metastatic effects of a recently developed, highly specific 3-amidinophenylalanine-type FXa inhibitor, WX-FX4, with weaker anticoagulant activity when compared to well-established FXa inhibitors, such as DX-9065a, as measured by the activated partial thromboplastin time, prothrombin time, prothrombinase complex activity, and coagulation time. Treatment of mice with WX-FX4 (1.5 mg/kg twice daily) led to significant reduction of experimental liver metastasis of a syngeneic T-cell lymphoma in DBA/2 mice (> 90%), and of experimental lung metastasis of a human fibrosarcoma in CD1 nu/nu mice (> 60%). Due to its relatively low anticoagulant activity, daily treatment over 100 days was possible, leading to significant survival benefits without inducing bleeding anomalities. FXa-inhibitors with highly efficient anti-metastatic potential without coagulation-related side effects may represent important new tools as anticancer agents.     

DX-9065a inhibition of factor Xa and the prothrombinase complex: mechanism of inhibition and comparison with therapeutic heparins

Factor Xa (fXa) is the key enzyme of the prothrombinase complex that generates thrombin hence it is a good target for antithrombotic therapy. Here, the anti-fXa and anti-prothrombinase activities of DX-9065a which is an active-site directed inhibitor of fXa, and therapeutic heparins which are dependent on antithrombin (AT) for their anticoagulant function, were studied in amidolytic and proteolytic activity assays. It was found that DX-9065a is a competitive inhibitor of the Spectrozyme FXa (SpFXa) cleavage by both fXa and prothrombinase with similar K(i) values of approximately 10-20 nM. However, DX-9065a acted as a non-competitive inhibitor of prothrombin activation by prothrombinase with a Ki of approximately 26 nM. On the other hand, therapeutic heparins were effective catalysts of both fXa and prothrombinase inhibition by AT in the presence of SpFXa, but were ineffective in the presence of prothrombin. Further studies revealed that Tyr(99), a residue in the extended S2-S4 binding pocket of fXa, plays a key role in determination of specificity of the DX-9065a interaction.     

Comparison of antithrombotic and haemorrhagic effects of edoxaban, an oral direct factor Xa inhibitor, with warfarin and enoxaparin in rats

Introduction

Factor Xa (FXa) is a key serine protease in the coagulation cascade and a promising target for a new antithrombotic agent. Edoxaban is an oral, selective and direct FXa inhibitor. The objective of this study was to compare the antithrombotic and haemorrhagic effects of edoxaban with clinically available anticoagulants, warfarin and enoxaparin, in rat models of thrombosis and haemorrhage.

Methods

Rats were treated with single oral administration of edoxaban, repeated oral dosing of warfarin for 4 days and single subcutaneous administration of enoxaparin before thrombosis or haemorrhage induction. Thrombosis was induced by the insertion of a platinum wire into the inferior vena cava for 60 min. Tail template bleeding time was measured after making an incision on the tail.

Results

Edoxaban at 0.3, 1 and 3 mg/kg exerted dose-dependent and significant inhibition of venous thrombus formation. The 50% thrombus inhibition dose (ED₅₀) was 1.9 mg/kg. At supra-therapeutic doses (10 and 20 mg/kg), edoxaban significantly but moderately (less than 2-fold) prolonged bleeding time. Warfarin and enoxaparin also dose-dependently inhibited venous thrombosis and prolonged bleeding time. The ED₅₀ values of warfarin and enoxaparin were 0.12 mg/kg and 500 IU/kg, and the 2-fold bleeding time prolongation doses (BT2) were 0.16 mg/kg and 1700 IU/kg, respectively. The safety margin (ratio of BT2 to ED₅₀) of edoxaban (> 10.5) was greater than those of warfarin (1.3) and enoxaparin (3.4).

Conclusions

Edoxaban inhibited venous thrombosis comparably to warfarin and enoxaparin, and the attendant bleeding risk of edoxaban was lower than that of warfarin and enoxaparin in rats.     

Effect of the novel direct factor Xa inhibitor DX-9065a on thrombin generation and inhibition among patients with stable atherosclerotic coronary artery disease

INTRODUCTION: Thrombin, a pluripotential effector enzyme with prothrombotic, proinflammatory, and mitogenic properties, plays a pivotal role in the pathobiology and clinical expression of atherothrombotic coronary artery disease. Existing anticoagulant drugs have not been shown to attenuate thrombin generation or activity consistently. We sought to investigate the effect of DX-9065a on thrombin generation and inhibition in patients with stable CAD. DX-9065a is a small-molecule, synthetic, direct inhibitor of factor Xa. MATERIALS AND METHODS: Peripheral venous blood samples were collected serially during and after administration of either placebo or 1 of 4 weight-adjusted regimens of DX-9065a, in 73 patients with stable CAD participating in the XaNADU-1B study. RESULTS AND CONCLUSIONS: At baseline, the median (25th, 75th) prothrombin activation fragment 1.2 (F1.2) level was 2.56 (2.05, 3.20) nmol/L, and the median d-dimer level was 0.26 (0.19, 0.38) mug FEU/L. There were significant relationships between measured plasma DX-9065a concentrations and both F1.2 (4.9% decrease for each doubling of DX-9065a) (P<0.0001) and d-dimer (5.5% decrease for each doubling of DX-9065a) (P=0.001). F1.2 was suppressed (below baseline) at 96 h after administration of DX-9065a. Coronary thrombotic events did not occur during or after study drug administration. DX-9065a, the first in a class of small-molecule, direct, selective and reversible factor Xa inhibitors, reduces thrombin generation and fibrin formation among patients with stable CAD. The effect is concentration-dependent and persists for at least 96 h following drug cessation, without biochemical or clinical evidence of rebound.     

A synthetic inhibitor of factor Xa, DX-9065a, reduces proliferation of vascular smooth muscle cells in vivo in rats

The effect of factor Xa inactivation on the proliferation of vascular smooth muscle cells in vivo was investigated in an experimental restenosis model in rats by using the direct factor Xa inhibitor DX-9065a. In the left common carotid artery, an injury of the vascular endothelium was produced by four external vessel clamps for 60 minutes. After 14 days, 3H-labeled methyl thymidine and 5-bromo-2'-deoxyuridine, respectively, were injected intraperitoneally. After 24 hours, both the left (damaged) and right (nondamaged) carotid arteries were removed, and the incorporation of 3H-methyl thymidine/microg protein was determined. For morphological analysis, the cells were labeled with hematoxylin as well as 5-bromo-2'-deoxyuridine. Stained vascular smooth muscle cell nuclei were counted, and the proliferation index (percentage of 5-bromo-2'-deoxyuridine-positive nuclei to total nuclei stained with hematoxylin) was determined. An external damage of the carotid artery induced proliferation of vascular smooth muscle cells and formation of a neointima within 2 weeks after vessel injury. As compared with control animals, single subcutaneous injection of DX-9065a (2.5, 5, and 10 mg/kg) given 30 minutes before vessel injury significantly reduced the incorporation of 3H-methyl thymidine/microg protein and the total cell number, as well as the proliferation index. The antiproliferative action of DX-9065a was not dose dependent in the range from 2.5 to 10 mg/kg s.c. A combination of bolus injection (5 mg/kg s.c.) with continuous administration (5 mg/kg/d s.c. for 7 and 14 days, respectively) did not increase the antiproliferative effect of DX-9065a. The results indicate a role of factor Xa in the complex pathogenesis of restenosis and the usefulness of a highly effective and selective inhibitor of factor Xa to inhibit proliferative processes.     

Evaluation of a novel kallikrein inhibitor on hemostatic activation in vitro

BACKGROUND: DX-88 is a potent kallikrein inhibitor that is being studied for the treatment of hereditary angioedema (HAE) and represents a potential alternative to aprotinin in cardiac surgical patients. The current study was designed to evaluate in vitro effects of DX-88 on coagulation in comparison with aprotinin. METHODS: Blood samples were obtained from consented 12 healthy volunteers. DX-88 or aprotinin was added to blood at 200 and 800 kallikrein inhibitory units (KIU) per milliliter for aprotinin, and at 1.1, 2.2, or 8.8 microg/ml for DX-88. Thromboelastography (TEG) was performed using celite, kaolin, or tissue factor (TF) activation. Kaolin-based activated clotting times (ACTs) were measured at different heparin levels. The whole blood prothrombin time (PT)/PTT values were also measured. The endogenous thrombin generation was assessed with a fluorogenic assay using platelet-poor plasma (PPP). RESULTS: With celite and kaolin activation of TEG, the reaction time was prolonged with DX-88 and aprotinin. With tissue factor activation, TEG parameters were not affected. DX-88 caused dose-dependent kaolin-ACT prolongation that was augmented by increasing doses of heparin. DX-88 or aprotinin had no significant effects on the PT values, but PTT values were dose-dependently prolonged. Both agents delayed the onset of thrombin generation when PTT reagent was used as a trigger, whereas no change was observed when tissue factor was used. CONCLUSION: We found that DX-88 delayed contact activator induced coagulation without affecting tissue factor mediated coagulation. For evaluation of coagulation during DX-88 therapy, the use of PT or tissue factor-activated TEG may be preferable.     

Signs of thrombin generation in pediatric cardiac catheterization with unfractionated heparin bolus or subcutaneous low molecular weight heparin for antithrombotic cover

Introduction: Thrombosis is one of the most frequent adverse events after cardiac catheterization, which can be reduced by anticoagulation with unfractionated heparin (UFH) in both children and adults. Low molecular weight heparin (LMWH) might possibly offer advantages. Laboratory signs of thrombin generation during pediatric cardiac catheterization, with unfractionated heparin (UFH) bolus or subcutaneous LMWH for thrombosis prophylaxis, were determined in a first step to investigate the potential of LMWH for antithrombotic cover. Materials and methods: Signs of thrombin generation (D-dimer and F₁₊₂), anti-Xa activity and activated clotting time (ACT) were measured in 65 patients with congenital heart disease. A total of 40 patients were treated with a UFH bolus of 100 IU/kg bodyweight and, in 25 children, enoxaparin was subcutaneously administered at a dosage of 1/1.6 mg/kg bodyweight. Results: The dose to plasma activity of enoxaparin was more consistent than in the UFH group. Only a slight elevation of F₁₊₂ was found in some patients, which was a little higher in the enoxaparin group, but no difference of incidence of increased F₁₊₂ generation was detected between the two groups. D-dimer was elevated in three children after UFH bolus application, but no such effect was observed in any child after LMWH administration. Conclusions: Application of LMWH was equally efficacious during pediatric cardiac catheterization than UFH bolus administration, as determined by plasma levels and markers of clotting activation. In contrast to UFH bolus, no further monitoring was necessary after the application of LMWH during cardiac catheterization due to a consistent dose to plasma activity.     

Comparison of antithrombotic efficacy between edoxaban, a direct factor Xa inhibitor, and fondaparinux, an indirect factor Xa inhibitor under low and high shear rates

Edoxaban is an oral, direct factor Xa (FXa) inhibitor under late-phase clinical development. This study compared the antithrombotic efficacy of edoxaban with that of an indirect FXa inhibitor, fondaparinux, in in vivo venous and arterial thrombosis models and in ex vivo perfusion chamber thrombosis model under low and high shear rates in rats. Venous and arterial thrombi were induced by platinum wire insertion into the inferior vena cava and by application of FeCl? to the carotid artery, respectively. The perfusion chamber thrombus was formed by blood perfusion into a collagen-coated capillary at 150 s?1 (low shear rate) and 1,600 s?1 (high shear rate). Effective doses of edoxaban that reduced thrombus formation by 50% (ED??) in venous and arterial thrombosis models were 0.076 and 0.093 mg/kg/h, respectively. In contrast, ED?? of fondaparinux in the arterial thrombosis model (>10 mg/kg/h) was markedly higher compared to ED?? in the venous thrombosis model (0.021 mg/kg/h). In the perfusion chamber thrombosis model, the ratio of ED?? under high shear rate (1.13 mg/kg/h) to that under low shear rate (0.63 mg/kg/h) for edoxaban was 1.9, whereas that for fondaparinux was more than 66. While the efficacy of fondaparinux markedly decreased in arterial thrombosis and in a high-shear state, edoxaban exerted consistent antithrombotic effects regardless of flow conditions. These results suggest that shear rate is a key factor in different antithrombotic effects between edoxaban and fondaparinux.     

Effects of acetyl salicylic acid therapy on an experimental thrombosis induced by laser beam

Aspirin inhibits the synthesis of both platelet and vascular arachidonic acid metabolism which have opposite effects on platelet functions. The rationale for its clinical use as an antithrombotic drug has therefore been questioned. Therefore, we investigated the effects of acetylsalicylic acid (ASA) at 100 mg/kg on an experimental thrombosis induced by laser beams using different groups of rats that were previously treated with the same dose (100 mg/kg), according to the delay between the first and second injections. A partial occlusion was induced by laser beams in the rat mesenteric microvessels (15-25 m). The thrombus formed within seconds after the laser lesion; both it and the embolization which began within minutes after, were continuously accounted. Experiments were done on 11 groups of 5 animals each: 45 rats received a first injection of ASA at j(0) and a second injection 30 minutes before thrombosis induction at j(0)+x (x=2, 4, 6, 8, 9, 10, 12, 14 and 16 days). Different groups are defined according to the x value. The rats receiving NaCl 0.9% or a single injection of ASA at 100 mg/kg 30 minutes before thrombosis induction were used as control (Group I) and reference group (Group II) respectively. In this study, ASA treatment showed two types of results. The administration of ASA (100 mg/kg) 30 minutes before laser-induced thrombosis prevented thrombus formation. In the same way, ASA injected to rats already treated with the same dose 2 or 4 day later also demonstrated a potent antithrombotic effect. The same trends were observed with animals receiving the second injection (100 mg ASA) at j(0+8), j(0+12), j(0+14), and j(0+16). However, when injected to rats at j(0+6) and at j(0+10), ASA did not shown any effects on thrombus formation compared to the control (p>/=0.05). The same phases of ASA action were observed on the induced hemorrhagic time. The antithrombotic effects of the later second injection of ASA (100 mg/kg) were neutralized in rats previously receiving the same dose of this drug. This phenomenon seems to be periodic and is of great importance for the observance of ASA treatment.     

Factor Xa acts as a PDGF-independent mitogen in human vascular smooth muscle cells

This study investigates the mitogenic effect of the coagulation factor Xa in smooth muscle cells (SMC) from human saphenous vein and the procoagulant activity of these cells. Factor Xa elicited a concentration-dependent increase in [3H]thymidine incorporation. This mitogenic effect of factor Xa was inhibited by DX-9065a and BABCH, indicating the requirement of proteolytic activity of the enzyme. Factor Xa activated the MAP kinases ERK1/2 concentration- and time-dependently. PDGF-neutralizing antibodies neither inhibited the increase in [3H]thymidine incorporation nor ERK-1/2 phosphorylation in factor Xa-stimulated cells, suggesting that factor Xa-induced signaling and mitogenic activity in human venous SMC are independent of PDGF. Exposure of SMC to recalcified plasma resulted in a significant thrombin generation which was inhibited by anti-tissue factor antibody, tissue factor pathway inhibitor, inactivated factor VIIa and DX-9065a. These data indicate that interaction of SMC with the clotting system may contribute to venous graft disease, i.e. thrombus formation and intimal hyperplasia.     

Effect of edoxaban on markers of coagulation in venous and shed blood compared with fondaparinux

Edoxaban, an oral direct factor Xa (FXa) inhibitor, is in phase III clinical development for stroke prevention in atrial fibrillation and treatment of venous thromboembolism. The shed blood model allows for study of activated coagulation at a site of standardised tissue injury due to local release of tissue factor. The objective of this study was to evaluate the effect of three doses of edoxaban on markers of coagulation in shed and venous blood versus placebo and a standard prophylactic dose of fondaparinux. A total of 100 healthy male subjects were randomised to receive single doses of one of five treatments: subcutaneously administered fondaparinux 2.5 mg; orally administered edoxaban 30, 60, or 120 mg; or placebo. The primary objective was measurement of blood coagulation markers prothrombin fragment 1+2 (F1+2) and thrombin-antithrombin (TAT) complex, and platelet activation marker β-thromboglobulin (β-TG), in venous and shed blood. Secondary objectives included pharmacokinetics, shed blood volume, and safety of edoxaban. Single doses of edoxaban caused rapid and significant decreases of F1+2, TAT, and β-TG in the shed blood model, indicating inhibition of thrombin generation and platelet activation. Inhibition was significantly less for fondaparinux versus edoxaban. Baseline-corrected F1+2, TAT, and β-TG values demonstrated sustained inhibition up to 24 hours for shed blood in the edoxaban groups but no significant inhibition in venous blood. Overall, edoxaban treatments were well tolerated. In conclusion, single oral doses of edoxaban 30, 60, or 120 mg caused rapid and sustained inhibition of coagulation up to 24 hours in the shed blood model.     

Enhanced endogenous thrombolysis induced by a specific factor Xa inhibitor,DX-9065a,evaluated in a rat arterial thrombolysis model in vivo

We have previously established an animal model to investigate mechanisms of arterial thrombolysis in vivo and have demonstrated that endogenous thrombolysis, mediated by thrombin-activatable fibrinolysis inhibitor, is enhanced by administration of specific thrombin inhibitors. The aim of the present study was to evaluate the effects of a synthetic and specific factor Xa inhibitor, DX-9065a, on endogenous fibrinolysis. Mural thrombi were formed in rat mesenteric arterioles by helium-neon laser irradiation in the presence of Evans blue. Thrombolysis was continuously monitored by video microscopy and was quantified using image analysis software. Oral and intravenous administration of DX-9065a enhanced endogenous thrombolysis in vivo. The mechanisms require additional investigation using other experimental systems, but nevertheless, the present results extended our previous findings and further suggested that the enhanced fibrinolysis might be due to depressed activity thrombin-activatable fibrinolysis inhibitor. The synthetic factor Xa inhibitor could provide the basis for a useful thrombolytic agent.     

Arterial antithrombotic effects of aspirin, heparin, enoxaparin and clopidogrel alone, or in combination, in the rat

INTRODUCTION: Many antithrombotic drugs may have a deleterious effect on normal haemostasis leading to bleeding complications. The aim of this study was to determine if sub-therapeutic (low) doses of antithrombotic agents, when administered in combination, have enhanced efficacy without augmentation of bleeding time. MATERIALS AND METHODS: The antithrombotic effects of i.v. aspirin (4-30 mg/kg), heparin (100-500 U/kg), enoxaparin (4-30 mg/kg) and clopidogrel (10-20 mg/kg) were studied in a rat Folts-like preparation of carotid arterial thrombosis. The frequency of cyclic flow reductions (CFRs; indicating occlusive thrombus formation) and bleeding time were measured. Drug doses that were singly ineffective at preventing occlusive thrombus formation were tested in the following combinations: aspirin (10 mg/kg) with heparin (250 U/kg); aspirin (4 mg/kg) with enoxaparin (4 mg/kg); and aspirin (10 mg/kg) with clopidogrel (10 mg/kg). RESULTS: Control period (pretreatment) CFRs were not significantly different between groups; average 7.0+/-0.3 CFRs/30 min (n=64). Tail bleeding time before drug(s) was 3.1+/-0.1 min (n=86). When administered alone, aspirin (4-30 mg/kg), heparin (250 U/kg) or enoxaparin (4 mg/kg) had no effect on CFRs or bleeding time. Heparin (500 U/kg), enoxaparin (10 and 30 mg/kg) and clopidogrel (20 mg/kg) significantly decreased CFRs. Single administration of heparin (500 U/kg) or enoxaparin (30 mg/kg) increased bleeding time by 4- or 11-fold. When co-administered, aspirin 10 mg/kg and heparin 250 U/kg decreased CFRs, but also increased bleeding time by 11-fold. However, combination of aspirin and enoxaparin (4 mg/kg each), or aspirin and clopidogrel (10 mg/kg each), decreased CFRs with no effect on bleeding. CONCLUSIONS: In a preparation of arterial thrombosis in the rat, combinations of sub-efficacious (low) doses of aspirin with enoxaparin or clopidogrel inhibited thrombus formation without augmenting bleeding time. However, low-dose aspirin combined with heparin, whilst inhibiting thrombus formation, exacerbated bleeding time. If these findings translate into the clinic, the use of effective low-dose combinations may have therapeutic advantages.     

Antithrombotic potential of new direct thrombin inhibitors built on the azaphenylalanine scaffold in two rat venous thrombosis models

The antithrombotic potential of new direct thrombin inhibitors built on the azaphenylalanine scaffold (LK-732, LK-639 and LK-731) and their amidoxime prodrugs (LK-658, LK-633 and LK-730) was studied in comparison to argatroban and nadroparin in two rat models of venous thrombosis, induced either by complete stasis combined with hypercoagulability (model 1) or by partial stasis combined with vessel injury (model 2). In initial experiments LK-732 was established as the most promising antithrombotic of the LK inhibitors and as such was further tested. In model 1, intravenous bolus administration of LK-732 produced a dose-dependent inhibition of thrombus formation with an ID50 value of 1.3 mg/kg. This ID50 value was approximately four times higher than the ID50 value of argatroban (0.3 mg/kg; p=0.011). However, in model 2, LK-732 and argatroban decreased thrombus weight by 50% at similar ID50 values (3.8 mg/kg vs 3.0 mg/kg, respectively; p=0.726). The ex vivo anticoagulant effect of LK-732 was substantially weaker compared to argatroban at doses that produced comparable antithrombotic effects. After subcutaneous administration, in vivo thrombus weight reduction of LK inhibitors (10 mg/kg) ranged between 22 to 48%. However, their oral antithrombotic effect at a dose of 30 mg/kg was rather low. LK amidoxime prodrugs failed to produce a substantial antithrombotic effect after subcutaneous (10 mg/kg) as well as after oral administration (30 mg/kg). In conclusion, thrombin inhibitors built on the azaphenylalanine scaffold represent a new group of intravenously effective antithrombotics. However, optimisation of the oral antithrombotic effect of amidoxime prodrug LK-658 of the lead inhibitor LK-732 is required for justifying further development of these inhibitors.     

Validation of a novel tissue factor assay in experimental human endotoxemia

BACKGROUND: Nuclear factor kappa B (NF-kappa B) activation and tissue factor (TF) expression may contribute to lethality in sepsis. Inappropriate in vivo expression of TF is likely responsible for fibrin deposition in sepsis-associated disseminated intravascular coagulation (DIC). Clinical assessment of TF expression has remained a major challenge. No point-of-care assays are currently available to measure the level of TF activity in whole blood. The current study examined the suitability of the TiFaCT assay as a point-of-care assay to detect TF expression. METHODS: 30 healthy male volunteers received 2 ng/kg of LPS. Tissue factor-dependent coagulation was quantified with a novel assay called tissue factor clotting time (TiFaCT), and by measurement of activation markers of downstream coagulation. RESULTS: Ex vivo addition of anti-TF antibodies to blood slightly increased clotting times at 0-24 h (p<0.01) indicating that some tissue factor activity was present in whole blood at any time. LPS bolus infusion decreased TiFaCT clotting time by -23% compared to baseline (p<0.01), when in vivo clotting increased, as demonstrated by a 10-fold increase in prothrombin fragment levels (F1+2). Ex vivo incubation with LPS considerably shortened TiFaCT (from 1000s to 400s as compared to control incubation; p<0.01). This effect was blunted at 2-4 h after LPS infusion (i.e. the time of monocytopenia), but twofold enhanced 24 h after LPS challenge (p<0.01). CONCLUSIONS: In summary, the TiFaCT assay was validated in our in vivo model of LPS-induced coagulation. It detected minute quantities of circulating TF even at baseline. TiFaCT is shortened at times of in vivo thrombin generation.     

The Procoagulant Envelope Virus Surface: Contribution to Enhanced Infection

Many virus types are covered by a lipid bilayer. This structure called an envelope, is derived from the host cell and includes host- and virus-encoded proteins. Because envelope components first interact with the host, it is the trigger for infection, immunity and pathology. The roles of especially host-derived constituents are poorly understood. Focusing on herpes simplex type 1 (HSV1) as a model, we have shown that the envelope acquires the physiological initiators of coagulation from the host cell; tissue factor (TF) and procoagulant phospholipid (proPL). Unlike resting cells, where TF and proPL accessibility is carefully restricted, their expression is constitutive on the purified virus enabling factor VIIa (FVIIa)-dependant factor Xa (FXa) and thrombin generation. Interestingly, HSV1-encoded glycoprotein C (gC) on the virus enhances FXa production. In addition to coagulation proteases, HSV1 also facilitates fibrinolytic plasmin generation. HSV1 TF and gC combine to optimally enhance cultured cell infection when both FVIIa and FXa are available through protease activated receptor (PAR) 2. Plasmin also increases infection through PAR2, whereas thrombin provides an additive effect via PAR1. Thus, depending on the host cell, TF and proPL may be a general feature of enveloped viruses, enabling coagulation protease activation and PAR-mediated effects on infection.     

Antithrombotic properties of Ixolaris, a potent inhibitor of the extrinsic pathway of the coagulation cascade

Ixolaris is a two-Kunitz tick salivary gland protein identified in Ixodes scapularis that presents extensive sequence homology to TFPI. It binds to FXa or FX as scaffolds and inhibits tissue factor/FVIIa complex (extrinsic Xnase). Differently from TFPI, ixolaris does not bind to the active site cleft of FXa. Instead, complex formation is mediated by the FXa heparin-binding exosite, which may also results in decreased FXa activity into the prothrombinase complex. In this report, we show that recombinant (125)I-ixolaris interacts with rat and human FX in plasma and prolongs the prothrombin time (PT) and activated partial thromboplastin time (aPTT) in vitro. We have also investigated the effects of ixolaris in vivo, using a venous thrombosis model. Subcutaneous (s.c.) or intravenous (i.v.) administration of ixolaris in rats caused a dose-dependent reduction in thrombus formation, with complete inhibition attained at 20 microg/kg and 10 microg/kg, respectively. Antithrombotic effects were observed 3 h after s.c. administration of ixolaris and lasted for 24 h thereafter. Ex vivo experiments showed that ixolaris (up to 100 microg/kg) did not affect the aPTT, while the PT was increased by approximately 0.4-fold at the highest ixolaris concentration. Remarkably, effective antithrombotic doses of ixolaris (20 microg/kg) was not associated with bleeding which was significant only at higher doses of the anticoagulant (40 microg/kg). Our experiments demonstrate that ixolaris is an effective and possibly safe antithrombotic agent in vivo.     

Recombinant tissue factor pathway inhibitor prevents lipopolysaccharide-induced systemic hypotension in rats by inhibiting excessive production of nitric oxide.

Excessive production of nitric oxide (NO) by the inducible form of NO synthase (iNOS) plays a key role in the development of endotoxin shock. Tumor necrosis factor-alpha (TNF-alpha) induces iNOS, thereby contributing to the development of shock. We recently reported that recombinant tissue factor pathway inhibitor (r-TFPI), an important inhibitor of the extrinsic pathway of the coagulation system, inhibits TNF-alpha production by monocytes. In this study, we investigated whether r-TFPI could ameliorate hypotension by inhibiting excessive production of NO in rats given lipopolysaccharide (LPS). Pretreatment of animals with r-TFPI prevented LPS-induced hypotension. Recombinant TFPI significantly inhibited the increases in both the plasma levels of NO2-/NO3- and lung iNOS activity 3 h after LPS administration. Expression of iNOS mRNA in the lung was also inhibited by intravenous administration of r-TFPI. However, neither DX-9065a, a selective inhibitor of factor Xa, nor an inactive derivative of factor VIIa (DEGR-F.Vlla) that selectively inhibits factor VIIa activity, had any effect on LPS-induced hypotension despite their potent anticoagulant effects. Moreover, neither the plasma levels of NO2-/NO3- nor lung iNOS activity were affected by administration of DX-9065a and DEGR-F.VIIa. These results suggested that r-TFPI ameliorates LPS-induced hypotension by reducing excessive production of NO in rats given LPS and this effect was not attributable to its anticoagulant effects, but to the inhibition of TNF-alpha production.