ximelagatran and Disease-Models--Animal

The search for the ideal anticoagulant has been one of the most active research fields in medicine in the past few years. Anti-vitamin K replacement, particularly in the long term treatment of venous thromboembolism is a difficult objective to achieve due to the wide experience gathered in normal practice and low costs. But to improve the weak points of these drugs is an attractive challenge and would have a great health and social impact. It can be seen that the low molecular weight heparins, or even pentasaccharide, drugs that are already available on the market, although the have very predictable pharmacokinetics, their parenteral use, or their long half life, they are far from being ideal anticoagulants. Ximelagatran, a promising drug, a direct inhibitor of thrombin seemed to be a step forward, but the appearance of undesirable side effects led to its withdrawal. However, this line of investigation has remained open, as such that we now have data from clinical trials that back it up: the direct inhibition of thrombin and activated factor X. These two different mechanisms of action are showing promising results, in that the direct inhibitors of thrombin (dabigatran, hirudins...) are showing not to be inferior in efficacy and safety to enoxaparin in the primary prophylaxis of venous thromboembolism. Similarly, the activated factor X inhibitors (Rivaroxaban, Apixaban ) are also showing the same and in some cases, superior in its prevention. This review looks at the mechanisms of action of both pharmacological groups, their effects on haemostasis, and how they are reflected in coagulation times, their pharmacokinetics and pharmacodynamics. These new anticoagulants are nearer to the ideal anticoagulant and may, in the near future, change the panorama of anticoagulation, not only at health level, but also by achieving improved levels in the quality of life of the patients.

Topics: Administration, Oral; Animals; Anticoagulants; Azetidines; Benzimidazoles; Benzylamines; Clinical Trials, Phase I as Topic; Clinical Trials, Phase II as Topic; Dabigatran; Disease Models, Animal; Factor Xa Inhibitors; Forecasting; Hemostasis; Heparin, Low-Molecular-Weight; Humans; Pyridines; Quality of Life; Thrombin; Time Factors

The oral thrombin inhibitor ximelagatran was withdrawn in the late clinical trial phase because it adversely affected the liver. In approximately 8% of treated patients, drug-induced liver injury (DILI) was expressed as transient alanine transaminase (ALT) elevations. No evidence of DILI had been revealed in the pre-clinical in vivo studies. A whole genome scan study performed on the clinical study material identified a strong genetic association between the major histocompatibility complex alleles for human leucocyte antigens (HLA) (HLA-DR7 and HLA-DQ2) and elevated ALT levels in treated patients. An immune-mediated pathogenesis was suggested. Here, we evaluated whether HLA transgenic mice models could be used to investigate whether the expression of relevant HLA molecules was enough to reproduce the DILI effects in humans. In silico modelling performed in this study revealed association of both ximelagatran (pro-drug) and melagatran (active drug) to the antigen-presenting groove of the homology modelled HLA-DR7 molecule suggesting "altered repertoire" as a key initiating event driving development of DILI in humans. Transgenic mouse strains (tgms) expressing HLA of serotype HLA-DR7 (HLA-DRB1*0701, -DRA*0102), and HLA-DQ2 (HLA-DQB1*0202,-DQA1*0201) were created. These two lines were crossed with a human (h)CD4 transgenic line, generating the two tgms DR7xhCD4 and DQ2xhCD4. To investigate whether the DILI effects observed in humans could be reproduced in tgms, the mice were treated for 28 days with ximelagatran. Results revealed no signs of DILI when biomarkers for liver toxicity were measured and histopathology was evaluated. In the ximelagatran case, presence of relevant HLA-expression in a pre-clinical model did not fulfil the prerequisite for reproducing DILI observed in patients. Nonetheless, for the first time an HLA-transgenic mouse model has been investigated for use in HLA-associated DILI induced by a low molecular weight compound. This study shows that mimicking of genetic susceptibility, expressed as DILI-associated HLA-types in mice, is not sufficient for reproducing the complex pathogenesis leading to DILI in man.

Topics: Animals; Azetidines; Benzylamines; Cell Line; Chemical and Drug Induced Liver Injury; Disease Models, Animal; Female; HLA-DQ Antigens; HLA-DR7 Antigen; Humans; Lymphocytes; Male; Mice, Inbred C57BL; Mice, Transgenic; Molecular Docking Simulation; Phenotype

Thrombin amplifies the blood coagulation via factor V (FV)-mediated positive feedback loop. We hypothesised that factor Xa (FXa) inhibitors would interfere more gradually with this feedback activation loop than thrombin inhibitors, thereby achieving a better balance between haemostasis and prevention of thrombosis. In this study, we compared the effects of TAK-442, a novel FXa inhibitor, versus ximelagatran, a thrombin inhibitor, on FV-mediated positive feedback, venous thrombosis and bleeding. In normal plasma, TAK-442 delayed the onset of tissue factor-induced thrombin generation and prolonged prothrombin time (PT) with more gradual concentration-response curve than melagatran, the active form of ximelagatran. The effect of melagatran on the onset of thrombin generation decreased in an FVa-concentration-dependent manner in FV-deficient plasma supplemented with FVa. Furthermore, in FV-deficient plasma, the PT-prolonging potency of melagatran was markedly increased with a change in its concentration-response curve from steep to gradual. In the rat venous thrombosis model, TAK-442 (10 mg/kg, p.o.) prevented thrombus formation by 55% with 1.2 times prolongation of PT; a similar effect was observed in ximelagatran-treated (3 mg/kg, p.o.) rats. TAK-442 at 100 mg/kg prolonged PT by only 2.1 times with no change in bleeding time (BT), whereas ximelagatran at 10 mg/kg prolonged PT by 3.9 times and significantly increased BT. These results suggest that the differential effects of the two agents on FV-mediated amplification of thrombin generation may underlie the observation of a wider therapeutic window for TAK-442 than for ximelagatran.

Topics: Administration, Oral; Animals; Anticoagulants; Antithrombins; Azetidines; Benzylamines; Blood Coagulation; Disease Models, Animal; Dose-Response Relationship, Drug; Factor V; Factor Xa; Factor Xa Inhibitors; Feedback, Physiological; Hemorrhage; Humans; Male; Phospholipids; Prothrombin Time; Pyrimidinones; Rats; Rats, Sprague-Dawley; Risk Assessment; Sulfones; Thrombin; Thromboplastin; Venous Thrombosis

The antithrombotic and bleeding properties of the oral direct thrombin inhibitor ximelagatran and of warfarin were investigated in an experimental venous thrombosis and bleeding model in anaesthetized rats. Rats were randomized to receive ximelagatran (1-20 micromol/kg), warfarin (0.20-0.82 micromol/kg), or vehicle (tap water) once daily orally for 4 days before surgery. Thrombosis was induced by partial stenosis and application of ferric chloride to the wall of the abdominal vena cava under anaesthesia. Sixty minutes after thrombus induction, rats were sacrificed, thrombi harvested, and their fresh weight determined. Bleeding was determined as haemoglobin in fluid collected from the abdominal cavity. Blood samples were taken before thrombus induction and sacrifice for determination of coagulation parameters and plasma concentrations of melagatran, the active form of ximelagatran. Ximelagatran and warfarin dose-dependently reduced thrombus formation. The highest doses of ximelagatran and warfarin almost completely prevented thrombus formation; however, the increase in bleeding (versus vehicle) was significantly lower with the highest dose of ximelagatran than with the highest dose of warfarin. The oral direct thrombin inhibitor ximelagatran is thus as at least as effective as warfarin in the prevention of thrombus formation in this animal model, but with a wider separation between antithrombotic effects and bleeding.

Topics: Animals; Azetidines; Benzylamines; Disease Models, Animal; Dose-Response Relationship, Drug; Drug Evaluation, Preclinical; Glycine; Hemorrhage; Male; Rats; Rats, Sprague-Dawley; Venae Cavae; Venous Thrombosis; Warfarin

SSR182289A 1 is the result of a rational optimisation process leading to an orally active thrombin inhibitor. The structure incorporates an original 2-(acetylamino)-[1,1'-biphenyl]-3-sulfonyl N-terminal motif, a central l-Arg surrogate carrying a weakly basic 3-amino-pyridine, and an unusual 4-difluoropiperidine at the C-terminus. Its synthesis is convergent and palladium catalysis has been employed for the construction of the key C-C bonds: Suzuki coupling for the bis-aryl fragment and Sonogashira reaction for the delta- bond of the central amino-acid chain. The compound is a potent inhibitor of thrombin's activities in vitro and demonstrates potent oral anti-thrombotic potencies in three rat models of thrombosis. The observed in vitro potency could be rationalized through the examination of the interactions within the SSR182289A 1 - thrombin crystal structure. SSR182289A 1, has been therefore selected for further development.

Topics: Administration, Oral; Aminopyridines; Animals; Azetidines; Benzylamines; Blood Coagulation; Crystallography, X-Ray; Disease Models, Animal; Humans; Hydrogen Bonding; Male; Models, Molecular; Molecular Structure; Platelet Aggregation; Rats; Structure-Activity Relationship; Sulfonamides; Thrombin; Thrombosis