The effects of oral and intravenous direct thrombin inhibitors on the size of photochemically induced cortical infarction in rats.

Oral thrombin inhibitors are under development as potential drugs for prophylaxis and treatment of thrombotic events. The effect of pretreatment with two direct thrombin inhibitors, melagatran and inogatran, was evaluated in a rat model of cerebral infarction. Ischaemic stroke was induced by photochemical reaction after an injection of Rose Bengal and focused posterior and to the right of the intersection of the coronal and sagittal sutures on the intact calvarium. A single oral dose of melagatran (30 micromol/kg) significantly reduced the volume of the cortical infarct by 53% (P<.05) compared with control. In addition, following intravenous inogatran (6 micromol/kg) or oral inogatran (100 micromol/kg), the volume of the cortical infarct decreased by 83% and 19%, respectively, compared with control. This study showed that experimental focal ischaemic infarction, elicited by photochemically induced endothelial cell damage, can be significantly reduced with melagatran and inogatran, direct thrombin inhibitors.

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.

Melagatran, an oral active-site inhibitor of thrombin, prevents or delays formation of electrically induced occlusive thrombus in the canine coronary artery.

Intravenous administration of thrombin inhibitors, such as hirudin, has been shown to decrease the frequency of coronary artery reocclusion after thrombolysis. However, recent findings in large clinical trials in patients with unstable angina and myocardial infarction have failed to demonstrate a sustained antithrombotic effect after cessation of drug treatment. These findings indicate a need for a prolonged antithrombotic regimen, preferably an orally active thrombin inhibitor. To test the hypothesis that a regimen consisting of oral thrombin inhibitor will delay or prevent the formation of occlusive clot, anesthetized dogs were given saline (n = 9) or a single dose of a novel active site low-molecular-weight thrombin inhibitor melagatran by nasogastric tube (1.5 mg/kg, n = 6; 2.5 mg/kg, n = 6), and 15 min later, a potent thrombogenic stimulus in the form of anodal current (100 microA) was applied to the intimal surface of the narrowed left anterior descending coronary artery (LAD). All saline-treated dogs developed stable thrombus, indicated by zero flow at 34 +/- 7 min after initiation of direct current. On the other hand, one of the six dogs given high-dose melagatran did not develop thrombotic occlusion of the LAD during the entire 4 h of observation. Mean time to occlusive thrombus formation in 11 other dogs was prolonged 4-5 times as compared with that in the saline-treated dogs (p < 0.001). Spontaneous thrombolysis was observed in three of 11 dogs after initial clot formation. Overall, the coronary artery was patent for 68% (low dose) and 75% (high dose) of the observation period in melagatran-treated dogs (vs. 14% of observation period in saline-treated dogs). Peak plasma concentration was 0.87 +/- 0.22 microM in dogs given low-dose and 1.38 +/- 0.30 microM in dogs given high-dose melagatran. The activated partial thromboplastin time (aPTT) increased 1.5-fold at peak plasma concentration of melagatran. These observations imply (a) thrombin generation plays a critical role in thrombus formation in narrowed coronary arteries, (b) oral melagatran prevents or delays thrombus formation, whereas the aPTT is only modestly prolonged, and (c) the thrombus formed in the presence of melagatran is prone to spontaneous lysis in this canine model of coronary thrombosis.

Effects of inogatran, a new low-molecular-weight thrombin inhibitor, in rat models of venous and arterial thrombosis, thrombolysis and bleeding time.

Inogatran (MW 439 Da), a new, selective, active site inhibitor of thrombin, was evaluated in three rat models of thrombosis. In the venous thrombosis model, inogatran dose-dependently inhibited thrombus formation with a > 80% antithrombotic effect at a plasma concentration of 0.45 mumol l-1. In the arterial thrombosis model, inogatran dose-dependently inhibited thrombus formation, preserved vessel patency and the mean blood flow. Acetylsalicylic acid (ASA) potentiated the effects of low plasma concentrations of inogatran in the arterial thrombosis model. In the model of rt-PA-induced thrombolysis of a thrombus in the carotid artery, inogatran improved the patency time and the cumulative blood flow during the two hour thrombolysis period more than rt-PA alone. At high therapeutic plasma concentration of inogatran, there was only a moderate prolongation of bleeding time compared with the control value. It is concluded that inogatran is an effective antithrombotic agent both in the venous and arterial thrombosis models and also as adjuvant to rt-PA in the thrombolysis model.

The role of sympathetic activity in atherogenesis: effects of beta-blockade.

Clinical and experimental evidence points to potential antiatherosclerotic effects of certain beta-adrenoreceptor antagonists. Long-term treatment with metoprolol resulted in significant reductions of total and cardiovascular mortality or morbidity due to decreased incidence of coronary and cerebrovascular complications both in a primary prevention trial in hypertensive patients and in a secondary prevention trial in patients surviving myocardial infarction. The observations suggest that a retardation of atherosclerosis development might have contributed to the reduced incidence of cardiovascular complications. An antiatherosclerotic effect of beta-blockers has been directly demonstrated in animal studies. In cholesterol-fed rabbits, metoprolol significantly reduced the development of atherosclerotic plaques in the aortic intima in the absence of any changes in blood lipids. Similar findings were reported for propranolol, which prevented psychosocial stress-induced atherosclerosis of the coronary artery in monkeys. Furthermore, beta-blockers have been shown to prevent stress-induced endothelial injury and platelet accumulation to intima at atherosclerotic predilection sites in animal models. These antiatherogenic effects may be due to biochemical and hemodynamic factors. Two biochemical effects of beta-blockade may lead to reduced cholesterol accumulation in arterial intima at unchanged serum cholesterol levels. One is a beta-blocker-induced increase of prostacyclin biosynthesis, and the other a metabolic change of low-density lipoprotein, reducing its potential for deposition in the arterial wall. The antiatherogenic effect of these factors may be reinforced by beta-blocker-induced hemodynamic changes leading to reductions of arterial flow aberrations and pressure-related wall stress.