Heparin and the thrombin inhibitor argatroban enhance fibrinolysis by infused or bolus-injected saruplase (r-scu-PA) in rabbit femoral artery thrombosis

Fibrinolytic Compromise by Synthetic and Recombinant Thrombin Inhibitors: Implications in the Treatment of Thrombotic Disorders

Site-directed synthetic and recombinant antithrombin agents are widely used to prevent reocclusion during thrombolytic therapy in acute myocardial infarction and other vascular occlusive disorders. However, minimal studies have been conducted to examine the interactions between these anticoagulant and thrombolytic agents. Because of the structural homology of serine proteases, some of these newly developed antithrombin agents are also capable of inhibiting fibrinolytic enzymes, which may lead to fibrinolytic compromise during thrombolytic therapy. In addition, inhibition of thrombomodutin-bound thrombin may also result in fibrinolytic deficit. Several thrombin inhibitors were studied in in vitro systems to assess whether their inactivating properties extend to fibrinolytic and profibinolytic enzymes, such as kallikrein, plasmin, urokinase, streptokinase, and tissue plasminogen activator. The thrombin inhibitors studied included hirudin, hirulog-I, argatroban, D-MePhe-Pro-Arg-H, and Ac-D-Phe-Pro-boroArg-OH. Their activities were compared with those of aprotinin, which is currently used clinically as an antifibrinolytic agent. Although argatroban, hirulog-I, and hirudin exhibited minimal inhibition of the nonthrombin enzymes studied, the tripeptide derivatives showed variable inhibitory activities, with the boronic acid derivative being the most potent and universal inhibitor. The in vivo antifibrinolytic activities of these thrombin inhibitors were also studied in a rabbit model of jugular vein clot lysis. In agreement with the in vitro studies, argatroban, hirulog-I, and hirudin exhibited minimal antifibrinolytic activities, while Ac-D-Phe-Pro-boroArg-OH and D-MePhe-Pro-Arg-H showed marked inhibition of the thrombolytic process. The results of these studies indicate that newly developed thrombin inhibitors with a broader serine protease spectrum may exhibit fibrinolytic compromise resulting in diminishment of the expected thrombolytic outcome. Key Words: Thrombolysis—Fibrinolysis—Thrombin inhibitors—Argatroban—Hirudin—Hirulog-I—Aprotinin.

A study on the safety, efficacy, and efficiency of sulodexide compared with acenocoumarol in secondary prophylaxis in patients with deep venous thrombosis

This study was carried out to study the safety and efficacy of a fixed dosage of sulodexide compared to adjusted dosages (INR) of acenocoumarol as secondary prophylaxis in patients with deep vein thrombosis (DVT) in lower limbs. An economic evaluation based on the criteria of use in normal clinical practice was also performed. One hundred and fifty patients of both sexes were included, all over 18 years of age and diagnosed with proximal DVT of the lower limbs by color echo-Doppler, and with clinical evolution of less than 1 month. The patients were initially treated with low-molecular-weight heparin (LMWH) and urokinase in accordance with the established protocol. They were then randomized to continue treatment with acenocoumarol and INR adjustments every 30 days, or with sulodexide. Treatment was extended for 3 months with monthly follow-up visits and a final visit at 3 months posttreatment. No differences between the groups were detected concerning demographic or basal characteristics in clinical evolution or adverse reactions. In the group treated with sulodexide, no major/minor hemorrhagic complications were detected. On the other hand, in the acenocoumarol group, 1 major hemorrhage and 9 minor hemorrhages were produced (13.3%), reaching statistical difference in relation to the sulodexide group (p = 0.014; CI from 95% of 4.7% to 19.4%). Regarding the economic impact, treatment costs with sulodexide are much less than those with acenocoumarol, the data confirmed by the sensitivity analyses performed. The results prove the efficacy, safety, and efficiency of sulodexide as a secondary prophylaxis in thromboembolic disease, avoiding hemorrhagic risks and the monitoring of patients, and providing significant savings to the health system.

Pharmacology of argatroban

Argatroban, a synthetic peptidomimetic antithrombin agent, is the first clinical anticoagulant solely to target thrombin. For some time, this drug has been used in Japan for the management of thromboembolic disorders. Recently, it has been approved in Japan for use in thrombotic and ischaemic stroke. Despite a large number of preclinical studies on the pharmacology of this agent, clinical trials in Europe and North America were only initiated in 1996. Argatroban produces anticoagulant effects comparable to therapeutic heparinisation at concentrations of approximately 1 microg/ml. At concentrations of 5-10 microg/ml, this agent produces adequate anticoagulation for inteventional cardiovascular procedures and prolongs the activated clotting time (ACT) to 400-600 s. The predictable anticoagulant effect of this agent is relatively short lasting, and may not warrant pharmacologic neutralisation in the majority of patients. However, patients with hepatic dysfunction may need some means of neutralisation. Unlike heparin, this drug produces its anticoagulant effects by direct inhibition of thrombin and thrombin-mediated processes. This agent is not influenced by endogenous factors such as platelet factor 4 and other proteins which bind heparin. Argatroban's use does not lead to the formation of antiplatelet antibodies. Thus, this drug is useful in the management of heparin induced thrombocytopenic (HIT) patients. Although argatroban was initially developed for the management of deep vein thrombosis (DVT), based on its pharmacologic properties, it can be developed for safer anticoagulation in such indications as acute coronary syndromes, as an adjunct to thrombolytics, thrombotic and ischaemic stroke and inflammatory diseases resulting in thrombotic complications.

Direct thrombin inhibitors are not equally effective in vivo against arterial thrombosis

BACKGROUND

Qualitative differences in antithrombotic efficacy between thrombin inhibitors may be explained by the affinity for which they bind thrombin. This affinity is inversely proportional to the inhibitory constant for the agent (Ki). Thrombin inhibitors, DuP714 (Ki=10(-11)) and argatroban (Ki=10(-8)), were compared to our previous studies with r-hirudin (Ki=10(-13)).

METHODS AND RESULTS

Prior to balloon angioplasty, thirty pigs randomly received DuP714 (0.1 mg/kg bolus and 0.6 mg/kg/h infusion; n=8), argatroban (0.2 mg/kg/min. continuous infusion; n=9), or saline (n=17). Injured arterial segments were measured for (111)In-platelet and 125I-fibrin(ogen) deposition and the incidence of macroscopic thrombus. In DuP714-treated animals, platelet and fibrin(ogen) deposition were significantly lower than controls in both carotid (10+/-2 vs. 62+/-18 and 20+/-4 vs. 74+/-6) and coronary (10+/-4 vs. 160+/-63 and 17+/-3 vs. 86+/-22) arteries (p<0.005). In contrast, platelet and fibrin(ogen) deposition were similar when comparing argatroban to saline in carotid (41+/-20 vs. 40+/-9 and 71+/-5 vs. 49+/-7) and coronary (92+/-33 vs. 151+/-45 and 114+/-37 vs. 89+/-38) arteries (p=0.82 and 0.38, respectively). Compared to argatroban, fibrin(ogen) (p<0.001) and coronary platelet deposition (p<0.05) were significantly reduced in animals treated with DuP714 with no significant difference in carotid platelet deposition (p=0.10). Neither inhibitor prevented macroscopic thrombosis. In previous studies with r-hirudin in this model, platelet deposition was limited to a monolayer with complete inhibition of macroscopic thrombus.

CONCLUSIONS

Direct thrombin inhibitors do not equally prevent arterial thrombosis. Qualitative differences may be explained in part by the affinity for which they bind thrombin.

Effects of argatroban and heparin on thrombus formation and tissue plasminogen activator-induced thrombolysis in a microvascular thrombosis model

Effects of (2R,4R)-4-methyl-1-[N(2)-(3-methyl-1,2,3,4-tetrahydro-8-quinolinesulfonyl)-L-arginyl]-2-piperidine-carboxylic acid monohydrate (argatroban) and unfractionated heparin (UFH) were compared with respect to thrombus formation and tissue-type plasminogen activator (t-PA)-induced thrombolysis in a microvasculature thrombosis model. The antithrombotic activities of anticoagulants were evaluated with respect to the time required for the initiation of thrombus formation (T(i)) and the time required for the thrombus to stop blood flow (T(s)). The effects of anticoagulants administered with t-PA were evaluated by percent stenosis of the vessel and percent area of the thrombus. Argatroban (1-3 mg/kg/bolus) significantly prolonged T(i) and T(s) in a dose-dependent fashion compared to control. Argatroban (3 mg/kg/bolus) significantly prolonged both the T(i) and T(s) more effectively than UFH (100 anti-XaU (a-XaU)/kg/bolus), despite equivalent prolongation of the activated partial thromboplastin time (aPTT). Higher doses of UFH (300-500 a-XaU/kg) were required to significantly prolong T(i) and T(s), but at these doses, UFH caused over-prolongation of aPTT (>180 s), which might consequently cause bleeding complications. Argatroban (0.1-0.3 mg/kg/h) significantly accelerated thrombolysis by t-PA in both a dose- and time-dependent fashion. Although argatroban (0.1-0.2 mg/kg/h) did not significantly prolong the aPTT and bleeding time (BT) as compared with control, it significantly accelerated thrombolysis by t-PA at these doses of lower bleeding risk. Argatroban (0.3 mg/kg/h) significantly enhanced thrombolysis by t-PA, while UFH (12.5 anti-XaU/kg/h) attenuated it again, despite equivalent prolongation of the aPTT and BT. We conclude that argatroban seems to be a more efficient and safer anticoagulant than UFH for the prevention of thrombus formation and acceleration of t-PA-induced thrombolysis.

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.

Saruplase in Myocardial Infarction

Saruplase is an unglucosylated single-chain recombinant urokinase-type plasminogen activator. Dose finding studies in patients with acute myocardial infarction indicated that a dose of 80 mg of saruplase, given as a bolus of 20 mg and iv infusion of 60 mg in one hour, led to excellent patency figures.Saruplase is most effective when combined with a bolus of 5000 IU heparin followed by an iv heparin infusion for at least 24 hours.When saruplase is compared to other thrombolytic agents (streptokinase, alteplase, urokinase), it becomes apparent that its profile is excellent. Early patency rates are at least comparable to alteplase. Further reocclusion rates of saruplase after one day are lower than those of streptokinase and alteplase. Patency rates 24-72 hours after start of medication are comparable between saruplase and urokinase.The large database in over 6000 patients shows that saruplase, in comparison to the other thrombolytic agents, is safe. Its bleeding complication rate is significantly lower than streptokinase, and a trend to lower in-hospital mortality is observed when compared to urokinase.Summarizing, when comparing to the presently available thrombolytic agents, saruplase is a fast acting, effective and safe thrombolytic agent.

Adjuvant effect of argatroban on staphylokinase induced thrombolysis of platelet rich thrombi in rat mesenteric venules in vivo

Effective, therapeutic thrombolysis should not only promote dissolution of fibrin but should also regulate continued thrombin-induced fibrin formation and the accumulation of platelets on the thrombotic lesion. The aim of the present study was to assess the use of a synthetic, low molecular weight thrombin inhibitor, argatroban in association with a well defined thrombolytic agent in a reproducible animal model of thrombolysis in vivo. Thrombi were formed in rat mesenteric venules with a helium neon (He-Ne) laser in the presence of Evans blue and were stabilised for 10 minutes. Thrombi formed in this manner were shown by transmission electron microscopy to be composed mainly of platelets. Thrombolysis was induced with recombinant staphylokinase in the presence and absence of argatroban and the process was monitored using computerised image analysis. Co-infusion of argatroban at a dose of 2.0 mg/kg/h with staphylokinase significantly enhanced the rate of thrombolysis. The results suggested that administration of the thrombin inhibitor together with the fibrinolytic agent moderated platelet-dependent mechanisms and led to a more rapid restoration of blood vessel patency.

Thrombin inhibitory and clot-specific fibrinolytic activities of the urokinase variant, M23 (rscu-PA-40 kDa/Hir)

The recombinant bifunctional urokinase variant, M23 (rscu-PA-40 kDA/Hir), comprising the kringle and protease domain of single-chain urokinase-type plasminogen activator and a C-terminal fragment of hirudin in one single-chain molecule, was evaluated for its thrombin-inhibitory and fibrinolytic properties in vitro and in vivo. M23 inhibited thrombin-activated coagulation of human blood and thrombin-induced aggregation of human platelet rich plasma in a concentration-dependent manner. The ADP-induced aggregation of human platelet rich plasma was not influenced by M23. In contrast, recombinant single-chain urokinase-type plasminogen activator (saruplase) inhibited neither blood coagulation nor platelet rich plasma aggregation. M23 and saruplase both lysed radiolabelled human thrombi immersed in human plasma (Chandler Loop system) with equal potency. However, there was a significantly lower systemic generation of plasmin (measured as consumption of alpha 2-antiplasmin) by M23 compared to saruplase. In anaesthetized non-heparinized rabbits, experimental femoral artery thrombosis was treated with intravenous bolus injections of M23 or saruplase (6 mg/kg, each). Thrombolytic restoration of arterial blood perfusion was significantly higher in M23- than in saruplase-treated rabbits. Plasma fibrinogen concentrations were decreased markedly in saruplase-treated animals, but remained at significantly higher levels in M23-treated rabbits. In conclusion, the bifunctional molecule, M23, showed thrombin inhibitory and fibrinolytic properties in human in vitro systems and exerted superior thrombolytic effects to saruplase in rabbit femoral artery thrombosis. In vitro and in vivo data indicate that the fibrinolytic activity of M23 is highly clot-specific.

Fibrin-specific lysis of microthrombosis in endotoxemic rats by saruplase

The dissolution by the fibrinolytic agent saruplase of microthrombi due to disseminated intravascular coagulation (DIC) has been studied in anesthetized rats. The intravenous infusion of E. coli lipopolysaccharide (endotoxin) for 4 hours (total dose: 25 mg/kg) induced marked thrombocytopenia and hypofibrinogenemia. DIC-related microthrombosis, detected as increased deposition of 125I-labelled human fibrin, was found in the liver and the kidneys, but not in the lungs, the heart, the mesenterium, the spleen and the M. rectus abdominis of endotoxemic rats. Treatment with 1-20 micrograms/kg.min saruplase, that was infused concomitantly with endotoxin, dose-dependently and significantly reduced endotoxin-induced microthrombosis in the liver and the kidneys by 85 resp. 88%. When saruplase (20 micrograms/kg.min) was administered only during the last two hours of endotoxin infusion, liver microthrombosis was still significantly dissolved by 69%, whereas renal microthrombosis was insignificantly reduced by 34%. The inhibition of endotoxin-induced microthrombosis took place in the same dosage range as the shortening of the euglobulin clot lysis time in normal rats by saruplase as a measure of its fibrinolytic activity. Saruplase did not modify thrombocytopenia and hypofibrinogenemia in endotoxemic rats. Saruplase per se did not affect plasma fibrinogen levels. Thus, in a fibrin-selective dose range saruplase is able to dissolve microthrombosis associated with DIC in endotoxemic rats.