Section Review—Cardiovascular & Renal: Recent Developments in Antithrombotic Agents

Antithrombin Agents as Anticoagulants and Antithrombotics: Implications in Drug Development

Antithrombin agents of recombinant and synthetic origin are now validated in experimental models as useful an ticoagulant and antithrombic drugs. Several clinical trials in cluding surgical anticoagulation, management of coronary syn dromes, adjunct to thrombolytic agents and treatment of throm boembolism have also shown the comparative efficacy of these agents in reference to heparin. Argatroban and hirudin are now available for specific clinical indications such as thrombotic and ischemic stroke and alternate anticoagulants for heparin- induced thrombocytopenia (HIT) patients in Japan and Euro pean countries, respectively. While these agents produce strong anticoagulant effects, their mechanism of action is distinct from that of heparins, thus these agents should be used carefully using specific guidelines provided for each product. Thrombin inhibitors are effective anticoagulants however, their therapeu tic index is narrower than heparin and as such their nonopti mized use is potentially associated with hemorrhagic compli cations.

Modulation of Endothelium by Heparin and Related Polyelectrolytes

The vascular endothelium is an important me diator of the hemostatic balance. In addition to shielding subendothelial tissue factor from flowing blood, endothe lial cells produce a number of substances which favor an antithrombotic state including TFPI and tPA. The ability of polyelectrolytes such as heparin and defibrotide to modulate endothelial function is examined using animal models and human studies. Like heparin, defibrotide is observed to increase plasma TFPI antigen levels. Addi tionally, defibrotide administration is observed to in crease plasma tPa antigen levels and to decrease PAI, TF and endothelin levels. Modulation of endothelial function by defibrotide may account for its beneficial effect in PAOD.

Piyavit from the Medicinal Leech Is a New Orally Active Anticoagulating and Antithrombotic Drug

Piyavit, a novel pharmacological preparation allowed in Russia as an oral antithrombotic drug for clinical use, contains medicinal leech saliva as the main source of biologically active substances that inhibit platelet-vascular and plasmic hemostasis and provide thrombolysis. It is shown that piyavit administered orally or subcutaneously to animals inhibits arterial thrombus formation. In 22 patients with acquired heart valvular disease after implantation of a cardiac artificial valve who received oral piyavit capsules and phenilin 2-3 days after the operation, blood hypercoagulability was reduced in comparison to that of 20 patients after the same type of operation who received only phenilin. An antiinflammatory effect and decreased blood hypercoagulability were observed in 38 patients with thrombophlebitis of the greater saphenous vein who received the same piyavit capsules orally. The results confirm that piyavit as an oral anticoagulant and antithrombotic drug may be an alternative to known antithrombotic preparations. Key Words: Anticoagulation—Antithrombotic drug—Leech saliva— Medicinal leech-Piyavit.

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.

Low molecular weight heparins: a developmental perspective

Low molecular weight heparins (LMWHs) are now universally accepted as drugs of choice for post-surgical prophylaxis of deep vein thrombosis (DVT). Currently these agents are also being developed for the treatment of thrombosis and various cardiovascular indications. Due to manufacturing differences, each of the LMWHs exhibits a distinct pharmacological and biochemical profile. The specific activity of these agents in the anticoagulant assays ranges from 35 - 45 anti-IIa U/mg, whereas the specific activity in terms of anti-Xa units is designated as 80 - 145 anti-Xa U/mg. These LMWHs are capable of producing product-specific dose- and time-dependent antithrombotic effects in animal models of thrombosis. While the ex vivo effects are initially present at doses that are antithrombotic, these agents have been found to produce sustained antithrombotic effects without any detectable ex vivo anticoagulant actions. In experimental animal models and in various clinical trials, these agents have also been found to release tissue factor pathway inhibitor (TFPI) after both iv. and sc. administration. Repeated administration of LMWHs produces progressively stronger antithrombotic effects; however, the haemorrhagic responses vary and are largely dependent on the product used. The release of TFPI following iv. and sc. administration in a primate model also demonstrates product individuality and the relevance of this inhibitor to the actions of LMWHs. Furthermore, repeated administration, mimicking the post-surgical prophylaxis of DVT, leads to product-based augmentation of the antithrombotic or haemorrhagic effects. Antithrombotic and haemorrhagic studies are discussed, comparing the pharmacological profile of some of the available LMWHs. Product individuality, in terms of relative potency in different assays and the failure of standardisation protocols to provide any guidelines for product substitution and prediction of the clinical effects, is also addressed.

Ecarin clotting time is sensitive to heparinoids: comparison of two different techniques

Ecarin clotting time (ECT) is currently developed for the specific monitoring of antithrombin drugs, such as hirudin, argatroban, and hirulog. Aqueous reagent and dry chemistry technology have become available for ECT monitoring of antithrombin agents. Currently, many heparinoids and heparinomimetic drugs are being developed. These agents activate heparin cofactor II (HCII) and primarily mediate their effects by inhibiting thrombin. Although the test is specific for antithrombin agents, heparin cofactor II-mediated thrombin inhibitors are capable of prolonging the ECT. In order to study the relative effects of some of these agents, ECT was measured in human plasma supplemented with Pl-88 (a sulfated pentomanose; Progen Industries Limited, Sydney, Australia), aprosulate, pentosan polysulfate, dermatan sulfate, unfractionated heparin (UFH), and recombinant hirudin (r-hirudin). All agents were supplemented to the citrated-pooled plasma prepared from 10 healthy volunteers at a graded dosage of 0 to 100 microg/ml. These techniques gave comparable results for all of the agents used (PI-88, r2 = 0.99; r-hirudin, r2 = 0.98; UFH, r2 = 0.98; dermatan sulfate, r2 = 0.95; aprosulate, r2 = 0.95; pentosan polysulfate, r2 = 0.94). The relative anticoagulant effects of various agents used on ECT varied widely, exhibiting their potency in the following order: r-hirudin = pentosan polysulfate > dermatan sulfate > PI-88 > aprosulate > UFH. The sensitivity of ECT was adjusted by varying the concentration of the ecarin reagent. The results suggest that HCII-mediated inhibition of thrombin can be detected by using ECT reagents.

Antithrombin agents: the new class of anticoagulant and antithrombotic drugs

Antithrombin drugs represent a wide group of natural agents, recombinant agents equivalent to some of the naturally occurring proteins, and synthetic agents. This group of drugs is characterized by marked structural and functional heterogeneity. Several of these drugs are currently in various phases of development. Argatroban represents the first clinically approved antithrombin agent, which was made available in Japan several years ago. Two recombinant hirudin preparations, Revasc (Novartis) and Refludan (Aventis), are available for postsurgical DVT prophylaxis and alternate anticoagulant use in patients with heparin-induced thrombocytopenia. A synthetic antithrombin agent based on the combined structures of hirudin and antithrombin peptides, hirulog (Bivalirudin), is undergoing clinical trials in cardiovascular indications. Additional studies on the hirudins are being carried out to test their efficacy as surgical and interventional anticoagulants as replacements for heparin. However, the need for a proper antagonist is one of the limiting factors for the optimal development of hirudin in this indication. Several of the synthetic thrombin inhibitors are also being developed for oral use for the prophylaxis of DVT in surgical patients. Since the therapeutic index of thrombin inhibitors is narrower than that of heparin, this route may not be an optimal approach for the development of these agents. Despite several unresolved developmental issues, the thrombin inhibitors provide a useful alternative to heparin anticoagulation and may prove to be useful in validated clinical use.

Antithrombin agents as anticoagulants and antithrombotics. Implications in drug development

Synthetic and recombinant thrombin inhibitors have undergone several clinical evaluations for thrombotic and cardiovascular indications. While the initial trials were focused in coronary indications, more recently, these agents are also developed for the prophylaxis and therapeutic management of thromboembolic disorders. Hirudin, PEG-hirudin and argatroban are in advanced clinical development. Recombinant hirudin has been approved in Europe as a substitute anticoagulant for the management of HIT patients. Several additional clinical trials are currently carried out to demonstrate the usefulness of these agents in thrombotic and cardiovascular indications. Despite these developments such issues as dosage optimization, laboratory monitoring, neutralization and drug interactions require additional studies for the optimal development of these drugs.

Preclinical studies on a low molecular weight heparin

Some major developments in the area of antithrombotic therapy have occurred during the past decade. Of these, the concept of fractionation of heparin has resulted in the development of several products from this agent. The introduction of low molecular weight heparins (LMWHs) has added a new chapter to the prophylactic and therapeutic management of thromboembolic disorders. These agents are now globally accepted as drugs of choice for post-surgical prophylaxis of deep vein thrombosis (DVT). Currently, the LMWHs are being developed for various therapeutic and cardiovascular indications. Reviparin is an optimized LMWH prepared by controlled nitrous acid digestion of porcine mucosal heparin. This drug has been developed using validated procedures and exhibits a relatively narrow molecular weight distribution in contrast to most other commercially available LMWHs. The specific activity in anticoagulant assays is approximately 32 U/mg whereas the specific activity in terms of anti-Xa units is 120 anti-Xa U/mg. Reviparin is capable of producing a dose- and time-dependent antithrombotic effect in animal models of thrombosis. While the ex vivo effects initially occur at dosages that are antithrombotic, this agent has been found to produce sustained antithrombotic effects without any detectable ex vivo anticoagulant actions. This agent has also been found to release tissue factor pathway inhibitor (TFPI) after both intravenous and subcutaneous administration. Repeated administration of reviparin produces progressively stronger antithrombotic effects. The current studies are designed to provide additional data on its molecular profile using new calibration methods and additional results on the pharmacological studies in a dose-dependent manner. In particular, the release of TFPI following i.v. and s.c. administration in a primate model is described. The effect of repeated administration mimicking the post-surgical prophylaxis of DVT is also reported in terms of any increase in the antithrombotic or haemorrhagic effects of this agent. Comparative antithrombotic and pharmacological studies are also reported to compare the pharmacological profiles of reviparin, nadroparin and enoxaparin.