Use of a direct thrombin inhibitor (argatroban) during pulse-spray thrombolysis in experimental thrombosis

Catheter-directed thrombolysis with argatroban and tPA for massive iliac and femoropopliteal vein thrombosis

PURPOSE

Catheter-directed thrombolysis (CDT) is a highly effective approach in the treatment of deep venous thrombosis (DVT). There are no data on the primary use of CDT with argatroban and tissue plasminogen activator (tPA) in patients without heparin-induced thrombocytopenia (HIT). The aim of this study was to evaluate the efficacy and safety of the combined administration of argatroban and tPA during CDT for massive DVT in patients without HIT.

METHODS

Thirty-three patients with massive symptomatic iliac and femoropopliteal DVT underwent CDT with tPA and argatroban within 28 ± 6 h of presentation. The dose of tPA was 0.75-1 mg/h through the infusion port and that of argatroban at 0.3-1 μg/kg/min through the side port of the sheath. The patients were evaluated for the efficacy and safety of CDT and recurrent symptomatic venous thromboembolism (VTE) at a mean follow-up of 22 months.

RESULTS

There was no bleeding or iatrogenic pulmonary embolism with the CDT regimen we used. Grade III lysis (complete resolution of thrombus on venography) was achieved in 30 patients (91 %). In 3 patients with additional inferior vena cava filter thrombosis, further thrombectomy of the filter was required. No patient developed recurrent VTE.

CONCLUSION

Concomitant administration of argatroban and tPA is a highly safe and effective regimen for CDT for massive DVT.

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.

Small-molecule direct antithrombins: argatroban

Argatroban represents the first antithrombin agent that was approved for clinical use. It belongs to the peptidomimetic (arginomimetic) group of drugs with multiple pharmacological properties. Unlike the other antithrombin drugs, such as hirudins and hirulogs, argatroban is a reversible antithrombin agent and therefore exhibits a considerably different pharmacological profile. Although argatroban is considered to be a member of the antithrombin family, its mechanisms of action include several other processes that have not been explored fully to date. These include the inhibition of non-thrombin serine proteases, a direct effect on endothelial cells and the vasculature (generation of nitric oxide), and downregulation of various inflammatory and thrombotic cytokines. Due to its lower molecular weight, argatroban is capable of passing through endovascular and cellular barriers and may, therefore, be more effective than heparins and hirudins in the antithrombotic management of microvascular disorders. Argatroban is an effective anticoagulant agent that produces a stronger anticoagulant effect than heparins and hirudins at equivalent anticoagulant levels, as measured by the activated clotting time (ACT) and activated partial thromboplastin time (APTT). At comparable ACT (300 seconds) and APTT (75-90 seconds), argatroban produces stronger inhibition of thrombin generation, as measured by in-vitro assays. Argatroban does not generate any neutralizing or non-neutralizing antibodies, and has predictable antithrombotic effects in different patients. In addition to the inhibition of thrombogenesis, argatroban also facilitates blood flow, inhibition of platelet activation and endothelial cell stimulation, mechanisms that are not necessarily related to thrombin inhibition. Despite these pharmacological advantages, additional clinical investigations are needed to validate the use of argatroban in clinical indications other than those for which it is currently approved, namely, heparin-induced thrombocytopenia and support of percutaneous coronary angioplasty.

Plasminogen-enriched pulse-spray thrombolysis with tPA: further developments

PURPOSE

To further improve methods for pulsed plasminogen-enriched thrombolysis and to compare results with the best obtainable with use of tissue plasminogen activator (tPA) alone.

MATERIALS AND METHODS

Parameters of plasminogen-enriched pulse-spray thrombolysis were manipulated in groups of rabbits with inferior vena cava thrombosis, and weights of 1-hour residual thrombus were compared. Variables evaluated were (i) tPA pulse frequency, (ii) amount of plasminogen used for enrichment, (iii) tPA concentration and amount, (iv) pulsed versus infused tPA, and (v) admixture versus separation of plasminogen and tPA.

RESULTS

With use of 3 mg of tPA and approximately 0.9 mg plasminogen enrichment, efficacy varied directly with pulse frequency over a pulse range of every 15 minutes to every 30 seconds. With use of 30-second pulses of tPA at a concentration 0.125 mg/mL, efficacy also correlated directly with increasing plasminogen enrichment up to, but not beyond, approximately 1.8 mg per 1.24 g of clot. Optimized methodology yielded 89% lysis in 1 hour, as compared to 74% lysis previously reported with use of optimized low-concentration (0.01 mg/ mL) tPA alone. Plasminogen enrichment in conjunction with low concentrations of tPA, admixture of tPA and plasminogen, and fractionation of the plasminogen enrichment all proved to be nonproductive or counterproductive.

CONCLUSION

Optimized in vivo postthrombotic plasminogen enrichment significantly accelerated thrombolysis of experimental clots compared to use of optimized tPA alone.

A model of in vivo human venous thrombosis that confirms changes in the release of specific soluble cell adhesion molecules in experimental venous thrombogenesis

PURPOSE

The mechanisms of venous thrombogenesis have been studied by using animal models and cells in culture. The results from these systems may not, however, be relevant to the human condition. The aim of this study was to develop a method by which thrombus could be safely produced in a human vein in vivo. The model that was developed was used as a means of studying the changes in soluble adhesion molecule expression in human venous thrombogenesis.

METHODS

An autologous thrombin extract was used to generate experimental thrombi in the disconnected portion of the long saphenous veins of 30 patients who were undergoing routine bilateral varicose vein surgery. The contralateral vein was perfused with thrombin extract diluent buffer to act as the control. The concentration of soluble P-, E- and L-selectin, intercellular adhesion molecule 1 (ICAM-1), and vascular cell adhesion molecule-1 were measured by means of specific enzyme-linked immunosorbent assays in samples of blood taken from veins in which thrombus had formed and in contralateral control veins.

RESULTS

Thrombosis invariably formed when at least 100 IU of thrombin activity was administered. Thrombus formation was independent of the time that the thrombin extract was allowed to remain within the emptied vessel. Thrombosis never developed in control vessels that were similarly treated with the buffer used to dilute the thrombin extract. Experimental thrombi were composed mainly of red cells, with layers of fibrin next to platelet and leukocyte packages. These findings are similar to those observed in samples of established human venous thrombi. There were small but significantly higher levels of the adhesion molecules, soluble P-selectin, and vascular cell adhesion molecule-1 in blood taken from veins in which experimental thrombi had formed, compared with controls (P =.015 and.007, respectively; Wilcoxon signed rank test). Serum levels of soluble L-selectin, E-selectin, and ICAM-1 were not affected by thrombosis.

CONCLUSION

This model is safe and reproducible. It produces thrombi with a morphology similar to that described for established human deep venous thrombi. The model may be appropriate for the study of the early changes that occur during human venous thrombogenesis and may also be of value in testing the efficacy of novel antithrombotic agents.

Technical determinants of success in catheter-directed thrombolysis for peripheral arterial occlusions

Local intraarterial thrombolytic therapy restores blood flow to the ischemic limb by dissolving the occlusive thrombus and identifies culprit lesions for treatment by means of surgical and/or percutaneous procedures. The techniques used for administration of the thrombolytic agent, the drug used, and the criteria for termination of the therapy are all factors that can influence both technical success and speed of lysis. This article discusses these factors and their influence on thrombolytic success.