US Food and Drug Administration approval of generic versions of complex biologics: implications for the practicing physician using low molecular weight heparins.

Low-molecular-weight heparins (LMWHs) have shown equivalent or superior efficacy and safety to unfractionated heparin as antithrombotic therapy for patients with acute coronary syndromes. Each approved LMWH is a pleotropic biological agent with a unique chemical, biochemical, biophysical and biological profile and displays different pharmacodynamic and pharmacokinetic profiles. As a result, LMWHs are neither equipotent in preclinical assays nor equivalent in terms of their clinical efficacy and safety. Previously, the US Food and Drug Administration (FDA) cautioned against using various LMWHs interchangeably, however recently, the FDA approved generic versions of LMWH that have not been tested in large clinical trials. This paper highlights the bio-chemical and pharmacological differences between the LMWH preparations that may result in different clinical outcomes, and also reviews the implications and challenges physicians face when generic versions of the original/innovator agents are approved for clinical use.

Protein C Pathway, Inflammation, and Pump Thrombosis in Patients With Left Ventricular Assist Devices.

Use of left ventricular assist devices (LVADs) for management of advanced heart failure is becoming increasingly common; however, device associated thrombosis remains an important cause of mortality in this patient population. We hypothesize that inflammation in LVAD implanted patients dysregulates the protein C pathway, creating a hypercoagulable state leading to thrombosis. Plasma samples from 22 patients implanted with the Thoratec HeartMate II LVAD were analyzed by commercial ELISAs. Retrospective sample selection included those collected 1-3 months prior to and within 1 month after a thrombotic or bleeding event. Unrelated to warfarin dosing, total protein S and free protein S (p = 0.033) levels were 20% lower in patients with LVAD-thrombosis than in patients with LVAD-bleeding. Levels of protein C, soluble endothelial cell protein C receptor, and soluble thrombomodulin were similar in both groups before and after the event. Compared to normal, C-reactive protein levels were 25-fold elevated in LVAD-thrombosis patients but only 9-fold elevated in LVAD-bleeding patients. This study suggests that protein S, influenced by the inflammatory state, is a gatekeeper for the function of protein C in patients with LVAD-associated thrombosis.

Structural and functional characterization of low-molecular-weight heparins: impact on the development of guidelines for generic products.

Low-molecular-weight heparins (LMWHs) are poly-pharmacologic drugs used to treat thrombotic and cardiovascular disorders. Recently, several generic versions of branded LMWHs have been introduced. Although generic versions of LMWHs exhibit similar profiles, marked differences in their biological and pharmacologic properties have been demonstrated. Several studies have demonstrated differences in terms of anti-Xa activity and tissue factor pathway inhibitor release. The current data emphasize the need to consider multiple functional parameters when defining bioequivalence of biologic drugs and also underscore the importance of further pharmacologic studies involving animal and human clinical trials. The US Food and Drug Administration (FDA) and the European Medicines Agency (EMEA) are currently developing guidelines for the acceptance of complex biological drugs including LMWHs. The US FDA considers these drugs as follow-on agents whereas the EMEA classifies these drugs as biosimilar agents. Until clear guidelines are developed, generic interchange of LMWHs may not be feasible.

Rivaroxaban--an oral, direct Factor Xa inhibitor--has potential for the management of patients with heparin-induced thrombocytopenia.

Rivaroxaban is an oral, direct activated Factor Xa (FXa) inhibitor in advanced clinical development for the prevention and treatment of thromboembolic disorders. Currently available anticoagulants include unfractionated heparin (UFH) and low molecular weight heparins (LMWHs); however, their use can be restricted by heparin-induced thrombocytopenia (HIT). HIT is usually caused by the production of antibodies to a complex of heparin and platelet factor-4 (PF4). This study was performed to evaluate, in vitro, the potential of rivaroxaban as an anticoagulant for the management of patients with HIT. UFH, the LMWH enoxaparin, fondaparinux and the direct thrombin inhibitor argatroban were tested to enable comparative analyses. Rivaroxaban did not cause platelet activation or aggregation in the presence of HIT antibodies, unlike UFH and enoxaparin, suggesting that rivaroxaban does not cross-react with HIT antibodies. Furthermore, rivaroxaban did not cause the release of PF4 from platelets and did not interact with PF4, unlike UFH and enoxaparin. These findings suggest that rivaroxaban may be a suitable anticoagulant for the management of patients with HIT.

Inflammatory and hemostatic activation in patients undergoing off-pump coronary artery bypass grafting.

To characterize hemostatic differences imposed by 2 common cardiac surgeries, the authors studied patients undergoing coronary artery revascularization by off-pump (n = 13) or cardiopulmonary bypass on-pump (n = 26) technique. Blood samples collected to 4 days post-surgery were evaluated by flow cytometry and enzyme-linked immunosorbent assay. A significant inflammatory response occurred in both the groups after surgery shown by increased interleukin cytokines and C-reactive protein; however, levels peaked lower and hours later in the off-pump group. Platelets (P-selectin; platelet-leukocyte complexes) and leukocytes (CD11b) were activated only in on-pump patients. Thrombin generation was enhanced in both groups after surgery. Only in the on-pump patients, the thrombin-antithrombin complex, pro-thrombin fragment 1.2, and thrombomodulin (vascular integrity) decreased intraoperatively. Tissue plasminogen activator and plasminogen activator inhibitor-1 were greater in the on-pump patients. Off-pump surgery may place patients at higher risk of postoperative hypercoagulability because of normal platelet function, intraoperative thrombin generation, less fibrinolytic activity, and lack of vascular protection.

Isolation and characterization of heparin from tuna skins.

This study characterized heparin isolated from tuna skins. Glycosaminoglycans were isolated from tuna skin after digestion using anion exchange resin. Heparin was eluted from the resin by sodium chloride gradient and was further fractionated by acetone fractionation. Anticoagulant activity was determined using the activated partial thromboplastin time and Heptest assays. Potency was determined using amidolytic antifactor IIa and antifactor Xa assays. The presence of heparin in the extracted tuna skin glycosaminoglycans was confirmed using (13)C-nuclear magnetic resonance. The activated partial thromboplastin time and Heptest clotting times were doubled at concentrations of about 4 and 1 microg/mL, respectively. The clotting time prolongation and antiprotease activity induced by tuna heparin was readily neutralized by 25 microg/mL protamine sulfate. These results demonstrate that biologically active heparin with properties similar to clinical grade heparin can be derived from tuna skin, a raw material with otherwise relatively little economic value.

Modulatory effects of Escherichia coli capsular-derived sulfaminoheparosans and heparins on tissue factor-mediated activation of platelets: flow cytometric analysis.

Sulfaminoheparosans (alternatively known as bioheparins) represent sulfated derivatives obtained from the K5 capsular polysaccharide of Escherichia coli. Previous studies have shown that these agents are structurally comparable to heparins and capable of exerting anticoagulant and antiprotease effects like heparins. Furthermore they are also able to release tissue factor pathway inhibitor (TFPI). Tissue factor (TF) plays a vital role in the pathogenesis of thrombotic and cardiovascular disorders. Anticoagulants such as heparins and bioheparins inhibit this thrombogenic mediator and thereby downregulate the activation of prothrombin and factor X. This study was carried out to determine the effects of several bioheparin fractions and heparins on TF-mediated platelet activation and their direct effect on platelets using human whole blood flow cytometry. Four different sulfaminoheparosan fractions with mean molecular weights of 20, 9, 7, and 6 kDa were tested for their inhibitory effects on platelet activation at two different concentrations (100 and 10 microg/mL). Unfractionated heparin and a low-molecular-weight heparin, tinzaparin, were also tested under the same experimental conditions for comparative modulatory responses. Fresh whole blood from healthy female and male volunteers (n = 5) was mixed with each of these agents and incubated with TF (diluted thromboplastin C) to activate platelets. Platelets were labeled with the antibodies CD61 FITC (GP IIIa) and CD62 PE (P-selectin). The data were analyzed in terms of percent platelet aggregation and platelet P-selectin expression. At 100 microg/mL, all of these agents strongly and significantly inhibited (approximately 40%) the platelet activation induced by TF in comparison to saline control. The inhibitory effects of each of these agents were slightly weaker (approximately 24% inhibition) at 10 microg/mL. The inhibitory effects of these agents on P-selectin expression correspond to their effects on platelet aggregation. At 100 microg/mL all the agents produced greater than 80% inhibition of P-selectin expression whereas at 10 microg/mL, the inhibition is greater than 70% except for bio-20 kDa, which produced less than 50% of inhibition. No molecular weight dependence was observed with bioheparin fractions in terms of inhibitory effects on platelet aggregation or P-selectin expression. None of the bioheparins and heparins exhibited any direct effects on platelets. These observations suggest that both the bioheparins and heparins are capable of inhibiting TF-mediated activation of platelets. Thus the therapeutic effects of bioheparins in the TF-mediated pathogenesis of platelet activation may be similar to those of heparins.

Product individuality of commercially available low-molecular-weight heparins and their generic versions: therapeutic implications.

The currently available brand-name low-molecular-weight heparins (LMWHs) in the United States include dalteparin (Pfizer), enoxaparin (Aventis), and tinzaparin (Pharmion). Other products available, in Europe, include certoparin (Novartis), reviparin (Abbott), nadroparin (GlaxoSmithkline), and parnaparin (Alpha-Wasserman). Each of these LMWHs has a characteristic molecular weight profile and biological activity in terms of an anti-FXa and anti-FIIa potency. The mean molecular weight of these drugs ranges from 4.0 kDa to 7.0 kDa and the anti-FXa:anti-FIIa ratio ranges from 1.5 to 3.5. These agents may also be characterized by the presence of specific chemical end groups such as 2-O-sulfo-4-enepyranosuronic acid at the nonreducing terminus (enoxaparin) or 2,5-anhydro-D-mannose at the reducing terminus (dalteparin). Further, the component oligosaccharide chains exhibit product-specific distribution profiles. It is now widely accepted that individual LMWHs are chemically unique agents and cannot be interchanged therapeutically. Each commercial LMWH has been individually developed for specific clinical indications, which are dose and product dependent. Recently, several generic LMWHs have become available in India (Cutenox and Markaparin) and South America (dilutol, clenox, dripanina), and three companies have filed for regulatory approval of a generic version of enoxaparin in the United States. As the primary aim of a generic drug is to reduce cost without compromising patient care, a generic drug is required to be chemically and biologically equivalent to the pioneer drug. Because LMWHs represent complex natural mucopolysaccharide drugs that have undergone chemical and enzymatic modifications, physicochemical and biological information in addition to molecular weight and anti-FXa:anti-FIIa ratio should be used to determine generic equivalency to the branded drug. We have utilized a previously reported approach to systematically compare three generic versions of enoxaparin obtained from India and Brazil with the branded enoxaparin (Lovenox) available in the United States. Testing included molecular and structural profiling, evaluation in clot-based and amidolytic anti-FXa and anti-FIIa assays, and heparinase-I digestion profiles. While the molecular profiles (4.8 +/- 1.8 kD) and anticoagulant potencies as determined by activated partial thromboplastin time (APTT) were comparable for all four agents, the generic products showed variations in the thrombin time (TT) and Heptest assays. Two generic and the branded enoxaparin were readily digested by heparinase-I, losing most of their anticoagulant activity, but one generic product resisted digestion. This may have been due to a unique structural feature in this product. These studies show that, while generic LMWHs may exhibit acceptable molecular weight and anti-FXa profiles, they can exhibit assay-based differences and digestion profiles. Testing in animal models to determine safety, efficacy, and pharmacodynamic parameters may be important to verify equivalence. In order to assure that the generic LMWHs are equivalent to branded LMWHs such that equivalent clinical results are obtained, there is a need to develop clear stepwise guidelines that will establish equivalency in terms of physical, chemical, biochemical, pharmacokinetic, and pharmacodynamic properties for these anticoagulant drugs.

Blood cell microparticles as biomarkers of hemostatic abnormalities in patients with implanted cardiac assist devices.

For heart failure patients unable to undergo cardiac transplantation, mechanical circulatory support with left ventricular assist devices can be utilized. These devices improve quality of life and prolong life expectancy, but they are associated with bleeding and thrombotic complications impacting patient survival. Little is known of the relevant mechanisms of these hemostatic issues, hindering identification of a clinically useful biomarker. However, there is suggestive evidence that blood cell-derived microparticles may fulfill this unmet clinical need. Recent publications have shown an association of up regulated microparticle production with implanted left ventricular assist devices and the potential to use this as a biomarker to predict thrombosis (and perhaps other adverse events) with an onset time earlier than currently used clinical indicators.

Development of generic low molecular weight heparins: a perspective.

It is clear that the introduction of generic versions of low molecular weight heparins (LMWHs) is inevitable; however, it is important that the generic products are manufactured in strict compliance with the manufacturing specification of the branded product. Furthermore, regulatory agencies should require additional data on the chemical biologic, pharmacologic/toxicologic, and dose-response relationship in specific settings. Although there is strong opposition to stop the introduction of these drugs, their development will reduce cost and permit availability to all patients who need them. Some objective guidelines for the proper development of these drugs are needed. Only expert groups and advisory panels to the regulatory bodies can develop these guidelines.

Antiplatelet agents: current drugs and future trends.

Antiplatelet drugs in clinical use are discussed in terms of their mechanisms of action and the relevancy of that to the physiology of platelets and the pathophysiology of arterial thrombosis. Current clinical usage is outlined in detail for each drug. Experimental antiplatelet drugs also are discussed.

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.

Fondaparinux: a synthetic heparin pentasaccharide as a new antithrombotic agent.

Fondaparinux (Arixtra, Sanofi-Synthélabo/Organon) is the first of a new class of antithrombotic agents distinct from low molecular weight heparins (LMWHs) and heparin. It is a chemically synthetic pentasaccharide mimicking the site of heparin that binds to antithrombin III (AT). It exhibits only factor (F) Xa (FXa) inhibitor activity via binding to AT, which in turn inhibits thrombin generation. In contrast to heparin and LMWH, plasma anti-Xa activity corresponds directly to levels of fondaparinux. It does not release tissue factor pathway inhibitor (TFPI). There is nearly complete bioavailability by the sc. route, rapid onset of action, a prolonged half-life in both iv. and sc. (14 - 20 h) dosing regimens and no metabolism preceding renal excretion. Phase IIb clinical studies have identified a dose of 2.5 mg once-daily for prophylaxis of venous thrombosis. Four Phase III studies (n > 7000) have demonstrated a combined 50% relative risk reduction of venous thromboembolic events in orthopaedic surgery patients in comparison to the LMWH, enoxaparin. Haemmorrhagic complications for fondaparinux were either comparable to or higher than those for LMWH. The activated partial thromboplastin time (aPTT) is not affected by fondaparinux. At present, laboratory monitoring is not recommended. Clinical trials for treatment of established thrombosis, coronary syndromes and adjunct to thrombolytic therapy are in progress.

Antithrombotic drugs for the treatment of heparin-induced thrombocytopenia.

Because patients with heparin-induced thrombocytopenia (HIT) have an extremely high frequency of developing thrombosis, treatment options other than heparin are essential. Prophylaxis against thrombosis should also be considered. The current American College of Chest Physicians guidelines for the treatment of acute heparin-induced thrombocytopenia and thrombosis syndrome (HITTS) include the use of danaparoid, lepirudin or argatroban, alone or in combination with warfarin. For documented clinical thrombosis associated with HIT, patients should be treated with a direct thrombin inhibitor at therapeutic activated partial thromboplastin time for 7 to 10 days. Warfarin should not be used during the acute phase of HIT, unless a thrombin inhibitor is being used simultaneously. Conversion to warfarin can be done when the acute phase of HIT has passed. Due to the high likelihood of cross-reactivity, the use of low molecular weight heparins in patients with HIT is not recommended. For prophylactic treatment of HIT patients, despite a lack of other indications for anticoagulation, a direct thrombin inhibitor can be initiated with a low level of anticoagulation until the thrombocytopenia resolves. This regimen is continued until laboratory evidence is provided that the HIT antibody is no longer detectable. HIT patients, in addition to needing anticoagulation to treat thrombosis, can require anticoagulation for non HIT-related events, such as for the treatment of myocardial infarction, unstable angina and long-term anticoagulation for heart valves or atrial fibrillation. For these situations, and if immediate anticoagulation is needed, the use of a direct thrombin inhibitor with switch-over to warfarin is a useful option. However, optimal dosing regimens have not been established in all cases.

Factor Xa inhibitors: today and beyond.

Serine proteases play an important role in thrombogenesis, the process that leads to blood clotting and conditions such as heart attack, stroke and other cardiovascular disorders. In the coagulation network, the activation of various serine proteases facilitates the formation of the serine protease Factor Xa, which plays a central role in the process of coagulation and platelet activation. Factor Xa is an essential component of the prothrombinase complex, from which thrombin is formed, which then directly leads to fibrin clot formation. Thus, the inhibition of Factor Xa and its generation is an important strategy in the development of new antithrombotic drugs.

Prevalence, isotype, and functionality of antiheparin-platelet factor 4 antibodies in patients treated with heparin and clinically suspected for heparin-induced thrombocytopenia. The pathogenic role of IgG.

Antibodies to heparin-platelet factor 4 (PF4) complexes have been observed in patient with heparin-induced thrombocytopenia (HIT) syndrome. These antibodies may be of various isotypes and differ with respect to their ability to activate platelets/endothelial cells. This study determined the isotypes and functionality of antiheparin-platelet factor 4 (AHPF4) antibodies in 111 patients treated with heparin and clinically suspected for HIT. In this patient population, 50% had detectable AHPF4 cumulative IgA, IgG, and IgM (determined by enzyme-linked immunosorbent assay, ELISA), but only 35% was positive when tested with the (14)C-serotonin release assay (SRA). Using antihuman Ig specific for different isotypes, we found that 50% of the 111 samples was positive for IgG, 45% for IgM, and 37% for IgA. In 50 normal human serum (NHS) samples, only two were positive for IgG, but 33 were positive for IgM, indicating a potential humoral response to the heparin-PF4 complex prior to heparin administration. Patients that were ELISA(+) for AHPF4 antibody titer were subdivided into SRA-positive (+) and SRA-negative (-) groups. The SRA(+) group had a mean ELISA optical density (OD) for AHPF4 IgA/IgG/IgM of 2.1, while the SRA(-) group had a mean OD of 0.8 (P<.001). The SRA(+) group had greater mean OD values for all three individual isotypes. Using flow cytometry, we determined the ability of different patient samples to activate platelets. Samples that contained IgG and were SRA(+) activated platelets (as measured by microparticle generation and P-selectin expression) in the presence of therapeutic concentrations of heparin. NHS and samples containing IgA and/or IgM that were SRA(-) were not able to produce microparticles nor were they able to increase expression of P-selectin. Together, these data indicate that IgG is the principal mediator of platelet activation in patients with HIT, with IgA and IgM playing a less significant role in the pathophysiology of this syndrome.

Differential effects of clivarin and heparin in patients undergoing hip and knee surgery for the generation of anti-heparin-platelet factor 4 antibodies.

The pathophysiology of heparin-induced thrombocytopenia (HIT) syndrome is mediated via a heterogeneous group of heparin(s)-platelet factor 4 (H-PF4) complexes bound to their antibodies. These anti-H-PF4 (AHPF4) antibodies that are capable of binding to the FcgammaRIIA receptor [cluster of differentiation (CD) 32] on platelets, resulting in platelet activation, widely vary in their specific activities as platelet activation (functionality). Predisposing factors related to specific pathologic conditions may also contribute to the generation of these antibodies and their relative functionality during HIT syndrome. To understand this phenomenon, a sub-study was carried out in patients undergoing elective total hip and knee replacement surgery (ECHOS Study) and who were treated with unfractionated heparin (UFH) and a low-molecular-weight heparin (LMWH; Clivarin). Approximately 600 patients per arm [UFH=7,500 anti-Xa U twice a day (b.i.d.) subcutaneous (s.c.) and clivarin=4200 U once daily (o.d.) s.c.], age >40 years, received prophylactic treatment for a minimum of 11-14 days. Plasma samples were collected at pre-dose, days 2-4, days 11-14 and at follow-up 6-8 weeks after discharge and were analyzed for AHPF4 antibody titers. Functionality of the enzyme-linked immunosorbant assay (ELISA)-positive AHPF4 antibodies to cause platelet activation was tested by 14C-serotonin release assay (SRA). Both UFH and clivarin treatments in orthopedic surgical patients resulted in a progressive generation of AHPF4 antibodies. The relative prevalence/functionality of AHPF4 antibodies in clivarin arm was markedly lower (two- to threefold, p<0.001) as compared to UFH at each time point. Most of the samples in clivarin group were found to be SRA negative, suggesting the presence of AHPF4 antibodies that did not activate platelets (nonfunctional). Within the UFH arm, the relative prevalence/functionality of AHPF4 antibodies was much higher (p<0.002) in knee group compared to the corresponding hip group. This study, for the first time, reports on the elevated levels of AHPF4 antibodies generated by heparin associated with the pathogenesis of knee surgery. Clinical significance of the differential generation of HIT-associated antibodies remains unexplored at this time.

Development of a Synthetic Heparin Pentasaccharide: Fondaparinux.

Fondaparinux (Arixtra®; Sanofi-Synthélabo/Organon) is the first of a new class of antithrombotic agents distinct from low molecular weight (LMW) heparins and heparin. It is a synthetic pentasaccharide mimicking the site of heparin that binds to antithrombin III (AT). It is homogeneous with a molecular weight of 1728 Da. It exhibits only factor (F) Xa inhibitor activity via binding to AT, which in turn inhibits thrombin generation. It does not inhibit thrombin, release TFPI, or possess other actions of heparin. Low AT levels can limit the efficacy of fondaparinux. There is nearly complete bioavailability subcutaneously, rapid onset of action, a prolonged half-life (15- 20 h) and no metabolism preceding renal excretion. Elderly and renal impaired patients have reduced clearance. The PT, aPTT and ACT are not affected by fondaparinux; anti-FXa assays are used if needed. Phase IIb clinical studies have identified a fixed dose of 2.5 mg once daily for prophylaxis of venous thrombosis without monitoring. Four phase III studies (n > 7000) demonstrated a combined 55% relative risk reduction of venous thromboembolic events in orthopedic surgery patients in comparison to the LMW heparin enoxaparin. Hemorrhagic complications for fondaparinux were either comparable to or higher than that for LMW heparin. The US FDA and the European CPMP have approved fondaparinux for prophylaxis of venous thrombosis after orthopedic surgery with limitations of use in elderly, low weight, renal impaired patients and in those receiving spinal anesthesia. Marketing is expected in Spring 2002. Clinical trials for treatment of established thrombosis, coronary syndromes and adjunct to thrombolytic therapy are in progress.

Anticoagulant and Antithrombotic Actions of AVE5026, an Enriched Anti-Xa Hemisynthetic Ultra-Low-Molecular-Weight Heparin.

INTRODUCTION: AVE5026 represents a new generation of ultra-low-molecular-weight heparin (LMWH) with high anti-Xa and low anti-IIa activities (anti Xa-IIa ratio >30). In addition, AVE5026 exhibits a relatively higher proportion of AT components. MATERIALS AND METHODS: The anticoagulant, antiplatelet, antithrombotic, and bleeding effects of AVE5026 in comparison to other heparins were investigated in this study. RESULTS: AVE5026 demonstrated weak effects in the global clotting assays; however, in the amidolytic anti-Xa assay, AVE5026 produced strong inhibitory effects. AVE5026 showed no cross-reactivity with the heparin-induced thrombocytopenia antibodies in the platelet aggregation system. AVE5026 produced a dose-dependent antithrombotic response after intravenous (IV) and subcutaneous (SC) administration in thrombosis models. The relative bleeding effects of AVE5026 in a rat tail bleeding and rabbit blood loss model were negligible after both IV and SC administration. CONCLUSIONS: This superior safety efficacy index in animal models in comparison with other LMWH may translate into improved antithrombotic efficacy with decreased bleeding risk.

Sustained release of tissue factor following thrombosis of lower limb trauma.

This study was undertaken to provide evidence for the mechanism of venous thromboembolism (VTE) in healthy patients with minor lower limb injury (fracture; Achilles tendon rupture) that was medically managed with plaster cast/brace immobilization. The Plaster Cast clinical trial provided a unique opportunity to identify the natural history of VTE using placebo-controlled patients (n = 183) with validation of the mechanism using the low-molecular-weight heparin (LMWH; reviparin)-treated patients (n = 182). Confirmed VTE in this population was associated with a burst of tissue factor release (and a minor fibrinolytic deficit) leading to thrombin generation that was sustained at least 5 weeks, greater with fractures than with soft-tissue injuries and greater with surgery than with conservative treatment. The root cause likely involves platelet/leukocyte activation (inflammation) rather than endothelial cell injury. Thromboprophylaxis with a low dose of LMWH reduced thrombin generation, with patients undergoing surgery benefitting the most.