Vorapaxar for Prevention of Major Adverse Cardiovascular and Limb Events in Peripheral Artery Disease

Peripheral artery disease (PAD) is a severe manifestation of atherosclerosis. Patients with PAD are at heightened risk for atherothrombotic complications, including myocardial infarction and stroke (MACE); however, there is also an equal or greater risk of major adverse limb events (MALE), such as acute limb ischemia (ALI) and major amputation. Therefore, there is a need for effective medical therapies to reduce the risk of both MACE and MALE. Recent trials have demonstrated the role of thrombin inhibition in reducing the risk of MACE and MALE in PAD patients. One such medical therapy, vorapaxar, is a potent inhibitor of protease activated receptor-1 which mediates the cellular effects of thrombin. Vorapaxar, used in addition to aspirin, has demonstrated robust reductions in MACE and MALE in PAD patients. In this article, we provide a contemporary review of the current state of PAD and the role of antithrombotic medications in the treatment of PAD, as well as the current clinical data on vorapaxar and strategies to integrate vorapaxar into contemporary medical management of peripheral artery disease.

Venous puncture wound hemostasis results in a vaulted thrombus structured by locally nucleated platelet aggregates

Primary hemostasis results in a platelet-rich thrombus that has long been assumed to form a solid plug. Unexpectedly, our 3-dimensional (3D) electron microscopy of mouse jugular vein puncture wounds revealed that the resulting thrombi were structured about localized, nucleated platelet aggregates, pedestals and columns, that produced a vaulted thrombus capped by extravascular platelet adherence. Pedestal and column surfaces were lined by procoagulant platelets. Furthermore, early steps in thrombus assembly were sensitive to P2Y12 inhibition and late steps to thrombin inhibition. Based on these results, we propose a Cap and Build, puncture wound paradigm that should have translational implications for bleeding control and hemostasis.

Measurement of Bivalirudin Thrombin Inhibition Activity in Plasma with Clotting or Chromogenic Assays and Dedicated Calibrators and Controls

Bivalirudin is a parenteral direct thrombin inhibitor anticoagulant and does not induce any impairment of the Protein C pathway, which function remains preserved. This drug meets increasing applications for cardiac surgery and heart diseases, especially when heparin is contra-indicated in presence of heparin-induced thrombocytopenia. Major indications concern Extra Corporeal Circulation, PCI/PTCA, and myocardial infarction. Drug clearance occurs partly through kidney. Patients with moderate or severe renal dysfunctions are exposed to drug accumulation and subsequent bleeding, the major adverse effect reported. This study presents 2 automated assays, a clotting method, and a kinetics chromogenic technique, proposed for the quantitative measurement of bivalirudin in citrated plasma. Both assays need a specific bivalirudin calibration, are fully automatable on coagulation instruments, and can be available at any time in specialized clinical laboratories for an on time monitoring of treated patients. Assay ranges are from 0.3 to 5.0 μg/ml (clotting assay) or to 6.0μg/ml (chromogenic assay), and up to 20.0μg/ml with an additional automatic plasma dilution. These methods offer excellent performances, with good reproducibility and repeatability. This study reports the results obtained with both assays on bivalirudin measurements in 26 treated patients collected at 4 timings. Both methods are fully consistent and contribute to facilitate and secure the use of this anticoagulant when it is indicated.

Functional Characterization of Antithrombin Mutations by Monitoring of Thrombin Inhibition Kinetics

Inactivation of thrombin by the endogenous inhibitor antithrombin (AT) is a central mechanism in the regulation of hemostasis. This makes hereditary AT deficiency, which is caused by SERPINC1 gene mutations, a major thrombophilic risk factor. Aim of this study was to assess to what extent AT mutations impair thrombin inhibition kinetics. The study population included 36 thrombophilic patients with 19 different mutations and mean AT levels of 65% in a thrombin-based functional assay, and 26 healthy controls. To assess thrombin inhibition kinetics, thrombin (3.94 mU/mL final concentration) was added to citrated plasma. Subsequently, endogenous thrombin inhibition was stopped by addition of the reversible thrombin inhibitor argatroban and the amount of argatroban-complexed thrombin quantified using an oligonucleotide-based enzyme capture assay. The plasma half-life of human thrombin was significantly longer in patients with AT mutations than in the controls (119.9 versus 55.9 s). Moreover, it was disproportionately prolonged when compared with preparations of wild type AT in plasma, in whom a comparable thrombin half-life of 120.8 s was reached at a distinctly lower AT level of 20%. These findings may help to better understand the increased thrombotic risk of SERPINC1 mutations with near normal AT plasma levels in functional assays.

Enhanced Anticoagulation Activity of Functional RNA Origami

Anticoagulants are commonly utilized during surgeries and to treat thrombotic diseases like stroke and deep vein thrombosis. However, conventional anticoagulants have serious side-effects, narrow therapeutic windows, and lack safe reversal agents (antidotes). Here, an alternative RNA origami displaying RNA aptamers as target-specific anticoagulant, is described. Improved design and construction techniques for self-folding, single-molecule RNA origami as a platform for displaying pre-selected RNA aptamers with precise orientational and spatial control, are reported. Nuclease resistance is added using 2’-fluoro-modified pyrimidines during in vitro transcription. When four aptamers are displayed on the RNA origami platform, the measured thrombin inhibition and anticoagulation activity is higher than observed for free aptamers, ssRNA-linked RNA aptamers, and RNA origami displaying fewer aptamers. Importantly, thrombin inhibition is immediately switched off by addition of specific reversal agents. Results for ssDNA and ssPNA (peptide nucleic acid) antidotes show restoration of 75% and 95% coagulation activity, respectively. To demonstrate potential for practical, long-term storage for clinical use, RNA origami was freeze-dried, and stored at room temperature. Freshly produced and freeze-dried RNA show identical levels of activity in coagulation assays. Compared to current commercial intravenous anticoagulants, RNA origami-based molecules show promise as safer alternatives with rapid activity switching for future therapeutic applications.