VWF-targeted thrombolysis to overcome rh-tPA resistance in experimental murine ischemic stroke models.

Recombinant human tissue plasminogen activator (rh-tPA) is an important thrombolytic agent for treatment of acute ischemic stroke. It requires fibrin binding for plasminogen activation. In contrast, Microlyse, a novel thrombolytic agent, requires von Willebrand factor (VWF) binding for plasminogen activation. We compared rh-tPA with Microlyse, administered 20 minutes after inducing thrombosis, in 2 randomized blinded acute ischemic stroke mouse models. Thrombosis was induced in the middle cerebral artery with different experimental triggers. Where thrombin infusion generates fibrin-rich thrombi, topical FeCl3 application generates platelet-rich thrombi. In the fibrin-rich model, both rh-tPA and Microlyse increased cortical reperfusion (determined by laser speckle imaging) 10 minutes after therapy administration (35.8 ± 17.1%; P = .001 39.3 ± 13.1%; P < .0001; 15.6 ± 7.5%, respectively, vs vehicle). In addition, both thrombolytic agents reduced cerebral lesion volume (determined by magnetic resonance imaging) after 24 hours (18.9 ± 11.2 mm3; P = .033; 16.1 ± 13.9 mm3; P = .018; 26.6 ± 5.6 mm3, respectively, vs vehicle). In the platelet-rich model, neither rh-tPA nor Microlyse increased cortical reperfusion 10 minutes after therapy (7.6 ± 8.8%; P = .216; 16.3 ± 13.9%; P = .151; 10.1 ± 7.9%, respectively, vs vehicle). However, Microlyse, but not rh-tPA, decreased cerebral lesion volumes (13.9 ± 11.4 mm3; P < .001; 23.6 ± 11.1 mm3; P = .188; 30.3 ± 10.9 mm3, respectively, vs vehicle). These findings support broad applicability of Microlyse in ischemic stroke, irrespective of the thrombus composition.

Microlyse: a thrombolytic agent that targets VWF for clearance of microvascular thrombosis.

Thrombotic microangiopathies are hallmarked by attacks of disseminated microvascular thrombosis. In thrombotic thrombocytopenic purpura (TTP), this is caused by a rise in thrombogenic ultra-large von Willebrand factor (VWF) multimers because of ADAMTS13 deficiency. We previously reported that systemic plasminogen activation is therapeutic in a TTP mouse model. In contrast to its natural activators (ie, tissue plasminogen activator and urokinase plasminogen activator [uPA]), plasminogen can directly bind to VWF. For optimal efficacy and safety, we aimed to focus and accelerate plasminogen activation at sites of microvascular occlusion. We here describe the development and characterization of Microlyse, a fusion protein consisting of a high-affinity VHH targeting the CT/CK domain of VWF and the protease domain of uPA, for localized plasminogen activation on microthrombi. Microlyse triggers targeted destruction of platelet-VWF complexes by plasmin on activated endothelial cells and in agglutination studies. At equal molar concentrations, Microlyse degrades microthrombi sevenfold more rapidly than blockade of platelet-VWF interactions with a bivalent humanized VHH (caplacizumab*). Finally, Microlyse attenuates thrombocytopenia and tissue damage (reflected by increased plasma lactate dehydrogenase activity, as well as PAI-1 and fibrinogen levels) more efficiently than caplacizumab* in an ADAMTS13-/- mouse model of TTP, without affecting hemostasis in a tail-clip bleeding model. These findings show that targeted thrombolysis of VWF by Microlyse is an effective strategy for the treatment of TTP and might hold value for other forms of VWF-driven thrombotic disease.

VhH anti-thrombomodulin clone 1 inhibits TAFI activation and enhances fibrinolysis in human whole blood under flow.

BACKGROUND: Thrombomodulin on endothelial cells can form a complex with thrombin. This complex has both anticoagulant properties, by activating protein C, and clot-protective properties, by activating thrombin-activatable fibrinolysis inhibitor (TAFI). Activated TAFI (TAFIa) inhibits plasmin-mediated fibrinolysis. OBJECTIVES: TAFIa inhibition is considered a potential antithrombotic strategy. So far, this goal has been pursued by developing compounds that directly inhibit TAFIa. In contrast, we here describe variable domain of heavy-chain-only antibody (VhH) clone 1 that inhibits TAFI activation by targeting human thrombomodulin. METHODS: Two llamas (Lama Glama) were immunized, and phage display was used to select VhH anti-thrombomodulin (TM) clone 1. Affinity was determined with surface plasmon resonance and binding to native TM was confirmed with flow cytometry. Clone 1 was functionally assessed by competition, clot lysis, and thrombin generation assays. Last, the effect of clone 1 on tPA-mediated fibrinolysis in human whole blood was investigated in a microfluidic fibrinolysis model. RESULTS: VhH anti-TM clone 1 bound recombinant TM with a binding affinity of 1.7 ± 0.4 nM and showed binding to native TM. Clone 1 competed with thrombin for binding to TM and attenuated TAFI activation in clot lysis assays and protein C activation in thrombin generation experiments. In a microfluidic fibrinolysis model, inhibition of TM with clone 1 fully prevented TAFI activation. DISCUSSION: We have developed VhH anti-TM clone 1, which inhibits TAFI activation and enhances tPA-mediated fibrinolysis under flow. Different from agents that directly target TAFIa, our strategy should preserve direct TAFI activation via thrombin.

Thrombo-Inflammation in Cardiovascular Disease: An Expert Consensus Document from the Third Maastricht Consensus Conference on Thrombosis.

Thrombo-inflammation describes the complex interplay between blood coagulation and inflammation that plays a critical role in cardiovascular diseases. The third Maastricht Consensus Conference on Thrombosis assembled basic, translational, and clinical scientists to discuss the origin and potential consequences of thrombo-inflammation in the etiology, diagnostics, and management of patients with cardiovascular disease, including myocardial infarction, stroke, and peripheral artery disease. This article presents a state-of-the-art reflection of expert opinions and consensus recommendations regarding the following topics: (1) challenges of the endothelial cell barrier; (2) circulating cells and thrombo-inflammation, focused on platelets, neutrophils, and neutrophil extracellular traps; (3) procoagulant mechanisms; (4) arterial vascular changes in atherogenesis; attenuating atherosclerosis and ischemia/reperfusion injury; (5) management of patients with arterial vascular disease; and (6) pathogenesis of venous thrombosis and late consequences of venous thromboembolism.

A head-to-head comparison of conjugation methods for VHHs: Random maleimide-thiol coupling versus controlled click chemistry.

Targeted delivery of therapeutics is an attractive strategy for vascular diseases. Recently, variable domains of heavy-chain-only antibodies (VHHs) have gained momentum as targeting ligands to achieve this. Targeting ligands need adequate conjugation to the preferred delivery platform. When choosing a conjugation method, two features are critical: a fixed and specified stoichiometry and an orientation of the conjugated targeting ligand that preserves its functional binding capacity. We here describe a comparison of popular maleimide-thiol conjugation with state-of-the-art "click chemistry" for conjugating VHHs. First, we demonstrate the modification of VHHs with azide via Sortase A mediated transpeptidation. Subsequently, optimal clicking conditions were found at a temperature of 50 °C, using a 3:1 M ratio of DBCO-PEG:VHH-azide and an incubation time of 18 h. Second, we show that stoichiometry was controllable with click chemistry and produced defined conjugates, whereas maleimide-thiol conjugation resulted in diverse reaction products. In addition, we show that all VHHs - independent of the conjugation method or conjugated residue - still specifically bind their cognate antigen. Yet, VHH's functional binding capacities after click chemistry were at least equal or better than maleimide thiol conjugates. Together these data underline that click chemistry is superior to maleimide-thiol conjugation for conjugating targeting ligands.

Iron nanomedicines induce Toll-like receptor activation, cytokine production and complement activation.

Approximately a dozen of intravenous iron nanomedicines gained marketing authorization in the last two decades. These products are generally considered as safe, but have been associated with an increased risk for hypersensitivity-like reactions of which the underlying mechanisms are unknown. We hypothesized that iron nanomedicines can trigger the innate immune system. We hereto investigated the physico-chemical properties of ferric gluconate, iron sucrose, ferric carboxymaltose and iron isomaltoside 1000 and comparatively studied their interaction with Toll-like receptors, the complement system and peripheral blood mononuclear cells. Two out of four formulations appeared as aggregates by Scanning Transmission Electron Microscopy analysis and were actively taken up by HEK293T- and peripheral blood mononuclear cells in a cholesterol-dependent manner. These formulations triggered in vitro activation of intracellular Toll-like receptors 3, -7 and -9 in a dose- and serum-dependent manner. In parallel experiments, we determined that these compounds activated the complement system. Finally, we found that uptake of aggregation-prone iron nanomedicines by peripheral blood mononuclear cells in whole blood induced production of the proinflammatory cytokine IL-1ß, but not IL-6.