Rat-specific decreases in platelet count caused by a humanized monoclonal antibody against sclerostin.

LY2541546 is a humanized monoclonal antibody (IgG(4)) that has been optimized for neutralizing activity against sclerostin. In 5-week and 6-month nonclinical safety studies in rats, LY2541546 caused dose-dependent reversible decreases in platelet counts accompanied by accelerated platelet production, increased megakaryocytes, and altered megakaryocyte morphology. These treatment-related effects resulted in altered primary hemostasis as manifested by prolonged bleeding after phlebotomy or incidental toenail break. In some cases, the defects in hemostasis were sufficient to result in death of the affected rats. There was no evidence in rats of general bone marrow suppression or processes (e.g., disseminated intravascular coagulopathy) that may result in thrombocytopenia. Cynomolgus monkeys given LY2541546 for 5 weeks or 9 months had no changes in platelet count or megakaryocytes. In vitro cross-reactivity studies in rats, cynomolgus monkeys, and humans revealed LY2541546-bound rat but not cynomolgus monkey or human platelets and megakaryocytes. These data taken together demonstrated that the platelet and megakaryocyte effects in rats had a species-specific pathogenesis which likely involved LY2541546 binding of a rat-specific antigen on the surface of platelets and megakaryocytes resulting in the increased clearance of platelets and megakaryocyte hyperplasia. The species-specific nature of these reversible toxicological findings combined with the ease of clinical monitoring using standard hematology enabled the safe initiation of clinical studies in human volunteers.

Intravitreal concentrations of a near-infrared fluorescence-labeled biotherapeutic determined in situ using confocal scanning laser ophthalmoscopy.

PURPOSE: The pharmacokinetics of ophthalmic biotherapeutics are difficult to determine in human vitreous humor. Because of the high transparency of living tissue to near-infrared (NIR) light, the temporal changes in vitreous concentrations of a biomolecule labeled with an NIR fluorescent probe can be monitored in situ with a scanning laser ophthalmoscope (SLO). METHODS: A humanized IgG was labeled with the NIR probe IRDye800CW (CVX-4164). Rabbits were given CVX-4164 intravitreally, and NIR fluorescence intensity was measured in the central plane of the vitreous humor with an SLO. Fluorescence intensities were converted to concentrations by using standard curves. RESULTS: Little background fluorescence was detected, and the minimum detectable concentration of CVX-4164 was <10 nM. Vitreal concentrations of CVX-4164 determined in situ declined with time, with C(max) ≈ 1 µM and t½ = 145 hours (112-µg dose). The t½ of CVX-4164 was approximately three times greater than that of the IRDye800CW alone, whereas the vitreal clearance (CL) and volume of distribution (V(ss)) of the native dye were approximately 2000- and 550-fold greater than that of the conjugate. CVX-4164 concentrations determined in situ were 2.6 to 4.4 times higher than those determined by ex vivo NIR fluorescence or ELISA in homogenized vitreous humor, reflecting the greater spatial resolution of in situ imaging. Moreover, vitreal concentrations determined in situ were >3 orders of magnitude greater than plasma concentrations of CVX-4164, as determined by ELISA, and had a different kinetic profile. CONCLUSIONS: This study demonstrates the feasibility of determining the pharmacokinetics of intraocular biotherapeutics labeled with NIR fluorescent probes by in situ monitoring.

Direct-acting fibrinolytic enzymes in shark cartilage extract: potential therapeutic role in vascular disorders.

Fibrinogen and fibrin are molecules with overlapping roles in blood clotting, fibrinolysis, wound healing, inflammation, matrix and cellular interactions and neoplasia. There is currently much interest in the possible use of fibrinolytic agents in human therapeutics. In this study, we report the presence of fibrinolytic activities in shark cartilage extract (SCE). In vitro, SCE at 100 microg/ml completely degraded fibrin gel in an aprotinin-insensitive manner, suggesting a non-plasmin molecular nature. SCE was able to cleave all chains of fibrinogen and fibrin and the cleavage was completely inhibited by 1,10-phenanthroline, suggesting an essential role for metalloprotease(s) in this process. Using fibrinogen zymography, we show that SCE contains two plasmin-independent fibrinolytic activities and that these activities are correlated with the presence of 58 and 62 kDa proteases in the extract. SCE-fibrinolytic activities are inhibited by dithiothreitol, suggesting that disulfide bonds are necessary for the protease structure. Finally, using thromboelastography, SCE markedly induced retraction of human platelet-rich plasma (PRP) clot, this process being completely abolished by 1,10-phenanthroline. These data suggest the presence of novel non-plasmin fibrinolytic activities within SCE. This extract may thus represent a potential source of new therapeutic molecules to prevent and treat vaso-occlusive and thromboembolic disorders.