Preclinical evaluation of the novel small-molecule integrin alpha5beta1 inhibitor JSM6427 in monkey and rabbit models of choroidal neovascularization.

OBJECTIVE: To evaluate the pharmacologic activity and tolerability of JSM6427, a potent and first selective small-molecule inhibitor of integrin alpha5beta1, in monkey and rabbit models of choroidal neovascularization (CNV). METHODS: JSM6427 selectivity for alpha5beta1 was evaluated by in vitro binding assays while the ability of JSM6427 to inhibit CNV was investigated in a laser-induced monkey model and a growth factor-induced rabbit model. Intravitreal injections of JSM6427 (100, 300, or 1000 microg) or vehicle were administered immediately after the CNV induction procedure and at weekly intervals for 4 weeks. Fluorescein angiography was performed weekly. Ocular tolerability was evaluated ophthalmoscopically and histologically in both models; additional assessments in monkeys included electroretinography, biomicroscopy, pathological examination, and analysis of JSM6427 pharmacokinetics. RESULTS: JSM6427 was highly selective for the alpha5beta1-fibronectin interaction. Weekly intravitreal injections of JSM6427 resulted in a statistically significant dose-dependent inhibition of CNV in laser-induced and growth factor-induced models without any ocular JSM6427-related adverse effects. JSM6427 was cleared through the systemic circulation with no evidence of systemic accumulation. CONCLUSIONS: Intravitreal JSM6427 provided dose-dependent inhibition of CNV in monkey and rabbit experimental models. CLINICAL RELEVANCE: JSM6427 may provide a new approach for the treatment of ocular neovascular diseases such as age-related macular degeneration in humans.

Preclinical safety of recombinant human thrombin.

Recombinant human thrombin (rhThrombin) is being developed as an alternative to thrombin products purified from pooled human or bovine plasma, which are currently marketed for topical hemostasis. Preclinical studies of rhThrombin were conducted prior to its evaluation as a topical adjunct to surgical hemostasis in clinical trials. No overt clinical pathology or signs were observed in cynomolgus monkeys following implantation of a gelatin sponge containing either rhThrombin or bovine thrombin to a surgical liver wound, and similar gross and microscopic wound healing characteristics were observed over an eight-week recovery period with either compound. Repeated subcutaneous injections of rhThrombin or bovine thrombin to cynomolgus monkeys produced no treatment-related effects. Whereas no monkeys demonstrated anti-rhThrombin antibody seroconversion, specific anti-bovine antibodies were detected in all tested monkeys exposed to bovine thrombin. Addition of rhThrombin or bovine thrombin to mouse fibroblast cells resulted in expected detachment and shape change. Topical application of rhThrombin to rabbits did not cause irritation to the eye, normal skin, or abraded skin. These studies showed that topical, subcutaneous, or implanted rhThrombin was minimally immunogenic, safe, and well tolerated in nonclinical models, and supported the clinical evaluation of rhThrombin in a variety of surgical settings.

Preclinical evaluation of an anti-alpha5beta1 integrin antibody as a novel anti-angiogenic agent.

Integrin alpha5beta1, the principal fibronectin receptor, is an important survival factor, playing a key role in angiogenesis. Angiogenesis is critical for tumor growth, and anti-angiogenic therapies have met clinical success. To validate the therapeutic potential of an anti-alpha5beta1 strategy, we generated volociximab (M200) a chimeric human IgG4 version of the alpha5beta1 function-blocking murine antibody IIA1; and F200, the Fab derivative. Volociximab, F200 and IIA1 showed similar activity by ELISA (EC50= 0.2nM), Biacore (Kd= 0.1-0.4nM) and inhibition of fibronectin binding (IC50= 2-3nM). The inhibitory potential of alpha5beta1 antibodies was compared to HuMV833, an anti-VEGF antibody. Both volociximab and HuMV833 inhibited HUVEC proliferation (IC50 of volociximab = 0.2-0.5nM; IC50 of HuMV833 = 45nM). However, IIA1, volociximab and F200 were also potent inhibitors of an in vitro model of angiogenesis (HUVEC tube formation assay), unlike HuMV833. Additionally, volociximab inhibited in vitro tube formation induced by VEGF and/or bFGF, suggesting a mechanism of action independent of growth factor stimulus. In fact, inhibition of alpha5beta1 function by volociximab induced apoptosis of actively proliferating, but not resting, endothelial cells. Volociximab does not cross-react with rodent alpha5beta1, therefore in vivo validation of an anti-alpha5beta1 approach was conducted in a cynomolgus model of choroidal revascularization. Volociximab and F200 were potent inhibitors of neovessel formation in this model. These data demonstrate that volociximab has therapeutic potential in diseases in which new vessel formation is a component of the pathology.