The current study showed in vivo safety, tolerability, and biocompatibility of the aflibercept-DDS in the eyes of healthy nonhuman primates for up to 6 months after IVT injection. All aflibercept-DDS injected eyes had no morphologic and functional abnormalities for up to 6 months after the IVT injection. The results of the present study using a nonhuman primate model are consistent with our previous studies using aflibercept-DDS in cell-based models and rodents.
18,20,23,30,31 In support of the current study, we have done detailed physicochemical characterization of the DDS formulation in our previous publications.
17,23,24 We have also previously demonstrated in vitro drug release
17,18,20,23,31 and in vivo safety and efficacy of the DDS in a small rodent model.
20,30 Specifically, the aflibercept-DDS and its degraded products showed no toxicity to any cells within the eye consistent with the lack of cytotoxicity observed in HUVECs when the aflibercept-DDS was washed for more than three times, identical to the protocol used in this study.
23 Also, the injected aflibercept-DDS showed no migration into the anterior chamber and no anterior and posterior uveitis up to 6 months for long-term IVT delivery of VEGF, which contrasts with other recent studies of DDS systems.
32–34 A recent study of IVT injection of PLGA microspheres in cynomolgus macaques describes a moderate to severe inflammatory response within 1 month postinjection that included corneal edema, corneal neovascularization, aqueous flare, vitreous cells, iridal hyperemia, posterior synechiae, inflammatory cells on the lens, and cystoid macular edema that necessitated euthanasia for animal welfare purposes.
34 Although it was observed in this study that smaller microspheres (20 µm in diameter) caused the most severe reaction, whereas the larger PLGA rods (0.9 × 3.7 mm) were well tolerated,
34 we highlight that the encapsulation of the 7 µm PLGA microspheres in the hydrogel is likely responsible for the minimal observed inflammation in the present study. Specifically, the crosslink density of the hydrogel has been optimized to prevent microsphere diffusion out of the hydrogel.
17 We have previously demonstrated that the radius of gyration of the hydrogel to be ∼17 nm in swollen state, and this dimension ensures that microspheres will not diffuse out of the hydrogel.
17 The lack of anterior and posterior uveitis observed in the present study combined with retention of normal retinal morphology and function suggests that encapsulation of microspheres within a hydrogel composite DDS may be a compelling alternative to IVT drug delivery with PLGA microspheres alone.