Injectable biodegradable bi-layered capsule for sustained delivery of bevacizumab in treating wet age-related macular degeneration

Abstract

Vascular endothelial growth factor (VEGF) is a key regulator of abnormal blood vessel growth. As such, bevacizumab-based inhibition of VEGF has been the clinically adopted strategy to treat colorectal and breast cancers as well as age-related macular degeneration (AMD). However, as the treatment of vascular diseases often requires a high drug concentration for a long period, the burst release of bevacizumab remains a critical limitation in anti-VEGF-based therapies. Maintaining bevacizumab at high concentrations over extended periods remains challenging due to insufficient drug loading capacity and drug-device interactions. We report the development of a polymeric based bi-layered capsule that could address these challenges by extending the release over one year, thereby providing an effective platform enabling treatment of chronic vascular diseases. Remarkably, the developed capsules have a bi-layered structure which ensures the structural integrity of the injectable capsules and appropriate diffusion of bevacizumab by providing optimal physical trapping and electrostatic interaction. Meanwhile, the central hollow design enables a higher drug loading to meet the need for long-term release of bevacizumab for several months to one year. Using an in vitro drug release assay, we demonstrated that the bi-layered capsule could produce longer-term local drug administration by intravitreal injection compared to previously reported devices. The capsules also present minimal toxicity and maintain anti-VEGF potency, suggesting that our approach may have the potential to treat vascular-related diseases using bevacizumab.

Keywords: Angiogenesis; Anti-VEGF; Drug delivery; Electrospinning; Intravitreal injection; Macular degeneration; Microcapsule; Polymer.