Nanoarchitectonics of Injectable Biomimetic Conjugates for Cartilage Protection and Therapy Based on Degenerative Osteoarthritis Progression

Abstract

Osteoarthritis (OA) is a common age-related degenerative disease characterized by changes in the local tissue environment as inflammation progresses. Inspired by the wind-dispersal mechanism of dandelion seeds, this study develops responsive biomimetic microsphere–drug conjugate for OA therapy and protection. The conjugate integrates dibenzaldehyde polyethylene glycol (DFPEG) with chitosan and polyethylene glycol diacrylate (PEGDA) through dynamic covalent bonds to form a dual-network hydrogel microsphere. Based on the progression of OA, the conjugate with the surface-anchored cyclic peptide cortistatin-14 (CST-14) achieves targeted drug therapy and a self-regulating hydrogel network. In cases of progressing inflammation (pH < 5), CST-14 dissociates from the microsphere surface (viz. the drug release rate increased) and inhibits TNF-α signaling to suppress OA. Concurrently, the monomer DFPEG responsively detaches from the hydrogel network and scavenges reactive oxygen species (ROS) to protect the cartilage tissue. The ROS scavenging of DFPEG is comparable to that of coenzyme Q10 and vitamin C. The degraded PEGDA microspheres provide tissue lubrication through reused conjugates. The rat OA model successfully achieved a synergistic therapeutic effect greater than the additive effect (1 + 1 > 2). This strategy offers an approach for anchoring amine-containing drugs and has marked potential for OA treatment and protection.