Inflammation and cartilage degeneration are critical challenges in osteoarthritis (OA) treatment. Achieving sustained drug efficacy while mitigating the adverse effects of inflammation and reactive oxygen species remains a significant challenge. This study synthesizes a gallic acid-magnesium (GA-Mg) metal-organic framework (MOF) as a drug carrier for puerarin (PA). The PA-loaded GA-Mg MOF (pGM) is encapsulated within chondroitin sulfate methacrylate, forming monodisperse hybrid microspheres (CM@pGM) under ultraviolet light using microfluidic technology. The pGM is physically confined within the microspheres through a network of structural obstructions and noncovalent interactions. During degradation, GA and Mg2+ ions release from pGM, improving the inflammatory microenvironment of the articular cavity and mitigating oxidative stress. The sustained release of Mg2+ and PA supports chondrocyte anabolism and facilitates cartilage repair. In vitro studies confirm that injectable microspheres extend the drug release period to over 2 weeks. In vivo experiments demonstrate that CM@pGM significantly reduces osteophyte formation, alleviates degenerative changes in articular cartilage, and delays OA progression. In conclusion, CM@pGM, as a drug delivery platform that ameliorates the inflammatory microenvironment, alleviates oxidative stress, and promotes cartilage repair, holds significant potential for OA treatment.
Keywords: anti-inflammation; cartilage degeneration; metal−organic frameworks; microspheres; osteoarthritis.