Surface-decorated Nanoliposomal Leonurine Targets Activated Fibroblast-Like Synoviocytes for Efficient Rheumatoid Arthritis Therapy

Rheumatoid arthritis (RA) is a chronic autoimmune disease that causes progressive joint destruction, leading to impaired life quality, disability, and even premature mortality. However, current medications suffer from limited clinical outcomes and severe side effects due to low bioavailability and non-specific distribution after administration. Herein, a targeting nanosystem (HAP-Lipo@Leo) was constructed for efficient RA treatment, which can precisely deliver a natural anti-arthritic drug leonurine (Leo) to the inflamed joint by HAP-1 peptide-mediated recognition of activated fibroblast-like synoviocytes (FLS). More specifically, HAP-Lipo@Leo was prepared by a combination of thin film hydration and high-pressure microfluidization and surface-decorated with HAP-1 peptide and PEG before encapsulating Leo by the ammonium sulfate gradient method. The as-obtained HAP-Lipo@Leo can be selectively internalized by activated FLS and impairs the lamellipodia formation and overexpression of inflammatory cytokines, both of which play detrimental roles in joint damage. Furthermore, HAP-Lipo@Leo demonstrated arthritic joint-specific distribution, significant inhibition of synovial inflammation, and reversal of cartilage and bone destruction in adjuvant-induced arthritis rats as evidenced by comprehensive investigations including ELISA tests, histopathology examinations, and micro-CT analysis. In addition, HAP-Lipo@Leo exhibited good biocompatibility and safety both in vitro and in vivo. Taken together, HAP-Lipo@Leo holds great potential for clinical RA management by integrating activated FLS targeting, long circulation, multifaceted therapeutic effects, and excellent biocompatibility. Construction of HAP-1 peptide-engineered liposomal leonurine (HAP-Lipo@Leo) for efficient treatment of rheumatoid arthritis by downregulating inflammation, halting migration and invasion of activated FLS, and preserving cartilage/bone integrity.