One-step soaking strategy toward mechanobiological double-network hydrogel with improving chondrogenesis capacity

Cartilage tissue engineering (CTE) is a promising strategy for addressing the persistent challenges in healing articular cartilage defects in the clinic, aiming to manufacture scaffolds with ideal mechanical characteristics that can provide a conducive microenvironment for the reconstruction or replacement of damaged cartilage defects. Easy operation, excellent mechanical strength, remarkable biocompatibility, and inherent capacity to promote cartilage formation are essential in CTE. This study designed a mechanobiological double-network (DN) hydrogel (KCS-PAA-Mn2+) through a one-step soaking strategy of immersing the composite hydrogel (KCS-PAA) of kartogenin (KGN)-conjugated short-chain chitosan (CS) covalent with polyacrylic acid (PAA) in manganese chloride (MnCl2) solution. Due to the strong physical interactions of CS chain-entanglement network and carboxylate-Mn2+ complex inducing polymer aggregation state transitions, the KCS-PAA-Mn2+ DN hydrogel exhibited exceptional mechanical characteristics, such as high tensile property (strength: 0.24 MPa at a strain of 552 %; toughness: 0.66 MPa), compressibility (strength: 51.98 MPa at a strain of 95 %; compressive modulus: 0.09 MPa), controllable swelling behavior (similar to 327 %), and sustained drug release (>2 weeks). Moreover, in vitro biological studies demonstrated that the KCS-PAA-Mn2+ DN hydrogel not only promoted cell growth and proliferation but also enhanced the expression of genes specific to cartilage and the release of cartilage extracellular matrix (ECM) by bone mesenchymal stem cells (BMSCs), thus enabling a continuous concentration for a long period and persistently enhancing its chondrogenic efficiency. Overall, this soaking methodology reported here is universal to construct mechanically bioactive scaffolds that could expand their bio-applicability with simultaneous advantages of mechanical supports, tailorable swelling, sustainable drug release and long-lasting biological function, thus facilitating the advancement of cartilage-engineered hydrogel biomaterials to a higher level.