Abstract

Abstract Ideal cartilage tissue engineering requires scaffolds featuring good biocompatibility, large pore structure, high mechanical strength, as well as minimal invasion procedure. Although significant progress has been made in the development of polymer scaffolds, the construction of smart systems with all the desired properties is still emerging as a challenge. The thermogels of stereocomplex 4‐arm poly(ethylene glycol)–polylactide (PEG–PLA) (scPLA gel ) and stereocomplex cholesterol‐modified 4‐arm PEG–PLA (scPLA–Chol gel ) from the equimolar enantiomeric 4‐arm PEG–PLA and 4‐arm PEG–PLA–Chol, respectively, are fabricated as scaffolds for cartilage tissue engineering. scPLA–Chol gel shows lower critical gelation temperature, higher mechanical strength, larger pore size, better chondrocyte adhesion, and slower degradation compared to scPLA gel as the benefit of cholesterol modification, which is more appropriate for cartilage regeneration. Moreover, the preservation of morphology, biomechanical property, cartilaginous specific matrix, as well as cartilaginous gene expressions of engineered cartilage mediated by scPLA–Chol gel are proven superior to those by scPLA gel . scPLA–Chol gel serves as a promising chondrocyte carrier for cartilage tissue engineering and gives an alternative solution to clinical cartilage repair.