Covalent Cell‐Loading Injectable Hydrogel Scaffold Significantly Promotes Tissue Regeneration In Vivo Compared with a Conventional Physical Cell‐Loading Hydrogel Scaffold

Abstract

AbstractCurrently, one of the major tendencies to be adopted for the design of hydrogel scaffolds in tissue engineering include that cells are loaded physically into the pores of 3D hydrogel networks. In this study, a drastic deviation from this tendency is proposed and developed a new type of hydrogel scaffold in which cells are covalently connected to 3D hydrogel networks via bioorthogonal click cross‐linking reactions of azide‐modified cells with alkyne‐modified polymers. The purpose of this study is to directly compare the utility of the covalent cell‐loading approach and the conventional physical cell‐loading approach as hydrogel scaffolds for in vivo tissue engineering. It is found that the proposed covalent cell‐loading approach significantly promotes tissue regeneration and functional recovery in vivo in comparison with the conventional physical cell‐loading approach. This is the first report demonstrating the importance of the covalent cell‐loading approach in tissue engineering. This covalent cell‐loading approach is applicable to a broad spectrum of mammalian cells, including stem cells. The present findings provide a promising new route to generate innovative hydrogel scaffolds for in vivo tissue engineering.