Novel Biomimetic Collagen-Based Corneal Repair Material Achieved via a “Killing Two Birds with One Stone” Strategy Using Carboxymethyl-β-Cyclodextrin

Collagen, as the principal structural component of the cornea, has emerged as a promising biomaterial for artificial corneal owing to its excellent biocompatibility and degradability. However, the mechanical properties of current collagen membrane cannot match the requirements of artificial corneal materials. Inspired by the hierarchical lamellar organization of native corneal stromal collagen, a biomimetic collagen-based corneal repair material was designed via a "killing two birds with one stone" strategy. In this strategy, carboxymethyl-β-cyclodextrin (CM-β-CD) was incorporated into the collagen, serving dual functions: regulating the in vitro self-assembly process of collagen molecules and establishing multiple covalent cross-linking sites within the network. Concurrently, controlled external shear forces were applied to induce anisotropic alignment of collagen fibers, effectively replicating the highly organized structural hierarchy characteristic of native corneal stromal tissue. The resulting membrane exhibited a 67% enhancement in tensile strength (0.52 MPa) compared to pure collagen membranes. Notably, in vivo lamellar keratoplasty evaluations revealed accelerated tissue regeneration, achieving complete re-epithelialization within 14 days versus 28 days for controls. These findings establish the material's potential as an advanced artificial corneal for tissue engineering applications.