Litcius/Paper detail

Bi-phasic integrated silk fibroin/polycaprolactone scaffolds for osteochondral regeneration inspired by the native joint tissue and interface

Zexing Zhang, Qingquan Dong, Zubing Li, Zubing Li, Gu Cheng, Zhi Li, Zhi Li

2025Materials Today Bio9 citationsDOIOpen Access PDF

Abstract

Osteochondral scaffolds designed with bi-phasic and multi-phasic have typically struggled with post-implantation delamination. To address this issue, we developed a novel integrated scaffold with natural and continuous interface and heterogeneous bilayer structure. Through layer-by-layer wet electrospinning, two-dimensional (2D) bi-layer integrated membranes of silk fibroin (SF) and polycaprolactone (PCL) were fabricated. These membranes were then transformed into three-dimensional (3D) scaffolds using a CO 2 gas foaming technique, followed by gelatin coating on the osteogenic layer to afford final bi-phasic porous scaffolds. In vitro studies indicated that the 3D scaffolds better-maintained cell phenotypes than conventional 2D electrospun films. Additionally, the 3D scaffolds showed superior cartilage repair and osteoinductivity potential, with increased subchondral bone volume and reduced defect area in rat osteochondral defects models at 12 weeks. Taken together, these gas-foamed scaffolds were a promising candidate for osteochondral regeneration.

Topics & Concepts

FibroinPolycaprolactoneRegeneration (biology)Materials scienceInterface (matter)SILKTissue engineeringJoint (building)Biomedical engineeringComposite materialPolymerEngineeringBiologyCell biologyStructural engineeringCapillary numberCapillary actionSilk-based biomaterials and applicationsBone Tissue Engineering MaterialsPeriodontal Regeneration and Treatments