Fabrication and characterization of an electrospun silk fibroin/gelatin transparent graft material for corneal epithelial regeneration

Abstract

The damaged corneal epithelial causing loss of vision can be restored by epithelial tissue regeneration through tissue engineering approach that provides an engineered corneal substitute with appropriate properties and nanofibrous architecture. This works reports a polymeric matrix that was derived from silk fibroin (SF) and gelatin (GE) natural polymer blend with optimized composition resembling the structure and function of the native epithelial tissue. SF/GE blend spinning solutions prepared with different volume ratios of SF/GE: 70/30, 50/50, and 30/70 were used to fabricate electrospun mats. The fabricated two-dimensional mats had nanofibrous porous architecture having interconnected pores with pore size range of 175–267 nm suitable for corneal epithelial regeneration and 891.2–558 nm fiber diameter range as revealed by scanning electron microscopic image analysis. The performed Fourier transform infrared spectra confirmed the presence of individual polymers in the scaffolds and the scaffolds are hydrophilic in nature. Among the scaffolds, SF/GE 70:30 and SF/GE 50:50 composition possess desired porosity range of 87–88%. The tensile strength was slightly decreased with increase in GE content and the strength obtained was in the range 2.74–2.26 Mpa. An enhanced transparency was obtained with increased GE concentration, the transparency range of 73–82% observed with SF/GE:50/50 matches with the transparency of natural corneal epithelium. The biocompatibility of the scaffolds was confirmed by cell attachment, cytotoxicity and ROS evaluation by culturing rabbit corneal fibroblast cells (SIRC) on the scaffolds. Among the scaffolds, SF/GE: 70/30 exhibited the highest cell viability, but with less transparency ranging 55–71%. Therefore, considering all the properties, SF/GE with 50:50 ratio scaffold may be a suitable substrate in the field of corneal tissue engineering.