Preparation, physico-biochemical characterization, and proteomic analysis of highly transparent corneal extracellular matrices for lamellar keratoplasty and tissue-engineered cornea construction

Abstract

Corneal opacity and deformation, which often require corneal transplantation for treatment, are among the leading causes of monocular blindness. To restore corneal clarity and integrity, there is a need for an artificial stroma that not only matches the transparency of donated human cornea but also effectively integrates to the corneal tissue. In this study, a transparent decellularized cornea was successfully developed using the high hydrostatic pressure method with processing conditions optimized for corneal decellularization. Biochemical analyses demonstrated the effective removal of cellular components from the transparent decellularized corneas, while preserving collagen and glycosaminoglycans. Proteome analysis also revealed that core matrisome and matrisome-associated proteins remained following decellularization, similar to the composition observed in untreated corneas. The light transmittance of the transparent decellularized corneas was 86.4 ± 1.5 % in the visible region, comparable to that of donated human corneas. No complications, such as angiogenesis, were observed following interlamellar corneal transplantation in rabbits. The grafts were almost imperceptible immediately following surgery and achieved complete transparency within a few days, becoming indistinguishable even under a microscope. The transparent decellularized cornea presented here has promising potential as a material for application in lamellar keratoplasty.