Purpose: To develop a collagen vitrigel (CV) optimized as a corneal endothelial cell (CEC) carrier and create an artificial corneal endothelial graft.
Methods: We first developed a flat-shaped collagen vitrigel for regenerative medicine (CV-RM) using porcine atelocollagen and ultraviolet (UV) irradiation. The optimal UV amount was determined by measuring the CV-RM transparency under various irradiating conditions. The collagen vitrigel for corneal endothelial regenerative treatment (CV-CERT), a transparent porcine atelocollagen with a curved shape, was made using spherically curved molds and UV irradiation. The membrane permeability of the CV-CERT was tested in vitro. The biocompatibility, transparency, and adhesiveness of the CV-CERT were evaluated in rabbit eyes. We also developed a culture technique for distributing human CECs on the curved CV-CERT.
Results: The optimal amount of UV irradiation for CV-RM transparency was 2400 mJ/cm(2). Membrane permeability of CV-CERT at day 5 was higher than that of commercially available CV (P = 0.032). The CV-CERT was transparent and biocompatible in rabbit corneas for up to 4 months. The CV-CERT remained attached to the rabbit corneal posterior surface, whereas the flat-shaped CV-RM, differing only in shape from the CV-CERT, dislocated soon after surgery. Human CECs seeded on the CV-CERT using our technique were evenly distributed with a single layer structure and a mean cell density of 2650 ± 100 cells/mm(2).
Conclusions: We developed a transparent and biocompatible porcine-derived atelocollagen vitrigel membrane with a spherical curvature. A transplantable artificial endothelial graft was created by combining cultured human CECs and the CV-CERT.
Keywords: collagen vitrigel; corneal endothelial cell transplantation; regenerative medicine.
Copyright 2014 The Association for Research in Vision and Ophthalmology, Inc.