Isolation and Identification of Limbal Niche Cells.

Here we report a standard procedure for the isolation and identification of limbal niche cells (LNCs). Limbus tissue obtained from an eye bank was used for LNCs isolation. The tissue was divided into 12 pieces under aseptic conditions and digested for 18 h at 37 °C in the cell culture incubator using collagenase A to obtain cell clusters with LNCs and limbal epithelial progenitor cells. The cell clusters were further digested for 15 min at 37 °C using 0.25% trypsin-EDTA to obtain single cells and then cultured in modified embryonic stem cell medium (MESCM) on a plastic surface coated with 5% Matrigel. Cells were passaged upon 70% confluence, and LNCs were identified using immunofluorescence, real-time quantitative PCR (qPCR), and flow cytometry. Primary LNCs were isolated and passaged more than 12 times. The proliferation activity of LNCs from P4 to P6 was the highest. LNCs expressed higher stem cell markers than BMMSCs (SCF, Nestin, Rex1, SSEA4, CD73, CD90, MSX1, P75NTR, and PDGFRß). Furthermore, results showed that P4 LNCs uniformly expressed VIM, CD90, CD105, and PDGFRß, but not Pan-CK, which could be used as a marker for the identification of LNCs. Flow cytometric analysis showed that approximately 95%, 97%, 92%, and 11% of LNCs expressed CD73, CD90, CD105, and SCF respectively, while they were 68%, 99%, 20%, and 3% in BMMSCs. The standard process for LNC isolation and identification could provide a reliable laboratory basis for the widespread use of LNCs.

Limbal Bio-Engineered Tissue Employing 3D Nanofiber-Aerogel Scaffold to Facilitate LSCs Growth and Migration.

Constrained by the existing scaffold inability to mimic limbal niche, limbal bio-engineered tissue constructed in vitro is challenging to be widely used in clinical practice. Here, a 3D nanofiber-aerogel scaffold is fabricated by employing thermal cross-linking electrospinned film polycaprolactone (PCL) and gelatin (GEL) as the precursor. Benefiting from the cross-linked (160 °C, vacuum) structure, the homogenized and lyophilized 3D nanofiber-aerogel scaffold with preferable mechanical strength is capable of refraining the volume collapse in humid vitro. Intriguingly, compared with traditional electrospinning scaffolds, the authors' 3D nanofiber-aerogel scaffolds possess enhanced water absorption (1100-1300%), controllable aperture (50-100 µm), and excellent biocompatibility (optical density value, 0.953 ± 0.021). The well-matched aperture and nanostructure of the scaffolds with cells enable the construction of limbal bio-engineered tissue. It is foreseen that the proposed general method can be extended to various aerogels, providing new opportunities for the development of novel limbal bio-engineered tissue.