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Literature DB >> 26607808

Stability of limbal stem cell deficiency after mechanical and thermal injuries in mice.

Neda Afsharkhamseh¹, Asadolah Movahedan¹, Sanaz Gidfar¹, Michael Huvard¹, Lisa Wasielewski¹, Behrad Y Milani¹, Medi Eslani¹, Ali R Djalilian².

Abstract

We studied the reproducibility and stability of limbal stem cell deficiency (LSCD) in mice following controlled injuries to the corneal and limbal epithelia. In one method, corneal and limbal epithelia were entirely removed with a 0.5 mm metal burr. In the other, limbus to limbus epithelial removal with the burr was followed by thermal injury to the limbus. These two methods were compared with a previously published one. Unwounded corneas were used as control. The corneas were examined monthly for three months by slit lamp with fluorescein staining. Immunofluorescence staining for cytokeratin 12 and 8 on corneal wholemount and cross sections were performed to determine the phenotype of the epithelium. Mechanical shaving of the epithelium, with or without thermal injury, resulted in a reproducible state of LSCD marked by superficial neovascularization, reduce of keratin 12 expression and presence of goblet cells on the cornea. The phenotype was stable in 100% of the eyes up to at least three months. Thermal injury produced a more severe phenotype with more significant stromal opacification. These corneal injury models may be useful for studying the mechanisms leading to limbal stem cell deficiency.

Entities: Chemical Disease Gene Species

Keywords: Conjunctivalization; Cornea; Corneal opacity; Epithelium; Limbal stem cell deficiency; Limbus; Mouse model; Neovascularization; Stem cell

Mesh：

Year: 2015 PMID： 26607808 PMCID： PMC4979604 DOI： 10.1016/j.exer.2015.11.012

Source DB: PubMed Journal: Exp Eye Res ISSN： 0014-4835 Impact factor: 3.467

33 in total

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