Ocular-Surface Regeneration Therapies for Eye Disorders: The State of the Art.
Matteo PosarelliDavide RomanoDavide TucciGiuseppe GiannaccareVincenzo ScorciaAndrea TaloniLuca PaganoAlfredo BorgiaPublished in: Biotech (Basel (Switzerland)) (2023)
The ocular surface is a complex structure that includes cornea, conjunctiva, limbus, and tear film, and is critical for maintaining visual function. When the ocular-surface integrity is altered by a disease, conventional therapies usually rely on topical drops or tissue replacement with more invasive procedures, such as corneal transplants. However, in the last years, regeneration therapies have emerged as a promising approach to repair the damaged ocular surface by stimulating cell proliferation and restoring the eye homeostasis and function. This article reviews the different strategies employed in ocular-surface regeneration, including cell-based therapies, growth-factor-based therapies, and tissue-engineering approaches. Dry eye and neurotrophic keratopathy diseases can be treated with nerve-growth factors to stimulate the limbal stem-cell proliferation and the corneal nerve regeneration, whereas conjunctival autograft or amniotic membrane are used in subjects with corneal limbus dysfunction, such as limbal stem-cell deficiency or pterygium. Further, new therapies are available for patients with corneal endothelium diseases to promote the expansion and migration of cells without the need of corneal keratoplasty. Finally, gene therapy is a promising new frontier of regeneration medicine that can modify the gene expression and, potentially, restore the corneal transparency by reducing fibrosis and neovascularization, as well as by stimulating stem-cell proliferation and tissue regeneration.
Keyphrases
- wound healing
- stem cells
- cell proliferation
- growth factor
- optical coherence tomography
- gene expression
- tissue engineering
- gene therapy
- cell therapy
- cell cycle
- cataract surgery
- dna methylation
- induced apoptosis
- randomized controlled trial
- systematic review
- single cell
- oxidative stress
- diabetic retinopathy
- mesenchymal stem cells
- cell cycle arrest
- endothelial cells