Ana de la Mata

Chitosan-gelatin biopolymers as carrier substrata for limbal epithelial stem cells

The aim of this work was to evaluate semi-synthetic biopolymers based on chitosan (CH) and gelatin (G) as potential in vitro carrier substrata for human limbal epithelial cells (hLECs). To that end, human corneal epithelial cells (HCE) were cultured onto different CH–G membranes. None of the polymers were cytotoxic and cell proliferation was higher when CH was functionalized with G. Expression levels of corneal epithelial markers (K3, K12, E-caherin, desmoplakin, and zonula occludens (ZO)-1) were better maintained in HCE cells grown on CH–G 20:80 membranes than other proportions. Consequently, CH–G 20:80 was chosen for the subsequent expansion of hLECs. Cells derived from limbal explants were successfully expanded on CH–G 20:80 membranes using a culture medium lacking components of non-human animal origin. The expression levels found for corneal (K3 and K12) and limbal epithelial stem cells (K15) specific markers were similar to or higher than those found in limbal cells grown onto the control substratum. Our results demonstrate that CH–G 20:80 membranes are suitable for the expansion and maintenance of stem cells derived from the limbal niche. These results strongly support the use of polymers as alternative substrata for the transplantation of cultivated limbal cells onto the ocular surface.

Consecutive expansion of limbal epithelial stem cells from a single limbal biopsy.

Abstract Purpose: Corneal epithelium is maintained by limbal epithelial stem cells (LESCs), the loss of which can be catastrophic for corneal transparency. Effective therapies include the transplantation of cultivated LESCs, requiring optimization of in vitro cultivation protocols. Unfortunately, optimization studies are hampered by the limited number of ocular tissue donors. We investigated the feasibility of obtaining more than one limbal primary culture (LPC) from the same 1-2 mm2 limbal explant (LE). Methods: LEs were plated and maintained until outgrowth surrounded each, being removed at this point. LPCs were allowed to reach confluence (LPC0). The same removed LE was plated again, following the same procedure, obtaining LPC1. This procedure was repeated as often as possible up to six times. LPCs from each passage were analysed by real time reverse transcription-polymerase chain reaction and immunofluorescence-microscopy. Results: LPCs from LPC0 to LPC2 presented a heterogeneous cell population, with cells positive for LESC markers K14, K15, ABCG2 and p63, differentiated corneal epithelial cell-specific markers K3 and K12, and for the fibroblast marker S100A4. These cells had an epithelial-like morphology. In LPC3-LPC4, elongated cell morphology appeared, and the presence of LESC markers decreased, while the presence of differentiated corneal epithelial-cell and fibroblast markers increased. Conclusion: One LE can be successfully cultivated up to three consecutive times while maintaining the LESC phenotype in the LPC cells. This protocol provides several homologous LPCs for basic research. Additionally, by using a cell-carrier, the resulting LPCs could serve reservoirs for potential autologous expanded LESC transplantations and/or for making correlations between laboratory and clinical outcomes.

Therapeutic Effect of Human Adipose Tissue‐Derived Mesenchymal Stem Cells in Experimental Corneal Failure Due to Limbal Stem Cell Niche Damage

Limbal stem cells are responsible for the continuous renewal of the corneal epithelium. The destruction or dysfunction of these stem cells or their niche induces limbal stem cell deficiency (LSCD) leading to visual loss, chronic pain, and inflammation of the ocular surface. To restore the ocular surface in cases of bilateral LSCD, an extraocular source of stem cells is needed to avoid dependence on allogeneic limbal stem cells that are difficult to obtain, isolate, and culture. The aim of this work was to test the tolerance and the efficacy of human adipose tissue‐derived mesenchymal stem cells (hAT‐MSCs) to regenerate the ocular surface in two experimental models of LSCD that closely resemble different severity grades of the human pathology. hAT‐MSCs transplanted to the ocular surface of the partial and total LSCD models developed in rabbits were well tolerated, migrated to inflamed tissues, reduced inflammation, and restrained the evolution of corneal neovascularization and corneal opacity. The expression profile of the corneal epithelial cell markers CK3 and E‐cadherin, and the limbal epithelial cell markers CK15 and p63 was lost in the LSCD models, but was partially recovered after hAT‐MSC transplantation. For the first time, we demonstrated that hAT‐MSCs improve corneal and limbal epithelial phenotypes in animal LSCD models. These results support the potential use of hAT‐MSCs as a novel treatment of ocular surface failure due to LSCD. hAT‐MSCs represent an available, non‐immunogenic source of stem cells that may provide therapeutic benefits in addition to reduce health care expenses. Stem Cells 2017;35:2160–2174