Ee distinct cellular layers and two acellular layers. The acellular Descemet’s membrane separates the cellular stroma from the innermost endothelial layer, which is a monolayer of cells in direct contact with the aqueous humour of the anterior chamber. The corneal endothelial layer is responsible for the maintenance of corneal transparency by acting as a “leaky” barrier to allow nutrients to flow from the aqueous humour in the anterior chamber into the collagen stroma and then preventing swelling by actively pumping excess fluid out. This state of equilibrium is lost in disorders such as Fuchs endothelial dystrophy, which is characterised by a progressive oedema of the cornea, due to a loss of endothelial cell density. Fuchs is the most commonly occurring dystrophy in the US affecting approximately 4 of the population over the age of 40 [1]. For treatment of disorders such as Fuchs, MedChemExpress MNS severalposterior lamellar techniques have been described as an alternative to the traditional full thickness corneal replacement known as penetrating keratoplasty (PK). These lamellar techniques replace only the defective endothelial layer and include Descemet’s stripping (automated) endothelial keratoplasty (DSEK (or DSAEK)) and Descemet’s membrane endothelial keratoplasty (DMEK). There are many advantages to the lamellar techniques over the PK procedure because the corneal surface is not compromised allowing for faster visual recovery, suture related problems are eliminated as endothelial keratoplasty requires no corneal sutures and wound healing complications are rare as the procedure can be performed through a self-sealing limbal or scleral tunnel incision at the periphery of the cornea [2,3]. Although these new techniques are an improvement on the classic PK method, the worldwide donor cornea shortage is increasingly becoming an issue [4], compounded by the fact that demand for corneal transplantation is expected to increase due to a rise in the aging population globally [5]. This has led to considerable interest in the development of a strategy to treatPC Collagen for Endothelial Transplantationendothelial disorders using cell replacement therapy as an alternative to one donor ?one recipient tissue transplants. The considerable challenge here is that corneal endothelial cells are maintained in a G1 cell cycle phase MedChemExpress AVP arrested state and do not proliferate in vivo [6]. However, these cells do retain their proliferative capacity and many research groups have successfully stimulated cell division in order to expand endothelial cell numbers in vitro [7?0]. Expanded cell therapy could potentially allow many patients to be treated using one donor cornea and may alleviate some of the current donor shortage problems. However, this approach requires a supporting material with properties enabling easy transfer of the propagated cells to the recipient while at the same time exhibiting no detrimental effect on the functionality of the endothelial cell population [11]. We have developed a process of plastic compression of type 1 collagen hydrogels to produce a thin (60?00 mm) collagen membrane-like construct with enhanced mechanical properties, which we have termed Real Architecture For 3D Tissues (RAFT). If required, RAFT can be seeded directly with cells in the collagen before compression and we have previously shown it to be suitable 1407003 for the generation of a human corneal 24272870 epithelial cell surface layer [12]. The major advantage of RAFT is its rapid, simple and rep.Ee distinct cellular layers and two acellular layers. The acellular Descemet’s membrane separates the cellular stroma from the innermost endothelial layer, which is a monolayer of cells in direct contact with the aqueous humour of the anterior chamber. The corneal endothelial layer is responsible for the maintenance of corneal transparency by acting as a “leaky” barrier to allow nutrients to flow from the aqueous humour in the anterior chamber into the collagen stroma and then preventing swelling by actively pumping excess fluid out. This state of equilibrium is lost in disorders such as Fuchs endothelial dystrophy, which is characterised by a progressive oedema of the cornea, due to a loss of endothelial cell density. Fuchs is the most commonly occurring dystrophy in the US affecting approximately 4 of the population over the age of 40 [1]. For treatment of disorders such as Fuchs, severalposterior lamellar techniques have been described as an alternative to the traditional full thickness corneal replacement known as penetrating keratoplasty (PK). These lamellar techniques replace only the defective endothelial layer and include Descemet’s stripping (automated) endothelial keratoplasty (DSEK (or DSAEK)) and Descemet’s membrane endothelial keratoplasty (DMEK). There are many advantages to the lamellar techniques over the PK procedure because the corneal surface is not compromised allowing for faster visual recovery, suture related problems are eliminated as endothelial keratoplasty requires no corneal sutures and wound healing complications are rare as the procedure can be performed through a self-sealing limbal or scleral tunnel incision at the periphery of the cornea [2,3]. Although these new techniques are an improvement on the classic PK method, the worldwide donor cornea shortage is increasingly becoming an issue [4], compounded by the fact that demand for corneal transplantation is expected to increase due to a rise in the aging population globally [5]. This has led to considerable interest in the development of a strategy to treatPC Collagen for Endothelial Transplantationendothelial disorders using cell replacement therapy as an alternative to one donor ?one recipient tissue transplants. The considerable challenge here is that corneal endothelial cells are maintained in a G1 cell cycle phase arrested state and do not proliferate in vivo [6]. However, these cells do retain their proliferative capacity and many research groups have successfully stimulated cell division in order to expand endothelial cell numbers in vitro [7?0]. Expanded cell therapy could potentially allow many patients to be treated using one donor cornea and may alleviate some of the current donor shortage problems. However, this approach requires a supporting material with properties enabling easy transfer of the propagated cells to the recipient while at the same time exhibiting no detrimental effect on the functionality of the endothelial cell population [11]. We have developed a process of plastic compression of type 1 collagen hydrogels to produce a thin (60?00 mm) collagen membrane-like construct with enhanced mechanical properties, which we have termed Real Architecture For 3D Tissues (RAFT). If required, RAFT can be seeded directly with cells in the collagen before compression and we have previously shown it to be suitable 1407003 for the generation of a human corneal 24272870 epithelial cell surface layer [12]. The major advantage of RAFT is its rapid, simple and rep.