A technique can consistently achieve thicknesses of ≤50 μm for corneal tissue for Descemet stripping automated endothelial keratoplasty (DSAEK). Grafts with thicknesses of ≤50 μm are also known as nanothin DSAEK (NT-DSAEK) grafts. Evidence shows that using thinner DSAEK grafts, particularly NT-DSAEK grafts, can significantly improve visual outcomes. According to an example embodiment, a method for producing a corneal graft includes drying a donor cornea to cause a pre-cut thickness of the donor cornea to decrease. The method includes, concurrently with drying the donor cornea, determining pre-cut thickness measurements for the donor cornea. The method includes, in response to the pre-cut thickness measurements indicating the pre-cut thickness of the donor cornea has decreased to a predetermined value, cutting the donor cornea to a post-cut thickness of ≤100 μm, or more particularly ≤50 μm, to produce a corneal graft.

A method and system for making a bone plug using cortical bone material. A patient jaw having insufficient bone at a surgical site may be scanned to provide a 3D image which may be used to design a virtual bone plug and to fabricate the bone plug for placement within the patient. The bone plug may be formed from cortical bone that can be reconstituted and demineralized or demineralized and milled to shape.

A scaffold according to an embodiment of the present disclosure is for cartilage regeneration. The scaffold may include a plurality of linear nano-patterns aligned in one direction, and stem cells adhered to the plurality of linear nano-patterns. The scaffold may improve regeneration and maturity of the cartilage, thereby being effectively used in treatment of cartilage defects.

The present invention discloses a bone void filler and a method for manufacturing the same by natural calcium-containing waste, which comprises steps of mixing 5-20 wt % of a calcium-containing waste powder, 5-20 wt % of acetic acid and a remaining weight percentage of water uniformly to obtain a mixing solution; adding 5-20 vol % of a diammonium hydrogen phosphate solution to the mixing solution to obtain a suspension; controlling a pH value of the suspension to obtain an alkaline solution; leaving the alkaline solution at room temperature for precipitation for 0.1 to 72 hours, centrifuging or suction filtrating the alkaline solution to obtain a precipitate, drying and grinding the precipitate to obtain hydroxyapatite; and mixing 30-60 wt % of a pore former and 30-60 wt % of the hydroxyapatite and a remaining weight percentage of a binder uniformly to form a mixture, compression molding the mixture in a mold and sintering the compression-molded mixture.

The invention provides a method for producing a cell aggregate containing a ciliary marginal zone-like structure by culturing a cell aggregate containing a retinal tissue in which Chx10 positive cells are present in a proportion of 20% or more of the tissue in a serum-free medium or serum-containing medium, each containing a substance acting on the Wnt signal pathway for only a period before the appearance of a RPE65 gene expressing cell, followed by culturing the “cell aggregate in which a RPE65 gene expressing cell does not appear” thus obtained in a serum-free medium or serum-containing medium, each not containing a substance acting on the Wnt signal pathway and so on.

The invention provides a method for inducing gelation and biomimetic mineralization of a silk fibroin solution by alkaline phosphatase. A micromolecular polypeptide that is sensitive to ALP and has good biocompatibility and self-assembly property is introduced as a gelator precursor, which can remove a phosphate group under the catalytic action of ALP to generate NY, to trigger supramolecular self-assembly, and therefore SF co-self-assembly is synergistically induced, finally resulting in rapid formation of SF hydrogel. ALP wrapped in an SF-NY hydrogel network still retains its catalytic activity and catalyzes beta-glycerophosphate to release free phosphate ions, so that formation of apatite minerals is induced in the gel. The biomimetic mineralized SF gel can be used as a biomimetic scaffold to promote the adhesion, proliferation and osteogenic differentiation of rat bone marrow mesenchymal stem cells in vitro, and can also promote the natural healing of femoral defects in a rat model.

Provided is a method for freezing a cell aggregate including neural cells. Provided is a method for freezing a cell aggregate including neural cells and having a three-dimensional structure, which comprises following steps (1) and (2): (1) soaking the cell aggregate including neural cells in a cryopreservation solution at 0° C. to 30° C. prior to freezing to prepare a cryopreservation solution-soaked cell aggregate; and (2) freezing the cell aggregate including neural cells in vapor phase of a liquid nitrogen container having a temperature of −150° C. or less.

Provided is a method for freezing a cell aggregate including neural cells. Provided is a method for freezing a cell aggregate including neural cells and having a three-dimensional structure, which comprises following steps (1) and (2): (1) soaking the cell aggregate including neural cells in a cryopreservation solution at 0° C. to 30° C. prior to freezing to prepare a cryopreservation solution-soaked cell aggregate; and (2) freezing the cell aggregate including neural cells in vapor phase of a liquid nitrogen container having a temperature of −150° C. or less.

A method of lamellar corneal graft implantation is disclosed herein. In one or more embodiments, the method includes the steps of: (i) modifying a genetic component of a lamellar cornea or other tissue of an animal so that the lamellar cornea or other tissue of the animal can be used for human transplantation; (ii) decellularizing the lamellar cornea or other tissue ex vivo using chemical means; (iii) modifying a shape of the lamellar cornea or other tissue before or after transplantation; and (iv) applying a photosensitizer and ultraviolet radiation to the lamellar cornea or other tissue so as to crosslink collagen and intercellular proteins of the lamellar cornea or other tissue, kill the cells exposed to the photosensitizer, and eliminate an immune response by a host to the implanted lamellar cornea or the tissue.

Methods of producing and methods of treatment using a nipple areolar complex extracellular matrix. A method for processing tissue comprises harvesting a human nipple areolar complex tissue, treating the tissue with a stabilizing medium, wherein the medium stabilizes the tissue during transport, decellularizing the tissue, and sterilizing the tissue to form a human nipple areolar complex extracellular matrix scaffold (ECMS). A method of treating an individual with a need for a nipple reconstruction comprises forming an ECMS and applying the ECMS to the individual for nipple areolar regeneration.