Provided herein are constructs of micro-aggregate multicellular, minimally polarized grafts containing Leucine-rich repeat-containing G-protein coupled Receptor (LGR) expressing cells for wound therapy applications, tissue engineering, cell therapy applications, regenerative medicine applications, medical/therapeutic applications, tissue healing applications, immune therapy applications, and tissue transplant therapy applications which preferably are associated with a delivery vector/substrate/support/scaffold for direct application.

A pig intestinal tract epithelium cell line with METTL3 gene knocked out and a construction method therefor. A gene interference vector for METTL3 form a pig is also provided.

Disclosed herein are synthetic leathers, artificial epidermal layers, artificial dermal layers, layered structures, products produced therefrom and methods of producing the same.

The invention relates to in vitro cell culture methods for expanding epithelial cells from head and neck tissue, including head and neck tumour tissue, to obtain organoids. The invention relates to culture media suitable for use with said methods, organoids obtainable or obtained by said methods and uses of said culture methods, media and organoids in drug discovery and validation, toxicity assays, diagnostics and therapy.

A spheroid tissue microarray comprises an array of tissue spheroids embedded within a porous mold. The product may be impregnated with a wax or resin and sectioned, and contains spheroids which are precisely located in a regular geometric grid. A method of manufacturing a spheroid tissue microarray comprises the steps of: forming a mold of porous material from liquid mold material in a casting mold, and allowing the liquid mold material to set; removing the porous mold from the casting mold; topping up the porous mold with further liquid mold material, and allowing recesses to form in the surface of the mold by the drawing-in of liquid mold material through shrinkage as the liquid mold material sets; placing tissue spheroids into the recesses in the surface of the porous mold; and sealing the tissue spheroids within the mold by topping off with liquid mold material and allowing the liquid mold material to set. An alternative method comprises the steps of: forming a mold of porous material from liquid mold material in a casting mold; allowing the liquid mold material to set; removing the porous mold from the casting mold; placing spheroids in recesses at the bases of wells in the mold of porous material; and sealing the spheroids within the porous mold by adding further porous material on top of the spheroids; wherein the recesses at the bases of the wells in the porous material are formed by protrusions of the casting mold carrying further, nipple-shaped, protrusions.

The growth factor profile, connective tissue matrix constituents, and immunoprivileged status of urodele extracellular matrix (ECM) and accompanying cutaneous tissue, plus the presence of antimicrobial peptides there, render urodele-derived tissue an ideal source for biological scaffolds for xenotransplantation. In particular, a biological scaffold biomaterial can be obtained by a process that entails (A) obtaining a tissue sample from a urodele, where the tissue comprises ECM, inclusive of the basement membrane, and (B) subjecting the tissue sample to a decellularization process that maintains the structural and functional integrity of the extracellular matrix, by virtue of retaining its fibrous and on-fibrous proteins, glycoaminoglycans (GAGs) and proteoglycans, while removing sufficient cellular components of the sample to reduce or eliminate antigenicity and immunogenicity for xenograft purposes. The resultant urodele-derived biomaterial can be used to enhance restoration of skin homeostasis, to reduce the severity, durations and associated damage caused by post-surgical inflammation, and to promote progression of natural healing and regeneration processes. In addition, the biomaterial promotes the formation of remodeled tissue that is comparable in quality, function, and compliance to undamaged human tissue.

An application of a transgenic stem cell-derived exosome in preparing a medicament or whitening cosmetic is provided. In the present disclosure, miR-27b-3p is transfected into an epidermal stem cell, and a transgenic stem cell-derived exosome is harvested. It is experimentally verified that the exosome can inhibit the expression of PIK3R3 protein in melanocytes and the proliferation and migration of melanocytes; and safety experiments further demonstrate the safety of the exosome. Therefore, corresponding medicaments or cosmetics prepared from the exosome have excellent medicinal and cosmetic application prospects.

A method for elongating telomeres of cells comprises steps of: providing physical stimulation directly or indirectly to cells; and culturing a mixture of the cells and a medium for a predetermined time, wherein providing the stimulation directly to the cells comprises applying physical stimulation to the medium containing the cells, and providing the stimulation indirectly to the cells comprises applying physical stimulation to the medium not containing the cells and then mixing the medium and the cells. The method for elongating telomeres of cells is simpler than a conventional method and is superior in terms of time, cost, efficiency, and safety. In addition, the method induces cell division and provides an anti-aging effect, in addition to simply elongating telomeres. Thereby, it is expected that the method can ameliorate and prevent not only problems caused by shortening of telomeres, but also various aging-related diseases and conditions.

In some embodiments, a kit for preparing a cell suspension may include a device and a housing. The device may include a first label identifying a first reservoir of the device for use with a first portion of a tissue processing method and a second label identifying a second reservoir of the device for use with a second portion of the tissue processing method. The housing includes a first housing portion configured to store a first set of components associated with the first portion of the tissue processing method. The first housing portion includes a first visual indicator associated with the first label of the device. The second housing portion may be configured to store a second set of components associated with the second portion of the tissue processing method. The second housing portion may include a second visual indicator associated with the second label of the device.

[Problem to Be Solved] The present invention is to provide a method of culturing a cell, which method safely increases GDNF mRNA expression without introducing a gene with a virus.

[Means to Solve the Problem] A method of producing a cultured cell comprising glial cell line-derived neurotrophic factor (GDNF) mRNA, including the step of culturing a human skin-derived stem cell in a serum-free medium containing at least one of SAG, purmorphamine and sonic hedgehog (SHUT) protein. The medium may further contain B-27 supplement, a ROCK inhibitor, EGF and FGF2.