Heparan sulphate HS/BMP2 is disclosed, together with the use of HS/BMP2 in the repair and regeneration of bone tissue.

Finding biologically relevant cancer markers is key to developing an effective treatment. Once specific antigens have been identified that are present on the cell population responsible for propagating tumors, T cells can be genetically altered to target these antigens and then used for personalized T cell therapy. A method to identify and select peptide antigens that effectively associate with and are presented by host HLA surface molecules originating from tumor cells responsible for the persistence and propagation of a cancer has been developed. The system of using these data to produce T cells engineered to express T cell receptors recognizing the peptide antigens is used in the production of a personalized adoptive T cell therapy for cancer that eliminates the cells capable of tumor propagation and cancer progression. The system is especially useful in the production of cancer treatments to achieve complete durable remission of cancers of epithelial origin.

The present application discloses a cell culture media for growth, maintenance and induction of reversion to a less mature state of a cell comprising a MUC1* activating ligand.

The present disclosure relates to a three-dimensional (3D) artificial skin model, and specifically, to a 3D artificial skin model that perfectly mimics the ridge shape of the dermal-epidermal junction, and a method for producing the same. Normal skin tissue has wavy ridges formed at the dermal-epidermal junction (DEJ), but the wavy ridges are known to flatten with aging. The artificial skin model of the present disclosure is a 3D artificial skin model that perfectly mimics the shape of the ridges at the dermal-epidermal junction. Since the artificial skin model mimics the structure and function of normal skin, it is expected to be widely used in the pharmaceutical and cosmetic fields.

Disclosed is a method for manufacturing a composite nanofiber support and a fish collagen/synthetic polymer nanofiber support manufactured by the method, wherein the method comprises: a first step for dissolving a synthetic polymer in an organic solvent; a second step for dissolving a fish collagen in water to prepare an aqueous fish collagen solution; a third step for adding the aqueous fish collagen solution prepared in the second step to the synthetic polymer solution prepared in the first step, followed by mixing; and a fourth step for electrospinning the mixture solution prepared in the third step to manufacture a nanofiber support.

The use of Dub3 protein, a nucleic acid molecule coding for the protein, or an inhibitor of the activity and/or of the expression of the protein for modulating cell differentiation.

The present invention relates to a composition and a method for inducing CD4.sup.+ T cells to differentiate into regulatory T cells and proliferate through an induced T cell co-stimulator ligand (ICOSL) or an ICOSL-overexpressing mesenchymal stem cell and for preventing or treating regulatory T cell-mediated diseases. The induced T cell co-stimulator ligand (ICOSL) or ICOSL-overexpressing mesenchymal stem cell according to the present invention effectively suppresses the proliferation of PBMCs, induces the expression of an ICOS in regulatory T cells, thereby inducing the differentiation and proliferation of the regulatory T cells through a PI3K-Akt mechanism, and thus can effectively prevent, treat, or enhance regulatory T cell-mediated diseases.

Novel MSC stem-cell culture and therapy methods and culture medium compositions for the purpose of inducing, activating, or priming discrete uniform cell phenotypes to selectively promote or suppress inflammation and immunity, yielding polarized, primed, activated, or induced cells used in cell-based therapy.

The isolation and identification of glycosaminoglycans capable of binding to proteins having a heparin-binding domain is disclosed, as well as the use of the glycosaminoglycans isolated in the growth and/or development of tissue.

A method of promoting spheroid formation, including: a preparation step of preparing a mixture obtained by mixing a cell sample with a promoter; and a culture step of culturing, inside a spheroid formation-culture vessel, the mixture obtained in the preparation step, in which the promoter is a polymer in which one or more selected from the group consisting of D-glucosamine, D-galactosamine, D-glucuronic acid, L-iduronic acid, and D-galactose are polymerized.