The present invention relates to a tissue adhesion agent having improved bio-tissue adhesiveness and bonding force by utilizing an adhesion-related gene. More specifically, a cartilage tissue adhesion composition prepared from fetal cartilage tissue-derived stem cells in which VCAN, CTGF, or EXT1 is inserted and expressed in an upregulated manner was found to show a remarkably superb adhesive force, compared to that prepared from fetal cartilage tissue-derived stem cells in which none of the genes are inserted. Accordingly, the cell composition in which the expression of VCAN, CTGF, or EXT1 is upregulated can be prepared into a tissue adhesion composition having improved bio-tissue adhesiveness and bonding force and VCAN, CTGF, or EXT1 can be provided as an additive composition for a tissue adhesion agent.

The present invention discloses formulation of a serum-free medium used for human pluripotent stem cells, which comprises the following raw materials: inorganic salt components, organic components, amino acids and amino acid salts, energy substances and metabolic intermediates, vitamins and antioxidants, proteins and polypeptides, trace elements and chromogenic substances; while the culture process comprises the following steps: selecting a basic formulation, performing combination screening, identifying and evaluating results, and testing a new formulation of culture; and proportioning according to the following methods: adding aforesaid raw materials into 950 ml of water for injection, stirring gently until dissolved, and finally adding 2.438 g of sodium bicarbonate, and stirring gently until dissolved, and then adding 1 liter of water for injection, adjusting the pH to the desired value with 1 mol/L sodium hydroxide solution or 1 mol/L hydrochloric acid solution, finally filtering sterilized with 0.1 μm diameter filter under positive pressure, and storing the medium solution in dark place at 2° C.-8° C., the invention solves the problem of high cost of domestic import of serum-free formulation.

The engineered system disclosed herein takes extracted adult stem cells from individual mammal organs (such as adipose fat, bone marrow, or blood) and epigenetically rejuvenates the adult stem cells ex vivo back to a youthful fetal state using chemically defined small molecules. The rejuvenated multipotent stem cells are then exponentially expanded ex vivo in an automated bioreactor under novel conditions that maintain the youthful stem cell function while greatly reducing the risks of producing cancer stem cells. In another variation, this engineered system can also include improving the genetics of autologous adult stem cells using CRISPR base editing of genes affecting all-cause morbidity or mortality or genetic mutations. With or without gene editing, rejuvenated autologous multipotent stem cells are then reintroduced back into an organ or injected systemically into the circulation or bone marrow. The engineered system also includes small molecule treatment of the mammal around the time of stem cell injection to promote tissue regeneration and stem cell engraftment. The engineered system has the potential to promote overall health and longer life expectancy in humans, cats, dogs, and other mammals. The rejuvenated stem cell and small molecule systems offer the potential to treat a wide variety of diseases and disorders such as heart failure, kidney disease, Chronic Pulmonary Disease, frailty, various cancers, rare genetic diseases via CRISPR treated stem cells, and brain diseases such as Alzheimer's, Parkinson's, and vascular dementia. The engineered system treatment with rejuvenated stem cells also has the potential to reverse aging and reduce mortality in humans, dogs, cats, and horses.

Provided herein are endocrine progenitor cells and organoids derived from adult islets in vitro, as well as methods for making and using the same. The compositions are useful for treating or preventing diabetes, other diseases or disorders characterized by impaired islet function, and symptoms thereof.

As an approach of efficiently inducing differentiation from pluripotent stem cells into insulin-producing cells, provided is a method comprising the step of three-dimensionally culturing cells in a medium containing a dihydroindolizinone derivative.

The present invention relates to cell culture media supplements or complete media compositions comprising plant-produced heterologous recombinant human albumin, as well as methods of making the cell culture media, and methods of using the supplemented cell culture media to improve viability, productivity, and growth characteristics of cultured cells.

A method of making an erythroid cell comprising elevated levels of a target protein or polypeptide, the method comprising: a) provision of an erythroid progenitor which is able to express the target protein or polypeptide; b) expression of the target protein or polypeptide; and c) maturation of the erythroid progenitor into the erythroid cell; wherein during maturation of the erythroid progenitor into the erythroid cell, the target protein or polypeptide is configured and/or inhibited such that ubiquitination of the target protein or polypeptide is hindered or prevented. Erythroid cells, pharmaceutical compositions and methods of use related thereto, and a method of screening for proteins or polypeptides degraded by ubiquitination during maturation of an erythroid progenitor are also provided.

Culture media capable of promoting differentiation of pluripotent stem cells (PSCs) into mesenchymal stem cells (MSCs) or supporting expansion of MSCs is provided. Methods of differentiation of PSCs into MSCs are provided. Methods of expanding MSCs without differentiation are also provided.

The application provides biocompatible carriers comprising bone forming and/or cartilage forming cells and methods for making them. The application further provides pharmaceutical compositions comprising said ATMPs and method of treatments using said ATMPs. The application further relates to said ATMPS for use in the treatment of bone disorders, cartilage disorders and joint disorders. The current invention further relates to method of treatments of bone disorders, cartilage disorders and joint disorders.

The present invention provides a cell culture having a cartilage-like tissue forming property, including a cell population in which the expression intensity of at least one cell surface marker selected from the group consisting of CD166, CD165, CD99, GD2, STRO-1, CD108, CD164, CD6, CD106, and CD107b is not higher than the threshold for each cell surface marker, and/or, the expression intensity of at least one cell surface marker selected from the group consisting of CD26, CD73, CD105, CD44, CD120a, CD201, EGFR, CD146, CD140a, and CD90 is not lower than the threshold for each cell surface marker.