The present invention describes methods and processes for the production of proteins by animal cell or mammalian cell culture. In one aspect, the methods comprise the growth of cells in a growth factor/protein/peptide free medium. In another aspect, the methods comprise the addition of growth factors during the production phase. The methods sustain a high viability of the cultured cells, and can yield an increased end titer of protein product, and a high quality of protein product.

Methods are provided for the production of retinal ganglion (RG) progenitor cells and mature RG cells from pluripotent stem cells optionally under feeder-free conditions, and further optionally under xeno-free conditions. Additionally provided are compositions of RG progenitor cells and mature RG cells, as well as methods of use thereof including therapeutic use thereof. Exemplary methods may produce substantially pure populations and cultures of RG progenitor cells and mature RG cells.

Methods are provided for the production of photoreceptor cells and photoreceptor progenitor cells from pluripotent stem cells. Additionally provided are compositions of photoreceptor cells and photoreceptor cells, as well as methods for the therapeutic use thereof. Exemplary methods may produce substantially pure cultures of photoreceptor cells and/or photoreceptor cells.

To provide a method for serum-free culture of human cartilage cells and a serum-free culture medium. A method for serum-free culture of cartilage cells, said method comprising: an enzymatic treatment step for treating a human cartilage cell-containing tissue with a protease; an inhibitor-treatment step for, after the enzymatic treatment step, treating the tissue with an inhibitor for the aforesaid protease; and a culture step for, after the inhibitor-treatment step, culturing the tissue in a serum-free culture medium that contains kartogenin and/or SAG, ITS, FGF2 and hydrocortisone. A serum-free culture medium for culturing cartilage cells, said serum-free culture medium containing kartogenin and/or SAG, ITS, FGF2 and hydrocortisone.

The present invention relates generally to a population of cells genetically modified to produce insulin in a glucose responsive manner and uses thereof. More particularly, the present invention relates to a population of cells genetically modified to produce insulin in response to physiologically relevant levels of glucose and uses thereof. The cells of the present invention are useful in a wide variety of applications, in particular in the context of therapeutic and prophylactic regimes directed to the treatment of diabetes and/or the amelioration of symptoms associated with diabetes, based on the transplantation of the cells of the present invention into mammals requiring treatment. Also facilitated is the design of in vitro based screening systems for testing the therapeutic effectiveness and/or toxicity of potential adjunctive treatment regimes.

The present invention relates to a serum-free conditioned medium that solves the drawbacks mentioned in the prior art, as it does not require prior handling of the cells, and it furthermore allows starting from a large population with no additional cost. This medium favors in vitro proliferation and conservation of the pluripotency potential that allows maintaining a state that is undifferentiated with respect to the subpopulation of cancer stem cells (CSCs) and in turn does not allow survival of the differentiated cells.

Vitronectin-derived cell culture substrates and methods of using the same for culturing pluripotent stem cells are presented. Also provided herein are defined culture systems for maintaining human pluripotent stem cells in a substantially undifferentiated state, where the defined culture system comprises human pluripotent stem cells, a defined culture medium, and at least one polypeptide selected from the group consisting of residues 43 to 378 of SEQ ID NO:1 and residues 45 to 378 of SEQ ID NO:1, and where the defined culture medium comprises insulin, selenium, transferrin, L-ascorbic acid, FGF2, DMEM/F12, NaHCO.sub.3, and one of TGFβ and NODAL.

Methods of generating functional human brown adipocytes, comprising exposing human stem cells, progenitor cells, or white adipocytes to culture with an differentiation cocktail that comprises one or more browning agents (e.g., one or more macromolecular crowders), and optionally one or more adipogenic agents, are described, as are populations of human brown adipocytes generated by the methods, and uses for the populations. Methods of generating functional human brown adipocytes in an individual, such as by administering a pharmaceutical composition comprising an differentiation cocktail, are also described.

There is provided herein cell culture mediums for generating organoids, including tumour organoids.

The presently disclosed subject matter provides hydrogel precursor compositions (e.g., solutions) for forming three-dimensional hydrogels that support growth of physiologically relevant tissue when at least one cell is cultured in the three-dimensional hydrogel, kits comprising the hydrogel precursor composition, three-dimensional hydrogels, methods of forming the three-dimensional hydrogels, methods of growing the physiologically relevant tissue using the three-dimensional hydrogels, physiologically relevant tissue grown in the three-dimensional hydrogels, methods of producing hormone-responsive tissue (e.g., milk-producing mammary tissue and related methods of producing milk), methods of screening for candidate agents useful for modulating hormonal responses (e.g., modulating milk production), method of screening for candidate therapeutic agents using the physiologically relevant tissue grown in the three-dimensional hydrogels (e.g., personalized cancer treatments), and related methods of treatment (e.g., administering agents identified using the methods herein, transplanting physiologically relevant tissue produced using the methods, etc.).