In one embodiment, the present application discloses a cell culture medium for culturing cell lines suitable for producing a therapeutic protein, comprising an amino acid selected from a group consisting of L-arginine, L-asparagine, L-proline, L leucine and L hydroxyproline and a mixture thereof; a vitamin selected from a group consisting of ascorbic acid Mg.sup.2+ salt, biotin, pyridoxine HCL, folic acid, riboflavin and D-calcium pantothenate, and a mixture thereof; an element selected from a group consisting of ammonium meta vanadate, sodium meta vanadate, germanium dioxide, barium acetate, aluminum chloride, rubidium chloride, cadmium chloride, ammonium molybedate, stannous chloride, cobalt chloride, chromium sulfate, silver nitrate, sodium metasilicate, zinc sulfate, manganese sulfate H.sub.2O, manganous chloride, ferric nitrate 9H.sub.2O, ferrous sulfate 7H.sub.2O, ferric ammonium citrate, magnesium chloride anhydrous, and magnesium sulfate anhydrous, and a mixture thereof; a nucleoside selected from a group consisting of uridine and cystidine; a sugar selected from a group consisting of galactose, mannose and N-Acetyl-D-Mannosamine; and a triple buffering system comprising sodium carbonate, sodium bicarbonate and HEPES; wherein the cell culture medium is animal component-free, plant component-free, serum-free, growth factors-free, recombinant protein-free, lipid-free, steroid-free, and free of plant or animal hydrolysates and/or extracts.

Disclosed is a method for microalgal cultivation. The method includes cultivating a microalgal species in a medium in an autotrophic mode for a predetermined first time period where light is supplied and supplying an organic carbon source to the medium to cultivate the microalgal species in a heterotrophic mode for a predetermined second time period where the supply of light is stopped.

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.

Production of etanercept using perfusion methods achieves attractive yields of properly folded protein. Desired temperature, feed media, titers and percent correctly folded protein are disclosed.

Provided are a sanal culturing composition and a method for culturing sanal using the same.

The present invention relates to a cell culture medium, in particular for culturing autologous fibroblasts, for use in aesthetic medicine for skin transplantation, said culture medium being serum-free and being characterized in that it contains glucose in a much lower quantity than conventional culture media.

A method of culturing adherent cells from a placenta or adipose tissue is disclosed. The method comprises culturing the adherent cells from the placenta or adipose tissue under 3 dimensional (3D) culturing conditions which allow cell expansion, the conditions comprising perfusion.

The present invention provides a method of isolating cells or tissues from a culture preparation of the cells or tissues in a medium composition which enables culture of the cells or tissues in suspension, which comprises at least one step selected from the group consisting of the following (A), (B) and (C): (A) passing the culture preparation through a filter having fine pores having a pore diameter of 5-500 μm, (B) adding a chelator to the culture preparation, and (C) diluting the culture preparation with a physiological aqueous solution.

The techniques described herein provide for improved efficiency of iPSC production from biological cells. The approach achieves improved iPSC production efficiency by obtaining a set of cells whose cell cycles are synchronized at a specific, desired cell cycle phase, such as mitotic phase (also referred to as M phase). The efficacy with which such synchronized cells can be transformed into iPSCs is higher than for an arbitrary set of cells that comprises cells at a variety of different stages in their cycles. Accordingly, the approaches described herein allow efficient generation of iPSCs, thereby facilitating myriad technologies for personalized and regenerative medicine that rely upon the effective production of iPSCs.

The present invention provides methods and compositions for making proteins, preferably antibodies, more preferably anti-tumor necrosis factor alpha antibodies, and most preferably adalimumab. The present invention further provides methods and compositions for mammalian cell culture, preferably Chinese Hamster Ovary cells.