Aspects of the present invention include methods and compositions related to the production and use of pluripotent stem cell-derived clonal embryonic progenitor cell types useful in the generation of cellular components of brown adipocyte tissue for research and therapy relating to applications in obesity, diabetes, and cardiovascular disease.

The present invention relates to a cell preparation method that includes a step in which cells are applied to a polyimide porous film and cultivated, wherein the polyimide porous film is a polyimide porous film with a three-layer structure, having a surface layer A and a surface layer B that have a plurality of holes, and a macrovoid layer that is sandwiched between the surface layer A and the surface layer B, and the polyimide porous film is produced by a method including the following steps: (1) a step in which a poly(amic acid) solution comprising poly(amic acid) and an organic polar solvent is flow cast in a film shape and the result is immersed in or brought into contact with a coagulation medium to create a porous film of poly(amic acid); and (2) a step in which the porous film of poly(amic acid) obtained in step (1) is heat-treated and imidized.

A method for culturing a bovine progenitor cell, comprising the step of: culturing a bovine progenitor cell in a serum-free medium for culturing a bovine progenitor cell, wherein said serum-free medium comprises an albumin; and a fibroblast growth factor (FGF).

The present invention is primarily directed to provide a new composition for a medium which can be used for differentiation induction from somatic cells to brown adipocytes.

The present invention can include, for example, a composition for a medium used in differentiation induction from somatic cells to brown adipocytes, wherein the composition comprises the following seven components: a thyroid hormone receptor agonist, a glucocorticoid receptor agonist, a phosphodiesterase inhibitor, insulin, an ascorbic acid derivative, albumin, and an antibiotic.

According to the present invention, direct differentiation induction from somatic cells to brown adipocytes can be effectively performed. In addition, according to the present invention, it is possible to effectively maintain brown adipocytes.

The present technology relates, inter alia, to perturbagens and methods for directing a change in the cell state of a progenitor cell. It also relates to methods for increasing a quantity of beige adipocytes, beige preadipocytes, and/or immediate progenitors thereof and/or the ratios thereof. Further, the present technology relates to methods for treating diseases or disorders characterized by, at least, abnormal numbers, ratios or bodily distributions of beige adipocytes, beige preadipocytes, white adipocytes, white preadipocytes, or immediate progenitors thereof, with respect to each other.

This disclosure relates to compositions and methods for recruiting brown adipocytes in vitro and in vivo from brown adipocyte progenitor cells found in human skeletal muscle. Methods for treating metabolic disease are also provided. Additionally, methods for treating hypothermia are provided. In some embodiments, the brown adipocyte recruiter is a human protein or peptide. In other embodiments the brown adipocyte recruiter may be a non-human protein or peptide. In still other embodiments, the brown adipocyte recruiter is a small molecule or natural product.

Devices and methods for delivering oxygen and other therapeutic gases to a target, such as a tissue, a tissue-engineered construct, and a wound, in a controlled and sustained manner are disclosed.

Non-enzymatic method and milling device for preparing therapeutic cells from adipose tissue comprising: continuously feeding the adipose tissue to the milling device (2); mechanically separating the cells or cell aggregates from adipose tissue moving through the milling device (2) by means of a multiplicity of blades (19) of a rotor (10), wherein the blades (19) are arranged in a spaced arrangement with respect to the overall direction of flow and the blades (19) are moving about an axis of rotation (18), wherein the axis of rotation (18) is provided essentially parallel to said overall direction of flow; continuously withdrawing the processed tissue comprising the separated cells from the milling device (2).

The present invention relates to adeno-associated viral vector useful for transducing adipose tissue. The invention also relates to polynucleotides, plasmids, vectors and methods for the production of such adeno-associated viral vector. The invention also relates to gene therapy methods useful for the treatment of a disease that requires the regulation of the expression levels of a gene.

The present invention provides methods and systems which accommodate 3-dimensional adipocyte expansion to produce, e.g., mature adipocytes and synthetic adipose tissue with cellular properties of mature adult organisms, including cell size and cytoarchitecture, and the use of such methods and systems for, e.g., in vitro drug screening and/or toxicity assays, disease modeling, and therapeutic applications.