A centrifuge device is provided for the sizing and separation of constituents of a biologic mixture, e.g., adipose tissue. The device provides for the mechanical breaking down of the fibrous structure in the tissue by centrifugation causing the tissue to pass through a mesh element, or a sizing helix, or an extrusion element, whereupon the material is reduced to a slurry. This processed material may then be separated by centrifugation into its constituents, in order to harvest the fraction containing the multipotent cells. These multipotent cells may be utilized for various medical procedures to stimulate healing and tissue regeneration.

The present invention relates to an in vitro method for creating a viable connective tissue and/or osseous tissue obtained by tribological solicitations of a biological culture. It further relates to a viable connective tissue and/or osseous tissue susceptible to be obtained by said method as well as to the use of said method or viable connective tissue and/or osseous tissue to prepare a biological implant.

The present invention relates to novel compositions and methods to produce 3D organ equivalents of the brain (i.e. “mini-brains”). The invention also relates to methods of using human induced pluripotent stem cells, a combination of growth and other soluble factors and gyratory shaking. Cells from healthy or diseased donors or animals can be used to allow testing different genetic backgrounds. The model can be further enhanced by using genetically modified cells, adding micro-glia or their precursors or indicator cells (e.g. with reporter genes or tracers) as well as adding endothelial cells to form a blood-brain-barrier.

The present disclosure discloses a crosslinked hydrogel for muscle stem cell culture and a preparation method and use thereof, and belongs to the technical field of biological food materials. The preparation method includes: dissolving collagen to prepare a solution and adding a certain amount of alginate and heparan sulfate proteoglycan for being uniformly mixed with the collagen solution; and adding ε-PL and TGase into the solution, uniformly stirring, and putting a slurry into a mold for crosslinking to obtain the hydrogel. The hydrogel is prepared by linking the collagen, the polylysine and the heparan sulfate proteoglycan using the TGase to form covalent crosslinking, and forming a compact three-dimensional “egg box” network structure through a physical electrostatic interaction between the polylysine and the alginate. The hydrogel can enhance the absorption to nutrient substances by the muscle stem cells and facilitate the growth of the muscle stem cells. The double-network crosslinked hydrogel has the potential to be a scaffold for the growth of muscle stem cells for cultured meat from stem cells.

The present invention relates to the fields of life sciences and cell and tissue cultures, especially 3D cultures. Specifically, the invention relates to a method of maintaining the presence or activity of a human or mouse estrogen receptor (ER) in a cell of an ex vivo mammary cell or tissue culture or in a cell of other hormone responsive cell or tissue culture. Also, the present invention relates to a method of maintaining a luminal epithelial phenotype and/or cell identity of a mammalian cell in an ex vivo cell or tissue culture. Still, the present invention relates to a 3D matrix or 3D medium comprising the matrix for ex vivo culture, wherein said 3D matrix or 3D medium comprises one or more mammalian cells or tissues embedded in said 3D matrix or 3D medium, and to a system for ex vivo culture, wherein the system comprises mammalian cells or tissues embedded in a 3D matrix or 3D medium comprising said matrix. Still furthermore, the present invention relates to use of the 3D matrix, 3D medium or system of the present invention e.g. for ex vivo culture of a mammalian cell, drug discovery methods, biomarker studies and/or estrogen receptor (ER) signaling studies.

The present invention provides compositions and methods for activation and expansion of T cells using a biocompatible solid substrate with tunable rigidity. Rigidity of a substrate is an important parameter that can be used to control the overall expansion and differentiation of T cells.

A method of manufacturing a microstructure comprises printing a positive mold structure, filling the positive mold structure with a second material to form an elastically deformable negative mold structure, filling the negative mold structure with a third material to form the microstructure, and releasing the microstructure from the negative mold structure. Advantageously, the negative mold structure can be stretched to facilitate the release of the microstructure. For example, the microstructure comprises a chamber with capped micropillars for the generation and/or analysis of muscle tissue.

The present invention describes a method for increasing transfection efficiency of cells. The present invention further provides a method for increasing the efficiency of stem cell reprogramming.

This disclosure relates to methods of growing cells within a hydrogel scaffold and pressurizing the hydrogel and cells to induce the cells to stretch and differentiation. The disclosed method can include coating a substrate of a bioreactor with a hydrogel and seeding cells onto the hydrogel and/or the substrate. The disclosed method can further include growing the seeded cells into a cell mass and pressurizing the cell mass and the hydrogel within the bioreactor. Pressurizing the cell mass and the hydrogel induces the cell mass and hydrogel to mechanically stretch, thereby inducing hypertrophy and cell alignment.

This disclosure relates to methods of washing cells from a grown cell mass to remove cell culture media and enriching the cells with a finishing media. The disclosed method includes growing a cell mass in cell culture media and then collecting and washing the grown cell mass with a series of wash buffers or a gradient wash buffer that changes over time. While the cell culture media contains nutrients and components beneficial for cell growth, cells grown in cell culture media often have off flavors, off aromas, poor color, poor salt/minerality compositions, and other shortcomings. Accordingly, the disclosed method comprises removing cell culture media remnants from a grown cell mass using a single or a series of wash media. The grown cell mass is further washed with a finishing or enrichment buffer to further improve sensory aspects and nutritional composition of the grown cell mass.