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.

A method for producing a product related to the specified technology includes adjusting the concentration of cells in a culture vessel to a value of from 310.sup.7 cells/ml to 310.sup.8 cells/ml; in a case in which the average diameter of single cells in the culture vessel is designated as A, adjusting the number proportion of cells having a single cell diameter of 1.4A or greater in the culture vessel to 5% or less, and adjusting the number proportion of cells having a single cell diameter in the range of AA/7 to 50% or more.

Provided herein are methods of producing a recombinant protein that include: providing a bacterium including a nucleic acid encoding a recombinant protein; and culturing the bacterium in a liquid culture medium including about 0.3 mM to about 300 mM Mg.sup.2+ under conditions sufficient for the production and release of the recombinant protein into the culture medium.

The invention relates to a process for preparing a non-expanded tissue derivative, that is not subjected to cell proliferation in vitro, comprising a vascular-stromal fraction enriched in stem and multipotent elements, such as pericytes and/or mesenchymal stem cells, or for preparing non-embryonic stem cells obtained from a tissue sample or from said derivative, wherein said tissue derivatives or said cells are subjected to vibrations derived from a heart sound such to control the degree of differentiation or possible differentiation of said stem and multipotent elements into several other types of cells that is to optimize their potency. The invention relates also to a device for carrying out said process, to stem cells obtainable by the process as well as a drug for the regeneration of an animal tissue.

The invention relates to implantable collagen devices made by seeding at least one elongate collagen construct, e.g., comprising at least one elongate synthetic collagen fiber with a plurality of cells and applying a strain and/or stress to the at least one elongate collagen fiber to induce the cells to differentiate into target phenotypes, e.g., tendon or ligament phenotype cells (and/or fibroblasts), typically with an extracellular matrix of collagen to organize into a tissue on the at least one collagen fiber.

The described invention provides an ex vivo dynamic multiple myeloma cancer niche contained in a pumpless perfusion culture device. The dynamic multiple myeloma cancer niche includes (a) a three-dimensional tissue construct containing a dynamic ex vivo bone marrow niche, which contains a mineralized bone-like tissue containing viable osteoblasts self-organized into cohesive multiple cell layers and an extracellular matrix secreted by the viable adherent osteoblasts; and a microenvironment dynamically perfused by nutrients and dissolved gas molecules; and (b) human myeloma cells seeded from a biospecimen composition comprising mononuclear cells and the multiple myeloma cells. The human myeloma cells are in contact with osteoblasts of the bone marrow niche, and the viability of the human myeloma cells is maintained by the multiple myeloma cancer niche.

The present invention provides methods and compositions for inducing pluripotency in differentiated mammalian cells. In particular, the methods include mechanically aggregating the cells into discrete masses or embryoid-like bodies and treated them with a small molecule compound. Provided herein are the compositions of the compounds which are derived from programin (e.g., reversine).

The subject invention concerns materials and methods for culture of cell aggregates. The subject invention utilizes three-dimensional (3-D) inserts comprising micro-channels having selected dimensions. The inserts are provided in or on tissue culture plates that can be supported on a programmable rocking platform/station, thereby providing for a hydrodynamic environment that promotes 3-D aggregation of cells cultured on the plates. The supporting rocker is programmed to provide motion that generates hydrodynamic conditions that support 3-D cell aggregation and long-term culture. The subject invention also concerns an apparatus comprising a tissue culture vessel that comprises a 3-D insert of the present invention, and a programmable rocking platform/station that can provide motion to the vessel provided thereon, thereby generating hydrodynamic conditions and wave motion that support 3-D cell aggregation and cell culture. The subject invention also concerns methods for growing 3-D aggregates of cells.

There is provided a device for vascularising a cell aggregate, the device comprising: a matrix region configured to contain a gel-like matrix and cells that form a vasculature network within th ematrix region. The matrix region having at least one opening for positioning the cell aggregate therein based on a desired three-dimensional spatial location; and one or more fluidic regions configured to contain a supporting fluid that is capable of supporting vascularisation of the cell aggregate, the one or more fluidic regions being in fluid communication with the matrix region, wherein a flow passage from the one or more fluidic regions to a gel-like matrix disposed in the matrix region is configured to allow three-dimensional vascularisation around the cell aggregate and perfusion of the vasculature once formed. There is also provided a chip comprising a plurality of the device as disclosed herein and a method for vascularising a cell aggregate.

The present invention relates to stem cell-derived microvesicles with enhanced efficacy, a use thereof, and a method for enhancing efficacy, and more particularly, to a use of stem cell-derived microvesicles with an enhanced expression level of microRNAs for the prevention or treatment of stroke, and a method for promoting the production of microRNAs of stem cell-derived microvesicles and enhancing efficacy, and a method for promoting the production of stem cell-derived microvesicles and microRNAs within the microvesicles and enhancing the efficacy of stem cells and microvesicles thereof by 3-dimensionally culturing or ischemically stimulating stem cells. Since the method according to the present invention has excellent effects capable of promoting the production of stem cell-derived microvesicles and microRNAs in the microvesicles and capable of enhancing the efficacy of stem cells or microvesicles isolated therefrom, it is possible to obtain stem cell-derived microvesicles containing high levels of materials including therapeutic microRNAs efficiently and in large quantities through this, and thus, the microvesicles are expected to be able to be usefully used in related research fields and future clinical settings.