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 3×10.sup.7 cells/ml to 3×10.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 1.4×A 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 A±A/7 to 50% or more.

Methods of isolating and purifying hematologic or non-hematologic tumor cells useful in a variety of assays and procedures, including tumor drug efficacy screening such as Microculture Kinetic assays, are disclosed herein. Further, Microculture Kinetic assays and methods suitable for comparing the relative efficacy of generic versus proprietary anti-cancer drugs are also disclosed.

The present invention relates to improved methods for producing jasmonates such as jasmonic acid and methyl jasmonate in filamentous fungi under shaking conditions, hence enabling scale-up manufacturing processes using conventional fermenters. Specifically, one or more fungal quorum sensing molecules and/or jasmonate production elicitors can be added in the nutrient medium during cultivation of the filamentous fungi to induce formation of favorable morphologies and jasmonate production.

Described herein are methods and systems for mechanoporation-based high-throughput payload delivery into biological cells. For example, one system can process at least 1 billion cells per minute or at least 25 billion cells per minute, which is substantially greater than conventional methods. A cell processing apparatus comprises a processing assembly formed by stacking multiple processing components. Each processing component comprises channels, which may be used for filtration, mechanoporation, and/or separation of cells in the cell media. This functionality depends on the configuration of each channel. For example, each channel comprises one or more ridges such that each ridge forms a processing gap with an adjacent one of the processing components. The ridges may extend to the side walls or form a bypass gap with the wall. The processing gaps can be specially configured to compress cells as the cells pass through these gaps thereby initiating the mechanoporation process.

The present invention provides: a lubricin-localized cartilage-like tissue characterized in that, when in an arbitrary cross section passing a first center of mass of a cartilage-like tissue derived from pluripotent stem cells or a center-of-mass region, which is a portion inside a concentric sphere being centered at the first center of mass and having a diameter of [first major diameter×0.2], the expression level of lubricin per unit area contained in a central region, which is a portion inside a concentric circle being centered at a second center of mass that is the center of mass of the cross section and having a diameter of [major diameter of cross section (second major diameter)×(0.4 to 0.9)] is referred to as the central lubricin level and the expression level of lubricin per unit area contained in the non-central region is referred to as the non-central lubricin level.

A method of promoting spheroid formation, including: a preparation step of preparing a mixture obtained by mixing a cell sample with a promoter; and a culture step of culturing, inside a spheroid formation-culture vessel, the mixture obtained in the preparation step, in which the promoter is a polymer in which one or more selected from the group consisting of D-glucosamine, D-galactosamine, D-glucuronic acid, L-iduronic acid, and D-galactose are polymerized.

A method of producing the constituents of a therapeutic product from mammalian cells is described herein. Cells are isolated from a mammalian source. The cells are exposed to supercritical carbon dioxide (SCCO.sub.2) for 1 to 30 minutes, where the SCCO.sub.2 is maintained at a pressure of 1071 pounds per square inch (PSI) and a temperature of 31.1 to 45 degrees Celsius during the exposure. The exposure dissociates the cellular membranes of the cells to release intramembrane components therein to produce constituents of the therapeutic product. The mammalian cells may include at least one of platelets, stem cells, germ cells, and somatic cells. The methods described herein are particularly advantageous for releasing and capturing therapeutic intramembrane components from platelets and alpha-granules.

Methods of preparing ovarian tissue for primordial follicle growth are presented comprising the steps: providing an ovarian tissue sample comprising cortical tissue and stromal tissue; removing damaged tissue from the ovarian tissue sample where present; removing excess stromal tissue from the ovarian tissue sample where present; and then mechanically stretching the ovarian tissue sample along at least one dimension of the ovarian tissue sample, such that the size of the ovarian tissue sample along the at least one dimension is increased by at least 10%. Methods of growing viable oocyte in vitro, and methods of preparing individual ovarian follicles for growth are also presented.

Efficient stem cell delivery into biomaterials using capillary driven encapsulation are disclosed herein where stem/progenitor and/or tissue specific cells are rapidly and efficiently seeded via capillary driven encapsulation into a porous scaffold for cell delivery in the skin or any other organ. The rapid capillary force approach maximizes both seeding time and efficiency by combining hydrophobic, entropic and capillary forces to promote active, ‘bottom-up’ cell engraftment. This methodology uses micro domain patterned biopolymers in a porous dry gel to generate capillary pressure to move a viscous stem cell mix from a hydrophobic reservoir into the polymer matrix to promote active cell seeding within the entire gel volume.

New cell lines designated as Hepa-SC and Hepa-RP, originating from human hepatoma line HEPARG® are disclosed. Methods of inducing stemness in parental cells lines using mechano-transduction techniques, and redirecting stem-like cells to reprogrammed cells of a target differentiated population are also described.