A simulation apparatus includes an acquisition unit that acquires a depletion speed at which a protein becomes depleted independently of the cells, a consumption speed at which the cells consume the protein under a first culturing condition, and condition data indicating a second culturing condition that differs from the first culturing condition; a simulation execution unit that simulates a change in a concentration of the protein accompanying propagation of the cells in response to the depletion speed, the consumption speed, and the condition data; and a display unit that acquires, as a result of the simulation, the concentration of the protein and displays whether the concentration of the protein lies within a predetermined range.

The present invention relates to a hollow microfiber comprising (1) one or more cell-adhesive layers having a cell-adhesive hydrogel, (2) an outer shell layer having a high-strength hydrogel that covers the outer periphery of the cell-adhesive layer that is positioned farthest from the center axis among the one or more cell-adhesive layers, and (3) a cell layer that covers the inner periphery of the cell-adhesive layer that is positioned closest to the center axis among the one or more cell-adhesive layers. The present invention also relates to a method of manufacturing the hollow microfiber and a kit for carrying out the manufacturing method.

Embodiments described herein generally provide for expanding cells in a cell expansion system. The cells may be grown in a bioreactor, and the cells may be activated by an activator (e.g., a soluble activator complex). Nutrient and gas exchange capabilities of a closed, automated cell expansion system may allow cells to be seeded at reduced cell seeding densities, for example. Parameters of the cell growth environment may be manipulated to load the cells into a particular position in the bioreactor for the efficient exchange of nutrients and gases. System parameters may be adjusted to shear any cell colonies that may form during the expansion phase. Metabolic concentrations may be controlled to improve cell growth and viability. Cell residence in the bioreactor may be controlled. In embodiments, the cells may include T cells. In further embodiments, the cells may include T cell subpopulations, including regulatory T cells (Tregs), helper, nave, memory, or effector, for example.

A method for making a culture medium for culturing neural cells is provided. An original carbon nanotube structure is provided. The original carbon nanotube structure includes a drawn carbon nanotube film including a number of carbon nanotubes joined end to end by van der Waals force. The carbon nanotubes are substantially oriented along the same direction. A carbon nanotube structure including a number of carbon nanotube wires spaced from each other is formed by treating the original carbon nanotube structure. The carbon nanotube structure is fixed on a substrate.

A fiber includes one or more layers of polymer surrounding a central lumen, and living animal cells disposed within the lumen and/or within at least one of the one or more layers, wherein the fiber has an outer diameter of between 5 and 8000 microns and wherein each individual layer of polymer has a thickness of between 0.1 and 250 microns. Also disclosed are model tissues including such fibers, and method of making such fibers. The fibers can serve as synthetic blood vessels, ducts, or nerves.

A microalgae culture broth producing system includes a device for culture broth sterilization using a micro bubble generator, an air compression and pressure equalization device for the injection of carbon dioxide and oxygen in the atmosphere into the culture broth. The system also includes an air chilling device to maintain suitable culture broth temperature when water temperature is too high, an automatic carbon dioxide supply device to promote photosynthesis, and a sealed vertical photobioreactor to block out pollutants and increase dissolved carbon dioxide and oxygen concentration. The system further includes a high-efficiency harvesting device using hollow fiber membranes, and a hot air drying device using the waste heat generated by air compression.

One embodiment provides a commensal gut production platform for ex vivo production of human gut commensal microbiota. Another embodiment provides devices, systems and methods for ex vivo culturing of gut microflora in a system that mimics the human gut environment. The culturing of the commensal microbiota in the disclosed systems produces gut microbiota having defined characteristics and properties that can be exploited to treat various conditions in a subject.

An object of the present invention is to provide a hollow-fiber membrane which does not require a coating treatment with a cell adhesion factor or surface modification by an electron beam or the like and which is capable of adhering and culturing cells, and a method for culturing cells using the hollow-fiber membrane. A hollow-fiber membrane for cell culture which is to be used as a culture substrate for adhesive cells, in which the hollow-fiber membrane includes a hydrophobic polymer and a hydrophilic polymer, the content of the hydrophilic polymer in the whole hollow-fiber membrane is more than 0% by mass and less than 1% by mass, and the content of the hydrophilic polymer on a surface of the hollow-fiber membrane is more than 0% by mass and less than 10% by mass.

An insect culture maintenance system includes a sequence of open-ended cylindrical tubes joined pairwise alternately at their tops and bottoms using multiple dual-cap connectors. Each dual-capped connector has a channel from an inside of a first cap to an inside of a second cap. In use, connectors that cap the bottoms of the tubes are filled with insect food media, while connectors that cap the tops of the tubes are open. As a result of this design, adults pass from one tube to the next through the top dual-cap connectors, while larvae pass from one tube to the next through the bottom dual-cap connectors, resulting in propagation of subsequent generations of insects through the sequence of tubes.

Provided is a cell culture device capable of mass culturing stem cells while reducing occurrence of karyotypic abnormalities due to an influence of magnetism. The cell culture device includes: a cell culture vessel that is a substantially cylindrical body having a flat bottom at a lower end; a dish-shaped body having, in a periphery, a plurality of first magnetic bodies at equal intervals, the dish-shaped body having a substantially disk shape and disposed horizontally in a hollow space of the cell culture vessel without contact; and an annular body having a plurality of magnetic bodies and positioned outside the cell culture vessel to have the cell culture vessel located inside a ring of the cell culture vessel. The annular body and the dish-shaped body move up and down in conjunction with each other due to a magnetic force to stir a medium and supply nutrients to the cells. The cell culture device includes a storage made of a ferromagnetic material and configured to store the annular body when the annular body moves downward below the bottom of the cell culture vessel.