A condenser system includes a collapsible container bag bounding a compartment and having an upper end and an opposing lower end, the container bag being formed of a polymeric film and being adapted to hold a fluid. A condenser bag is formed of a polymeric film and bounds a channel that extends between a first end and an opposing second end, the first end of the condenser bag being fluid coupled with the upper end of the container bag. A tubular transfer line has a first end coupled with the condenser bag at a first location so as to communicate with the channel and an opposing second end coupled with the condenser bag at a second location located between the container bag and the first location so as to communicate with the channel.

The present invention provides a system and a method for the production of cells and/or cell products. The system comprises at least one cell culture unit comprising at least one bioreactor for culturing cells, at least one technical control unit for controlling a cell growth parameters, said technical control unit is at least fluidly connected to the cell culture unit, and at least one air treatment unit for treating ambient air, said air treatment unit is fluidly connected to the cell culture unit. The system is characterized in that the system is autonomous and the bioreactor total volume is at most 1000L.

Disclosed are a process and an automated facility for manufacturing a purified protein of interest. The protein of interest can be a recombinant or naturally occurring protein and/or a therapeutic or other medically useful protein. For example, the disclosed process and automated facility are useful for manufacturing a purified protein drug substance.

Provided is a cell culture apparatus including a cell supply unit that supplies cells; a culture medium supply unit that supplies a culture medium; an additive supply unit that supplies an additive for inducing the differentiation of undifferentiated cells; a stirring unit that stirs a processing target; a separation unit that separates a component contained in the processing target; a culture vessel that cultures the cells; a first flow channel that forms a circulation route passing through the cell supply unit, the stirring unit, the separation unit, and the culture vessel; a second flow channel that connects the culture medium supply unit and the first flow channel; a third flow channel that connects the additive supply unit and the first flow channel; and a control unit that controls the feeding of liquid through the first flow channel, the second flow channel, and the third flow channel.

The present invention relates to a fungible suspension cell culture device. In particular, the invention relates to a fungible device with a configuration which allows modifying the volume of the cell culture area by automatically transferring said cell culture between different cell culture chambers which have different volumes. Furthermore, the present invention provides a suspension cell culture system.

A process for fermenting syngas is provided which is effective for decreasing an amount of time needed to inoculate a main reactor. The process includes propagating a culture of acetogenic bacteria to provide an inoculum for a main reactor and fermenting syngas in the main reactor.

The invention provides a process for producing a fermentable gas stream from a gas source that contains one or more constituent which may be harmful to the fermentation process. To produce the fermentable gas stream, the gas stream is passed through a specifically ordered series of removal modules. The removal modules remove and/or convert various constituents found in the gas stream which may have harmful effects on downstream removal modules and/or inhibitory effects on downstream gas fermenting microorganisms. At least a portion of the fermentable gas stream is preferably capable of being passed to a bioreactor, which contains gas fermenting microorganisms, without inhibiting the fermentation process.

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), for example.

The present invention relates to a device and processes for producing liquid media for cell cultures, whereby the liquid media are produced automatically by dissolving ingredients in water. The present invention also relates to a device for producing media used in cell cultures or a substance produced by cell cultures using a bioreactor process.

An automated cell culturing device, which expands, detaches and prepares cells, ready to be implanted in vivo is disclosed. The device is composed by a multi-layered cell culture chamber, a cell preparation chamber, and critical parameters control units which automatically drive the cell culture medium circulation, change and refill. The device according to the invention is characterized in that all the components contacting cells and culture medium constitute a totally disposable “cartridge” in order to avoid cross-contamination and improve safety. The device is particularly useful for expanding and preparing mesenchymal stem cells for osteoarthritis (OA) therapy, and for other cell based therapies in mammals.