A culture device includes a culture vessel that contains a culture solution for culturing cells, a gas supply device that supplies a gas to the culture vessel, and a humidification device that humidifies the gas flowing from the gas supply device to the culture vessel. The humidification device includes a hollow fiber membrane filter that includes a hollow fiber membrane through which the gas from the gas supply device passes and a casing that accommodates the hollow fiber membrane, a water supply device that fills the casing of the hollow fiber membrane filter with water, and a first heater that heats the hollow fiber membrane filter.

The present invention relates to a device (100) for monitoring the development of a biological material, said device in the orientation intended for use comprising: a housing (2) having an extension in a longitudinal direction (X) and an extension in a transversal direction (Y), said housing comprises: two or more culture dish compartments (4), each adapted to accommodate a culture dish (6) comprising a biological material (8) to be monitored, each said compartment being separated from each of said other compartments, said two or more compartments being arranged along the longitudinal direction; each said culture dish compartment (4) comprising a lid (10) adapted to be able to be shifted between an open configuration in which access to the interior (12) of said culture dish compartment is provided, and a closed configuration sealing off the interior of said culture dish compartment from its surroundings; wherein each said culture dish compartment comprises an inlet (14) for supplying gas to and an outlet (16) for removing gas from said culture dish compartment; wherein each said culture dish compartment comprising heating means (18) for heating the interior of said culture dish compartment; wherein said housing comprises one or more cameras (20) for capturing images of a biological material in a culture dish.

A cell culture matrix is provided that has a substrate with a first side, a second side opposite the first side, a thickness separating the first side and the second side, and a plurality of openings formed in the substrate and passing through the thickness of the substrate. The plurality of openings allow flow of at least one of cell culture media, cells, or cell products through the thickness of the substrate, and provides a uniform, efficient, and scalable matrix for cell seeding, proliferation, and culturing. The substrate can be formed from a woven polymer mesh material that provides a high surface area to volume ratio for cells and good fluid flow through the matrix. Bioreactor systems incorporating the cell culture matrix and related methods are also provided.

Control of humidity in chemical reactors, and associated systems and methods, are generally described. In certain embodiments, the humidity within gas transport conduits and chambers can be controlled to inhibit unwanted condensation within gas transport pathways. By inhibiting condensation within gas transport pathways, clogging of such pathways can be limited (or eliminated) such that transport of gas can be more easily and controllably achieved. In addition, strategies for purging condensed liquid from chemical reactor systems are also described.

Embodiments described herein generally relate to passively replacing media in a closed cell expansion system to reduce or prevent the dilution of chemical signaling used to inhibit signaling pathways that keep a cell population in the lag phase of cell growth. To prevent such dilution, active inlet fluid flow to the system may be halted. To replace fluid lost by the system, a bag containing media may be attached to the waste line in replacement of the waste or outlet bag connected thereto. By turning off one or more pumps, media from the replacement bag is added to the system at the rate of evaporation. Chemical signaling dilution may be prevented while conserving system resources. Enhancement of chemical signaling to reduce the lag phase of cell growth may further be accomplished by adding molecules, such as chemical-signaling proteins, from a direct source to the system.

Reactors, systems and processes for the production of biomass by culturing microorganisms in aqueous liquid culture medium circulating in a loop reactor which utilize substantially vertical flow zones are described. Recovery and processing of the culture microorganisms to obtain products, such as proteins or hydrocarbons is described.

A fixed-bed bioreactor system is provided that includes a vessel with a media inlet, a media outlet, and an interior cavity disposed between and in fluid communication with the media inlet and media outlet. The vessel further includes a cell culture substrate disposed in the interior cavity between the media inlet and the media outlet in a packed-bed configuration, the cell culture substrate including a plurality of porous disks in a stacked arrangement. The interior cavity includes a cell culture section and a spacer section, the cell culture substrate defining the cell culture section and the spacer section being disposed between the cell culture section and the media outlet, and each of the plurality of porous disks has a surface configured to culture cells thereon.

A cell culture matrix is provided that has a substrate with a first side, a second side opposite the first side, a thickness separating the first side and the second side, and a plurality of openings formed in the substrate and passing through the thickness of the substrate. The plurality of openings allow flow of at least one of cell culture media, cells, or cell products through the thickness of the substrate, and provides a uniform, efficient, and scalable matrix for cell seeding, proliferation, and culturing. The substrate can be formed from a woven polymer mesh material that provides a high surface area to volume ratio for cells and good fluid flow through the matrix. Bioreactor systems incorporating the cell culture matrix and related methods are also provided.

A method includes directing fluid flow from a bioreactor to an external path of a re-circulation loop, separating cells from the medium and returning the cells to the bioreactor thereby leaving spent medium, depleting the spent medium of biological waste products, replenishing the spent medium with beneficial growth factors to thereby provide replenished medium, and directing the replenished medium back to the bioreactor to thereby complete the re-circulation loop such that recycling of the medium occurs. The replenishing of the spent medium with beneficial growth factors may occur within a medium collection reservoir. The method may further include monitoring the spent medium within the medium collection reservoir including temperature of the spent medium within the medium collection reservoir and pH of the spent medium within the medium collection reservoir.

A bioreactor (1; 2; 3) includes a receiving container (10) for receiving a disposable bag (44). A bottom surface (11) of the receiving container (10) is designed to support the disposable bag (44) in the receiving container (10). An outlet opening (5) is formed in the bottom surface (11) and tapers down with respect to the ground for receiving a drain port (45) of the disposable bag (44). The drain port is complementary to the outlet opening (5).