There is provided a cell culture vessel for culturing a cell in an interior thereof, wherein a width of a bottom surface is equal to or larger than a height of a side surface, the cell culture vessel comprising a flow path configured to supply a fluid into the interior, and wherein the interior is able to be closed.

A portable bioreactor is provided for driving displacement of at least one stirring sleeve relative to at least one tube cassette in a first direction and includes a machine frame unit and a first elevator. The first elevator includes a first linear movement module, a first transmission module, and a first turning module. The first linear movement module includes a first slider which is slidable on the first guide rail in the first direction between a first top position and a first bottom position. The first turning module is coupled to the first slider through the first transmission module so as to permit turning of the first turning module to be translated by the first transmission module into linear sliding movement of the first slider at a varying speed.

Some embodiments are directed to a system for the efficient cultivation of algae using both cultivation media and growth media. The system can include: discrete biomass receptacles, each receptables being configured to contain the cultivation medium and the algae; a supplier configured to supply the cultivation media to each of the receptacles, the supplier being configured to provide the growth media to each of the multiple receptacles, the supplier defining an orifice through which at least one of the cultivation media and the growth medium is provided to each of the receptables; sensors, one sensor being disposed at each of the multiple receptacles to sense conditions therein; and a controller that is in communication with each of the sensors, the controller being configured to control an amount of growth media supplied to each receptacle based on sensed conditions so as to enhance algae growth within each of the receptacles.

A bioreactor system can include one or more bioreactor groups, where each group has a plurality of bioreactor clusters and a gantry shared by the plurality of bioreactor clusters. Each bioreactor cluster can include one or more manifolds and a plurality of bioreactor units. Each bioreactor unit can include a well, a lid covering the well, a waste valve to control a flow rate of waste out of the well, and one or more dispensing valves to control flow rates of dispensing one or more materials into the well. The gantry can include one or more sensors and a movable gantry head with one or more sensor probes configured to selectively sense properties of contents of respective bioreactor units included in the plurality of bioreactor units.

A method of carrying out a bioreaction in a multivessel bioreactor system may include flowing a culture medium at an initial flow rate through one or more fluidic paths between a master vessel and one or more slave vessels, detecting a first culture medium parameter value in the master vessel or the slave vessels, transmitting the first culture medium parameter value to a control system, determining an adjusted flow rate of the culture medium at the control system based on the first culture medium parameter value, and controlling a bidirectional fluid transfer device with the control system to adjust the flow rate of the culture medium through the one or more fluidic paths. The control system may adjust the flow rate of the culture medium to maintain a substantially uniform value of the first culture medium parameter value in the master vessel or the one or more slave vessels.

A fermentation tank having a first supply or discharge line with a first central opening arranged at the lower end of the fermentation tank for supplying or discharging a product. The fermentation tank also has a second and a third supply or discharge line, each with a centrally arranged opening for supplying or discharging a product, the three openings being arranged at different height levels. Also, a method of fermentation using the fermentation tank.

A bioreactor system may include (a) two or more fluidically coupled vessels configured to collectively carry out a bioreaction; (b) one or more fluidic paths coupling the two or more vessels to one another, where the fluidic paths are configured to provide flow of culture medium between the two or more vessels; (c) one or more fluid transfer devices along at least some of the one or more fluidic paths; and (d) a control system. The control system may be configured to (i) read or receive values of one or more parameters characterizing the culture medium in one or more of the vessels, and (ii) use the values to determine an adjusted flow rate in at least one of the fluidic paths to maintain substantially uniform values of the one or more parameters in the culture medium from vessel-to-vessel among the two or more vessels.

A one-time use or repeated use self-contained biofilm-biomat reactor comprising a container with at least one compartment and placed within the compartment(s), a feedstock, a fungal inoculum, a gas-permeable membrane, and optionally a liquid nutrient medium is provided.

Methods of production of edible filamentous fungal biomat formulations are provided as standalone protein sources and/or protein ingredients in foodstuffs as well as a one-time use or repeated use self-contained biomat reactor comprising a container with at least one compartment and placed within the compartment(s), a feedstock, a fungal inoculum, a gas-permeable membrane, and optionally a liquid nutrient medium.

A culture module is contemplated that allows the perfusion and optionally mechanical actuation of one or more microfluidic devices, such as organ-on-a-chip microfluidic devices comprising cells that mimic at least one function of an organ in the body. A method for pressure control is contemplated to allow the control of flow rate (while perfusing cells) despite limitations of common pressure regulators. The method for pressure control allows for perfusion of a microfluidic device, such as an organ on a chip microfluidic device comprising cells that mimic cells in an organ in the body, that is detachably linked with said assembly, so that fluid enters ports of the microfluidic device from a fluid reservoir, optionally without tubing, at a controllable flow rate.