A bioreactor for growing micro-organisms in a reaction mixture including a reaction medium and micro-organisms. The bioreactor includes a first reaction chamber, a second reaction chamber and means for connecting the first reaction chamber to the second reaction chamber. The first reaction chamber has first volume for containing first number of micro-organisms, a first input for providing reaction mixture thereto, and a first output for removing excess gases therefrom. The second reaction chamber, arranged downstream from first reaction chamber, has a second volume for containing a second number of micro-organisms, a second input for providing gases thereto, and a second output for removing reaction mixture therefrom. The means for connecting is the sole input for allowing the reaction mixture to flow from the first reaction chamber to the second reaction chamber and for gases to flow from the second reaction chamber to the first reaction chamber.

A fluidic cartridge comprises a fluidic disk having a plurality of alignment openings; a fluidic chip comprising a body, one or more channels formed in the body in fluidic communications with input ports and output ports for transferring one or more fluids between the input ports and the output ports, and a plurality of protrusions formed on the body and received in the alignment openings of the fluidic disk for aligning the fluidic chip to the fluidic disk; an actuator operably engaging with the one or more channels for selectively and individually transferring the one or more fluids through the one or more channels from at least one of the input ports to at least one of the output ports at desired flow rates; and a tube member defining a cylindrical housing for accommodating the fluidic disk, the fluidic chip and the actuator therein.

A deepwater photobioreactor system including a vertical stack extending between an ocean surface and an ocean floor. The vertical stack includes an inlet conduit and an outlet conduit where the inlet conduit is arranged to transport at least seawater and the outlet conduit is arranged to transport at least a biomass. The system includes a first photobioreactor in fluid communication with the inlet conduit and the outlet conduit that is connected to the vertical stack via the inlet and outlet conduits at a first position along the vertical stack below the ocean surface. The first bioreactor is arranged to cultivate the biomass. The system also includes a mooring system arranged to anchor the vertical stack to the ocean floor and arranged to receive the biomass via the outlet conduit and output the biomass to a harvest pipeline.

A cell culturing system includes a docking station, a handling unit, a culturing module and an actuation layer. The culturing module has a culturing well and a culturing membrane separating the culturing well in an apical culturing chamber and a basal culturing chamber. The handling unit removably accommodates the culturing module and the actuation layer. The docking station has a coupling structure for removably holding the handling unit in a predefined position and an actuation feeding channel, wherein, when the handling unit is held by the coupling structure in the predefined position, a first end of the actuation feeding channel is connected to the actuation bore and a second end of the actuation feeding channel is connected to a connector.

Provided are a culture apparatus and a culture method with which microalgae can be cultured satisfactorily. The culture apparatus includes a plurality of culture tanks and a water storage tank, and cultures microalgae in a culture solution. Each of the plurality of culture tanks has a translucent accommodating portion containing the culture solution and microalgae. The volumes of the accommodating portions of the plurality of culture tanks are different from each other. The water storage tank has a translucent water storage unit for storing a stored water. The plurality of culture tanks are selectively arranged in the water storage unit.

A method for treating an aqueous fluid comprising a biodegradable organic substance in an installation comprising an upflow bioreactor containing a sludge bed, said sludge bed comprising biomass, an external separator, and a conditioning tank, the method comprising: treating the fluid in the conditioning tank; feeding the treated fluid into a lower part of the bioreactor and forming biogas; withdrawing the fluid from an upper part of the bioreactor, which withdrawn fluid comprises biomass; feeding the aqueous fluid withdrawn from the upper part of the bioreactor into the external separator wherein the aqueous fluid comprising the biomass is separated into a liquid phase, and a fluid phase enriched in biomass; returning said fluid phase enriched in biomass from the external separator to the bioreactor; and returning a part of said liquid phase to the conditioning tank.

A photobioreactor is particularly suited for producing micro-organisms such as microalgae. The photobioreactor is a closed reactor with reactor vessels which have an open top that is closed by a top wall of the photobioreactor and in which a nutrient medium can be held. At least some of the reactor vessels are individual vessels. Adjacent reactor vessels form a gap between a front wall and a rear wall, the gap being closed at the top side by an overflow wall region and having a vessel overflow opening between the adjacent reactor vessels. A lighting element is held in the gap. Each of the reactor vessels has a partition which divides the reactor vessel into a front reactor chamber and a rear reactor chamber. At least one partition through-flow opening between the front and rear reactor chambers is formed in the partition close to the bottom wall.

According to the present disclosure, there is provided a cell stimulation and culture platform using a ultrasonic hologram, including a culture vessel in which a culture well with an open lower portion is formed; a transmission sheet which is installed to cover a lower surface of the culture vessel and where a biological sample is seated; a platform body that is filled with a liquid medium and an open upper end is covered by the transmission sheet; an ultrasonic transducer that is installed inside the platform body in a state of being spaced apart from the biological sample; and an ultrasonic hologram lens that is installed on the ultrasonic transducer, and spatially modulates the phase of the ultrasonic waves using a surface structure designed to have different height distributions to focus the ultrasonic waves in a set pattern shape on a target surface on which the biological sample is located.

Provided is a culture vessel for adherent cells that has a large culture portion surface area and ensures easily dissociating and recovering cells without consuming a medium or a dissociation solution more than necessary. The bag-shaped adherent cell culture vessel made of flexible packaging material includes a vessel body portion having a first vessel wall and a second vessel wall and one or more injecting/ejecting ports. The vessel body portion has an intermediate culture wall between the first vessel wall and the second vessel wall. A culture chamber is disposed in each of between the first vessel wall and the intermediate culture wall and between the second vessel wall and the intermediate culture wall, and a flow passage communicating between the respective culture chambers is disposed.

Microorganisms present within a plurality of microorganism clusters immobilized in a porous support material may collectively define a supported bio-catalyst. When the microorganisms are effective to convert methane into one or more oxidized carbon compounds (e.g., methanotrophic bacteria), the supported bio-catalysts may be utilized to remove methane from methane-containing gas streams, such as those obtained from mining ventilation. Methods for processing a methane-containing gas stream may comprise interacting the gas stream with the supported bio-catalyst in substantial absence of a liquid phase, and obtaining a methane-depleted gas stream downstream from the supported bio-catalyst. Systems for processing a methane-containing gas stream may comprise the supported bio-catalysts housed in one or more vessels fluidly coupled to a source of methane-containing gas stream. A gas concentration in the methane-containing gas stream and/or the methane-depleted gas stream may be used to determine a current state or anticipated remaining lifetime of the supported bio-catalyst.