An anaerobic digestion device based on self-sustained air flotation includes an anaerobic digestion tank unit, a self-sustained air flotation screening unit and a biogas measurement and collection unit. The self-sustained air flotation screening unit includes an air flotation screening part, a material sedimentation part, a reflux part and a three-phase separation part connected sequentially from bottom to top. A digested material in the anaerobic digestion tank unit is pumped into the air flotation screening part, overflows into the material sedimentation part, and then is raised to the reflux part. Gas passing through the three-phase separation part and gas produced in the anaerobic digestion tank unit enter the biogas measurement and collection unit to be measured and collected.

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.

A compound algae culture apparatus is provided, which includes a photobioreactor module, a growth regulating module, a circulation transfer module, and a circulation pipeline module. The photobioreactor module includes at least one photobioreactor unit, and the growth regulating module includes at least one growth tank unit. The photobioreactor unit includes a light-transmitting coiled pipe. The growth tank unit has a tank body, and a plurality of partitions are disposed in the tank body to divide an inside of the tank body for formation of a curved flow channel A culture fluid for culturing algae passes through the photobioreactor unit and enters the growth tank unit. A volume of the growth tank unit is larger than a volume of the photobioreactor unit, and a residence time of the culture fluid in the growth tank unit is greater than a residence time of the culture fluid in the photobioreactor unit.

Disclosed is an in vitro exposure system that may radiate a uniform field having a constant wavefront to an experimental cell container and expose each cell container to a same electromagnetic field.

The present invention relates to a microfluidic device (1), preferably for producing a three-dimensional cell culture, having at least one chamber (2), and a fluid channel (3) which flows through at least part of the chamber (2) in order to provide a fluid stream which flows through the chamber (2) preferably continuously, wherein the chamber (2) is connected to a loading opening (4) and via the loading opening (4) can be loaded with hydrogel up to a desired fill level, characterized in that the chamber (2) comprises a main chamber (5) and a secondary chamber (6) connected to the main chamber (5), wherein, when the chamber (2) is being loaded with hydrogel up to the desired fill level, the secondary chamber is at least partially filled with hydrogel backed up from the main chamber (5).

The present invention relates to a device and a method for the analysis of cultured cells, comprising a plurality of culture vessels, optical sensors and a detection system with detectors for determining a physico-chemical parameter in a culture vessel and for imaging the morphology of cells in a vessel. The device comprises a microscope adapted to be moved and having an optical path provided with switching means to switch between an optical path for determining a physico-chemical parameter and an optical path for imaging the morphology of cells.

A method for producing a carbonate-containing species-rich, nitrogen-containing species-free solution from a urea-rich solution is proposed. The method comprising the steps of: providing a first reservoir comprising a first mixture including urea and a catalyser comprising an enzymatic catalyser and/or a microorganism; allowing an enzymatic reaction catalysed by the catalyser to decompose urea, thereby obtaining a second mixture comprising nitrogen-containing species and carbonate-containing species; converting at least some of the nitrogen-containing species into gaseous nitrogen-containing species to obtain a third mixture comprising the gaseous nitrogen-containing species and the carbonate-containing species; filtering the third mixture by a gas- permeable filter, thereby separating at least some of the gaseous nitrogen-containing species from the carbonate-containing species while keeping the catalyser away from the gas-permeable filter; and collecting the so-obtained carbonate-containing species-rich, nitrogen-containing species-free solution.

A cell culture method is a cell culture method for arranging cultured cells in a culture dish and continuously culturing the cultured cells by supplying a liquid required to grow or maintain the cultured cells to the culture dish and discharging the liquid from the culture dish. The cell culture method includes: providing a supply port of the liquid at one end of the culture dish and providing a discharge port of the liquid at other end of the culture dish so as to sandwich the cultured cells between the supply port and the discharge port, and discharging the liquid while supplying the liquid to the culture dish so that a moving linear velocity of the liquid from the supply port toward the discharge port is less than a maximum velocity at which shear stress is not applied to the cultured cells.

The current invention relates to a bioreactor cabinet, configured to be incorporated in a biomolecule production system, wherein said bioreactor cabinet is preferably a mobile bioreactor cabinet suited to receive a bioreactor, said bioreactor cabinet is provided with a bioreactor docking station, wherein said bioreactor cabinet, more preferably a side wall of said bioreactor cabinet, is provided with a connector allowing the transmission of power, signals and/or data when paired with a biomolecule production system, such as a bioreactor chamber of said system. The current invention equally relates to a biomolecule production system and methods for producing biomolecules.

An object of the present invention is to provide a novel approach capable of conveniently and efficiently removing air that has entered a cell culture bag at the time of addition of a culture medium. The present invention provides a system for culturing cells or cell aggregates using a cell culture bag, the cell culture bag having a lower face comprising a plurality of recesses, the culturing system comprising a mechanism which removes air in the cell culture bag through the cell culture bag by applying a pressure before cell addition to the cell culture bag supplemented with a culture medium.