An apparatus comprising a culture dish and a removable lid, wherein the culture dish comprises a main body having a side wall defining a reservoir region for receiving a quantity of liquid media, and the removable lid is arranged to cover the reservoir region during normal use, wherein the lid comprises a gas permeable material and includes an engagement portion formed of a resilient material adapted to cooperatively engage with the side wall of the main body of the culture dish so as to compress a part of the engagement portion of the removable lid against the side wall to form a vapour-tight seal for the reservoir region when the removable lid is coupled to the culture dish. The lid fitted to the culture dish enables a substantial portion of the culturing media to remain in the environment enclosed between the reservoir and the lid without use of a cover media to limit evaporation while allowing gaseous exchange therethrough.

Provided is a cell culture vessel for culturing cells with a high density having excellent gas permeability and strength. A bag-shaped cell culture vessel of a closed system includes at least one port and mutually opposed planar substrates. At least one of the planar substrates is formed of a gas permeable film, the at least one gas permeable film has an outer surface provided with a protruding portion having a shape different from an inner surface shape of the gas permeable film, a culture space for culturing cells is provided in the inner surface side of the gas permeable film, and when the gas permeable film is brought in contact with a planar surface, a space enabling ventilation is formed between the gas permeable film and the planar surface by the protruding portion.

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.

The disclosure generally relates to a test device that detects microorganism growth by detecting a gas metabolite (e.g., carbon dioxide) produced during the growth of bacteria or other microorganism in a tested sample. The test device can contain a culture growth media separated from a detection area by a gas-permeable membrane. The gas-permeable membrane permits carbon dioxide to permeate into the detection area. The detection area includes a solidified mixture of pH indicators and a gelling agent in the form of a semi-permeable matrix. The optical properties, including the absorbance of light at various wavelengths, of the detection solution change with alterations in carbon dioxide concentration. This test device can then be placed in an incubation and optical detection instrument to monitor changes in optical properties of the detection are induced during microorganism growth in the culture medium.

Several embodiments of the invention relate generally to a system and methods for the treatment of gaseous emissions comprising methane and one or more non-methane compounds that can influence the metabolism of methane-oxidizing microorganisms. In several embodiments, there is provided a system and methods for the treatment of methane emissions through the use of methanotrophic microorganisms to generate functionally consistent and harvestable products. Certain embodiments of the invention are particularly advantageous because they reduce environmentally-destructive methane emissions and produce harvestable end-products.

There is provided a bioreactor which is provided with a lid (13) that facilitates access to the incubation cavity. Specifically the end wall of the incubation cavity is constituted by the lid (13) so that removal of the cap renders the incubation cavity fully accessible.

A fluid transfer assembly for single use bioreactors includes a fluid transfer housing that can be mounted to the impeller shaft using a bearing that places the fluid transfer assembly directly below the lowest impeller but allows the impeller shaft to spin inside independently of the fluid transfer assembly. A fluid conduit connects the fluid transfer housing to a port in the single use bag wall which allows fluids to be introduced into the sparger and which also helps prevent the fluid transfer assembly from rotating with the impeller shaft.

A fluid transfer assembly for single use bioreactors includes a fluid transfer housing that can be mounted to the impeller shaft using a bearing that places the fluid transfer assembly directly below the lowest impeller but allows the impeller shaft to spin inside independently of the fluid transfer assembly. A fluid conduit connects the fluid transfer housing to a port in the single use bag wall which allows fluids to be introduced into the sparger and which also helps prevent the fluid transfer assembly from rotating with the impeller shaft.

Novel methods and apparatus are disclosed for cell culture and cell recovery. The methods and apparatus simplify the process of cell separation from media, minimize potential damage to gas permeable devices during fluid handling, and allow closed system automated cell culture and cell recovery from gas permeable devices.

A cell sheet transfer device and a cell sheet processing equipment. The cell sheet transfer device includes a first tubular body; a second tubular body at one end of the first tubular body and connected thereto; and a cell shovel at the end of the first tubular body and on one side of the second tubular body. A free end of the cell shovel is beyond a free end of the second shovel body.