A large-flux in-situ filtration device for marine microorganism based on a multi-channel circulation distributor is provided, comprising an energy and control module, a circulation distribution module, a filtration module, a pump module, a filtration volume measurement module, a pipeline connection, and a main body support frame. The circulation distribution module may include a multi-channel circulation distributor, a deep-sea servo motor, etc. The filtration module may include a plurality of filter film holders. The pump module may include a stainless steel gear pump, a deep-sea drive motor, etc. The filtration volume measurement module may include a water meter, a camera, and an LED light.

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 disclosure provides an in vitro life culture system, comprising: a culture module used to cultivate a culture, the culture module including at least a culture chamber for holding a culture fluid; a culture fluid provision module used to provide the culture fluid to the culture module; and a fluid output module used to discharge the culture fluid from the culture chamber.

The present invention provides a shake-type culture apparatus which can perform large scale culture without using stirring blades and a culture method using the same. More particularly, there are provided a shake-type culture apparatus comprising: a culture bag made from a soft packaging material; an outer shell container being arranged to house the entirety of the culture bag to be able to perform adjustment of a temperature thereof; and a power source for shaking the outer shell container housing the culture bag, wherein the contents in the culture bag can be stirred and mixed by shaking the outer shell container housing the culture bag; and a culture method using the same.

The present invention is in the field of a method of producing lactic acid in high yield in a sequencing batch reactor. Therein glucose may be used as feedstock for bacteria, which ferment the glucose into lactic acid. The reactor is operated under at least partly defined non-axenic conditions and in a cyclic mode.

An enzymatic processing plant for continuous flow-based enzymatic processing of organic molecules. The enzymatic processing plant including an enzymatic processing area, wherein the enzymatic processing area includes a turbulence-generating pipe with a repeatedly changing centre-line and/or a repeatedly changing cross-section, for generating turbulence to mix a reaction mixture and prevent sedimentation of particles as the reaction mixture is flowing through the turbulence-generating pipe. The enzymatic processing plant and the enzymatic processing area are arranged such that the reaction mixture is subjected to turbulence within the enzymatic processing area for a reaction time of 15 minutes or more.

The invention discloses a bioreactor apparatus (1;101;201;301) for cultivation of cells comprising: a) a disposable bioreactor vessel (2) with one or more walls (3,4,5) defining an inner volume (6), at least one port (10) in a wall, wherein the disposable bioreactor vessel is positioned in a rigid support structure (8;108); and b) a heater (9;109;209;309), capable of heating an amount of culture medium to a target temperature in the range of 55-95° C., while the amount of culture medium is being confined in or conveyed to the inner volume.

The present invention provides a means to prevent the clogging of pipes by freezing of gas discharged from a fermenter, especially in a low temperature environment such as in winter. Disclosed is an organic compound production system (10A) for producing an organic compound by microbial fermentation, including: a catalytic reactor (1) comprising a reactor containing a biocatalyst for synthesizing an organic compound; a valve (3) for discharging exhaust gas withdrawn from the catalytic reactor (1); and a pipe (6A) connecting the catalytic reactor (1) and the valve (3), wherein at least a part of the pipe (6A) is covered with an insulator (4).

A decentralized based biowaste treatment system for treating biowaste (i.e., organic matter type/based waste such as manure, sawdust and/or food scraps) by manner of anaerobic digestion (e.g., an anaerobic digestion based waste-to-resource system) and a method of biowaste treatment in association with the biowaste treatment system.

A device for breaking cells that has a reactor with a reaction chamber, an agitator, a cooling jacket, a cooling jacket inlet, a cooling jacket outlet, a sampling port, and a temperature probe insertion fitting, and a motor suitable for mounting the reactor on its top and which is operably connected with the agitator. A system for breaking cells comprising at least one device, at least one temperature probe inserted in the temperature probe insertion fitting of the device, a cooling system operably connected to the temperature probe, and an electronic control panel. The cooling system has at least one solenoid valve, each device of the system having one corresponding solenoid valve.