A system, device and method for electroporation of living cells and the introduction of selected molecules into the cells utilizes a fluidic system where living cells and biologically active molecules flow through a channel that exposes them to electric fields, causing the molecules to be transferred across the cell membrane. The device is structured in a manner that allows precise control of the cells location, motion, and exposure to electric fields within the flow channel device. The method is particularly well suited for the introduction of DNA, RNA, drug compounds, and other biologically active molecules into living cells.

An exemplary embodiment of the present invention provides an apparatus for producing fermented soybean meal, which produces fermented soybean meal for monogastric animals and ruminant selectively or together. An apparatus for producing fermented soybean meal according to an exemplary embodiment of the present invention includes: a solid-liquid separating part, which mixes raw material soybean meal and an extraction solvent and extracts the soybean meal, and separately produces a remaining soybean meal and a soybean meal extract; a lactic acid bacteria culturing part, which produces the lactic acid bacteria by putting inoculum into the soybean meal extract, and supplies the lactic acid bacteria to the solid-liquid separating part; a solid substrate fermenting part, which is selectively supplied with and mixes at least two of the remaining soybean meal supplied from the solid-liquid separating part, the raw material soybean meal supplied through bypass, and lactic acid bacteria supplied from the lactic acid bacteria culturing part to produce a mixed material, and solid-substrate ferments the mixed material to produce primary solid substrate fermented soybean meal; and a drier, which dries the primary solid substrate fermented soybean meal supplied from the solid substrate fermenting part to produce secondary solid substrate fermented soybean meal.

An enzymatic processing plant for continuous flow-based enzymatic processing of organic molecules, comprises an enzymatic processing area, wherein the enzymatic processing area comprises 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, and wherein 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.

Biological sample collection kits are devised with physical features to enable a high performance collection system which delivers preprocessed biological matter via conventional shipping means to a testing laboratories. In particular, untrained and unskilled users deposit biological matter such as saliva or blood into a receiving vessel. By sealing the container, the user causes release of a premixed solution containing preservatives and optionally lysis reagents. In addition, a purification agent is arranged to bind to target molecules and facilitate their removal from solution. These time consuming processes occur while the sample is in transit to the testing facility such that when it arrives, it is in a preconditioned state immediately ready for execution of washing steps. Thus, the high performance containers taught herein are useful for collection biological samples and performing initial process steps on received matter—steps which are largely effected during the shipping stage of the transfer process.

We have modified a commercially-available adherent cell culture bioreactor, developing a new sampling manifold configuration and new way of taking samples to reduce contamination risk.

We have modified a commercially-available adherent cell culture bioreactor, developing a new sampling manifold configuration and new way of taking samples to reduce contamination risk.

A biopellet reactor for marine aquariums. The invention is functionally dependent upon a unique fluidizing plate located between the water inlet port at the base and the media reaction chamber above. This fluidizing plate converts the upward momentum of the incoming water stream into a cyclonic flow in the reaction chamber. This cyclonic flow completely suspends and fluidizes the biopellets within the reaction chamber

A bioreactor apparatus includes a vessel establishing an interior space environmentally separable from an exterior space outside of the vessel, an agitation system including mixing means arranged in the interior space and drive means adapted to rotate the mixing means. The drive means includes a drive motor that is arranged in the interior space.

A system for oxygenating a biological culture includes a container bounding a compartment and having a top wall, a bottom wall, and an encircling sidewall extending therebetween; a tubular member projecting into the compartment of the container and terminating at a terminal end; a gas supply coupled with the tubular member and being configured to blow gas through the tubular member; and a mixing element disposed within compartment of the container at a location between the terminal end of the tubular member and the bottom wall of the container, the mixing element being configured to mix the liquid.

The present disclosure provides methods and materials for the cultivation and/or propagation of a photosynthetic organism. Such methods may comprise the use of a lamp assembly that comprises a plurality of circuit boards, each comprising at least three edges, arranged in a substantially spherical shape defining an interior lamp assembly volume, wherein the plurality of circuit boards comprise a first planar surface in contact with the interior lamp assembly volume and an opposing second planar surface comprising light emitting diodes (LEDs); and a barrier that surrounds the plurality of circuit boards forming the substantially spherical shape.