A device (1) for accommodating a disposable container (44) has a receptacle (10) with at least one receptacle wall (16) that defines an interior of the receptacle (10) for accommodating the disposable container (44). The device includes a temperature control unit for controlling the temperature of the receptacle wall (16). A lighting device (50) is located on an inner face of the receptacle wall (16) that faces the interior of the receptacle (10) and that has the temperature controlled by the temperature control unit. The lighting device (50) is designed to emit light into the interior of the receptacle (10).

Provided are systems and methods for spatially and temporally controlling light with an illumination device comprising a light source operably connected to a circuit board, one or more light guide plates, one or more optical masks, a controller, and a computer readable medium, comprising instructions that, when executed by the controller, cause the controller to: illuminate a cell or a substrate with light from the light source, and spatially and temporally control illumination of light to the cell or the substrate with one or more illumination parameters, wherein the one or more light guide plates provides uniform illumination of the light. Also provided herein are methods of screening using the system and/or device of the present disclosure.

Embodiments of the present invention provide an automatic micro algae culturing device and system for self-cleaning, continual automatic algae culturing and irradiant optimizing. The culturing device includes a photosynthesis tubular reactor for micro algae culturing, with transparent cleaning particles to scrape off any unwanted particles or components such as including and not limited to formation of biofilm. The tubular reactor has multiple double-walled glasses. Inner walls of the tubes in the tubular reactor may be coated with superhydrophobic coating to avoid bio film formation, or sticking of any hydro dirt or dust particles. Because the cleaning particles are transparent, they wont block any sunlight for photosynthesis in the tubular reactor.

The invention relates to a bioprocess container (10) having an optical measuring device (100) for non-invasive spectroscopic measurement comprising: a container housing (12), a port housing (102), which is connected to the container housing (12) and is sealed off with respect to the interior (18) of the container housing (12); at least one radiation-emitting element (124), which is designed to transmit electromagnetic radiation through the at least one fluid contained in the container housing (12); at least one radiation-receiving element (126), which is designed to at least partly receive the radiation which was transmitted by the radiation-emitting element (124); and at least one measuring insert (122), which holds and supports the at least one radiation-emitting element (124) and/or the at least one radiation-receiving element (126).

An apparatus for enhancing bacterial sporulation can include a laminar flow chamber including multiple laminar flow tubes that smooth flow of coolant, a coolant input port that is coupled to the laminar flow chamber that supplies the coolant to the laminar flow chamber, a transparent tube section that is coupled to the laminar flow chamber and includes light-emitting diode (“LED”) light modules, the transparent tube section receives the smoothed flow of coolant from the laminar flow chamber, a culture solution tube that traverses through the laminar flow chamber and the transparent tube section, wherein a portion of the culture solution tube that is within the transparent tube section is surrounded by the coolant and is exposed to light from the LED light modules, and a culture solution input port that is coupled to the culture solution tube and supplies a culture solution to the culture solution tube.

The invention relates to a photobioreactor (1), in particular for the production of microorganisms, wherein the photobioreactor (1) is designed as a closed reactor which has a plurality of upwardly open reactor containers (2) which are closed by a top wall (7) of the photobioreactor (1) and in which a nutrient medium can be accommodated. According to the invention, at least some of the reactor containers (2) are designed as individual containers, whereby adjacent reactor containers (2) form a gap (13) between a front wall (3) and a rear wall (4), which gap is closed at the top by an overflow wall region (12) and has a container overflow opening (16) between the adjacent reactor containers (2). At least one lighting element (29) is received in the gap (13). Furthermore, in each of the reactor containers (2) a partition (6) is provided which divides the reactor container (2) into a front reactor chamber (8) and a rear reactor chamber (9), wherein in the partition (6), in the bottom wall side region, at least one partition-through-flow opening (10) is provided between the front and rear reactor chambers (8, 9). At least one or at least a part of the reactor containers (2) has at least one feeding device (33) by means of which a CO2-containing medium can be introduced into at least one reactor container (2) from outside the reactor container (2), wherein the CO2-containing medium is a CO2-containing gas or a CO2 obtained from a CO2-containing gas. The invention further claims a reactor container and a method.

The present disclosure is generally directed to methods and devices for the precise and simultaneous optical irradiation and oscillating magnetic field radiation of a target, such as mammalian cells and/or nanostructures.

The present invention relates to the field of stem cells. More specifically, the present invention provides compositions and methods for using optogenetics to sustain the pluripotency of stem cells. In one embodiment, a vector comprises a nucleotide sequencing encoding a fusion protein comprising the intracellular domain of fibroblast growth factor 1 receptor (FGFR1) and a photoactivatable domain.

The present disclosure relates to processes for desulfurizing hydrocarbon feedstocks. The processes may include introducing a feedstock comprising hydrogen sulfide to an absorber comprising a metal chelate to form a reduced metal chelate. The processes may further include introducing the reduced metal chelate to a photobioreactor comprising a phototrophic bacterium. The present disclosure also relates to apparatuses for desulfurizing hydrocarbon feedstock. An apparatus may include and absorber and a photobioreactor fluidly connected to the absorber. The photobioreactor may be an anaerobic vessel with a light source.

A passage timing calculation device includes a processor and a memory encoded with instructions executed by the processor, wherein the instructions causing the processor to perform operations comprising calculating a time change in an area occupied by an extraction target region that is a region in which a striated pattern appears from a plurality of images of pluripotent stem cells captured at different times, detecting a change point of the time change in an area occupied by the extraction target region, and calculating a passage timing of the pluripotent stem cells on the basis of the change point.