Disclosed is an internally illuminated bioreactor, and related algae production methods, that employ integrated in-water grow light assemblies configured to manage the heat generated by lighting elements, such as light emitting diodes (“LEDs”) on the in-water grow lights. The bioreactor includes an outer shell and one or more in-water grow light fixtures positioned within the outer shell that are positioned around the perimeter of a hollow, internal tube. The lighting elements and internal tube are themselves contained within a preferably clear, exterior tube of the light fixture that allows light generated by the lighting elements to pass through to the algae culture inside of the growth chamber. A heat management system is provided for cooling the light fixture using forced directed through the hollow, internal tube from the top to the bottom of the tube, out from outlets at the bottom of the internal tube, and upward in the fixture through buoyancy of the warmed air, and thus without additional mechanical air handling devices. As the air moves upward between the lighting elements and the exterior tube, it draws additional heat away from the lighting elements. The warmed air is ultimately exhausted from the top of the lighting fixture. Each lighting fixture preferably also includes a cleaning system that enables the automated cleaning of the outer surface of the exterior tube of the lighting fixture, thus preventing newly formed algae from collecting on the lighting fixture and ensuring a continuous flow of light from the fixture into the algae culture throughout algae production.

The present invention relates to a device (100) for monitoring the development of a biological material, said device in the orientation intended for use comprising: a housing (2) having an extension in a longitudinal direction (X) and an extension in a transversal direction (Y), said housing comprises: two or more culture dish compartments (4), each adapted to accommodate a culture dish (6) comprising a biological material (8) to be monitored, each said compartment being separated from each of said other compartments, said two or more compartments being arranged along the longitudinal direction; each said culture dish compartment (4) comprising a lid (10) adapted to be able to be shifted between an open configuration in which access to the interior (12) of said culture dish compartment is provided, and a closed configuration sealing off the interior of said culture dish compartment from its surroundings; wherein each said culture dish compartment comprises an inlet (14) for supplying gas to and an outlet (16) for removing gas from said culture dish compartment; wherein each said culture dish compartment comprising heating means (18) for heating the interior of said culture dish compartment; wherein said housing comprises one or more cameras (20) for capturing images of a biological material in a culture dish.

When detachment of a cell sheet from a culture dish has started at an unintended timing, immediately detach the cell sheet from the culture dish while preventing generation of wrinkles and the like in the cell sheet. A cell culture device captures an image of cells in the culture dish, and controls a cooling mechanism and a shaking mechanism based on the image so as to shake the cells while cooling them.

This disclosure describes an improved heat transfer system for use in reaction vessels used in chemical and biological processes. In one embodiment, a heat transfer baffle comprising two sub-assemblies adjoined to one another is provided.

A biogas digester tank heating method, system and modular heating rack is provided. The method can include providing a digester tank having a base and a vertical wall surrounding the base. A plurality of heating racks can be provided, where each of the plurality of heating racks is a pre-assembled unit including a plurality of parallel pipes and a stand configured to secure the plurality of parallel pipes to the base of the biogas digester tank. The plurality of heating racks can be secured to the base, adjacent to the vertical wall. Each of the plurality of heating racks can be connected to a heating manifold arranged outside of the digester tank in parallel such that a heat exchange fluid is configured to independently flow from the heating manifold through the plurality of parallel pipes of each individual heating rack of the plurality of heating racks.

The present invention relates to a process for microbial synthesis process having less water consumption and yielding desired product profile. More particularly, the present invention relates to an improved process of microbial synthesis using ultra fine nutrient mist in a specially designed biofilm-bioreactor under controlled conditions. The present invention also relates to an apparatus for microbial synthesis and preparation of optimized biofilm for continuous product formation.

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.

A portable apparatus and method for transport and incubation of a medical sample in a blood culture flask includes a sealable container having a thermally insulated compartment for receiving the blood culture flask and a heater for heating the medical sample to a temperature suitable for pre-culturing of the sample. An agitator is provided for agitating the sample in the blood culture flask.

A portable apparatus for transport and incubation of a medical sample in a blood culture flask includes a sealable container having a thermally insulated compartment for receiving the blood culture flask and a heater for heating the medical sample to a temperature suitable for pre-culturing of the sample. An agitator is provided for agitating the sample in the blood culture flask.

A cell printing apparatus according to the present disclosure comprises: a nozzle through which a liquid cell substance is discharged; a container in which the liquid cell substance discharged through the nozzle is laminated into a three-dimensional structure; and a supply unit for supplying the liquid heated to a predetermined temperature to the container.