A storage assembly for storing a plurality of specimens includes a frame, a plurality of modular storage units for perfusion and/or incubation of one or more specimens removably coupled to the frame, a sample transfer apparatus configured to retrieve a specimen holder from a chosen modular storage unit of the plurality of modular storage units, and a control unit communicatively coupled to the sample transfer apparatus. The control unit is configured to cause the sample transfer apparatus to retrieve a specimen from a modular storage unit of the plurality of modular storage units and deliver the specimen to a delivery position.

What is described herein relates to a method for improving a cell culture comprising a) heating a cell culture process fluid using a single-use dense membrane hollow fiber module wherein said single-use dense membrane hollow fiber module comprises a plurality of dense membranes arranged as hollow fibers in a housing and/or b) wherein the cell culture has at least one cell culture chamber and at least the bottom or at least the top of said cell culture chamber is covered with an insulation.

A dynamic incubator system and method for mammalian cells. The dynamic incubator system includes an incubator and a programming device communicatively coupled to the incubator. The programming device includes a memory, one or more processors, a display, and an input mechanism. The programming device is adapted to enable at least one preset temperature and gas concentration sequence to be one or more of designed for the interior of the incubator, saved to the memory of the programming device and/or selected for implementation within the interior of the incubator. The at least one temperature and gas concentration sequence includes programmed changes to the temperature and a CO.sub.2 gas concentration. A purging mechanism is coupled to the incubator and releases a portion of a gas concentration to enable rapid changes in the temperature and gas concentration in the incubator.

The subject invention provides methods and systems for producing microbe-based compositions that can be used in the oil and gas industry, environmental cleanup, agriculture, and many other applications. More specifically, the subject invention provides methods and systems for producing microorganisms and/or growth by-products thereof using a hybrid solid state-submerged fermentation method, wherein a matrix comprised of a solid material covered in an alginate coating is formed inside a liquid fermentation vessel. In some embodiments, the solid material is a plurality of natural loofa sponges.

A dynamic incubator system and method for mammalian cells. The dynamic incubator system includes an incubator and a programming device communicatively coupled to the incubator. The programming device includes a memory, one or more processors, a display, and an input mechanism. The programming device is adapted to enable at least one preset temperature and gas concentration sequence to be one or more of designed for the interior of the incubator, saved to the memory of the programming device and/or selected for implementation within the interior of the incubator. The at least one temperature and gas concentration sequence includes programmed changes to the temperature and a CO.sub.2 gas concentration. A purging mechanism is coupled to the incubator and releases a portion of a gas concentration to enable rapid changes in the temperature and gas concentration in the incubator.

System and method for providing biocompatible, nutrient filled media to the Human Cells, Tissues, and cellular and tissue-based Products (HCT/P) while removing wastes. The present teachings provide for sensing the characteristics of the media, and modifying the characteristics when necessary. The present teachings can also provide components that can provide fluid pumping integrated with fluid gas exchange, and sensing of fluid characteristics at consistent times during the fluid flow cycle. System and method control multiple bioreactors from a centralized media reservoir, while fluidically isolating the bioreactors from cross-contamination.

A method includes directing fluid flow from a bioreactor to an external path of a re-circulation loop, separating cells from the medium and returning the cells to the bioreactor thereby leaving spent medium, depleting the spent medium of biological waste products, replenishing the spent medium with beneficial growth factors to thereby provide replenished medium, and directing the replenished medium back to the bioreactor to thereby complete the re-circulation loop such that recycling of the medium occurs. The replenishing of the spent medium with beneficial growth factors may occur within a medium collection reservoir. The method may further include monitoring the spent medium within the medium collection reservoir including temperature of the spent medium within the medium collection reservoir and pH of the spent medium within the medium collection reservoir.

A system for growing algae includes a gas concentrator configured to receive a first gas containing CO2 at a first concentration and discharge a second gas containing CO2 at a second concentration higher than the first concentration, and a photobioreactor containing algae in an algae slurry and fluidically coupled to the gas concentrator to receive the second gas. A recycling line extends from a gas outlet on the photobioreactor to remove a third gas from the photobioreactor for future use in the photobioreactor.

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.

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.