Disclosed herein are bioreactors that include a container for holding fluid aligned on a vertical axis, wherein at least a portion of the container is oriented at an angle relative to the vertical axis, wherein the angle is from about 0 to 90. In some embodiments, the container is placed on a support structure with portions of the container oriented at alternating angles. The system is essentially closed except for at least one opening (for example an opening at the bottom edge) that allows for the introduction of gases and/or nutrients. The gas and/or nutrients are introduced in such a way as to provide mixing and aeration of a cell culture in the bioreactor. Also disclosed are methods of culturing cells (such as microalgae, macroalgae, bacteria, fungi, insect cells, plant cells, animal cells, or plant or animal tissue or organs) using a bioreactor described herein.

The invention relates to methods and apparatuses for producing Class A biosolids. In yet another embodiment, the invention relates to a method comprising digesting waste material by anaerobic digestion, and yielding Class A biosolids. In still yet another embodiment, the invention relates to a system for anaerobic digestion of waste material to produce Class A biosolids. In still yet another embodiment, the invention relates to a system for anaerobic digestion of waste material comprising a mixing chamber, a digester, a heating pit, and an effluent pit.

The present disclosure provides a reagent cartridge configured for use in an automated multi-module cell processing environment. The reagent cartridges may include an electroporation device, as well as sample receptacles, reagent receptacles, waste receptacles and the like, and a script for controlling a processor to dispense samples and reagents contained in the receptacles, and to porate cells in the electroporation device. Also described are kits including the cartridges, automated multi-module cell processing instruments including the reagent cartridges and methods of using the reagent cartridges.

The present disclosure provides a reagent cartridge configured for use in an automated multi-module cell processing environment. The reagent cartridges may include an electroporation device, as well as sample receptacles, reagent receptacles, waste receptacles and the like, and a script for controlling a processor to dispense samples and reagents contained in the receptacles, and to porate cells in the electroporation device. Also described are kits including the cartridges, automated multi-module cell processing instruments including the reagent cartridges and methods of using the reagent cartridges.

Embodiments of the present invention provide novel, low-cost fermentation systems and methods of their use. More specifically, the present invention provides biological reactor systems for fermenting a wide variety of, for example, bio level 1 microorganisms with very high cell densities. The reactor systems can be used to grow yeast, fungi and bacteria, as well as growth by-products thereof. In specific embodiments, the reactor systems are used to produce yeast-based compositions. In certain specific embodiments, the reactor systems can be used for the production of Starmerella bombicola yeast compositions.

Discloses is a continuous fermenter for sequential fermentation of hexose and pentose which includes (a) a hexose fermenter equipped with a saccharified solution supply unit containing hexose, pentose and lignin, a plurality of trays closing at least half of the diameter of the fermenter, impellers disposed on each of the trays, an impeller driving unit, a lignin discharge unit disposed at the bottom of the fermenter, a fermented solution discharge unit, and a temperature control jacket; and (b) a pentose fermenter equipped with a fermented solution supply unit for supplying the fermented solution discharged from the hexose fermenter, a plurality of trays closing at least half of the diameter of the fermenter, impellers disposed on each of the trays, an impeller driving unit, a lignin discharge unit disposed at the bottom of the fermenter, a fermented solution discharge unit, and a temperature control jacket.

Disclosed is a jacketed, tiered baffle, bioreactor tank comprising an outer cylindrical-shaped jacket and a cylindrical tank having an inner tank surface defining a chamber configured for supporting a flexible bag disposed within the chamber, and an outer tank surface having tiered baffles configured for routing a heat exchange fluid around the entirety of the outer tank surface, the cylindrical tank disposed axially within the outer cylindrical-shaped jacket. The outer cylindrical-shaped jacket is sealed to the cylindrical tank in a manner sufficient to prevent or minimize loss of the heat exchange fluid.

A heat exchange module for use in a chemical, pharmaceutical or biological reactor system includes a generally hollow body having an interior space for receiving a replaceable or single use reactant container, and at least one thermally conductive surface adapted to contact the replaceable reactant container to facilitate heat transfer, a fluid circulation path formed within the body between an outer wall of the body and an inner wall of the body through which a heat exchange fluid can be circulated, and at least one baffle protruding from the inner wall of the body into the interior space.

The present disclosure provides a reagent cartridge configured for use in an automated multi-module cell processing environment.

Functional assays using reporter cell assays are described which probe the activity of at least one cell of interest. The ability to probe at least one cell is provided by using the microfluidic methods, devices and kits described herein. Assays combining both reporter cell signaling as well as binding assay signaling for at least one cell is also described herein.