The present disclosure provides devices, machines and methods for incubating or washing a biological sample. This disclosure provides a device comprising a motor and a control for the motor, a supporting frame comprising a receptacle, an assembly comprising a rotatable liquid storage container, a washing cassette, and a liquid collection and recovery tank. The disclosure also provides methods using the device.

The present disclosure provides improved cell therapy vessels, cell therapy vessel adapters, kits, and methods of using the same.

In some aspects, the invention relates to automated cell culture incubators and their methods of use. In one aspect, the disclosure provides cell culture incubators having an airlock chamber, a storage chamber and/or an internal chamber. In some aspects, the disclosure provides methods for producing autologous mammalian cell cultures.

An automated carousel and system configured for translationally moving a plurality of biological production units in unison along a vertical frame while maintaining a precise alignment of each of the biological production units relative to gravity, and simultaneously providing independent dynamic adjustment of the axial orientation of each of the plurality of biological production units relative to gravity. The automated carousel may be adapted for use with a variety of biological production units supporting cell culture and/or tissue engineering systems in various clinical and laboratory settings and provides for ergonomic use thereof.

Disclosed herein are cell processing systems, devices, and methods thereof. A system for cell processing may comprise a plurality of instruments each independently configured to perform one or more cell processing operations upon a cartridge, and a robot capable of moving the cartridge between each of the plurality of instruments.

Disclosed herein are cell processing systems, devices, and methods thereof. A system for cell processing may comprise a plurality of instruments each independently configured to perform one or more cell processing operations upon a cartridge, and a robot capable of moving the cartridge between each of the plurality of instruments.

The present disclosure is directed to portable bioreactors that allow the custom production of microbial cultures, and in some embodiments, the production of custom microbial biofilms. Also disclosed are portable bioreactor systems that are networked and capable of cooperative work in parallel.

A cell culture system is provided that includes at least one multi-layered vessel for culturing cells, and a cabinet comprising an interior cavity enclosed by one or more sidewalls. The cabinet being configured to house the multi-layered vessel within the interior cavity. The multi-layered vessel includes a cell culture space within the multi-layered vessel. The cabinet can change an orientation of the multi-layered vessel from an upright orientation to a tilted orientation.

An apparatus (100, 700, 8001, 802, 803) for growing biomass, wherein the apparatus comprises: at least one plate (110, 210, 310, 410, 710) comprising at least two plate sections (120, 220, 320, 331, 332, 333, 420, 421, 422) configured to be movable between an opened position and a closed position. In the closed position the at least two plate sections jointly form a first surface for receiving and holding a growth medium for growing biomass and in the opened position the at least two plate sections are pivoted away from the closed position such that the growth medium is slidably released from the at least one plate. The at least one plate is movably supported on at least one first railing (150, 750), wherein the apparatus further comprises a first drive mechanism (715) for independently moving each of the at least one plate along the at least one first railing; and the at least two plate sections are pivotable about a first axis (251) and a second axis (252) respectively.

A fluidic cartridge comprises a fluidic disk having a plurality of alignment openings; a fluidic chip comprising a body, one or more channels formed in the body in fluidic communications with input ports and output ports for transferring one or more fluids between the input ports and the output ports, and a plurality of protrusions formed on the body and received in the alignment openings of the fluidic disk for aligning the fluidic chip to the fluidic disk; an actuator operably engaging with the one or more channels for selectively and individually transferring the one or more fluids through the one or more channels from at least one of the input ports to at least one of the output ports at desired flow rates; and a tube member defining a cylindrical housing for accommodating the fluidic disk, the fluidic chip and the actuator therein.