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

A container includes a lower portion and a lid to connect with the lower portion. The lid includes a fluidic interface, a swing bar, and a counter structure disposed on an opposite side of the fluidic interface relative to the swing bar. The fluidic interface includes a first liquid port, a second liquid port, a gas port, and a seal ring disposed around the first liquid port, the second liquid port, and the gas port, the first liquid port disposed along a center axis of the container.

A fluid thermal processing device may include a substrate, a platform projecting from the substrate, a fluid heating element supported by the platform, a temperature sensing element, distinct from the fluid heating element, supported by the platform and an enclosure supported by and cooperating with the substrate to form a fluid chamber about the platform. The fluid chamber forms a volume of uniform thickness conforming to and about the platform.

Methods and devices are provided herein for identifying a cell population comprising an effector cell that exerts an extracellular effect. In one embodiment the method comprises retaining in a microreactor a cell population comprising one or more effector cells, wherein the contents of the microreactor further comprise a readout particle population comprising one or more readout particles, incubating the cell population and the readout particle population within the microreactor, assaying the cell population for the presence of the extracellular effect, wherein the readout particle population or subpopulation thereof provides a direct or indirect readout of the extracellular effect, and determining, based on the results of the assaying step, whether one or more effector cells within the cell population exerts the extracellular effect on the readout particle. If an extracellular effect is measured, the cell population is recovered for further analysis to determine the cell or cells responsible for the effect.

The invention relates to a container system for transport of biological material comprising a container casing and an insulating device, wherein the container casing defines a container interior space for accommodation of the insulating device and for accommodation of biological material to be transported, and wherein the insulating device is constituted of at least two insulating portions, which are formed so as to surround the biological material inside the container interior space. The invention further relates to uses of such a container system for packaging and transport of biological material, as well as methods of packaging biological material for transport.

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.

The present invention relates to encapsulated microfluidic packages and methods thereof. In particular embodiments, the package includes a device, a cradle configured to support the device, and a lid having a bonding surface configured to provide a fluidic seal between itself and the device and/or cradle. Other package configurations, as well as methods for making such fluidic seals, are described herein.

A method of analyzing a phase transformation process of a material comprises providing a spherical sample of the material, measuring and recording a first data series of core temperature at the sample's center of gravity, measuring and recording a respective second data series of temperature at the sample's periphery, measuring and recording a respective third data series of radial displacements at the sample's periphery, and calculating a change in pressure in the sample at a plurality of points in time based on first, second and third said data series.

A rack to be suspended from a support structure includes a hook portion, an upright portion, and a shelf. The hook portion defines a cavity configured to receive an upper edge of a wall of the support structure therein. The upright wall is connected to and extends from the hook portion. The shelf is connected to the upright wall at a location spaced apart from the hook portion along a height of the upright wall. The shelf projects outward from the upright wall to a distal edge of the shelf that is spaced apart from the upright wall. The shelf defines a plurality of slots through the thickness of the shelf. The slots are open along the distal edge and are configured to accommodate one or more of multiple reclosable container caps or multiple tubes connected to the reclosable container caps.