A well plate assembly with an interior channel system in the well plate lid provides a more efficient and uniform distribution of fluid into a receptacle positioned below the well plate lid. The channel system in the lid allows air, or other fluid, to pass through with the use of a pump to each of a plurality of channels in the receptacle. Inlet and outlet valves in the lid prevent a gasket positioned between the lid and the receptacle from releasing contact with the receptacle due to high pressure experienced during the injection of fluid into the assembly. Specifically, pressure under a specified tolerance passes through the inlet valves, and if the pressure within the channel system exceeds the limit of the outlet valve, the outlet valve opens and allows air to escape the lid safely without disturbing the fluid flow into the channels below.

The present invention describes a device consisting of a rotor, a holding-down device, and a base plate. The base plate is normally a fluidic system, a planar fluidic system for example or a fluidic system with several fluidic ports for a directed guidance of liquids or gases through different channels, channel systems, cavities or tubing, for the combination liquid and gas streams, or for prevention of liquid flows.

The invention provides integrated Organ-on-Chip microphysiological systems representations of living Organs and support structures for such microphysiological systems.

A fluidic manifold cartridge includes a plurality of source fluid inlets and fluid outlets. A plurality of fluid input flow channels are provided. Each fluid inlet is in fluid communication with a fluid input flow channel. Each fluid input flow channel directs fluid from the fluid inlet past a plurality of valves. A plurality of fluid output flow channels are in fluid communication with a fluid outlets. Each valve includes a valve seat, a portion of membrane, and a control fluid opening. Each valve has an open and closed condition. The valve in the open condition directs fluid from a fluid input flow channel to a fluid output flow channel. The control fluid opening directs control fluid to move the membrane so as to change the valve between the open and closed conditions. Systems and methods for fluidic manifold are also disclosed.

Described is a modular microfluidic device (MMD) for producing an analyte composition from a biological fluid sample, said device comprising: (a) a reagent module (RM) comprising a reagent reservoir containing a reagent and an eluent reservoir containing an eluent, said reagent and eluent reservoirs being coupled to one or more RM microchannels; and (b) a sample preparation module (SPM) comprising a SPM microchannel adapted to couple with the RM microchannel whereby fluid continuity between SPM and RM microchannels is produced on coupling, and: (i) a sample inlet for receiving said biological fluid sample; (ii) an outlet for delivering said analyte composition; (iii) a mixing chamber; (v) a metering chamber; (vi) an eluent chamber; (vii) a valve; (viii) a solid phase extraction element (SPE); and (ix) an aspirator in fluid communication with the sample inlet of the SPM for withdrawing an aliquot of said biological fluid when contained in a sample vessel, said aspirator being operably coupled to a pneumatic fluid level sensor.

A fluid dispensing device includes a dispensing cylinder, a first inlet and a second inlet. The first inlet is disposed within a first container on which the fluid dispensing device is mounted. The first inlet and the second inlet are configured to facilitate intake of only one fluid into the dispensing cylinder at a given point in time. The fluid dispensing device also includes a first outlet and a second outlet. The first outlet and the second outlet are configured to dispense only one fluid out of the dispensing cylinder at a given point in time. The fluid dispensing device further includes a valve assembly fluidically coupled to the first inlet and the second inlet, and to the first outlet and the second outlet. The valve assembly is configured to control flow of the fluids within and/or out of the dispensing cylinder.

A system that includes a cartridge housing and a hollow transfer module, according to an embodiment is described herein. The cartridge housing further includes at least one sample inlet, a plurality of storage chambers, a plurality of reaction chambers, and a fluidic network. The fluidic network is designed to connect the at least one sample inlet, a portion of the plurality of storage chambers and the portion of the plurality of reaction chambers to a first plurality of ports located on an inner surface of the cartridge housing. The hollow transfer module includes a second plurality of ports along an outer surface of the transfer module that lead to a central chamber within the transfer module. The transfer module is designed to move laterally within the cartridge housing. The lateral movement of the transfer module aligns at least a portion of the first plurality of ports with at least a portion of the second plurality of ports.

A channel bubble reduction device includes a liquid accommodation portion, that accommodates a liquid, a liquid supply apparatus that, with a pushing operation of a rod, discharges the liquid through an aperture portion of a tube portion, a first channel that connects the aperture portion of the liquid supply apparatus with the liquid accommodation portion, and an air layer formation apparatus that forms an air layer in at least one of the first channel or the tube portion.

This disclosure relates to a system for sorting sperm cells in a microfluidic chip. In particular, various features are incorporated into the system for aligning and orienting sperm in flow channels, as well as, for determining sperm orientation and measuring relative DNA content for analysis and/or sorting.

A sample vessel includes a biological sample container and a sample stabilizer container. The biological sample container is configured to receive a biological sample and to store the biological sample. The sample stabilizer container is configured to contain a stabilizer associated with the biological sample. The sample stabilizer container is assembled from a stabilizer vial, an adaptor, and a fluid channel. The stabilizer vial is configured to store an amount of the stabilizer. The adaptor is configured to secure the biological sample container and the stabilizer vial such that the biological sample container and the stabilizer vial form the sample vessel. The fluid channel extends through the adaptor from the stabilizer vial to the biological sample container, the biological sample moving from the biological sample container into the stabilizer vial through the fluid channel.