Devices and methods for multi-well plate liquid distribution are provided. Devices herein provide a plurality of dispensing stations configured to receive and dispense or disburse liquid to the wells of a multi-well plate. The dispensing stations include dispensing surfaces configured to receive liquid droplets dispensed by manual or automatic pipettes. The dispensing surfaces are configured to retain received liquids until force is applied and distribution to the wells of the multi-well plate occurs. Devices and methods provided herein increase the consistency of laboratory results in procedures requiring liquid distribution.

A biological sample collection system includes: a sample collection vessel having a sample collection chamber for receiving a biological sample; a sealing cap including a reagent chamber for storing a sample preservation reagent and being configured to associate with the sample collection vessel; and a selectively movable valve at least partially disposed within the sealing cap. The selectively movable valve includes a post with an interior chamber and fluid vent and a valve head associated with a distal portion of the post that initially occludes the fluid vent when the valve is in the closed configuration. Associating the sealing cap with the sample collection vessel causes a physical rearrangement of the post and the valve head in order for the fluid vent to become unoccluded by the valve head, thereby placing the valve in an open configuration and allowing fluid communication between the reagent chamber and the sample collection vessel.

The present invention relates to a method and a system (400) for filling a closed container (200) with a fixative solution. The system comprises a container (200) comprising a container body (230) for receiving a biological specimen, a lid (220) for selectively closing the container body (230) and a port (100) forming a unidirectional barrier in a direction from the inside (IC) to the outside (OC) of the closed container (200). The system further comprises a dispensing apparatus (500) having a filling nozzle (300) for dispensing the fixative solution. The filling nozzle (300) is relatively moveable with respect to the container (200) between a retracted position and a filling position to fill the container (200) with the fixative solution.

An automatic nucleic acid extraction cartridge and an automatic nucleic acid extraction system including the same are described herein. The cartridge having a housing that includes a sample port, a cell processing chamber, a wash fluid chamber, a filter assembly comprising a filter member, and a diverter valve having a first and a second reversibly sealable output, wherein each of the sample port and the cell processing chamber, the cell processing chamber and the filter assembly, and the wash fluid chamber and the filter assembly are in one-way fluid communication, and the filter assembly is in fluid communication with the diverter valve and (i) a waste conduit when the diverter valve is biased to the first reversibly sealable output and (ii) a pathogen nucleic acid conduit when the diverter valve is biased to the second reversibly sealable output. The present disclosure further describes methods of using the same.

A single-use valve arrangement that includes a valve housing, a diaphragm carried by the valve housing, a pressure sensor, and a controller coupled to the pressure sensor. The valve housing defines an inlet and an outlet, the inlet adapted to be fluidly connected to an outlet of a virus removal filter. The diaphragm divides the valve housing into a first chamber and a second chamber fluidly isolated from the first chamber. The pressure sensor is configured to measure a pressure change in the second chamber due to movement of the diaphragm responsive to a pressure change in the first chamber. The controller is configured to determine an actual leak rate of the filter based on the measured pressure change, the controller further configured to determine the integrity of the filter by comparing the actual leak rate to an expected leak rate of the filter.

A sample processing tubule is provided including, from a proximate to a distal end, an opening through which a sample is introducible, at least three segments, and an reagent introduction port operatively connected to a distal segment of the at least three segments. The reagent introduction port enables the addition of a reagent in the distal segment of the tubule, enabling the user to create a customizable assay tubule.

An integrated testing device and fluid module are disclosed, as well as a method of manufacture. Fluid module contains a reservoir containing a test fluid, and a control vessel. The reservoir discharges test fluid into the control vessel, which discharges the test fluid in a controlled way to a test component.

The present disclosure relates to a fluid system for a sample processor and a sample processor including the fluid system. The fluid system includes a sample line, a processing fluid line, a vacuum line, and an air pump. The sample line communicates a sample container with a sample port of a flow cell unit. The processing fluid line communicates a sheath fluid container with a processing fluid port of the flow cell unit. The vacuum line is in communication with the flow cell unit. The air pump includes a first output port and a second output port. Pressurized gas is generated at the first output port, and the first output port is in communication with the sample container and the sheath fluid container. A vacuum is generated at the second output port, and the second output port is in communication with a vacuum port of the flow cell unit through the vacuum line.

The microfluidic device capable of initiating sequential flow according to the present invention includes: a main flow path in which a suction port for sucking the fluid with a negative pressure is formed at one end; a plurality of reservoirs that supply a fluid stored therein to the main flow path through an outlet by the negative pressure applied to the suction port, and are connected to a plurality of different points of the main flow path; and a blocking element that blocks the inflow of external air to the main flow path through the outlet when all the fluid in the reservoir flows out, wherein the fluid stored in a plurality of the reservoirs may flow sequentially.

The present invention relates to a container assembly for collecting and transporting a tissue sample. The container includes a container having a chamber therein for receiving the tissue sample. The container assembly includes a cap configured to be attached to the container to close off the chamber. The cap includes a base section, which is configured to be attached to the container, and a movable section, which is movably coupled to the base section. The base section and movable section are configured to form a reservoir therebetween, the reservoir being sized and shaped so as to contain a preservation solution. The base section and the movable section are configured such that the preservation solution is discharged into the chamber from the reservoir when the movable section is moved relative to the base section from a closed position to an open position.