A fluid ejection device may include a blank cassette that includes a substrate, a die coupled to the substrate, a number of assigned electrical traces formed on the substrate, and a number of unassigned electrical traces formed on the substrate. At least one wirebond may couple at least one of the unassigned electrical traces to the die thereby assigning at least one function to the fluid ejection device.

A nucleic acid amplification reaction method includes subjecting a reaction mixture containing a nucleic acid amplification reaction reagent to be used for amplifying a nucleic acid to a thermal cycle for amplifying the nucleic acid, wherein in the thermal cycle, a heating time for an annealing reaction and an elongation reaction is 1 sec or more and 10 sec or less, the nucleic acid amplification reaction reagent contains a forward primer, a reverse primer, a polymerase, and a fluorescently labeled probe, the concentration of the forward primer is 0.4 μM or more and 3.2 μM or less, the concentration of the reverse primer is 0.4 μM or more and 3.2 μM or less, the amount of the polymerase is 0.5 U or more and 4 U or less, and the concentration of the fluorescently labeled probe is 0.15 μM or more and 1.2 μM or less.

A continuous throughput microfluidic system includes an input system configured to provide a sequential stream of sample plugs; a droplet generator arranged in fluid connection with the input system to receive the sequential stream of sample plugs and configured to provide an output stream of droplets; a droplet treatment system arranged in fluid connection with the droplet generator to receive the output stream of droplets in a sequential order and configured to provide a stream of treated droplets in the sequential order; a detection system arranged to obtain detection signals from the treated droplets in the sequential order; a control system configured to communicate with the input system, the droplet generator, and the droplet treatment system; and a data processing and storage system configured to communicate with the control system and the detection system.

Systems for performing cellular analysis and related devices for conditioning environments adjacent chips in such systems. A device for conditioning an environment adjacent a chip in a system for performing cellular analysis, the device includes a cover for being disposed adjacent the chip and comprising a planar body having a top surface, a bottom surface, and an outer edge surface. The cover includes a central opening extending between the top surface and the bottom surface and bounded by an inner edge surface of the cover. The cover also includes a fluid inlet extending into the body from the outer edge surface between the top surface and the bottom surface the fluid inlet arranged to accept a gas to be delivered to the central opening. The cover also includes a plurality of fluid outlets defined in the inner edge surface and in fluid communication with the fluid inlet. The plurality of fluid outlets are arranged to receive the gas from the fluid inlet and exhaust the gas into the central opening.

Described herein in an embodiment is a diagnostic device for detecting the presence of one or more target nucleic acids (e.g., a nucleic acid of a pathogen, such as SARS-CoV-2 or an influenza virus). In some cases, the diagnostic device comprises a substrate comprising both a reagent delivery region comprising one or more reagents (e.g., one or more nucleic acid amplification reagents) and a lateral flow assay region configured to detect one or more target nucleic acids. The substrate may be removably or permanently coupled to an inner component that is movable relative to an outer component. The diagnostic device may further comprise a sample-collecting component coupled to the outer component and/or the inner component. In some embodiments, the inner component may be moved relative to the outer component in order to sequentially expose the substrate to the collected sample. In some cases, the diagnostic device may be used with a reaction tube comprising one or more liquids (e.g., a reaction buffer) and/or a heating unit.

Customization of a universal reagent cartridge with a lyophilized target-specific PCR component reagent is disclosed. The universal reagent cartridge includes multiple chambers populated with predetermined non-target-specific reagents therein. A custom reagent storage device that stores a lyophilized, target-specific reagent is provided and is configured to be end user insertable into the universal reagent cartridge to customize the universal reagent cartridge with the target-specific reagent.

An automatic assaying system having a multiplex pipette cartridge section in which pipette cartridges are docked. At least one pipette cartridge has a different pipetting characteristic from another corresponding pipette cartridge, the different pipetting characteristic being selectable from a number of different pipetting characteristics. A multiplexing work item holder has an array of work item holder docks that dock corresponding work item holders selectable from pipette trays and pipette tip set racks that define the selectable different pipetting characteristic. One or more of the work item holder docks are indexed to selectably multiplex both the different interchangeable pipette trays and the at least one pipette set rack. A carrier moves the pipette cartridge or a work item holder carriage and a controller selects the at least one pipette tip set rack corresponding to a work item holder dock so as to effect automatic selection of the different pipetting characteristic.

This invention relates to an apparatus for conducting immunoassay test. The apparatus includes a groove unit having a groove along a vertical direction configured to hold a rod-shaped portion of a probe along the vertical direction, and a push pin configured to move along a horizontal direction, the push pin being capable of residing at a first position and a second position. A tip of the push pin is capable of pressing the rod-shaped portion of the probe against the groove when the push pin resides at the first position. The distance between the tip of the push pin and the groove is larger than a diameter of the rod-shaped portion of the probe when the push pin resides at the second position.

An analysis system may perform operations on an analyte that may be combined with multiple regents prior to being introduced into a flow cell. The instrument may include a volume into which the reagents to be combined with the analyte are aspirated one-by-one. The volume may be formed as a serpentine channel in a valve manifold associated with sippers for aspirating the reagents. The reagents may then be mixed by cycling a pump to move the reagents within the mixing volume or channel. For this, the reagents may be aspirated from a recipient into the volume or channel, ejected back into the recipient, and this process may be performed repeatedly to enhance mixing.

Provided herein are an optical test platform and corresponding method of manufacturing the same. The test platform may include a shell defining a cavity for receiving a sample tube, a first aperture, and a second aperture. The first aperture and the second aperture of the shell may each be configured to optically couple the cavity with an exterior of the shell. The test platform may further include a first window and a second window embedded in the shell. The first window may seal a first aperture and the second window may seal a second aperture. The first window and second window may each permit the optical coupling of the cavity with the exterior of the shell. The first window and the second window may be optically coupled via the cavity, and the shell may prohibit optical coupling between the first window and the second window through the shell.