Cartridges for the isolation of a biological sample and downstream biological assays on the sample are provided, as are methods for using such cartridges. In one embodiment, a nucleic acid sample is isolated from a biological sample and the nucleic acid sample is amplified, for example by the polymerase chain reaction. The cartridges provided herein can also be used for the isolation of non-nucleic acid samples, for example proteins, and to perform downstream reactions on the proteins, for example, binding assays. Instruments for carrying out the downstream biological assays and for detecting the results of the assays are also provided.

A microplate reader and a method for operating the microplate reader are disclosed. The microplate reader includes a housing, a first NFC reader/writer, a filter tray positioning device, a filter tray, an optical filter disposed in the filter tray, and a controller. The filter tray has a filter tray NFC tag disposed thereon and the filter has a filter NFC tag disposed thereon. The controller receives information about an assay protocol to be undertaken, wherein the assay protocol specifies a filter to be used. The first NFC reader/writer reads filter information stored in the filter NFC tag, the controller directs the NFC reader/writer to store the filter information in the filter tray NFC tag, and the controller enables operation of the microplate reader to undertake the assay protocol only if filter information indicates that the optical filter is in accordance with the filter specified in the assay protocol.

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.

A processing module is configured to extend the capabilities of an analyzer configured to process substances within each of a plurality of receptacles. The module includes a container transport configured to transport a container from a location within the processing module to a location within the analyzer that is accessible to a substance transfer device of the analyzer. A receptacle distribution system is configured to receive a receptacle from the analyzer, transfer the receptacle into the processing module, and to move the receptacle between different locations within the analyzer. A substance transfer device of the module is configured to dispense substances into or remove substances from the receptacle within the processing module. A reagent card exchanger provides an input device for inserting reagent cards into and removing reagent cards from the module, stores reagent cards within the module, and transfers reagent cards to different location within the module.

One or more temperature cycles are applied to the contents of a processing vial closed by an interlocked cap within a thermal cycler. The processing vial and the interlocked cap are transferred from the thermal cycler to a storage compartment within the instrument with a transfer mechanism with a probe engaged with the cap. In the storage compartment, the processing vial and interlocked cap are moved to an access opening in the instrument and are removed from the instrument through the access opening.

Provided herein are systems, devices and methods for retaining chromatographic minicolumns in a holding fixture. A retaining apparatus may be provided with a pair of laterally spaced apart upright supports and a horizontal beam spanning between the upright supports to hold them in the laterally spaced apart relationship. The apparatus may be configured to contact a holder plate only along peripheral edges of the holder plate. The apparatus may be configured to slide along the holder plate after the minicolumns have been inserted therein, thereby retaining the minicolumns in the holder plate but allowing access to the minicolumns through vertical holes in the horizontal beam.

A method for reconstituting a reagent within a reagent pack including one or more wells and at least one of the wells containing a lyophilized reagent comprises the steps of receiving reagent packs into a reagent pack input carousel, transferring one reagent pack with a rotary distributor from the input carousel to a reagent pack storage carousel, retrieving the reagent pack from the storage carousel with the rotary distributor and placing the reagent pack into a reagent pack loading station, and dispensing a reconstitution reagent with an automated pipettor into the well containing the lyophilized reagent to form a reconstituted reagent.

Provided is a biochemical reaction substrate which can achieve higher test sensitivity and shorter testing time in an allergy test, which can also reduce a required amount of blood or the like needed as a specimen and decrease the number of test steps, thereby facilitating performance of the test, and which is to be used in an allergy test in which infection risk of the test staff is reduced. A biochemical reaction substrate, including: a reaction plate; an absorber; a reaction plate storing portion for storing the reaction plate; an absorber storing portion for storing the absorber; a storage container having a heated portion; and a cover assembled to the storage container so as to cover at least a part of the reaction plate and the absorber stored in the storage container, wherein the reaction plate includes a reaction area in which a specific binding substance that specifically reacts with a substance to be tested in a specimen is immobilized, and a flow passage that connects the absorber and the reaction area, and wherein the cover includes an injection hole for injecting a specimen or the like into the reaction plate.

Described is a lateral flow high throughput assay device analyzer for preparing and analyzing a plurality of lateral flow assay samples. The analyzer comprises a cartridge stage for supporting an assay cartridge, an elevation adjustment mechanism, and a translation adjustment mechanism for aligning the cartridge stage and assay cartridge relative to a vertical support structure, fluid metering device, and detection device for high throughput lateral flow assay analysis.