A reagent cartridge includes a cartridge body configured to store a solid reagent, the cartridge body having a reagent well accessible through an access port. A seal plate is proximate the access port, the seal plate extends away from the access port to a seal plate edge remote from the access port. The reagent cartridge includes an isolation envelope surrounding the reagent well. The isolation envelope includes a seal membrane covering the access port, at least one isolation wall, and at least one isolation cavity interposed between the isolation wall and the well sidewall. One or more reagent cartridges are received in a cartridge magazine. The cartridge magazine includes at least one complementary profile seat configured to receive the one or more reagent cartridges having a corresponding cartridge profile.

A liquid chromatography sample organizer includes a first chamber, a plurality of stacked sample organizer shelves mounted within the first chamber each individually configured to store a sample-vial carrier including a sample, and a shelf magnet affixed to a surface of each of the plurality of stacked sample organizer shelves. A portion of the first chamber is configured to be located adjacent to, and open to, a sample manager configured to inject liquid chromatography samples into a chromatographic flow stream. Disclosed further is a liquid chromatography system having the sample organizer, a sample drawer, and a method of transferring samples between a sample manager and the sample organizer.

The technology described herein generally relates to systems for extracting polynucleotides from multiple samples, particularly from biological samples, and additionally to systems that subsequently amplify and detect the extracted polynucleotides. The technology more particularly relates to microfluidic systems that carry out PCR on multiple samples of nucleotides of interest within microfluidic channels, and detect those nucleotides.

A handling system for high throughput processing of a large volume of biological samples is provided herein. Such systems can include an array support assembly that supports multiple diagnostic assay modules in an array having at least two dimensions, a loader that loads multiple diagnostic assay cartridges within the multiple diagnostic assay modules. The array support assembly can be movable relative the loader to facilitate loading and unloading so as to provide more efficient processing.

The present invention provides: a drawer that is supported so as to be horizontally movable in the front-rear direction between an open position and a closed position through a front-face opening; a table that allows an expendable or a processing unit used for analysis to be mounted in the drawer; and a moving-direction transforming means that, while the drawer is moved toward the rear side from the open position to the closed position, moves horizontally until the expendable or the processing unit mounted on the table passes through the front-face opening from the front side to the rear side and moves the table toward the upper side in synchronization with the horizontal movement of the drawer toward the rear side after the expendable or the processing unit mounted on the table passes through the front-face opening. This makes it possible to easily and reliably perform the work of replacing a chip rack.

An automatic analyzer for analyzing samples includes a lift, a part take-out station and a rack recovery station. The lift is configured to raise and lower a plurality of stacked part racks to the part take-out station and to the rack recovery station while keeping the part racks together. The part take-out station comprises a first rack separator configured to prevent the uppermost one of said stacked part racks from being lowered when the lift lowers, while allowing the other part racks to lower, so that the uppermost rack is separated from the other part racks so as to remain in the part take-out station. The rack recovery station comprises a second rack separator configured to prevent the uppermost one of said stacked part racks from being lowered when said lift lowers, while allowing the other part racks to lower, so as to remain in the rack recovery station.

A digital slide scanning apparatus slide rack carousel allows continuous loading and unloading of slide racks into the carousel while the digital slide scanning apparatus is simultaneously digitizing glass slides. The slide rack carousel includes a base having an interior portion of its upper surface at an angle. The slide rack carousel also includes plural rack spacers extending upward from the base and adjacent rack spacers define a rack slot. Each rack spacer also includes a rack stopper on each side such that adjacent rack spacers have rack stoppers facing each other. The rack stoppers prevent a slide rack from moving further toward the center of the carousel than desired.

The present invention relates to methods, devices and systems for associating consumable data with an assay consumable used in a biological assay. Provided are assay systems and associated consumables, wherein the assay system adjusts one or more steps of an assay protocol based on consumable data specific for that consumable. Various types of consumable data are described, as well as methods of using such information in the conduct of an assay by an assay system.

Luminescence test measurements are conducted using an assay module having integrated electrodes with a reader apparatus adopted to receive assay modules, induce luminescence, preferably electrode induced luminescence, in the wells or assay regions of the assay modules and measure the induced luminescence.

We describe apparatuses, systems, method, reagents, and kits for conducting assays as well as process for their preparation. They are particularly well suited for conducting automated sampling, sample preparation, and analysis in a multi-well plate assay format. For example, they may be used for automated analysis of particulates in air and/or liquid samples derived therefrom in environmental monitoring.