Disclosed are cartridges and modules that may be utilized in diagnostic systems and methods. The cartridge includes a flexible seal that caps the cartridge. The flexible seal has an opening for a pipette tip, and the flexible seal is configured to create a sealed environment when a pipette tip is positioned in the opening of the flexible seal and when the pipette tip is moved in the X-axis, Y-axis, and Z-axis.

The present invention relates to a sampling housing and to a modular controller formed by this sampling housing when it is connected to a control station. This housing comprises a device supporting an assembly (3) consisting of a well plate (4), of a cap adapter (5) comprising as many orifices as there are wells and arranged on said well plate (4), and of caps (6), each cap (6) cooperating with a single well of the plate (4). The invention is applicable in the field of analyzing biological samples.

An assay plate is provided. The assay plate has a body with a plurality of reservoirs formed therein. The reservoirs are shaped and aligned in the body in an orientation to induce drainage of fluids contained therein in a desired direction. A plate array and a funnel array forming an assembly for pooling of samples contained in the assay plate is also provided.

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 data in the conduct of an assay by an assay system. The present invention also relates to consumables (e.g., kits and reagent containers), software, data deployable bundles, computer-readable media, loading carts, instruments, systems, and methods, for performing automated biological assays.

The present invention relates to a cell cryopreservation device, and can comprise: a first housing for accommodating a plurality of test tubes; a second housing for covering the first housing; center support ribs extended upward from the inner bottom surface of the first housing to come in contact with and support the side surfaces of the surrounding test tubes; and side support ribs extended from the inner wall surface of the first housing toward the inner side of the first housing to come in contact with and support the side surfaces of the test tubes.

The invention relates in a first aspect to an improved fluidic device for determining a property of a microbe. The device comprising a bottom layer comprising a plurality of light-transmissive wells; and a top layer comprising an injection opening and a fluid distribution system. Each of said plurality of distribution channels has: essentially the same channel length between the inlet end and the outlet end; and essentially the same channel volume. The invention relates in a second aspect to a use of the device for determining a susceptibility of a microbe, preferably a bacterium, to an antimicrobial drug.

An apparatus is provided for holding down membrane elements in respective wells of a multiwell plate, which has, at its top side, respective openings of the respective wells. The apparatus has, at its upper region, a support structure having respective openings, and respective corresponding retention elements which extend downwards from the respective openings of the support structure, so that respective retention elements protrude into respective wells when the support structure has been placed onto the top side of the multiwell plate. A retention element has multiple webs which extend downwards from the support structure and the ends of which are connected to one another at a bottom side of the apparatus by means of a connection element. Furthermore, a retention element has multiple openings between the webs, which openings extend continuously from the support structure right up to the connection element and which openings furthermore extend continuously from the top side of the multiwell plate right up to the connection element when the support structure has been placed onto the top side of the multiwell plate.

The invention is a device for quantitatively collecting pooled samples from multiwell plates.

A system for hands-free collection of biomaterials, such as urine, in a vessel disposed below a closable port, the vessel being sealable by an at least partially automated sealing mechanism, the sealed vessel being transferable to a storage area. In general terms this application is directed to a hands-free, biomaterial collection system that is it least partially automated. In one aspect, a biomaterial collection system comprises a biomaterial capture area including a port, a collection area disposed below the capture area, a vessel disposed in the collection area and aligned with the port, and a sealing mechanism disposed in the collection area for sealing the vessel.

An all-electronic high-throughput detection system can perform multiple detections of one or more analyte in parallel. The detection system is modular, and can be easily integrated with existing microtiter plate technologies, automated test equipments and lab workflows (e.g., sample handling/distribution systems). The detection system includes multiple sensing modules that can perform separate analyte detection. A sensing module includes a platform configured to couple to a sample well. The sensing module also includes a sensor coupled to the platform. The sensing module further includes a first electrode coupled to the platform. The first electrode is configured to electrically connect with the sensor via a feedback circuit. The feedback circuit is configured to provide a feedback signal via the first electrode to a sample received in the sample well, the feedback signal based on a potential of the received sample detected via a second electrode.