The invention relates to an optical measurement device for a reaction vessel, and a method therefor. An object is to measure the optical state within a reaction vessel in an efficient, rapid, and highly reliable manner, without an expansion of the device scale. The configuration includes: a vessel group in which two or more reaction vessels are arranged; a light guide stage having two or more linking portions to which front ends of light guide portions, which have a flexibility, that optically connect with the interior of the linked reaction vessels, are provided; a connecting end arranging body that has an arranging surface that arranges and supports along a predetermined path two or more connecting ends, to which back ends of the light guide portions, in which the front ends thereof are provided to the linking portions, are provided, the connecting ends are provided corresponding to the respective linking portions; a measurement device provided approaching or making contact with the arranging surface that has measuring ends that are successively optically connectable with the respective connecting ends along the predetermined path, and in which light from within the reaction vessels is receivable by means of optical connections between the connecting ends and the measuring ends; and a light guide switching mechanism that relatively moves the respective connecting ends arranged on the connecting end arranging body and the respective measuring ends such that they are successively optically connected.

The present disclosure is, in one aspect, directed to a locking assembly for securing a sample tube assembly to a sample manifold of a measurement system. The locking assembly includes a ramp block having one or more slots defined therein and configured to at least partially receive a portion of the sample tube assembly. The ramp block also includes a plurality of surface features defined therealong and configured to engage and move the sample tube assembly toward and into engagement with the sample manifold. The ramp block further is movable between a plurality of positions including an open position for allowing the sample tube assembly to be received through the one or more slots or openings, and a closed position substantially sealing the sample tube assembly against or within the sample manifold. Other aspects also are described.

The present disclosure relates to automated medical diagnostic systems and methods. One example embodiment includes a system. The system includes a test cartridge, a test strip usable to indicate the presence of one or more patient conditions, and a kiosk configured to receive and process the test cartridge and the test strip. The kiosk includes a vortex mixer; a conveyor belt; a robotic pipette module; an imaging system; a display; and a processor communicative coupled to the vortex mixer, the conveyor belt, the robotic pipette module, the imaging system, and the display. The processor is configured to execute instructions stored within a memory to operate the vortex mixer, the conveyor belt, the robotic pipette module, the imagine system, and the display; to receive the image of the test strip from the imaging system; and to analyze the image to determine whether one or more patient conditions is present.

A rack for a diagnostic robot with at least one support for at least one container; at least one gas-outlet to supply the at least one container with a gas at a predefined but individually adjustable pressure level; a first gas pump to generate a gas at a predefined super-atmospheric pressure level; a second gas pump to generate a gas at a pre-defined sub-atmospheric pressure level; a first tubing system attached to the first gas pump and holding the gas generated by the first gas pump; a second tubing system attached to the second gas pump and holding the gas generated by the second gas pump; and at least one tube bridge, wherein one end of the bridge connects via a first valve into the first tubing system and the other end of the bridge connects via a second valve into the second tubing system, and wherein the at least one gas-outlet is connected to the center of the bridge.

An apparatus and a corresponding method used, in the field of medical analysis, to determine erythrocyte sedimentation rate, as well as other connected parameters.

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.

Systems and methods are provided for sample processing. A device may be provided, capable of receiving the sample, and performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing multiple assays. The device may comprise one or more modules that may be capable of performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing the steps using a small volume of sample.

A sample preparation cartridge for use with a sample preparation device, the cartridge includes a housing defining plural separate segments, at least one of said segments comprising a fixed section of a pipette component; and a moveable head comprising a pipette tip, the head being configured, in use, to be moved between a position in which the pipette tip is in sealed engagement with the fixed section of pipette component and a position in which pipette tip is positioned adjacent to another of said plural segments. With the present invention a disposable sample preparation cartridge and corresponding analytical reader can be provided in a very cost effective and simple manner.

A method for detecting a covering state of a laboratory sample container is presented. Light is injected into the laboratory sample container and an optical power is measured at a measuring location. A corresponding laboratory sample distribution system is also presented.

A sample measurement system according to an embodiment may include: sample measurement units that perform measurement on samples by using consumables; a consumable setting unit in which a consumable rack storing the consumables to be supplied to the sample measurement units is set; a sample setting unit in which a sample rack storing the samples to be supplied to the sample measurement units is set; a first transport path that transports the consumable rack from the consumable setting unit to at least one of the sample measurement units; and a second transport path that transports the sample rack from the sample setting unit to at least one of the sample measurement units.