Point-of-care biomarker assay apparatus arranged for measuring a presence or concentration of a biomarker in a sample, said biomarker assay apparatus comprising cartridge receiving means arranged for receiving at least one cartridge having multiple chambers designed for receiving a plurality of liquid media comprising said sample, labelled binding reagent, magnetic beads reagent and wash buffer, a sample distribution unit arranged for processing pipetting steps with said chambers, thereby providing a liquid reactant mixture in one or more of said chambers, a magnetic coil assembly arranged for applying a magnetic field to said liquid reactant mixture for separating biomarkers bound to said magnetic beads and said labelled binding reagent, from said reactant mixture, a photo detector or assembly arranged for measuring said presence or concentration of said labelled binding reagent, a control unit arranged for controlling said processing pipetting steps with said chambers, and for controlling said sample distribution unit along said chambers according to a test protocol, wherein said test protocol comprises an order of subsequent processing steps performed in said plurality of chambers to be processed by said sample distribution unit, said processing steps comprising one or more processing pipetting steps by the sample distribution unit and one or more processing incubation steps of the reaction mixture within any of the chambers wherein the control unit being programmed for performing multiple, distinct test protocols.

A device for mounting a plurality of actuator modules in a grid pattern to a support frame with support bars is provided. Each actuator module has a regular polygonal basic shape with three, four or six corners. The device comprises a plurality of support brackets mountable to the support bars. Each support bracket is provided with a support structure arranged at a node of the grid pattern and having a cross element adapted to support corner regions of neighboring actuator modules at the node. A transport device comprising a plurality of actuator modules and a device for mounting the plurality of actuator modules in a grid pattern to a support frame is also provided. A laboratory sample distribution system and a laboratory automation system comprising a laboratory sample distribution system are also provided.

Disclosed are mixing apparatus adapted to provide mixing of components in an automated analyzer. The mixing apparatus includes a reservoir configured to contain a coupling liquid, a transducer configured to be driven at a frequency and communicate with the coupling liquid, and a signal generation unit configured to provide a phase modulatable drive signal to the transducer. In some embodiments, improved patient sample and reagent mixing may be provided. Systems and methods are provided, as are other aspects.

A parallel preceding system for processing samples is described. In one embodiment, the parallel processing system includes an instrument interface parallel controller to control a tray motor driving system, a close-loop heater control and detection system, a magnetic particle transfer system, a reagent release system, a reagent pre-mix pumping system and a wash buffer pumping system.

An analysis apparatus includes a first analysis unit which collects samples by utilizing a first nozzle to analyze the sample, a second analysis unit which collects samples by utilizing a second nozzle to analyze the sample, and a transport apparatus which transports a plurality of sample vessels along a predetermined transport route. When a predetermined waiting state is provided such that the transport of the plurality of sample vessels is interrupted or stopped, then the sample collecting position is changed for at least one of the first and second nozzles, and the samples are collected from the plurality of sample vessels by means of the nozzle having the changed position. Accordingly, it is possible to enhance the efficiency of the analysis process performed by the analysis apparatus, while suppressing the transport apparatus from being large-sized and suppressing the structure from being complicated.

An analyzer system for in vitro diagnostics includes a sample handler module having a robot arm that delivers samples from drawers into carriers on a linear synchronous motor automation track. Samples are delivered via the automation track to individual track sections associated with individual analyzer modules. Analyzer modules aspirate sample portions directly from the sample carriers and perform analysis thereon.

Provided is a transport device in which reliability is increased by suppressing deterioration of the transport surface and transport efficiency is increased by suppressing electrical current loss. A transport device 1 comprising a transported body having either a permanent magnet 10 or a magnetic body, and an electromagnet unit in which coils 21 are wound around teeth 25 comprising magnetic bodies, and having recesses on surfaces of the teeth 25 facing the transported body. Specifically, the surfaces of the teeth 25 facing the transported body have at least two surfaces (first facing surface 22, second facing surface 23, etc.) which have different distances to the transported body.

An in-vitro diagnostics system arranged is presented. The system comprises a track, carriers to carry samples with data carriers, and a control station comprising a camera to detect sample images, a data carrier reader, a relocation device to relocate the sample, and a controller. The data carrier reader reads the data carrier through a read-out window. Measurement data indicates data carrier characteristics on a sample in a starting position determined from the camera images. Obscuring data indicates obscuring of part of the data carrier when the images are detected in the starting position. The controller determines, from the measurement data and the obscuring data, characteristics of the data carrier comprising location and size of the data carrier. Based on the data carrier characteristics, the sample is relocated relative to the read-out window from the starting position into a read-out position optimizing visibility of the data carrier through the read-out window.

An automatic analyzer is capable of normally maintaining a device condition and exhibiting a stable performance by automatically monitoring a cleaning implementation situation using a wash rack. The automatic analyzer includes an analysis unit, a rack loading unit into which at least a sample rack that holds the sample and a wash rack that holds a cleaning liquid are loaded. A transportation mechanism transports the sample rack and the wash rack to the analysis unit. A management control unit causes the wash rack to be transported to an analysis unit, causes a cleaning operation of the analysis unit by the cleaning liquid held by the wash rack, and causes stopping of the sample analysis operation of the analysis unit to which the wash rack has been transported until a performance of the analysis unit is determined to be normal based on the cleaning operation.

To minimize cross talk in systems and methods for detecting two or more different optical signals emitted from each of a plurality of reaction receptacles, an excitation signal associated with each of the optical signals has a known excitation frequency, and any detected signal having a frequency that is inconsistent with the excitation frequency is discarded. The receptacles are moved relative to optical sensors configured to detect each unique optical signal from an associated receptacle, and to further minimize cross talk, the optical sensors are arranged so that only one reaction receptacle at a time is in a signal detecting position with respect to one of its associated optical sensors, and the optical sensors are grouped by the optical signal they are configured to detect so that a first optical signal is detected from each of the reaction receptacles before a second optical signal is detected from the reaction receptacles.