The present invention provides an automatic blood-sampling tube preparation system which can reduce the reading mistake of the information of the RFID tags by selectively taking out a blood-sampling tube required to an examination of a patient according to a doctor's instruction information from the blood-sampling tube containing section, writing the patient examination information on a RFID tag of the taken out tube on the basis of the instruction information, reading simultaneously all patient examination information from all RFID tags contained in the prepared container for every patient, and comparing the information read from the RFID tags with the instruction information to ensure accuracy.

An automation system for an in vitro diagnostics environment includes a plurality of intelligent carriers that include onboard processing and navigation capabilities. A central scheduler can communicate wirelessly with the carriers to direct the carriers to carry a fluid sample to testing stations along a track within the automation system. The carriers can utilize landmarks and distance encoding to reach destinations accurately and quickly, including, for example within less than the time for a single operation cycle of an automated clinical analyzer. The distance encoding can include optical marks repeated at regular intervals (pitch), where the intervals are conveyed to the carriers wirelessly or via optical encoding. The pitch of the encoding can differ for different sections of track depending on the position precision desired.

A printer for printing on histology-laboratory consumable articles (16) includes a control apparatus (8), which is configured to receive analog or digital image signals of a target impression image pattern, and an optical reading apparatus (13). The optical reading apparatus (13) reads an impression (18) printed on a histology-laboratory consumable article (16) by the printing device (4), generates analog or digital impression image signals relating to the impression (18) that has been read, and transfers the impression image signals to the control apparatus (8). The control apparatus (8) evaluates the impression image signals received from the optical reading apparatus (13) by comparing them with the analog or digital image signals of the target impression image pattern and determines at least one quality parameter relating to the impression (18).

A laboratory automated system can include a host conveyor assembly configured to transport a plurality of carriers and receptacles coupled thereto between at least a sample processing instrument and at least one assay instrument. The system includes an intermediate conveyor assembly configured to transport a plurality of carriers and receptacles coupled thereto from within sample processing instrument to the host conveyor assembly. The system also includes an intermediate conveyor assembly for each assay instrument configured to transport a plurality of carriers from host conveyor assembly to a respective processing position within the assay instrument. The intermediate conveyor assembly coupled to the assay instrument can include a buffer conveyor subassembly configured to receive carriers from the host conveyor assembly, and a spur conveyor assembly configured to transport a carrier to the processing position of the assay instrument.

The present disclosure relates to a cleaning device and a chemiluminescence detector. A cleaning device is provided with a cup inlet station and a cup outlet station, wherein the cleaning device comprises a pedestal, a plurality of magnetic adsorption components, a turntable arranged on the pedestal, and a primary cleaning mechanism arranged on the pedestal, wherein each of the plurality of magnetic adsorption components comprises a plurality of magnets; magnetic adsorption heights of a plurality of magnets of the first magnetic adsorption component are equal and are recorded as A; magnetic adsorption heights of a plurality of magnets of the middle magnetic adsorption component are equal and are recorded as B, and B>A.

A laboratory automation system for processing sample containers containing laboratory samples and/or for processing the samples is presented. The laboratory automation system comprises a digital camera configured to take an image of the sample container together with a calibration element. The image comprises image data related to the sample container and image data related to the calibration element. The laboratory automation system also comprises an image processing device configured to determine geometrical properties of the sample container depending on the image data related to the sample container and the image data related to the calibration element.

An automatic analyzer with high processing capacity is capable of immediately measuring an emergency specimen rack. The automatic analyzer includes a conveying line for conveying a specimen rack, and an analysis unit which has a dispensing line in which a plurality of specimen racks are arranged for waiting until sample dispensing, and a sampling area for dispensing the sample to the analysis unit. A rack save area is provided in the dispensing line and at a position adjacent to the upstream side of the sampling area. When a specimen rack exists in the sampling area at the time of measuring an emergency specimen rack, a controller moves the specimen rack to the save area and positions the emergency specimen rack to be moved from a downstream side of the sampling area to the sampling area.

An apparatus including a receptacle including a slot for receiving a basket; a push bar disposed in the receptacle, the push bar having an end to contact an edge of a single slide of a plurality of slides in a basket, the push bar including a first position below a bottom surface of a base of a basket that is received in the slot and a second position in the slot; and a sensor focused in a direction of the slot operable to acquire information from a slide in a received basket. A method including placing a slide basket into a slot of a receptacle; individually raising one or more slides from a respective position in the basket; using a sensor, acquiring information from the raised slide in the basket; and after acquiring information, lowering the raised slide.

A method of reading machine-readable marks on a movable support and object of a sample instrument. The method includes capturing a first image of the moveable support as the moveable support moves from a first position to a second position using an image capture device; determining whether a first fiducial machine-readable mark on the moveable support is in the first image; determining, when the first fiducial machine-readable mark is in the first image, whether a first machine-readable mark on a first object coupled to the moveable support is in the first image at a predetermined position relative to the first fiducial machine-readable mark; and associating information decoded from the first machine-readable mark on the first object with a first location on the moveable support associated with the first fiducial machine-readable mark.

Method and associated system for reading machine-readable labels on a plurality of sample receptacles held by a sample rack. In the method, a machine-readable label associated each of the plurality of sample receptacles is read with a first label reader when the rack is at a first location. The sample rack is then moved from the first location to a second location, where a rack identifier on the sample rack is sensed with a sensor separate from the first label reader. Finally, the rack identifier is associated with the machine-readable labels of the plurality of sample receptacles.