A laboratory sample distribution system is presented. The laboratory sample distribution system comprises a number of container carriers. The container carriers each comprise at least one magnetically active device such as, for example, at least one permanent magnet, and carry a sample container. The system further comprises a transport plane to carry the container carriers and a number of electro-magnetic actuators being stationary arranged below the transport plane. The electro-magnetic actuators move a container carrier on top of the transport plane by applying a magnetic force to the container carrier.

A laboratory sample distribution system is presented. The laboratory sample distribution system comprises a number of container carriers. The container carriers each comprise at least one magnetically active device such as, for example, at least one permanent magnet, and carry a sample container. The system further comprises a transport plane to carry the container carriers and a number of electro-magnetic actuators being stationary arranged below the transport plane. The electro-magnetic actuators move a container carrier on top of the transport plane by applying a magnetic force to the container carrier.

A sample tube rack for receiving at least one sample tube comprises an upper part comprising an upper surface, wherein at least one upper opening for receiving the sample tube is provided in the upper surface; an intermediate part comprising an intermediate surface, wherein at least one intermediate opening for receiving the sample tube is provided in the intermediate surface; and a lower part comprising a supporting surface, wherein at least one supporting position for supporting the sample tube is provided in the supporting surface. Therein, the intermediate part is connected to both the upper part and the lower part such that the at least one upper opening is substantially aligned above the at least one intermediate opening and above the at least one supporting position for receiving the at least one sample tube. At least one gripping orifice is provided in a lateral side of the lower part.

Systems and methods are provided for measuring and tracking radio-frequency (RFID) tags. Inlay data, converting data, and tag scan data can be received from entities in the supply chain and stored in a database. The tag scan data, including measurement and performance data, can be stored and used for applications such as determining whether RFID tags are defective. The tag scan data, inlay data, and converting data can be analyzed to produce analytic data for reporting and failure prediction purposes. Inlay-SKU combinations of RFID tags can be validated to ensure that the correct inlays are being utilized for RFID tags intended for particular products. More accurate inventory data may be obtained and costs for re-tagging products that have defective RFID tags may be reduced. Entities in the supply chain can also be assisted to comply with various quality control, licensing, and tracking requirements related to the RFID tags.

A laboratory sample distribution system and a laboratory automation system comprising such a laboratory sample distribution system are presented. The laboratory sample distribution system comprises a number of sample container carriers adapted to move autonomously and to communicate with each other and with a central control unit.

Disclosed is a sample processing apparatus that comprises a rack with positions to hold sample tubes, the rack including a rack identification suited to a kind of sample tube, a rack set unit that accepts the rack in a detachable manner, a tube transfer unit with mechanical movement to grab and take out each sample tube from a rack held in the rack set unit, a rack detector comprising a sensor to detect the rack identification of the rack held in the rack set unit, and a controller that controls movement of the tube transfer unit based on a detection result of the rack detector.

An automation system for an in vitro diagnostics environment includes a plurality of intelligent carriers that include onboard processing and navigation capabilities. The intelligent carriers can include one or more image sensors to observe the relative motion of the track as the carrier traverses it. The carriers can also observe position marks on the track surface to provide absolute position information, which can include additional data, such as routing instructions. Synchronization marks may be provided to correct errors in the observed trajectory.

A sample-containing device configured to be placed into a sample processing instrument for performing a process on a sample contained in the device includes redundant identification features, such as machine-readable tags. A first machine-readable information tag is read before the device is placed in the instrument, and a second machine-readable information tag is read after the device is in the instrument. Information read from the two tags is compared to determine if there is proper correspondence between the information read from the tags to ensure that the correct sample processing device was placed in the instrument.

Tissue sample cassettes for receiving tissue samples include an upper tray including compartments separated by dividers, a lower tray coupled to the upper tray and having a central recess, and an absorbent material located in the recess of the lower tray. Related systems and methods for automated gross processing of tissue samples are also disclosed.

A reagent container carrier structure for holding at least one reagent container, wherein the carrier structure has thereon an RFID assembly and an optically detectable definition pattern defining an orientation of the carrier structure, is disclosed. The reagent container carrier structure may have an orientation identification label that has a front surface and a back surface, and further include an RFID assembly positioned on the back surface, and an optically detectable definition pattern defining an orientation of the label on the front surface. A reader module for reading RFID data in combination with optically detectable data defining an orientation of a respective label is also disclosed.