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.

The present disclosure relates to blood sample preparation devices and methods. In some embodiments, a method for preparing a blood sample comprises: receiving at a sample preparation machine a sample container containing the blood sample; scanning an identifier of the sample container, the identifier containing information indicative of a characteristic of at least one of the sample container or the blood sample contained therein, actuating, after the scanning, and based on the information, the sample container to repeatedly change a position of the sample container; determining, based on the information, whether the sample container should be centrifuged; and transporting the sample container to a centrifuge to be centrifuged and then to a storage compartment when the determining indicates that the sample container should be centrifuged, and to the storage compartment without entering the centrifuge when the determining indicates that the sample container should not be centrifuged.

An automated pre-analytical processing method and an apparatus for pre-analytical processing of samples to be forwarded to an adjacent analyzer for analysis. Rack label information is read and communicated to a processor. From the rack label information, the processor determines where to route the rack. The pre-analytical system has a rack robot that conveys racks to discrete locations depending upon the routing information assigned to the rack by the processor. The pre-analytical system has an automated station that reads the labels of individual sample containers in the rack that are brought to the automated station on instructions from the processor. Depending on the type of sample container and the type of sample disposed therein, the samples are either prepared for analysis by the automated station or the sample containers are directly passed through the automated station. Prepared samples and passed through samples are passed individually to a batching rack.

A method to localize a carrier on a laboratory transport system is presented. The laboratory transport system comprises a carrier associated with an identity, a multi-lane transport module, and a control unit. The carrier comprises a signal transmitter configured to transmit a signal comprising information about the identity. The multi-lane transport module comprises a transport surface comprising a first and a second transport lane as well as a first signal receiver and a second signal receiver each configured to receive the transmitted signal. Based on received signal strengths, the control unit localizes the carrier on one of the transport lanes of the multi-lane transport module.

Since the measurement start timings for a plurality of specimens in different test fields deviate from one another, the measurement results are not coordinated, leading to a delay in reporting. When determining an order for measuring a newly recognized specimen using an automated analysis device capable of performing measurements in a plurality of test fields, the measurement order for specimens waiting to be measured is changed to minimize the time difference between measurement result output timings for a plurality of specimens for the same patient, with reference to specimen information such as urgent test information, a measurement completion time, and an earliest measurement completion time for other specimens, relating to the patient's other specimens having the same patient number in the specimen information.

A system and method for mounting a section onto a substrate, the system comprising: a fluid channel including: a fluid channel inlet that receives the section, processed from a bulk embedded sample by a sample sectioning module positioned proximal the fluid channel inlet, a section-mounting region downstream of the fluid channel inlet, and a fluid channel outlet downstream of the section-mounting region; a reservoir in fluid communication with the fluid channel outlet; and a manifold, fluidly coupled to the reservoir, that delivers fluid from the reservoir to the fluid channel inlet, thereby transmitting fluid flow that drives delivery of the section from the fluid channel inlet toward the section-mounting region.

A system for tracking one or more subjects for collecting airborne contaminants. The system includes one or more subjects configured to collect air contaminants. Each of the one or more subjects includes an identification tag encoded with identification information identifying the each subject. The system further includes an identification reader configured to decode the identification information encoded within the identification tag of a scanned one of the one or more identification tags. A computer receives and stores the decoded identification information in a record in a database. The computer may also receive and stored an identification code for a user who scanned the scanned identification tag in the record in the database. Additional records in the database are created each time the identification tag of one of the one or more subjects is scanned. The one or more subjects are thereby tracked as they collect airborne contaminants and are incubated.

A system and method for locating sample vessels are presented. The system comprises a holder having an array of positions for holding sample vessels. An information tag is attached to the holder for storing and/or retrieving machine-readable information related to the positions of sample vessels with respect to the array of positions. The system further comprises a handheld device capable of reading information on the information tag. The handheld device has an input for inputting information related to a to-be-located sample vessel and an output for outputting a position of the to-be-located sample vessel with respect to the array of positions based on information stored in the information tag. The method comprises inputting information related to a to-be-located sample vessel into the handheld device, reading information stored in the holder's information tag with the handheld device; and outputting a position of the to-be-located sample vessel.

A sample vessel assembly, comprising a base member including a base flange having first and second opposing surfaces, first and second sides intersecting with one another; and a first sidewall extending from the first surface at a distance from the first and second sides; and a lid member, including: a lid flange having third and fourth opposing surfaces, third and fourth sides intersecting with one another; and a second sidewall extending from the third surface at a distance from the third and fourth sides, the second sidewall engageable with the first sidewall such that the first surface of the base flange and the third surface of the lid flange are in an opposing spaced-apart relationship with one another and such that the first and second sidewalls cooperate with one another to define a sample chamber. Further disclosed is a method for automated analysis of samples in a sample vessel assembly.

Systems, methods, and apparatus are described for the handling of biological specimens for analysis. The systems, methods and apparatus are designed to reduce errors in misidentification, incorrect processing, and recordkeeping and reporting. The systems, methods, and apparatus can also provide real time tracking of samples at any stage, from collection to processing to analyzing to storage.