A device and method for delivering a laboratory sample carrier from a stack of sample carriers includes providing a retaining mechanism that retains the stack of laboratory sample carriers, and an ejector mechanism including a displaceable mechanism comprising a carrier support portion and a carrier transporting portion which are hingeably interconnected. The stack is supported by the carrier transporting portion and the carrier transporting portion is supported by a carrier transporting portion support of the ejector mechanism when the displaceable mechanism is in a first carrier receiving position and configuration. The displaceable mechanism is displaced from the first carrier receiving position and configuration to a second carrier release position and configuration by a further displacement mechanism of the ejector mechanism. This involves moving a lowermost carrier from the bottom of the stack in a carrier accommodating region of the carrier transporting portion as the displaceable mechanism is displaced from the first carrier receiving position and configuration. The displaceable mechanism is displaced such that the carrier transporting portion moves past the carrier transporting portion support and drops so that the displaceable mechanism adopts the second carrier release position and configuration and the carrier in the carrier accommodating region is released. The stack is supported with the carrier support portion when the displaceable mechanism is in the second carrier release position and configuration.

The present disclosure relates to systems and methods for tracking and printing within a histology system. In some embodiments, a system is provided that includes an information reader configured to read identifying data associated with a tissue block, a microtome configured to cut one or more tissue sections from the tissue block, one or more slides for receiving the one or more tissue sections, and a printer configured to receive the identifying data and print, after the one or more tissue sections are cut from the tissue block, one or more labels for the one or more slides, the one or more labels comprising information associating the one more tissue sections on the one or more slides with the tissue block.

Disclosed is a fluid collection device wherein multiple, individual samples of fluid can be collected simultaneously. The device includes a chamber and an adapter which substantially and simultaneously distributes the blood to individual chambers with chamber specific additives. Also included is a system for using the blood collection device, preferably within a diagnostic testing laboratory.

A printing module configured to print a label on a curved surface of an article includes an expandable printing mechanism configured to be expanded to an open configuration for receiving the article or contracted to a closed configuration placing the curved surface in an operative position with respect to a print head and an article moving assembly configured to grasp and hold the article and effect relative movement between the curved surface and the print head. The printing mechanism includes contact elements, such as rollers, that contact or otherwise engage the article when the printing mechanism is in the closed configuration and maintain the curved surface in the operative position with respect to the print head during relative movement between the curved surface and the print head.

A printer for printing on histology-laboratory consumable articles (16) includes an optical reading device (13), which reads an image pattern of a histology-laboratory consumable article (16) to be printed on by means of the printing device (4), generates analog or digital image-pattern image signals with regard to the read image pattern and transfers the image-pattern image signals to a control device (8) of the printer, and/or which reads an overprint (18) printed onto a histology-laboratory consumable article (16) by the printing device (4), generates analog or digital overprint image signals with regard to the read overprint (18) and transfers the overprint image signals to a control device (8) of the printer, which control device determines at least one quality parameter with regard to the overprint (18).

A system and method of automatically preparing and analyzing urine samples for identifying cancer cells is able to complete conventional diagnostic tasks without lab technicians, cytopathologists, or other medical professionals. The method is provided with at least one source sample, at least one manipulator arm, at least one centrifuge, at least one electronic microscope, and at least one unitary controller. The method is further provided with a cytopathological index containing a visual characteristic database and identification confidence threshold rubrics supporting the automation of visual analyses typically performed manually with a conventional microscope. This method is further provided with a data processing function, wherein data stemming from multiple testing cycles may be collated, formatted, and presented for use by medical professionals in determining and projecting the effectiveness of a course of treatment.

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).

An example system may be used to automate one or more processes relating to drill cutting handling, cleaning, and packing to produce consistently high-quality cleaned samples. In some implementations, an example system may employ cleaning processes including centrifugal and ultrasonic processes to clean a sample automatically without the aid of a human operator thereby increasing efficiency and quality of the produced samples for better subsequent sample analysis. A system may include an unloading module, a cleaning module, and packing module, all of which may be operated in combination with a robotic arm.

A blood-sampling-tube automatic preparation device comprising a blood-sampling-tube containing section having at least two blood-sampling-tube containers, a label printing and pasting unit that prints blood sampling information data and then pastes the printed label on a surface of a blood-sampling-tube, a hand pasting label printer, a blood-sampling-tube collecting section in which one or more blood-sampling-tubes with label pasted and/or one or more printed labels for hand pasting are collected for each patient, a blood-sampling-tube transferring device that receives a blood-sampling-tube from the blood-sampling-tube container and transfers it to the label printing and pasting unit, and a control device that controls each component. All blood-sampling-tube containers of the blood-sampling-tube containing section are arranged in a row on a same horizontal surface and the blood-sampling-tube transferring device, the label printing and pasting unit, and the hand pasting label printer are arranged to be mutually superposed under the blood-sampling-tube containing section.

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.