A multi-sample container disposal module is provided with a discharging mechanism comprising a storage box, the storage box being internally provided with a storage space, wherein the storage space is divided into a first storage cavity and a second storage cavity via a partition plate in the storage space; a transition mechanism, two ends of which are respectively a receiving end and a discharging end, wherein the receiving end is provided with a receiving rack and the discharging end is provided with a rotating structure and a discharging plate, and a driving structure is arranged between the receiving rack and the rotating structure; and a printing mechanism located above the transition mechanism, wherein the printing mechanism comprises a laser head, and a position of an emission light source of the laser source corresponds to a position of the rotating structure up and down.

Freshly obtained blood samples are deposited into a device that contains blood sample carriers, each of the carriers is designed to hold a fixed amount of blood and allow excess blood sample to flow through and be discarded. A desiccant within the blood sample carrier aids with the drying of the blood and the discarding of the excess sample blood. The device is stored/transported within a modified atmosphere package comprised of an impermeable sealable bag and an oxygen scavenger compound for removing oxygen from the bag.

The present invention relates to a device adapted to facilitate transport of a biopsy sample from a sterile extraction site to laboratory-type equipment by which the biopsy sample is processed, while maintaining the biopsy sample wetted and sterile and automatically transferring the biopsy sample from the device to the laboratory-type equipment.

A method of obtaining and analyzing at least one tissue sample includes forming, in a tissue container, first tracking data associated with the at least one tissue sample. Second tracking data is formed, in a transport container. The second tracking data is associated with the at least one tissue sample. The at least one tissue sample is placed in the tissue container. The first and second tracking data from the tissue container and the transport container are scanned with an electronic scanning system to ensure that the first and second tracking data are both associated with the removed tissue sample.

A tissue sample that has been removed from a subject can be properly fixed for evaluation using the disclosed transporter assembly for carrying a tissue sample and method for fixing an unfixed tissue sample. In one embodiment, the disclosed assembly includes a transport container, a fixative in the transport container, and a cooling device that reduces and/or maintains the temperature of the fixative to perform a pre-soaking process at a temperature of less than about 7° C. The pre-soaking process can, for example, be performed during sample transport or during extended periods of storage, such as over a weekend.

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.

A module for an automated laboratory system is disclosed. The module comprises a module connector configured to releasably connect to a component of the automated laboratory system, a detector at least configured to detect at least one component marker located at the component so as to obtain position data of the module indicating an actual position of the module, a processor configured to calculate a position deviation of the module from a target position defined by the component based on the position data and to calculate position alignment data based on the position deviation, and a alignment device configured to align the module to the target position based on the position alignment data. Further, an automated laboratory system and a method for aligning a module are disclosed.

Provided are methods, devices, and systems for a loop-mediated isothermal amplification (LAMP) reactions for detecting the presence of genetic material. A LAMP device includes an enclosure having outer walls configured to define an internal space. The LAMP device also includes a tray assembly configured to support a reaction vessel configured for holding a sample for amplification. The LAMP device also includes a plurality of light emitters configured to illuminate the reaction vessel for exciting a fluorescence of the sample in the reaction vessel. The LAMP device also includes an imaging device configured to obtain an image of the sample for determining a quantity of the fluorescence in the sample. The LAMP device also includes a controller configured to regulate a temperature of the tray assembly and instruct the imaging device to obtain the image for determining the quantity of the fluorescence in the sample.

A biological analysis system comprising at least one inlet and one outlet, at least two biological analysis devices connected to one another by a conveyor defining a closed circuit, each biological analysis device comprising a region for the exchange of tube holding racks with the conveyor. The conveyor and the at least one inlet of the biological analysis system comprise a reader of an identifier of a tube holding rack which reader is designed to communicate an identifier it has read to a controller of the biological analysis system, which controller is designed to apply a specific treatment to a tube holding rack identified by the reader of the conveyor and the identifier of which has not previously been read by the reader of the at least one inlet of the biological analysis system.

An analyte identifying and sorting apparatus for sorting a target analyte based on an identification result of analytes dispersed in a liquid. The apparatus includes an identification unit including an analyte storage section configured to store analytes dispersed in a liquid, a pressure control section configured to feed the liquid to a flow path provided to extend downward from the analyte storage section, a light irradiation section configured to irradiate light to the analytes, an optical information measurement section measuring optical information of the analytes, and a determination section determining whether the analyte is a target analyte or a non-target analyte based on the optical information. Also included is a sorting unit that includes a sorting nozzle connected to the identification unit and sorts a sorted solution containing the target analyte to the vessel, an effluent collection section having a suction nozzle to suck and collect an effluent involving an effluent discharged from a tip of the sorting nozzle, and a collection vessel configured to collect the sorted solution containing the target analyte. A moving unit moves the sorting nozzle and/or the collection vessel, a control unit moves the sorting nozzle and/or the collection vessel based on the optical information, and a stirring unit including a stirring member in an inner space of the analyte storage section.