A method for sorting and/or treating containers includes the steps of: recording at least one image and/or a video of a plurality of containers by an image recording device, which is configured for recording spatially resolved color images; analyzing the at least one recorded image; identifying the individual containers; assigning an identification information and at least one portion of the recorded image to each of the identified containers; and ascertaining a color information, which is characteristic of an identified container, from the portion of the recorded image.

A sample identification system for an automated sampling and dispensing device is described. In an example implementation, the sample identification system includes a sample probe configured to contact a sample positioned within a sample vessel. Further, the sample identification system includes an identifier capture device configured to measure a sample identifier associated with the sample vessel and generate a data signal in response thereto, where the data signal corresponds to an identity of the at least one sample. During operation, the identifier capture device scans a sample holder, a sample vessel, or a table top of the automated sampling and dispensing device to measure the sample identifier and to generate the data signal in response thereto.

The present invention generally relates to the determination of an analyte concentration (quantitative determination) or whether an analyte threshold level has been passed (qualitative determination) in a biological sample through employment of a disposable analytical microprocessor device. The device can include a batch-specific, self-executable algorithm for the calculation of the analyte concentration.

The present invention provides devices and systems for use at the point of care. The methods devices of the invention are directed toward automatic detection of analytes in a bodily fluid. The components of the device are modular to allow for flexibility and robustness of use with the disclosed methods for a variety of medical applications.

The present invention provides devices and systems for use at the point of care. The methods devices of the invention are directed toward automatic detection of analytes in a bodily fluid. The components of the device are modular to allow for flexibility and robustness of use with the disclosed methods for a variety of medical applications.

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.

Tissue sample management systems include a central network, a medical professional system, and a pathology lab system for processing a tissue sample in a matrix having a sectionable code. At least the pathology lab system includes at least one imaging device, and the central network is configured to process images from the at least one imaging device to identify and record at least the sectionable code of the matrix. Methods for tissue sample processing include providing a matrix having a sectionable code and measurement marks, the matrix for receiving a tissue sample, and identifying the sectionable code from an image taken of the tissue sample in the matrix. Tissue sample-receiving matrices include a sectionable alphanumeric code or bar code, a tissue sample receptacle, and measurement marks formed along a sidewall thereof. The matrices include one or more proteins and one or more lipids.

Provided is an automatic analyser capable of switching an apparatus operation mode, such as automatic reexamination, without stopping measurement by efficiently using a rack. The automatic analyser includes a storage unit that stores an operation mode, such as automatic reexamination, of the automatic analyser, a detection unit that detects an operation mode switching rack inserted into an insertion unit, and a control unit that switches the operation mode stored in the storage unit on the basis of the detection of the operation mode switching rack by the detection unit. The control unit applies the switched operation mode to an examination object rack transported from the insertion unit to a transport line after the operation mode switching rack.

An automated system for handling core samples in and out of an imaging device retrieves the samples from a staging area. During handling, the identity of each core sample is known to the system so that the imaging results are correlated appropriately. The system positions the core sample so the vertical and slab side orientations of the core sample discernable during handling. Core samples are staged in a location, and the automated system includes a robotic arm, which senses the core sample to discern its vertical and slab slot orientations, and then loads the core sample into the imaging device. When imaging is complete, the automated system removes the core sample from the imaging device; and in designated circumstances, transfers the core sample to a location for further analysis. In one example the further analysis is based on analyzing areas of interest identified in the core sample.

A robotic system is provided for accurately and quickly sorting sample tubes within or between sample tube racks.