Measuring apparatus (1) for tracking human and/or animal tissues comprising: a working area (2) for receiving a tissue; a detecting unit (5) configured to detect a unique tissue code provided with the tissue placed on the working area (2); a measuring unit (9) configured to automatically measure quantitative properties of the tissue placed on the working area (2); and a processing and storing unit (22) configured to automatically link the quantitative properties with the tissue code and to automatically store the so linked quantitative properties and tissue code such that the quantitative properties can be retrieved based on the tissue code.

An automatic analyzer can be miniaturized as a whole and can accurately determine presence or absence of a sample container and a type thereof. The automatic analyzer of includes a conveyance line for conveying a loaded sample container; an identification information reading device that reads identification information attached to the sample container; and a container height detection device. The identification information reading device and the container height detection device perform reading and detection when the sample container is at a common position on the conveyance line. The container height detection device includes sensors having different height ranges for a detection target, a part of the sensors being disposed on the same side as the identification information reading device with respect to the conveyance line, and the rest of the sensors being disposed on the opposite side of the identification information reading device with respect to the conveyance line.

A sample analyzer and a method for obtaining reagent information are disclosed, wherein the sample analyzer analyzes a sample by using a reagent contained in a reagent container, comprising a first reagent container holder configured to hold a first reagent container containing a first reagent, a first electronic tag, on which a reagent information regarding the first reagent is recorded, attached to the first reagent container; a second reagent container holder configured to hold a second reagent container containing a second reagent, a second electronic tag, on which a reagent information regarding the second reagent is recorded, attached to the second reagent container; an antenna that is arranged between the first reagent container holder and the second reagent container holder, and is configured to receive a radio wave from each of the first and second electronic tags; and a reagent information obtainer unit configured to obtain the reagent information recorded on the first electronic tag based on a radio wave received from the first electronic tag, and to obtain the reagent information recorded on the second electronic tag based on a radio wave received from the second electronic tag.

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.

In order to easily identify a specimen to be extracted because, for example, an item remains uninspected, from a rack 31 collected in a storage part 13 or the rack 31 taken out from the storage part, a camera of a smart device takes an image of the rack; and a calculation unit included in the smart device provides a mark, by AR technology, at the position of a specimen to be extracted. For example, the item that remains uninspected is identified on the basis of information about a combination of a rack ID and an identifier and information, which is received from an operation unit about specimens at respective positions. Thus, irrespective of a place or whether the specimen to be extracted is inside or outside of the device, the specimen to be extracted can be reliably specified from a plurality of specimen containers provided on a holder.

Measuring apparatus (1) for tracking human and/or animal tissues comprising: a working area (2) for receiving a tissue; a detecting unit (5) configured to detect a unique tissue code provided with the tissue placed on the working area (2); a measuring unit (9) configured to automatically measure quantitative properties of the tissue placed on the working area (2); and a processing and storing unit (22) configured to automatically link the quantitative properties with the tissue code and to automatically store the so linked quantitative properties and tissue code such that the quantitative properties can be retrieved based on the tissue code.

A method for handling a sample tube containing a biological sample is presented. A tube label can be attached to the sample tube. The tube label can carry tube data. The tube data can comprise at least geometric tube data descriptive of at least one geometric property of the sample tube. At least the geometric tube data can be read from the tube label by a reader device. At least the geometric tube data from the reader device can be transmitted to a processing device. The processing device for handling the sample tube can be controlled in accordance with the at least one geometric property described by the read geometric data.

An apparatus for spectroscopic analysis of vinificition liquids features a sample holder for a sample container of vinification liquid, a light source for directing a beam of light into the sample supported by the sample holder, a spectrometer arranged for receiving and measuring the beam of light after interaction thereof with the sample in order to perform a spectroscopic scan of the sample and generate measured spectral data thereon, and a scanning device positioned for scanning a machine readable code on the sample container. A computing device in communication with the spectrometer and the scanning device applies a classification to the measured spectral data of the sample according to a classification code read from the sample container. The classification code is used to determine what parameters should be calculated from the spectral data for the particular sample in question.

Conventional laboratory tests require calibration before each test. This results in the need for a reagent for calibration before each test. Additionally, calibration takes a long time, and the total TAT (Turn Around Time) of a testing system increases. The testing system thus suffers from the difficulty of improving the testing efficiency. This invention, which has been made to solve the problem, provides a testing element for performing a laboratory test, wherein the testing element includes an information recording section at the surface of and/or inside the testing element, and the information recording section stores information on a characteristic of the testing element.

A method for handling a sample tube containing a biological sample is presented. A tube label can be attached to the sample tube. The tube label can carry tube data. The tube data can comprise at least geometric tube data descriptive of at least one geometric property of the sample tube. At least the geometric tube data can be read from the tube label by a reader device. At least the geometric tube data from the reader device can be transmitted to a processing device. The processing device for handling the sample tube can be controlled in accordance with the at least one geometric property described by the read geometric data.