Abstract: A method of tube slot localization is provided using a tray coordinate system and a camera coordinate system. The method includes receiving, a series of images from at least one camera of a tray comprising tube slots arranged in a matrix of rows and columns. Each tube slot is configured to receive a sample tube. The method also includes automatically detecting fiducial markers disposed on cross sectional areas between the tube slots on the tray and receiving an encoder value indicating when each row of the tray is substantially at the center of the camera's field of view. The method further includes determining calibration information to provide mapping of locations from the tray coordinate system to locations from the camera coordinate system and automatically aligning the tray based on the encoder value and calibration information.

Abstract: Embodiments provide a method of using image-based tube top circle detection based on multiple candidate selection to localize the tube top circle region in input images. According to embodiments provided herein, the multi-candidate selection enhances the robustness of tube circle detection by making use of multiple views of the same tube to improve the robustness of tube top circle detection. With multiple candidates extracted from images under different viewpoints of the same tube, the multi-candidate selection algorithm selects an optimal combination among the candidates and provides more precise measurement of tube characteristics. This information is invaluable in an IVD environment in which a sample handler is processing the tubes and moving the tubes to analyzers for testing and analysis.

Abstract: The invention relates to a gas in/outlet-adapter system for a container/rack assembly for a diagnostic robot comprising: —a receptacle (15) comprising a gas-inlet wherein the receptacle (15) is attached to a container (12), —a nozzle (16) comprising a gas-outlet wherein the nozzle (16) is attached to a rack to supply the container (12) via the receptacle (15) with a gas at a defined pressure level, wherein the receptacle (12) —provides one opening (24) —which provides for a fluidic contact to the interior of the container (12) —and a second opening (25) —which provides for a gas leak-proof connection to the nozzle (16) on the rack when the receptacle (15) is placed over the nozzle (16), and wherein the nozzle (16) —provides one opening (26)—which provides for a fluidic contact to a tubing system of the rack—and a second opening (27)—which provides for a fluidic contact to the nozzle (16) when the receptacle (15) is placed to cover the nozzle (15).

Abstract: Zwitterion-containing compounds for the modification of hydrophobic molecules to improve their solubility and/or to lower their non-specific binding as provided. The zwitterion-containing compounds may be suitable for modification of detectable labels such as biotin and fluorescein to improve their solubility. The zwitterion-containing compounds may also be useful for the preparation of conjugates of proteins, peptides and other macromolecules or for crosslinking molecules and/or macromolecules.

Abstract: Methods and reagents are disclosed for minimizing a false result in an assay measurement for determining a concentration of an analyte in a sample suspected of containing the analyte. The method comprises pretreating both an antibody and a sample to be subjected to a non-agglutination immunoassay. In the method the antibody and the sample are combined with a pretreatment agent selected from the group consisting of hydroxyphenyl-substituted C1-C5 carboxylic acids and metallic salts thereof and halogen-substituted C1-C5 carboxylic acids and metallic salts thereof in an amount effective to enhance the accuracy of the non-agglutination immunoassay.

Abstract: Systems and methods for use in an in vitro diagnostics setting may include an automation track, a plurality of carriers configured to carry a plurality of sample vessels along the automation track, and a characterization station including a plurality of optical devices. A processor, in communication with the characterization station, can be configured to analyze images to automatically characterize physical attributes related to each carrier and/or sample vessel. A method may include receiving a plurality of images from a plurality of optical devices of a characterization station, wherein the plurality of images comprise images from a plurality of perspectives of a sample vessel being transported by a carrier, automatically analyzing the plurality of images, using a processor, to determine certain characteristics of the sample vessel, and automatically associating the characteristics of the sample vessel with the carrier in a database.

Abstract: A method for analyzing digital holographic microscopy (DHM) data for hematology applications includes receiving a DHM image acquired using a digital holographic microscopy system and identifying one or more erythrocytes in the DHM image. For each respective erythrocyte included in the one or more erythrocytes, a cell thickness value for the respective erythrocyte using a parametric model is estimated, and a cell volume value is calculated for the respective erythrocyte using the cell thickness value.

Abstract: Methods and apparatus configured and adapted to provide less carryover in an automated clinical analyzer are disclosed. The methods include immersing a pipette into a neutralizing liquid vessel and aspirating a neutralizing liquid (e.g., a hypochlorite solution) into an interior of a pipette. The aspirated portion of the neutralizing liquid used to cleanse the pipette interior is then dispensed back into the neutralizing liquid vessel, rather than disposing of the used neutralizing liquid to a waste station. Apparatus and systems configured to carry out the methods are provided, as are other aspects.

Abstract: A method and a device for determining the concentration of an analyte in whole blood is disclosed. In one embodiment, the method includes generating a plasma layer in the whole blood sample. Furthermore, the method includes exposing the plasma layer to light. The method also includes capturing light reflected from the plasma layer. Additionally, the method includes analyzing the reflected light to determine the concentration of the analyte.

Abstract: In vitro diagnostic sensors are disclosed that include membranes formed of a polymer matrix that has been modified to contain surface adhesion functional group(s) that enables attachment of the membrane to a substrate of the sensor. Also disclosed are membranes of these sensors as well as multi-sensor arrays that include multiple sensors. In addition, methods of producing and using these membranes, sensors, and arrays are disclosed.

Abstract: Devices, kits, and methods related to embodiments of an improved liquid test sample injection device for use in diagnostic assays and for the collection of liquid waste produced from such diagnostic assays.

Abstract: A sensor assembly has a substrate with a first surface and a second surface opposite the first surface, at least one analyte sensor positioned on at least one of the first surface and the second surface of the substrate, and at least one electrical contact positioned on the substrate in electrical communication with a corresponding one of the at least one analyte sensor. The substrate is configured to define a tube having an interior surface, and an exterior surface. At least a portion of the first surface of the substrate defines the interior surface of the tube, and the at least one analyte sensor is disposed on at least one of the interior surface and the exterior surface of the tube.

Abstract: The timing of the reaction of moisture-sensitive reagents for detecting the presence of analytes, e.g. leukocytes in urine samples, is used to detect when the reagents have been compromised by excess humidity. The ratio of light reflectance at wavelengths characteristic of the products of reaction between the reagents and the analyte and an infra-red reference dye is measured at two preset times after a urine sample has been applied to a test strip and used to determine whether the reagents have been compromised by excessive humidity. The presence of unusually dark samples is determined from the reflected light at 470 and 625 nm in order to confirm that the test strips are humidity-compromised.

Abstract: The present invention relates to a device comprising a container having an inner wall and at least one opening, containing a mixture containing at least one reagent, and at least one additive, a method of producing this device, and a method of extracting a substance from a sample, enriching a substance in a sample, and/or detecting a substance in a sample using the device.

Abstract: Disclosed herein is a method of enabling supervision of a laboratory environment utilizing diagnostic equipment. The method includes utilization of a device for capturing an optical image of at least a portion of the laboratory environment. The method further requires selectively capturing the optical image using the image capture device and selectively transmitting the captured image over a communications medium. The method further requires receiving the transmitted optical image by an image receiver in communication with the image transmission device via the communications medium. The method then requires selectively generating, by an image processor in communication with the image receiver, a display of at least a portion of the captured optical image on an image display device and receiving status information from the diagnostic equipment at a laboratory manager that is in communication with multitude of diagnostic equipment.

Abstract: The invention relates to a container for a rack of a diagnostic robot comprising: —a container body comprising a sidewall or multiple sidewalls, a bottom and a top wherein the container body is of round, oval, square, rectangular, hexagonal or polygonal cross sectional shape, —the top is provided with an opening that matches the size and form of a filter membrane/supporting body of an object carrier which is placed over the opening in the top of the container for filtration of a sample, wherein the opening exhibits a rim and —the top is provided with a top-guiding-means which matches with a corresponding object-carrier-guiding-means on or in the object carrier so that the object carrier locks with a predetermined surface faced up into a predetermined position on the top and —the container is equipped with an adapter which matches a gas outlet on the rack.

Abstract: Hydrophilic, high quantum yield, chemiluminescent acridinium compounds with increased light output, improved stability, fast light emission and decreased non specific binding are disclosed. The chemiluminescent acridinium esters possess hydrophilic, branched, electron-donating functional groups at the C2 and/or C7 positions of the acridinium nucleus.

Abstract: A location based dynamic information provision system integrates operator positional awareness within a laboratory environment with a laboratory environment asset site map. At least one operator proximity metric, defining a distance threshold for establishing whether an operator within the laboratory is proximate to a respective asset, is defined for each asset. Operator detection and position is provided by an indoor positioning system. A signaling device associated with each operator is in communication with a laboratory process management platform for receiving operator information contingent upon the respective operator being within the proximity metric for a respective laboratory asset and the asset having communicated status of a given urgency to the process management platform. The signaling device may enable the operator to communicate with the process management platform and may provide a tactile or other attention attracting signal to the operator.

Abstract: A characterization apparatus including pattern generation. The characterization apparatus is configured to characterize a specimen and or a specimen container in some embodiments. The characterization apparatus includes an imaging location configured to receive a specimen container containing a specimen, one or more image capture devices located at one or more viewpoints adjacent to the imaging location, and one or more light panel assemblies including pattern generation capability located adjacent to the imaging location and configured to provide back lighting. Methods of imaging a specimen and/or specimen container using the pattern generation are described herein, as are other aspects.

Abstract: A nephelometry system for an automatic analysis device may include a light source, a stop, and a photodetector on the one hand and a receptacle position on the other hand that are movable relative to one another in order to improve the measurement quality of a nephelometry system. The nephelometry system may determine a location of an interval I of recorded light intensity signals which only contains light intensity signals that emerge from a scattered portion of a light beam after passing through a measurement cell placed into the nephelometry system. Methods of nephelometric determination of an analyte are also provided, as are other aspects.