Abstract: A sensor array is disclosed. The sensor array includes a fluid inlet, a fluid outlet, a flow path extending between the fluid inlet and the fluid outlet; and at least one optimization sensor positioned outside of the flow path of the sensor array and configured to provide at least one performance parameter of the sensor array. The at least one performance parameter having performance data of the sensor array.

Abstract: A reagent analyzer having a circuit board, an imaging system and a processor is disclosed. The circuit board has a substrate, and a plurality of conductive leads. The substrate has a first and a second major surface. The first major surface is opposite the second major surface. The substrate has an opening extending between the first major surface and the second major surface. The reagent analyzer also includes an imaging system having a field of view extending through the opening formed in the substrate and configured to capture an image of a wet reagent test device positioned at a read position in the field of view, the image having a plurality of pixels. The processor is configured to receive the image, and to analyze pixels of the image to determine a presence or an absence of a target constituent being in a sample applied to the wet reagent pad.

Abstract: A reagent analyzer comprising an imaging system having a first field of view of a reagent test device and a second field of view of a fluid sample information indicator, and configured to capture a first image depicting the reagent test device and a second image depicting the information indicator; a mirror moveable between a first position outside the first field of view and a second position inside the first field of view and located between the imaging system and the reagent test device, the mirror in the second position reflecting light to produce the second field of view; and a processor executing instructions to: receive the first and second images; analyze the first image to determine calibration information from the information indicator; and analyze the second image to determine constituent presence/absence in the fluid sample applied to the reagent test device, using, in part, the determined calibration information.

Abstract: Methods of visualizing sample status within a diagnostic laboratory system are provided. The methods include displaying on a display screen, a visual image representing a layout of a plurality of laboratory analyzers included within the diagnostic laboratory system, and further to display on the visual image, for a particular selected sample scheduled for testing, status indicators located proximate to the visual images of the analyzers on which the tests are scheduled. The status indicators denote: the testing is completed on one or more analyzers (processed), the testing is currently being conducted on one or more analyzers (current), or the testing has not yet been received on the one or more analyzers (to do). Systems including such sample status indicators are provided as are other aspects.

Abstract: Methods of controlling diagnostic laboratory systems include providing one or more modules, each of the one or more modules configured to process a specimen container and/or analyze a specimen; providing middleware configured to communicate with the one or more modules, wherein the middleware is configured to generate instructions to change an operational state of at least one of the one or more modules to enabled or disabled; generating, by the middleware, one or more instructions to change the operational state of at least one of the one or more modules; and changing the operational state of at least one of the one or more modules in response to one or more instructions generated by the middleware. Systems including a middleware server configured to carry out the methods are provided as are other aspects.

Abstract: Disclosed are internal electrolyte layers for ion selective electrodes, wherein the internal electrolyte layers contain carbon paste doped with a metal salt. Also disclosed are ion selective electrodes and sensor array assemblies containing the internal electrolyte layers. Also disclosed are methods of producing and using the internal electrolyte layers, ion selective electrodes, and sensor array assemblies.

Abstract: A fluid analyzer for analyzing fluid samples comprising one or more analytes and a method of calibrating such. The fluid analyzer includes a control system to control at least one automated valve to pass at least three calibration reagents through a fluid channel to a secondary ion selective electrode, a primary ion selective electrode, and a reference electrode, and determine calibration information using calibration logic from signals generated by a meter, control the at least one automated valve to selectively pass different subsets of the at least three calibration reagents through the fluid channel to the secondary ion selective electrode, the primary ion selective electrode, and the reference electrode, and determine re-calibration information using the signals generated by the meter and at least one of the calibration information and re-calibration logic.

Abstract: An apparatus, vortex generator assembly and method for automated cell lysis and nucleic acid purification and processing. The vortex generator assembly includes sample holder having a lysis well, at least one wash well, and an elution well. The vortex generator assembly also includes a sample holder cover having a plurality of vibration rods for creating a vortex in the wells of the sample holder. The apparatus includes motor operating a rotating cam to cause the vibration rods to vibrate and create the vortex in a well holding fluid and magnetic beads, wherein the vortexing speed is sufficient to overcome the magnetic attraction between the beads and disperse the beads in solution, to collect nucleic acids such as DNA.

Abstract: Absorbance spectroscopy methods and systems are disclosed including a spectroscopy analyzer, comprising: an optical element device positioned to receive an analysis light that passes through a sample of a fluid specimen from an illumination unit, the analysis light including first light in a first light range and second light in a second light range different than the first light range, the optical element device comprising: a housing assembly that defines an internal space; and a dichroic mirror-reflector within the internal space positioned to receive the analysis light, the dichroic mirror-reflector configured to filter the analysis light such that a first portion of the analysis light in the first light range is reflected off the dichroic mirror-reflector as a spectrometer light, and such that a second portion of the analysis light in the second light range passes through the dichroic mirror-reflector as a detector light.

Abstract: A method of characterizing a serum or plasma portion of a specimen in a specimen container includes capturing a plurality of images of the specimen container from multiple viewpoints, stacking the multiple viewpoint images along a channel dimension into a single stacked input, and processing the stacked input with a single deep convolutional neural network (SDNN). The SDNN includes a segmentation convolutional neural network that receives the stacked input and outputs multiple label maps simultaneously. The SDNN also includes a classification convolutional neural network that processes the multiple label maps and outputs an HILN determination (Hemolysis, Icterus, and/or Lipemia, or Normal) of the serum or plasma portion of the specimen. Quality check modules and testing apparatus configured to carry out the method are also described, as are other aspects.

Abstract: Methods of visualizing performance of a diagnostic laboratory system are provided. The methods include displaying on a display, an image representing a layout of a plurality of laboratory analyzers included within the diagnostic laboratory system, and overlaying the image with a dynamically-changeable color overlay that indicates a performance for the plurality of laboratory analyzers over a period of time via using changeable colors. Systems including color-changeable overlays are provided as are other aspects.

Abstract: There is provided a chloride selective membrane including an epoxide-based matrix reacted with a stoichiometric amount of an amino compound and an activator such that the epoxide-based matrix comprises a number of quaternary ammonium groups.

Abstract: An embodiment is a sample rack system. The sample rack system comprises a rack having a base, a top opposite the base along a vertical direction, a receptacle that extends from the top toward the base along the vertical direction, and a receiver element proximate the top. The receptacle is sized to receive a sample collection unit. The system also includes a retention clip for holding the sample collection unit in the receptacle. The retention clip includes an engagement head for attachment to the receiver element of the rack. The engagement head defines an outer surface. The retention clip also includes a curved tail that extends from the engagement head and contacts the sample collection unit when the sample collection unit is placed in the receptacle. The outer surface of the retention clip does not project outwardly from the rack when the retention clip is attached to the rack.

Abstract: An apparatus, a method and a device for calibrating the apparatus is disclosed. The apparatus comprises one or more light sources, at least one image acquisition device for acquiring images; and a device. The device comprises a processing unit, a memory coupled to the processing unit. The memory comprising a calibration module configured to obtain a value of current flowing through each of one or more light sources in real-time, compare the value of current flowing through each of the one or more light sources with a predefined threshold current value, and calibrate color gain value associated with at least one image acquisition device, if the determined value of current for each of the one or more light sources is above the predefined threshold current value.

Abstract: A method of detecting a level of a liquid in a well of a container. The method includes looking up an expected liquid level of the liquid in the well of a container; measuring and recording a measured liquid level of the liquid in the well; changing a level of the liquid in the well based upon an expected amount of the liquid to be added or removed; and calculating a next expected liquid level at least in part based on multi-point filtering. Apparatus for carrying out the method are provided, as are other aspects.

Abstract: Methods of troubleshooting non-event malfunctions. The methods include providing a database including pre-populated non-event issues and associated corrective actions, inputting search criteria regarding a particular non-event issue via entry of a search string at the user interface, parsing and normalizing the search string into a meta-data schema to produce a normalized search string, searching the database with the normalized search string to generate a listing of one or more particular corrective actions, and receiving the listing of one or more particular corrective actions that are associated with the normalized search string. Apparatus configured to carry out the methods are provided, as are other aspects.

Abstract: An embodiment is a sample analysis system for analyzing a sample that includes at least one test device for analyzing the sample. The system also includes a rack handler operable to move a sample from a first location to a second location along a travel path. The rack handler has a rotation assembly including a) an engagement element for engagement with the sample rack, and b) a motor coupled to the engagement element and is operable to cause rotation of the engagement element. The rotation assembly rotates the sample rack from a first orientation into a second orientation along the travel path when the engagement element engages the sample rack.

Abstract: Multi-use biosensors are disclosed that include enzymes that have been modified to reduce the solubility thereof; the multi-use biosensors are used to detect analytes in fluidic biological samples, and the biosensors also maintain their enzyme activity after many uses. Multi-sensor arrays are disclosed that include multiple biosensors. Also disclosed are methods of producing and using these devices.

Abstract: Systems and methods for use in an in vitro diagnostics setting incorporating existing or additional sensors in an automation system to assess the health and maintenance status of the automation system are disclosed. Such systems include any of a variety of sensors, such as Hall Effect sensors, temperature probes/thermocouples, ohm meters, volt meters, etc., which are in communication with a local or preferably remote monitoring station that can alert a user or maintenance personnel of needed service.