Abstract: Various embodiments herein disclose a device, comprising one or more fluid interfacing components and a cartridge holder, wherein the one or more fluid interfacing components are fixed while the cartridge holder moves along a linear guide. Also disclosed herein are methods of using the device to analyze a sample containing particles, and methods of diagnosing a disease in a subject by using the device.

Abstract: The present disclosure provided a blood cell analyzer, a control device and a blood analysis method thereof. In the method, a first reagent is mixed with a sample to obtain a first testing sample, and then a second reagent is mixed with the first testing sample for a further reaction to get a second testing sample for basophil classification and/or HGB measurement. A blood sample may be tested in one reaction cell through time-division multiplexing technology to obtain four groups leukocytes classification result and HGB result by single detection channel. Thus, the structure of the analyzer may be greatly simplified on the premise of guaranteeing the performance of the analyzer, the size and cost of the analyzer may reduce and a performance-price ratio of the analyzer may increase.

Abstract: A switch for a conveying line for transporting a laboratory diagnostic vessel carrier is presented. The conveying line comprises a first line portion and a second line portion. The switch comprises a curved first guiding surface and a second guiding surface. The switch is moveable between a first position, in which the laboratory diagnostic vessel carrier is transportable along the curved first guiding surface from the first line portion to the second line portion, and a second position, in which the laboratory diagnostic vessel carrier is further transportable along the second guiding surface on the first line portion. A switch assembly and a conveying line are also disclosed.

Abstract: A method for identifying, analyzing, and quantifying the cellular components of whole blood by means of an automated hematology analyzer and the detection of the light scattered, absorbed, and fluorescently emitted by each cell. More particularly, the aforementioned method involves identifying, analyzing, and quantifying the cellular components of whole blood by means of a light source having a wavelength ranging from about 400 nm to about 450 nm and multiple in-flow optical measurements and staining without the need for lysing red blood cells.

Abstract: Systems and methods for sending scheduling information to a mobile robotic device from an application of a communication device. The application of the communication device generates at least one scheduling command and transmits the at least one scheduling command to a router using a first wireless communication channel. The router is configured to transmit and receive the at least one scheduling command to and from at least one cloud service. A charging station of the robotic device receives the at least one scheduling command from the router using the first wireless communication channel and stores the at least one scheduling command on the charging station. The charging station transmits the at least one scheduling command to a processor of the robotic device using a second wireless communication channel and the processor of the robotic device modifies its scheduling information based on the at least one scheduling command.

Abstract: Systems and methods for refrigerated storage of controls and calibrators utilize a refrigerant storage assembly having an insulated housing and door assembly, thermoelectric coolers, and the refrigerated base assembly having a metal plate thermally coupled to coolers, one or more sensors, and a plurality of receptacles to receive fluid tubes. Refrigerated storage provides a refrigerated environment suitable for multi-day storage of control and calibrator fluids.

Abstract: The disclosure provides example rinse station apparatus, cartridges, and methods for flow cytometry. The rinse station apparatus includes: (a) a cartridge docking station having a base with a recessed receptacle for a cartridge, a vertical support coupled to the base's first end and a top support coupled to the vertical support and cantilevered over the base, the top support has an opening that aligns with the cartridge's opening, (b) a locking arm coupled to the base's second end, the locking arm's free end has a ridge to cooperate with a detent coupled to the cartridge's rear wall to retain the cartridge in place, (c) a spring coupled to the vertical support's front face to apply force to the cartridge's front wall to bias the cartridge toward the locking arm, and (d) a load cell coupled to the base of the cartridge docking station, the load cell measure's the cartridge's weight.

Abstract: A method for performing flexible liquid handling processes among a plurality of consumables includes moving consumables by at least one arm having a magnetic interface device, connecting the at least one arm from the consumables, based on magnetic attraction utilizing said magnetic interface device, and aspirating and dispensing liquids on the consumables by at least one static or quasi-static pipette. The aspiration and dispensing actions are performed without displacement of the pipettes. The method further includes sensing, by the at least one arm, magnetic presence of a matching consumable connector or magnetic vector field modified by a presence of a matching consumable connector. The method includes disconnecting the at least one arm from the consumables based on a repulsive magnetic force.

Abstract: Disclosed are high-throughput vessel supply systems and methods of supplying sample vessels, such as samples stored in test tubes. A system for supplying a plurality of individual vessels that each contains a sample is disclosed.

Abstract: Methods, devices, and systems for analyzing biological samples are provided. A biological sample may be analyzed for the presence of an analyte by an initial assay, and the performance of, or method of performance of, a subsequent assay may be contingent upon the results of the initial assay. For example, the following may be contingent on the results of a prior assay: whether or not a subsequent assay is performed; which subsequent assay is performed; the method of performing a subsequent assay; the order of performance of a sequence of subsequent assays; the steps, or order of steps, performed in a subsequent assay; the timing of the performance of a subsequent assay; the choice of a reagent used in a subsequent assay; the detection method used in a subsequent assay; and other particulars of assays may be contingent on the results of a prior assay.

Abstract: A urine testing device and a smart toilet having the urine testing device, which includes a base, a paper feeding module, a sample adding module, and a testing module installed on the base and arranged in a linear form. The paper feeding module has a test paper box, a lifting mechanism, and a pushing mechanism. A horizontal paper leakage groove is disposed at a bottom of the test paper box to receive a bottommost piece of test paper. The lifting mechanism lifts and descends the test paper box to reveal/seal the paper leakage groove. The pushing mechanism pushes out test paper from the paper leakage groove and delivers test paper to the sample adding and testing modules. The sample adding module dropwise adds urine to be tested on test paper. The testing module tests test paper added with the sample to obtain a urine testing result.

Abstract: A laboratory distribution system is presented. The system comprises diagnostic laboratory container carriers and a conveyor. The conveyor comprises an endless drive defining a closed-loop conveyor pathway. The system comprises supporting elements attached to the endless drive. The supporting elements receive a container carrier and transport the container carrier in an upright position along a pathway section. The supporting elements are mounted pivotally about a horizontal pivot axis to the drive and structured such that a center of gravity of the supporting element with or without an empty or loaded container carrier is arranged below and vertically aligned with the pivot axis when the supporting element is in an upright position such that each supporting element is free to pivot about the associated pivot axis under the effect of gravitational forces acting on the supporting element for maintaining the supporting elements in an upright position while travelling along the path.

Abstract: The invention relates to a device (1) for the automated analysis of solids or fluids. Said device comprises a first station (5) having a metering unit (51) for the filling of at least one sample chamber (2) with a specified sample quantity, a second station (6) having at least one measurement device (61) for an analysis of the sample situated in a sample chamber (2) and a third station (7) having an emptying device and cleaning device (71, 72) for the at least one sample chamber (2). Moreover, there is provided a transport device (3) for a revolving transport of the at least one sample chamber (2) from one station to the next until the first station (5) is reached again. According to the invention, the measurement device (61) of the second station (6) is a spherical measurement system, through the interior of which it is possible to guide the at least one sample chamber (2).

Abstract: The automatic analyzer includes a sample storage section for accommodating a plurality of samples, a reagent storage section for accommodating a plurality of reagents, an analysis section for carrying out an analysis by reacting the sample with the reagent, a display, a storage section for storing a setting of an operation item to be automatically executed, which is effective only at restarting, and a control section which displays a screen for setting the operation item to be automatically executed upon acceptance of power shutdown operation by an operator during the analysis on the display to accept the setting from the operator, and automatically executes or omits execution of the operation item to be automatically executed, which has been set by the operator in accordance with the setting read from the storage section at the restarting.

Abstract: A hematology analyzer is provided. In certain embodiments, the hematology analyzer comprises: a) a flow cell; b) a light source for directing light to the flow cell; c) a plurality of detectors for detecting a plurality of optical characteristics of a blood cell passing through the flow cell; and d) a data analysis workstation programmed to: i. enumerate test blood cells passing through the flow cell; and ii. flag a blood sample as containing lysis-resistant red blood cells or fragile white blood cells.

Abstract: The present invention is directed to a system and method for transferring specimen containers between detection instruments. The method may include transporting a specimen container in a locator well to a container transfer station in a first automated detection apparatus; sensing the specimen container at the container transfer station using a first sensor; transferring the specimen container from the container transfer station of the first automated microbial detection apparatus to an automated loading mechanism of a second automated microbial detection apparatus; detecting that the specimen container is positioned over the automated loading mechanism of the second automated microbial detection apparatus using a second sensor; and releasing the specimen container onto the automated loading mechanism of the second automated microbial detection apparatus.

Abstract: Aspects of the present invention relate to an automated cell culture instrument and to methods for operating such an instrument. In one aspect, the cell culture instrument includes a computing unit and a plurality of electrically controllable resources (e.g., sensors, actuators, etc.). The computing unit receives a protocol, schedules the resources so as to execute the protocol, and operates the resources as scheduled or in response to so as to provide an improved environment for cell culture growth. The computing unit may simulate protocol execution in connection with the scheduling or execution of the protocol.

Abstract: A kit which has a first and second component parts, which are adapted for connection with each other. The first component part has a first array of electrical sensors, two substantially parallel lateral walls on the sides of the electrical connectors, two rails extending along the sides of the array, a front contact point and an overhang for receiving the second part. The second component part has a second array of electrical sensors for connection to the first array, front end configured to fit between the lateral walls of the first connector, and lateral sides having rail reliefs to fit the rails of the first connector. Connection of the first component part and the second component part forms a shoulder that aligns to locate the second array of electrical connectors in correct position for connection to the first array of electrical connectors.

Abstract: An analysis instrument may perform analytical operations on an analyte that is combined with multiple reagents prior to being introduced into a flow cell. The instrument may include a nozzle sipper that aspirates reagents from a recipient, along with an analyte. The reagents may be directed to a volume and may be repeatedly moved into and out of the volume by cycling of a pump. The reagents may be ejected into a destination recipient with the nozzle sipper promoting vorticity in the recipient to enhance mixing. The repeated aspiration and ejection through the nozzle sipper effectively mixes the reagents and the template in an automated or semi-automated fashion.

Abstract: The present invention provides, among other thing, devices and methods for simple, fast, and sensitive assaying, including imaging.

Abstract: An analysis container comprises a main body; a first chamber that is provided inside the main body and holds a liquid sample; a second chamber; a liquid passage; and an air passage. The liquid passage connects the first chamber and the second chamber, and moves the liquid sample from the first chamber to the second chamber. The air flow chamber connects the first chamber and the second chamber, and moves air from the second chamber to the first chamber.

Abstract: A vehicle system provided according to one aspect of the present disclosure includes a power transmitter and a vehicle. The power transmitter is placed at one of at least one charge position. The vehicle includes: a power receiver, a capacitor, and a motor. The power receiver wirelessly receives first electric power from the power transmitter, and outputs second electric power deriving from the first electric power. The capacitor stores the second electric power output by the power receiver such that the capacitor is charged from a first voltage Vc1 to a second voltage Vc2. The motor is driven by the second electric power from the capacitor. The vehicle automatically travels a distance Dx along a route from one to a next one of the at least one charge position on the route. The distance Dx satisfies a certain relationship.

Abstract: An apparatus and a method for the automated processing of samples containing biological cells—in particular, of blood samples or other cell samples is provided. The apparatus has a sample receiving device configured to receive samples, an auxiliary material receiving device configured to receive auxiliary materials, a sample carrier receiving device configured to receive sample carriers, a discharge device configured to discharge samples from a discharge position, and a capture device configured to capture discharged samples in a capture position to obtain prepared samples, and at least one temperature control device for controlling the temperature of at least one of the sample carriers. The distance between the discharge position and the capture position can be adjusted to a prespecified height. The method includes wetting a temperature-controlled sample carrier with at least one auxiliary material and discharging the sample onto the wetted temperature-controlled sample carrier from a prespecified height.

Abstract: An automated system for processing a sample contained in a liquid sample container includes an automated tool head configured to rotate about a first axis, and to translate along a second axis different than the first axis, an analytic element positioner having an analytic element holder configured to releasably grip an analytic element, and a specimen transfer device carried by the tool head, wherein the tool head is configured to automatically position a working end of the specimen transfer device to obtain a specimen from a sample container held in the sample container holder, and to transfer the obtained specimen to an analytic element held by the analytic element holder, respectively, through one or both of rotation of the tool head about the first axis and translation of the tool head along the second axis.

Abstract: Systems, methods, and related technologies are disclosed for multi-device robot control. In one implementation, input(s) are received and provided to a personal assistant or another application or service. In response, command(s) directed to an external device are received, e.g., from the personal assistant. Based on the command(s), a robot is maneuvered in relation to a location associated with the external device. Transmission of instruction(s) from the robot to the external device is initiated.

Abstract: An apparatus for processing biological sample is provided, which comprises a semi-permeable membrane column, an adaptor column and a vacuum manifold. The at least one semi-permeable membrane column is configured for accommodating biological sample therein and comprises a curved surface. The at least one adaptor column is configured for accommodating the semi-permeable membrane column therein and comprises a stopping element. The vacuum manifold is configured for creating a vacuum that facilitates flowing of the biological sample into the semi-permeable membrane column through a semi-permeable membrane therein. The stopping element abuts against the curved surface.

Abstract: A metrology system is provided with a transparent workpiece surface mode, for which the system is configured to vary a focus position over a plurality of positions along a Z height direction proximate to a workpiece. An image stack is acquired, wherein each image of the image stack includes a first surface (e.g., an upper surface of the workpiece) that is transparent or semi-transparent and at least a second surface that is at least partially viewable through the first surface. A plurality of focus curves are determined based on the image stack (e.g., with pattern projection utilized for improved contrast), from which first, second, etc. local focus peaks may be determined from each focus curve that correspond to the first, second, etc. surfaces, respectively. An image is displayed (e.g., extended depth of field, 3D) including a selected surface and for which features of the selected/displayed surface may be measured.

Abstract: A system, method, and apparatus are provided for flow cytometry. In one example, the flow cytometry system includes dual laser devices and dual scatter channels to measure velocity of particles in a core stream of sample fluid. The total flow rate of the sample fluid and the sheath fluid around the sample fluid is controlled, and thus held constant, by a feedback control system controlling a vacuum pump based on differential pressure across ends of a flow channel in the flow cell. A stepper flow control valves are disclosed that apply a physical fluid resistance to a flow of sheath fluid in the flow cytometer. The physical fluid resistance regulates a flow rate of the sheath fluid and thereby regulates a flow rate of sample fluid in the flow cytometer.

Abstract: Disclosed is a station, for testing an analyte in a sample, enabling accurate and quick reaction and analysis of the sample and a reagent in one apparatus. To this end, the present disclosure provides a station, which is for testing a sample by means of inserting a cuvette, having a standby chamber on which a collecting member is placed, a sample chamber, a reagent chamber and a detection unit. The station comprises: a housing which has an input/output part into which a cuvette is inserted; a driving unit which is provided inside the housing, horizontally moves the cuvette, vertically moves a collecting member, reacts a sample in a sample chamber and a reagent in a reagent chamber, and injects a reaction result thereof into a detection unit; and an optical reader which is provided on the horizontal movement path of the cuvette and is for analyzing the reaction result.

Abstract: A rack includes a container holder that is fixed to a stage and holds a container that contains a liquid to be dispensed and a camera that is fixed to the stage and located in a position where the camera is capable of capturing an image of the container.

Abstract: The invention relates to flexible PCM sheet materials having a high latent thermal energy storage density for the purpose of heat management. The flexible PCM sheet material includes a flexible supporting structure and phase-change-material elements arranged thereon separately in a specific geometry. The phase-change-material elements are geometrically defined structures composed of polymer-bound phase-change material. The flexible PCM sheet materials are characterized by a high latent heat storage capacity and optimized thermal conductivity, are dimensionally stable even in the event of temperature changes and after phase transitions, can be rolled, folded, wound, or cut to size without problems, and can be transported, stored, processed, or used in a single layer or in multiple layers.

Abstract: Provided in part herein are static-defeating apparatus for use in multipipettor systems. Multiple pipette tips can be retained by a static-defeating sheet of material. A multipipettor, having multiple pipettes or nozzles, can engage the pipette tips retained by the sheet. After use, the multipipettor can eject the pipette tips, which sometimes are ejected as a single unit due to the pipette tips being retained by the sheet. In certain embodiments, an apparatus includes a snap plate having one or more holes, and a base rack for ease of mounting.

Abstract: A sample heating device includes: a rail-shaped disposal rail extending in one direction in a horizontal plane so that sample boats after heating are arranged and placed in a straight line; a disposal tray that houses the sample boat pushed-out from one end of the disposal rail; a sample boat conveying portion that places the sample boat after the heating at a predetermined placing position on the disposal rail; and a sample boat push-out portion that is positioned closer to the other end side of the disposal rail than the placing position when the sample boat is placed on the disposal rail and that is displaced toward the one end side of the disposal rail after the sample boat is placed at the placing position to slide the sample boats on the disposal rail toward the one end side.

Abstract: The present invention relates to a robot comprising a horizontal or horizontally slanted transparent experiment layer being adapted to support items at arbitrary positions on or in the experiment layer, and a moveable sensor arranged below the transparent experimental layer said sensor being configured for providing a sensor signal indicative of item(s)' location on the experiment layer, an actuator arranged for being moved into different positions above the horizontal transparent layer a display device being configured for visually representing located item(s) a user input device configured for receiving information as to operation of the actuator.

Abstract: An automatic tissue staining device includes a supply head that supplies a treatment fluid, a horizontal direction movement unit that moves the supply head in a horizontal direction, and a holding unit that holds a plurality of glass slides on which samples are set. The automatic tissue staining device further includes a control unit that judges an occupancy status of the horizontal direction movement unit in a condition that one or more of the glass slides are situated in a first region prior to supplying the treatment fluid from the supply head to one or more samples in the first region, suspends a start of a treatment for the samples in the first region when the horizontal direction movement unit is occupied, and permits the treatment for the samples in the first region when the horizontal direction movement unit is not occupied.

Abstract: According to an aspect, a fixing structure includes: a supporting plate; a substrate arranged on a first surface of the supporting plate, the substrate including a component that is arranged on a surface opposite to the supporting plate and projects toward opposite to the supporting plate; a male screw that is fixed to the supporting plate so that a first end projects from the first surface to pass through the substrate, and a second end opposite to the first end does not project from a second surface opposite to the first surface of the supporting plate; and a female screw that is screwed with the first end of the male screw projecting from the substrate.

Abstract: The present disclosure provides methods, device, assemblies, and systems for dispensing and visualizing single cells. For example, provided herein are systems and methods for dispensing a dispense volume into a plurality of wells of a multi-well device, where, on average, a pre-determined number of cells (e.g., 1-20) are present in the dispense volume, and determining, via a cellular label, the number of cells present in each of the plurality of wells. Such dispensing and cell detection may be repeated a number of times with respect to wells identified as having less than the pre-determined number of cells in order increase the number wells in the multi-well device containing the desired number (e.g., a single cell).

Abstract: Systems and methods are provided for sample processing. A device may be provided, capable of receiving the sample, and performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing multiple assays. The device may comprise one or more modules that may be capable of performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing the steps using a small volume of sample.

Abstract: The present invention relates to an leucocyte antigen mediated microfluidic assay and a microfluidic device for analyzing a subjects' body fluids containing leucocytes to determine if the subject has been previously exposed to a predetermined antigen.

Abstract: Disclosed is a reaction vessel handling apparatus adapted for use in a biological fluid testing apparatus. The reaction vessel handling apparatus includes an incubation member and wash member that are overlapping. A transfer device transfers reaction vessels between the incubation member and wash member at the overlapping portions. Incubation and wash members may be rings. Testing apparatus (e.g., immunoassay apparatus or clinical analyzer apparatus) including the reaction vessel handling apparatus and methods of operating the apparatus are provided, as are other aspects.

Abstract: An examination container includes a main body, a membrane assembly and a cover. The main body has an accommodating trough for holding sample. The membrane assembly covers an opening end of the accommodating trough. The membrane assembly includes a support body and a membrane. The support body has a first surface and a second surface, wherein the support body is flat and has a first through-hole penetrating through the first surface and the second surface. The membrane is arranged on the second surface side of the support body and has a second through-hole. The second through-hole is opposite to the first through-hole and allows a charged particle beam to pass the second through-hole. The cover is detachably connected to the main body to secure the membrane assembly. The membrane assembly is easy to replace and uses less consumables. An electron microscope using the abovementioned examination container is also disclosed.

Abstract: The present invention relates to systems and methods of determining quality compliance for a set of biological sample testing devices used with one or more test instruments at the point-of-care in a hospital or other location that delivers medical care. In particular, the systems and methods ensure that only biological sample testing devices that pass a quality assurance protocol are used for point-of-care testing.

Abstract: Systems and methods are provided for sample processing. A device may be provided, capable of receiving the sample, and performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing multiple assays. The device may comprise one or more modules that may be capable of performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing the steps using a small volume of sample.

Abstract: The system for management of rack and tube positions for clinical chemistry laboratories includes tubes (10) capable of containing human biological material, a rack (20) configured for receiving and/or holding the tubes (10) to be stocked, a supporting base (30) configured for supporting the rack (20) thereon, a reader (50) configured for reading an identifier (RID) of the rack (20) to be put onto the supporting base (30) and an identifier (TID) of the tube to be put into the rack (20), a camera (40) for detecting the rack (20) on the supporting base (30), and at least one of the tubes (10) into the rack (20), a processing unit (60) for mapping the detected rack (20) into a plurality of allowed positions (Pi) and the detected tube (10) into a tube position (P) included in the plurality of allowed positions (Pi).

Abstract: A nucleic acid amplifier comprises a holder 3 which is provided with a plurality of temperature control blocks 10 each designed to hold at least one reaction vessel 105 storing a reaction solution. The temperature of the reaction solution in each reaction vessel 105 is controlled individually by using temperature control devices 14 and 15 arranged in each of the temperature control blocks 10. The temperature that is set in each temperature control block 10 and the timing for temperature changes are controlled independently of the temperatures of other temperature control blocks 10. This configuration makes it possible to provide a nucleic acid amplifier and a nucleic acid inspection device (employing the nucleic acid amplifier) capable of processing multiple types of samples differing in the protocol in parallel (parallel processing) and starting a process for a different sample even when there is a process in execution.

Abstract: A sample storage including a frame and an array of sample container holding areas disposed within the frame where a spacing between adjacent sample container holding areas is independent of a gripping area for sample containers held by the sample storage.

Abstract: The invention is in the field of automatic analysis devices and relates to a heatable pipetting device for an automatic analysis device and a method for providing a reaction mixture. The pipetting device comprises a pipetting needle having two temperature sensors at different distances to the tip of the pipetting needle.

Abstract: Provided is a cell suction system that supports suction work of a substance within a cell. The cell suction system includes: a suction section including a tubular tip configured to suction the substance from the inside of the cell received in a container; a detection section configured to acquire information on a front end part of the tip; and a conveyance section configured to make the suction section three-dimensionally movable, the conveyance section being configured to move the suction section to guide the front end part of the tip attached to the suction section into one specific cell based on the information obtained in the detection section.

Abstract: The present invention is directed to a system and method for transferring specimen containers between detection instruments. The method may include transporting a specimen container in a locator well to a container transfer station in a first automated detection apparatus; sensing the specimen container at the container transfer station using a first sensor; transferring the specimen container from the container transfer station of the first automated microbial detection apparatus to an automated loading mechanism of a second automated microbial detection apparatus; detecting that the specimen container is positioned over the automated loading mechanism of the second automated microbial detection apparatus using a second sensor; and releasing the specimen container onto the automated loading mechanism of the second automated microbial detection apparatus.

Abstract: The invention relates to a configuration control device for a laboratory instrument, a laboratory instrument with a configuration control device for instrument-controlled treatment of at least one laboratory sample and a method for configuring the laboratory instrument by means of the configuration control device. By using user-dependent configuration data, the requirement for the user of having to perform a completely manual configuration of the laboratory instrument, which is effected by the user-dependent configuration data, is dispensed with.