Abstract: A device for handling laboratory plates comprising a base platform and opposing gripping members including one or more gripping members each pivotally attached to a first side of the base platform and one or more gripping members each pivotally attached to a second side of the base platform, wherein said gripping members extend down from the base platform and include a gripping tip disposed at the end of the gripping member, and methods of using the same.

Abstract: An automated analyzer includes a reagent dispensing probe that dispenses a reagent to a reaction vessel, a sample dispensing probe that dispenses a sample to the reaction vessel, a stirring rod that stirs a sample and a reagent in the reaction vessel, and a storage unit that stores special washing information including information about a condition for performing special washing to prevent sample carryover and a washing method. The automated analyzer further includes: a determination unit that determines whether the special washing is required based on information about the sample dispensed by the sample dispensing probe and the special washing information; and a controller that causes the reagent dispensing probe to dispense a wash liquid to the reaction vessel and causes the stirring rod to stir the wash liquid in the reaction vessel based on the special washing information, when the special washing is performed.

Abstract: When washing the inside of a reactor vessel which is used repeatedly, a rough suction is performed before suctioning with a washing tip; however, unwanted washing liquid may remain that may affect analysis results. The present invention provides an automatic analysis device for analyzing a sample using light, in which the automatic analysis device is characterized in that: a washing mechanism comprises a washing liquid supply nozzle that supplies washing liquid to a reactor vessel after analysis, a washing liquid suction nozzle that suctions the supplied washing liquid, a washing tip provided to the bottom end of the washing liquid suction nozzle, and a rough suction nozzle that suctions, in advance, a liquid within the reactor vessel before suctioning with the washing tip; and after the rough suction, liquid is caused to remain so that the bottom surface of the reactor vessel is not exposed.

Abstract: A measurement portion includes a containment unit including a plurality of containers containing a liquid, a dispensing unit including a dispensing probe for dispensing the liquid, and a gauging portion for gauging the liquid dispensed by the dispensing unit. An excessive immersion determination portion determines whether an immersion of the dispensing probe is excessive immersion that exceeds a predetermined range. An input portion can select and set an operation of the measurement portion to be performed after the excessive immersion determination portion determines that the immersion is excessive immersion from a plurality of modes. A measurement control portion controls the measurement portion depending on a mode set by the input portion.

Abstract: The present invention provides: a drawer that is supported so as to be horizontally movable in the front-rear direction between an open position and a closed position through a front-face opening; a table that allows an expendable or a processing unit used for analysis to be mounted in the drawer; and a moving-direction transforming means that, while the drawer is moved toward the rear side from the open position to the closed position, moves horizontally until the expendable or the processing unit mounted on the table passes through the front-face opening from the front side to the rear side and moves the table toward the upper side in synchronization with the horizontal movement of the drawer toward the rear side after the expendable or the processing unit mounted on the table passes through the front-face opening. This makes it possible to easily and reliably perform the work of replacing a chip rack.

Abstract: Provided in part herein are pipette tip rack assemblies having one or more of the following features: (i) having a plurality of pipette tip receptacle plates, each plate having an array of pipette tips, stacked upon one another supported by a rack base; (ii) each plate having one or more projections from the proximal or distal surface and, optionally, orifices that oppose the projections of the next plate in the stack, and (iii) the rack base having a proximal surface with one or more orifices or projections that oppose the projections or orifices of the plate in the stack. Also provided are methods of dispensing pipette tips from pipette tip rack assemblies and manufacturing pipette tip rack assembly components.

Abstract: Systems and methods for calibrating laboratory instruments. In an example, a laboratory instrument for testing patient specimens includes a testing apparatus configured to receive a cassette that includes a patient specimen or a quality control specimen. In response to determining that a quality control specimen is present, the instrument obtains a first measurement of a parameter. If the first parameter is outside an expected tolerance, the instrument ceases performing tests on all specimens, the instrument re-tests the quality control specimen to obtain a second measurement of the parameter. If the second measurement is within the expected tolerance, instrument resumes processing of the cassette. If the second measurement is outside the expected tolerance, the instrument indicates that recalibration or service is required.

Abstract: A dispersant system comprises a plurality of taggant vessels, each having a taggant that corresponds to a position in a tag string and a computer controller convert the tag string into a selection of a taggant set while computer-controlled valves allow or block a flow of taggants to a manifold output tube. From the output tube, a mix of the taggants flow to form a dispersant formed according to the tag string. A nozzle disperses the dispersant onto an object to be tagged, possibly atomized with air. The taggant can comprise a DNA taggant comprising a static portion and a dynamic portion that is unique to each tag string position. Tag strings for adjacent lots might have a low Hamming distances to reduce cross-contamination and/or have redundancy for error detection and correction and selected so that consumption of taggants evens out over the plurality of taggant vessels.

Abstract: In a pre-processing system, a state in which a sample dispensing probe 20a and a syringe pump 81 communicate with each other through a channel 91 and a state in which the sample dispensing probe 20a and a culture tank 301 communicate with each other through the channels 91, 93, and 94 can be switched by operation of the three-way valves 82 and 83. For this reason, the liquid sample in the culture tank 301 can be automatically discharged from the sample dispensing probe 20a without requiring the user to directly sample the liquid sample. As a result, in the pre-processing system, the user's manual sampling work can be omitted, and the user's work can be simplified.

Abstract: An automatic analyzer includes: a specimen holding unit configured to hold a specimen container in which a specimen is stored; a dispensed container holding unit configured to hold a plurality of dispensed containers; a dispensing probe configured to separate a predetermined amount of the specimen from the specimen container, and configured to dispense the specimen into the dispensed container; a probe washing device configured to wash a leading end of the dispensing probe in a washing liquid; and a controller configured to control driving of the dispensing probe. The controller includes an arithmetic processing unit configured to calculate a concentration of the specimen in the specimen container. The specimen is subject to dilution with the washing liquid adhered to the leading end of the dispensing probe in the probe washing device. The arithmetic processing unit sets a maximum number of times for dispensing the specimen, based on the concentration.

Abstract: The objective of the present disclosure is to provide a technique for reducing a quantity of magnetic particles remaining on a reaction vessel wall surface in a cleaning step for reducing, in a stepwise manner, an amount of a magnetic particle solution in the reaction vessel. The automated analysis device according to the present disclosure causes an agitating mechanism to operate in such a way that a magnetic substance remaining on the wall surface of the vessel in the previous cleaning step is captured by a cleaning solution in the next cleaning step.

Abstract: Provided is an automatic analyzer that can perform a reagent preparation/disposal operation comfortably and smoothly as when printing a reagent list such as a reagent preparation/disposal list on paper even without printing the reagent list. The automatic analyzer that performs analysis using a sample and a reagent, the automatic analyzer including: a storage unit that stores reagent information related to a reagent remaining amount or a reagent expiration date of each of reagent containers; and a display unit that displays a reagent list in which reminder information that gives a reminder to an operator is assigned to each of setting positions of the reagent containers based on the reagent information stored in the storage unit. The reagent managing unit updates display of the reagent list such that a reagent container selected by the operator is visually identifiable while the reagent list is displayed.

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: Described is an automated analyzer capable of effectively cleaning a dispensing probe without using a sweeping cleaning member. The automated analyzer includes: a receptacle holding portion for holding a plurality of receptacles in which aliquots of liquid are stored, an immersion cleaning solution holding portion for storing an immersion cleaning solution, an aliquot dispenser equipped with a drive mechanism for holding a dispensing probe operative to collect the aliquots of liquid from the receptacles, a measurement controller for controlling the drive mechanism and the dispensing probe such that the aliquots of liquid are successively collected at given cycles from the receptacles, and an immersion cleaning controller for controlling the drive mechanism and the dispensing probe such that an immersion cleaning operation is carried out for an immersion time that is at least twice as long as the period of each of the given cycles.

Abstract: This automated analysis device is provided with a plurality of analysis units for analyzing a specimen, a buffer portion which holds a plurality of specimen racks on which are placed specimen containers holding the specimen, a sampler portion which conveys the specimen racks held in the buffer portion to the analysis units, and a control portion which, when performing a process to deliver the specimen racks to the plurality of analysis units, outputs synchronization signals to all the plurality of analysis units, wherein the analysis unit performs a delivery process starting from the synchronization signal, and the analysis unit performs a delivery process starting from the synchronization signal.

Abstract: A portable detector is disclosed for detecting certain analytes of interest, such as genetic material (e.g., nucleic acids). The detector includes a reading component for the detection of the analytes, and control circuitry for controlling operation of the reading component. Processing circuitry may be included to perform both primary analysis of acquired data, and where desired, secondary analysis. Where desired, some or all of the computationally intensive tasks may be off-loaded to enhance the portability and speed of the device. The device may incorporate various types of interface, technologies for reading and analysis, positioning system interfaces, and so forth. A number of exemplary use cases and methods are also disclosed.

Abstract: A biological sample reaction vessel comprising a reagent storage portion and a push rod movable relative to the reagent storage portion is provided. The reagent storage portion comprises at least one reagent containing cavity, and the reagent containing cavity is sealed by a sealing element; and the push rod is connected to the sealing element, and the push rod is used for cooperation with an external device to separate the sealing element from the reagent storage portion. In reaction, the biological sample reaction vessel cooperates with a test cassette. By inserting the biological sample reaction vessel into the external device, the reagent in the reagent storage portion can be released rapidly.

Abstract: The present invention relates to a horizontal-flow-type apparatus for automatically transporting reagent cartridges. The apparatus includes: a magazine (110) in which a plurality of reagent cartridges (1) is stacked; a conveyer belt (120) having a plurality of separating projections (121) arranged in a conveying direction to horizontally separately convey the reagent cartridges (1); a driving motor (130) for driving the conveyer belt (120); a feeding unit (140) for feeding the reagent cartridges (1) stacked in the magazine (110) onto the conveyer belt (120); an examining unit (150) disposed over the front end of the conveyer belt (120) to examine the reagent cartridges (1); and reagent cartridge aligning members (161, 162) disposed in the conveying line of the conveyer belt (120), opposite to the examining unit (150), to align the reagent cartridges (1) in position.

Abstract: The present patent of invention relates to a reader device for biological samples used in the field of remote laboratory tests (TLR), for clinical diagnostic purposes, based on an optimized design constituted by a cowling (C) with inlet port (OE) and with switch (I); by a holding support (SS) containing a mirror (ES), two batteries (BT), two reading illumination arrays (BIL), operational status illumination arrays (BIS) and an elevator support (SE); by an elevator (EL); by an electronics board (PE) with energy loading circuit (PE-1), with supply circuit (PE-2), with processor (PE-3), with Bluetooth® device (PE-4) and with position sensor (PE-5); and by a base (BA) with software that reads various types of biological samples, the present invention providing the advantages of: ease of use, optimized operating flows, ease of training, modularity, compactness, reduced size, portability, lightness of weight, ergonomic design, used-friendliness, enhanced practically and low cost.

Abstract: A method of controlling a needle actuator to interact with a cell is provided, the method comprising: providing an actuator comprising a tower, a stage and a needle, wherein the needle is mounted on the stage; applying an electrostatic potential between the tower and the stage to retract the needle; moving the actuator towards the cell; reducing the potential so as to allow the stage and needle to move towards the cell; applying calibration data to detect when the needle has pierced the cell; and reducing the potential further once it has been detected that the needle has pierced the cell. The cell can be a biological cell. The needle can be a micro-needle and the stage can be a micro-stage.