A detection device using a lateral flow strip for detection and a detection method thereof are provided, which relates to the technical field of a detection device using a lateral flow strip. An upper rotor, a middle rotor and a lower rotor are respectively provided with upper paddle(s), middle paddle(s) and lower paddle(s) along respective circumferential directions. Each upper paddle is provided with a test tube with openings at both ends thereof for placing the lateral flow strip. The middle paddle blocks a bottom one of the openings of the test tube. Each lower paddle is provided with a sample tube for placing sample solution. The bottom opening of the test tube is opposite to a top opening of the sample tube up and down.

Disclosed herein is an apparatus for facilitating chemical analysis based on color principle. Accordingly, the apparatus may include a base located at the bottom of the apparatus. Further, the base may be composed of a rectilinear receptacle. Further, the apparatus may include an intermediate plate located above the base. Further, the apparatus may include a hood located atop the intermediate plate. Further, the hood may include a hood rectilinear receptacle. Further, the hood rectilinear receptacle may be secured to the intermediate plate using a fastening mechanism. Further, the apparatus may include a roundtable housed within the hood. Further, the apparatus may include a motion system passing through and engaging with the roundtable and the hood. Further, the apparatus may include an analysis system embedded into at least one board suspended within the base. Further, the analysis system facilitates automated chemical analysis of a plurality of extraneous vials.

The present invention comprises: an ISE measurement unit 32 that measures the electrolyte concentration of a sample; a spectrophotometer 14 that measures biochemical parameters of a sample; a pH measurement mechanism 34 that measures the pH of a sample; sample dispensing mechanisms 21, 22 that dispense the sample for measurement in the ISE measurement unit 32 or the spectrophotometer 14 from a container that contains the sample; and a conveyance mechanism 27 that conveys the container. The conveyance mechanism 27, the sample dispensing mechanisms 21, 22, and the pH measurement mechanism 34 are disposed such that the dispensing of the sample by the pH measurement mechanism 34 for pH measurement, or pH measurement, is performed after the dispensing of the sample by the sample dispensing mechanisms 21, 22.

The present invention reduces the turnaround time of an automated analyzer. During a period when cyclic measurement by a measurement unit is unnecessary, a controller washes a reaction vessel using a washing cycle having a cycle time shorter than that of an analysis cycle. A single analysis cycle and a single washing cycle both include a reaction disc stopping period and rotation period. In the washing cycle, there is no time during the stopping period when a sample dispensing mechanism, reagent dispensing mechanism, or stirring mechanism operates but there is a time when a washing mechanism operates. The washing cycle stopping period is shorter than the analysis cycle stopping period. The amount of rotation of the reaction disk in the analysis cycle rotation period is the same as the amount of rotation of the reaction disk in the washing cycle rotation period.

One embodiment of the invention is directed to a sample processing system for analyzing a biological sample from a patient. The sample processing system comprises: a plurality of analyzers comprising at least one mass spectrometer, wherein each analyzer in the plurality of analyzers is configured to acquire at least one measurement value corresponding to at least one characteristic of the biological sample; at least one data storage component which stores (i) a list of parameters for the plurality of analyzers, and (ii) at least two condition sets, which contain data associated with completing one or more test orders. The condition sets contain data which differ by at least one variable; and a control system operatively coupled to the plurality of analyzers, and the at least one data storage component. The control system is configured to (i) determine which condition set of the at least two condition sets to use based on the determined condition set, (ii) determine which analyzer or analyzers of the plurality of analyzers to use to process each test order based on the determined condition set and one or more parameters from the list of parameters, and (iii) cause the determined analyzer or analyzers to acquire one or more measurement values for the biological sample.

One aspect of the present invention provides a nucleic acid extraction device. The nucleic acid extraction device includes a container which stores each of a cleaning solution and an eluting solution, a water level sensor configured to detect amounts of the cleaning solution and the eluting solution which are stored in the container, a tube sensor configured to sense a sample tube disposed on a sample tube accommodation portion, and an operation initiation portion configured to determine whether the cleaning solution and the eluting solution which are necessary for a nucleic acid extraction operation are provided on the basis of the number of such sample tubes which is sensed by the tube sensor and the amounts of the cleaning solution and the eluting solution which are sensed by the water level sensor.

A method for the distribution of supports impregnated with antibiotics, includes a step of positioning of a plurality di tubular containers, each one containing a plurality of supports impregnated with antibiotics and stacked, in a corresponding plurality of seats of a dispenser. Extraction of at least a first support from a first container is performed using an extractor, the step of extraction being performed in correspondence of an upper end of the first container and comprising a movement of the first support between a first position inside of the first container and a second position extracted from the first container, said first position and said second position lying substantially in correspondence of an upper surface of the dispenser. Collection of the first support from the second position is performed using a collector Transportation of the first support towards a culture plate by the collector is performed.

In order to increase efficiency, to minimize the size of the apparatus and in order to reduce the workload of the operator who runs the analyzer, the apparatus for the automated analysis of liquid samples, including a sample tray, at least two reagent trays, at least two reaction trays, and at least two measuring devices. The sample tray is arranged in the center of the analysis area, the at least two reaction trays are arranged adjacent to the sample tray, the at least two reagent trays are arranged adjacent to the reaction trays and the at least two measuring devices are arranged adjacent to the reaction trays. Between the sample disc and each of the at least two reaction trays there is a pipetting device. Between each of the at least two reagent trays and their corresponding reaction trays there is a pipetting device.

An automatic analyzer controls a sequence including optical measurement and cleaning and includes a discharge mechanism including a discharge nozzle for discharging a liquid into a reaction vessel; and an overflow suction mechanism including an overflow suction nozzle for sucking an overflow amount of the liquid in the reaction vessel. In a liquid discharge step included in a cleaning process and interposed between a preceding step using a detergent and a succeeding blank value measurement step, the automatic analyzer establishes a first state where a lower end of the discharge nozzle is located in a height-wise lower part of the reaction vessel and a lower end of the overflow suction nozzle is located in an upper part of the reaction vessel, and provides control to carry out the discharge of liquid from the discharge nozzle and the suction of the overflow amount of liquid through the overflow suction nozzle.

Provided is an automated analyzer comprising an ultrasonic cleaner capable of obtaining a consistent cleaning effect regardless of the operating temperature environment. This automated analyzer comprises: a dispensing mechanism having a nozzle for dispensing a sample or reagent; an ultrasonic cleaner 26 for cleaning the nozzle; and a control unit 28. The ultrasonic cleaner comprises: a cleaning tank 206; an ultrasonic vibrator 205; and a vibration head 209 that extends from the ultrasonic vibrator to the cleaning tank and has a distal end part that is inserted into the cleaning tank. The control unit inserts the nozzle into the cleaning tank and carries out a heating operation for heating the ultrasonic vibrator by driving the ultrasonic vibrator according to a driving condition different from that for a cleaning operation for cleaning the nozzle by driving the ultrasonic vibrator.