Provided is an automatic analysis device that can suppress concentration of a reagent made to react with a specimen. This automatic analysis device is provided with: a reagent container which accommodates a reagent and which has attached thereto a perforable lid; a perforation unit for perforating the lid; and a reagent suction nozzle that is inserted into a hole formed by perforation and that sucks up the reagent. The automatic analysis device is characterized by being further provided with a state storage unit that stores the state as to whether the reagent container is in an unused state or in a used state, and a state update unit that, when the lid is perforated by the perforation unit while the reagent container is in an unused state, updates the state stored in the state storage unit to the used state.

An analysis system includes one or a plurality of analysis devices and a fluid remaining amount management device. The one or plurality of analysis devices perform an analysis using fluid supplied from a gas cylinder that is used as a fluid source. The fluid remaining amount management device includes a scheduled usage amount estimator and a remaining amount shortage time determiner. The scheduled usage amount estimator estimates transition of a scheduled usage amount of fluid to be used later than a current point in time in the one or plurality of analysis devices. A remaining amount shortage time determiner determines a remaining amount shortage time when a shortage of a remaining amount of fluid in each gas cylinder occurs based on the estimated transition of the scheduled usage amount.

The invention generally provides devices and methods for particle detection for minimizing human-caused contamination in manufacturing environments requiring low levels of microbes, such as cleanroom environments for electronics manufacturing and aseptic environments for manufacturing pharmaceutical and biological products, such as sterile medicinal products. Methods of the invention may incorporate wirelessly transmitting an alarm signal from a particle detector to a remote device, replicating a graphical user interface of the particle detector on an electronic display of the remote device, and passing one or more user instructions from the remote device to the particle detector via the replicate graphical interface of the remote device.

Apparatuses and methods for washing a plurality of fluid samples are disclosed herein. In an embodiment, a system for washing a plurality of fluid samples respectively located within a plurality of cuvettes includes a rotor configured to rotate the plurality of cuvettes about an axis, a traveler mechanism located beneath the rotor, the traveler mechanism configured to move a plurality of magnets parallel to the axis of rotation of the rotor to position the plurality of magnets so that each cuvette of the plurality of cuvettes is located adjacent to at least one magnet of the plurality of magnets, and a wash system located above the rotor, the wash system configured to at least one of inject fluid into or aspirate fluid from the plurality of the cuvettes, while the plurality of magnets suspend magnetic particles located within each of the plurality of cuvettes.

The present disclosure is, in one aspect, directed to a locking assembly for securing a sample tube assembly to a sample manifold of a measurement system. The locking assembly includes a ramp block having one or more slots defined therein and configured to at least partially receive a portion of the sample tube assembly. The ramp block also includes a plurality of surface features defined therealong and configured to engage and move the sample tube assembly toward and into engagement with the sample manifold. The ramp block further is movable between a plurality of positions including an open position for allowing the sample tube assembly to be received through the one or more slots or openings, and a closed position substantially sealing the sample tube assembly against or within the sample manifold. Other aspects also are described.

Systems and methods for automated detection and classification of objects in a fluid of a receptacle such as, for example, a soft-sided receptacle such as a flexible container. The automated detection may include initiating movement of the receptacle to move objects in the fluid contained by the receptacle. Sequential frames of image data may be recorded and processed to identify moving objects in the image data. In turn, at least one motion parameter of the objects may be determined and utilized to classify the object into at least one of a predetermined plurality of object classes. For example, the object classes may at least include a predetermined class corresponding to bubbles and a predetermined class corresponding to particles.

A data storage section stores LC/MS analysis data for a large number of culture-medium samples acquired with an LC-MS. Based on those data, a quantitative analyzer calculates concentration values of a large number of compounds in each sample and stores the result in an analysis result storage section. A result display processor retrieves analysis results with the same culture name and different sampling date from the analysis result storage section, creates a table in which concentration values are arranged for each compound and for each sampling date, as well as a graph showing a temporal change in the concentration value of one compound, and displays the table and graph on the same window on a display unit. An operator using an operation unit selects a compound on the displayed table. The result display processor creates a graph for the selected compound and renews the graph on the display.

On a device state confirmation screen (100), a first sample arrangement image (111) showing a top-view image of a sample placement section in a preprocessing device for performing preprocessing of removal of proteins or the like and a second sample arrangement image (121) showing a top-view image of a sample placement section of an auto-sampler of an LC-MS are simultaneously displayed. In the respective sample arrangement images (111, 121), a placement position of a vial is indicated by a circular region (113, 122), and the same vial number A1, A2, . . . , is assigned to a vial in which one culture medium sample is accommodated and a vial in which a preprocessed sample is accommodated. Further, circular regions 113 and 122 are displayed in different display colors depending on a state of progress of the preprocessing operation and the analysis operation. As a result, an operator can visually recognize easily and assuredly the correspondence relationship between positions of a large number of vials placed in the sample placement section and positions of a large number of vials accommodating preprocessed samples placed in the auto-sampler, which prevents erroneous selection of samples.

A method for operating a laboratory system comprising instruments for processing samples and a control unit connected by a communication network is presented. The method comprises receiving and identifying a biological sample and retrieving an order list from a database. The list comprises a plurality of targets defining one or more processing steps to be carried out on the biological sample by one or more of the laboratory instruments. The method also comprises selecting a workflow strategy and retrieving workflow acceptance criterion corresponding to the workflow strategy. The control unit determines a sample workflow for processing the sample based on the workflow strategy and determines whether the sample workflow satisfies the workflow acceptance criterion. If the sample workflow does not satisfy the workflow acceptance criterion, workflow strategy and the workflow acceptance criterion is refined and the sample workflow is determined again until it satisfies the workflow acceptance criterion.

Work, such as status confirmation, in a plurality of automatic analyzers is efficiently performed. In an automated analysis system, a tablet terminal 114 has a terminal information management unit 210 and a terminal display unit 208. A terminal information management unit 210 acquires device information showing the state status of a device from automatic analyzers 101a to 101d, and generates a status confirmation screen showing the device status of the automatic analyzer. A terminal display unit 208 displays the status confirmation screen. The status confirmation screen has a status information screen showing the device status of one automatic analyzer and a device switch button configured to switch the status information screen to a status information screen corresponding to another other automatic analyzer. When the switch button is selected, the terminal information management unit 210 generates a status confirmation screen for an automatic analyzer corresponding to the selected switch button, and displays the status confirmation screen on the display unit.