A method for providing guidance through a graphical user interface (GUI) to assist with the completion of one or more steps of an experimental process may include the following. At least one processor may receive a first command to select an experiment comprising one or more steps to be performed on an instrument or other equipment. The at least one processor may further provide a second command to display at least a subset of the one or more steps of the experiment on a UI display. The at least one processor may further provide a third command, to instruct the instrument or other equipment to at least partially carry out the one or more steps of the experiment.

The invention has an object to provide an automatic analyzer and a control program that can shorten total analysis time. The automatic analyzer comprises: a sample rack that houses a sample; a sample dispensing mechanism that aspirates the sample from the sample rack and dispenses the sample into a reaction container; a plurality of detection units that detect a reaction liquid in the reaction container; and a control unit that controls the sample dispensing mechanism and the detection units. The control unit checks the measurement item specified for the sample and checks one of the detection units that is specified by the measurement item. When measurements specifying the same detection unit among the detection units are specified consecutively, the order of dispensing by the sample dispensing mechanism is changed so that measurements specifying different detection units are made consecutively.

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.

A system and method for ejecting one or more fluids from a digital dispense device. The method includes a) inputting to a memory a volume per unit area for each of the one or more fluids to be ejected from the digital dispense device; b) matching the volume per unit area to a device resolution for the digital dispense device; c) formatting fluid ejectors for the digital dispense device for the device resolution; and d) ejecting fluid from the digital dispense device to provide the volume per area for each of the one or more fluids.

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.

The specimen conveyance device and method can easily specify, regardless of the size of the system, the position on the device of the specimen tube whose position is desired to be grasped and the position on the device of the device part whose position is desired to be grasped. A specimen conveyance unit 10 includes a plurality of conveyance blocks 1, each of which includes one or more light emitting bodies 3 and conveys a specimen tube holder 6 that holds a specimen tube 5 storing a specimen, and a control unit 4 for controlling the conveyance operation of the specimen tube holder 6 by the conveyance block 1, in which the control unit 4 causes the light emitting body 3 of a specific conveyance block 1 among the conveyance blocks 1 to emit light in accordance with the conveyance state of the specimen tube holder 6.

A laboratory automation device comprises a workspace with liquid containers and a pipetting arm for moving liquids between the liquid containers; a housing enclosing the workspace; a door of the housing for accessing the workspace, wherein the door comprises a transparent display for displaying information and for allowing a person to view into the workspace and a tracking sensor for tracking an eye position of the person. The laboratory automation device is adapted for determining the eye position of the person from sensor data acquired with the tracking sensor; and for displaying information for a notification area in the workspace on the transparent display, such that the information is displayed from a perspective of the person in front of the notification area.

Embodiments of a platelet testing system include an analyzer console device and a blood testing cartridge configured to releasably install into the console device. The cartridge device is configured with one or more measuring chambers and one or more mixing chambers that are fluidically connected within the cartridge device that enable the mixing of saline and a blood sample to a desired dilution. Additionally, the cartridge device is further configured with a cartridge slider that provides a reagent bead to the saline and blood mixture at a desired time. As such, one or more platelet activation assays can be conducted by measuring, through cartridge electrodes of the cartridge device, the detectable changes in platelet activity within the blood and saline mixture.

A specimen processing system 100 which performs preprocessing and analysis of a specimen includes sensors 5a, 5b, . . . each detecting a driving state of a driving device installed in the system, an abnormality detecting part 3a determining from signal waveforms detected by the sensors 5a, 5b, . . . whether an abnormality occurs in the driving device, and a recording device sequentially recording the signal waveforms detected by the sensors 5a, 5b, . . . and storing a sensor signal waveform before or after the occurrence of an operation abnormality into an unerasable area when the abnormality is determined to have occurred in the abnormality detection part 3a. Consequently, there is provided a specimen processing system capable of realizing restoration from the time of the occurrence of an abnormality faster than in the past.

A method for sharing system information data in a network of two or more diagnostic instruments for performing assays is provided. The system information data includes operating information for the diagnostic instruments in the network. The method includes: sending a system information metadata packet to at least a first diagnostic instrument in the network, wherein the system information metadata packet, is associated with system information data on a second diagnostic instrument in the network and comprises one or more attributes of a system information data packet containing the associated system information data; receiving a request from the first diagnostic instrument to send the system information data packet, and in response to the request from the first diagnostic instrument to send the system information data packet, sending the system information data packet containing the associated system information data to the first diagnostic instrument.