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.

An operator creates a function table on an analyzing device, a computer for analysis or a server. In the function table, an instruction is described which includes designation of the computer(s) for analysis or the server, and a process to be executed by the designated computer(s) for analysis or server, and optionally includes parameter information required for execution. For analysis, the function table is displayed on a display screen of the analyzing device. When the operator selects an instruction in the table and instructs execution, the analyzing device causes the designated computer(s) for analysis or server described in the instruction to execute a process associated with the instruction. Such instruction can include a process of powering on the computer(s) for analysis. By previously describing expected processes and the computer(s) for analysis scheduled to perform the processes the processes to be executed can be instructed from the analyzing device.

A display is provided for an automatic analyzer to display statistics such as measurement results. A width of a display in a window that displays statistics may be adjusted and the amount of information to be displayed on the display is changed according to a level of detail of the information which the operator wants to confirm. Sample information, measurement results, and detailed information related to the measurement results are simultaneously displayed without a subwindow being displayed in overlapped form in the limited display area.

An automatic filter changer that automatically inserts and removes a filter from a fluidic path. Filters are introduced into the automatic filter changer in stacks. The lead filter and each stack is removed from its respective stack one by one by a filter separator. The separated filters are deposited onto a shuttle plate which moves the filters into their respective fluidic paths. Fluid couplers connect to each filter to complete their respective fluidic paths and allow fluids to be filtered before sampling. Once collection of the samples is complete, the filters are removed from the fluidic path and discarded or saved for reuse. The shuttle path is returned to its original position to receive new filters to repeat the process again. A graphic user interface is provided to allow the user to program a specific set of instructions to automate the entire process.

A sample identification system for an automated sampling device is described. A system embodiment includes, but is not limited to, a sample holder having a plurality of apertures configured to receive a plurality of sample vessels therein, the sample holder having one or more corresponding sample holder identifiers positioned proximate to the sample holder; and an identifier capture device configured to detect the one or more sample holder identifiers positioned proximate to the sample holder and generate a data signal in response thereto, the data signal corresponding to at least an orientation of the sample holder relative to a surface on which the sample holder is positioned.

An automatic analyzer having no limitation on a range of a placeable position on a sample placement disk for patient specimens, emergency specimens, quality control samples, and calibration samples, and being capable of performing analysis while changing the number of simultaneously-measurable samples for each type of each specimen is provided. In the automatic analyzer, either a calibration sample dedicated disk or a patient specimen dedicated disk is placed in an analyzing unit 8 as a sample placement disk 19, and the analyzing unit 8 has a disk identifying unit 24 which identifies a type of the sample placement disk 19, and a computer 22 identifies the type of the sample placement disk 19 based on an identification result of the disk identifying unit 24, and performs analysis on a liquid sample based on the identified type of the sample placement disk 19.

A lab automation system receives an instruction from a user to perform a protocol within a lab via an interface including a graphical representation of the lab. The lab includes a robot and set of equipment rendered within the graphical representation of the lab. The lab automation system identifies an ambiguous term of the instruction and pieces of equipment corresponding to the ambiguous term and modifies the interface to include a predictive text interface element listing the pieces of equipment. Upon a mouseover of a listed piece of equipment within the predictive text interface element, the lab automation system modifies the graphical representation of the lab to highlight the listed piece of equipment corresponding to the mouseover. Upon a selection of the listed piece of equipment within the predictive text interface element, the lab automation system modifies the instruction to include the listed piece of equipment.

Devices, systems, and methods for detecting molecules of interest within a collected sample are described herein. In certain embodiments, self-contained sample analysis systems are disclosed, which include a reusable reader component, a disposable cartridge component, and a disposable sample collection component. In some embodiments, the reader component communicates with a remote computing device for the digital transmission of test protocols and test results. In various disclosed embodiments, the systems, components, and methods are configured to identify the presence, absence, and/or quantity of particular nucleic acids, proteins, or other analytes of interest, for example, in order to test for the presence of one or more pathogens or contaminants in a sample.

A parallel preceding system for processing samples is described. In one embodiment, the parallel processing system includes an instrument interface parallel controller to control a tray motor driving system, a close-loop heater control and detection system, a magnetic particle transfer system, a reagent release system, a reagent pre-mix pumping system and a wash buffer pumping system.

A medical diagnostic system is provided to automate analysis of samples to predict a medical condition, such as pregnancy or chronic kidney disease. The system may provide test strip usage automation. The medical diagnostic system may include a sample collection component, collection cup contamination protection mechanism, sample volume control component, test strip reader component, which may be manifested as a lateral flow strip reader, flow reader, sample analytic component, data processing component, data communication component, networked data management component, and device cleaning mechanism. A method to automate analysis of samples to predict a medical condition using the medical diagnostic system is also provided.