A system for tracking one or more subjects for collecting airborne contaminants. The system includes one or more subjects configured to collect air contaminants. Each of the one or more subjects includes an identification tag encoded with identification information identifying the each subject. The system further includes an identification reader configured to decode the identification information encoded within the identification tag of a scanned one of the one or more identification tags. A computer receives and stores the decoded identification information in a record in a database. The computer may also receive and stored an identification code for a user who scanned the scanned identification tag in the record in the database. Additional records in the database are created each time the identification tag of one of the one or more subjects is scanned. The one or more subjects are thereby tracked as they collect airborne contaminants and are incubated.

A pretreatment apparatus includes: a pretreatment unit that subjects to a pretreatment a sample to be analyzed by an analysis device; an input unit that receives an analysis condition input; a communication IF that transmits to the analysis device the analysis condition input via the input unit; and a display unit that displays, on a single screen, an analysis result derived using a calibration curve from analysis data obtained by the analysis device based on the analysis condition, and calibration curve information about the calibration curve used to derive the analysis result.

An accommodation unit includes a plurality of accommodation positions, each of the plurality of accommodation positions being capable of accommodating one of the plurality of samples. A detection unit detects identification information of each of the plurality of samples in the accommodation unit. A control unit holds the identification information of each of the plurality of samples received from the detection unit as detected identification information. The control unit is configured to receive identification information of each of a plurality of samples designated as analysis targets, and hold the received identification information as designated identification information. The control unit includes a notification means configured to output a warning before analysis is started by the analysis unit, when the control unit makes a comparison between the designated identification information and the detected identification information and determines that there is a mismatch therebetween.

To reduce the risk of mistaken operation and improve convenience in an automatic analysis device. Information about types of measurement inputted from an input device is combined in an examination mode creation screen image 301 on a display device of an automatic analysis device that performs analysis of specific types of measurement on a specimen container accommodating a specimen, the information about types of measurement including biochemistry examination items 303, immunology examination items 304, ISE examination items 304, blood clotting examination items 306, etc. This information is associated with an examination mode name 302, which comprises discretionary setting information, and is stored in a table of a storage unit. Information which is to be displayed on the display device and for which a change in settings is to be enabled is limited on the basis of the stored information about types of measurement associated with the examination mode name 302.

Carriers are provided for microbiological laboratory use, as are methods for their use. The carriers may be used to transport patient samples between laboratory stations and can be loaded into automated AST systems. In an aspect, a method of performing AST may include loading a tube comprising a patient sample onto a carrier. An AST panel may be loaded onto the carrier. The carrier may be conveyed to an automated inoculation assembly. The patient sample may be inoculated from the tube into the AST panel. The AST panel may be loaded into an automated AST system.

A sample receptacle can be used for ordering assays to be performed by an automatic sample processing instrument. The sample receptacle can include a body defining a chamber for containing a sample and a label. The label can include discrete areas configured to be altered from a first assay order state to a second assay order state. Each discrete area has a known association with a different assay. The label can also include assay-identifying indicia indicating the respective assay associated with a respective discrete area. A method of processing a sample in a receptacle having one or more assay order states can include automatically determining assay order states of the discrete areas and performing an assay on the sample, using the automatic sample processing instruments, based on the determined assay order states of the discrete areas.

Systems and methods for managing a sample preparation and analysis system based on detected unique sample identities and locations is described. A system embodiment includes, but is not limited to, a sample analysis information system communicatively connected with each of a sample data manager, a sample logging manager, and a sample preparation system, wherein the sample data manager stores on the sample analysis information system a sample type with a sample type protocol for execution by the sample preparation system, the sample logging manager assigns the sample type with a unique identifier positioned on a sample container, and the sample preparation system includes an identifier capture device to identify the unique identifier, access the sample type protocol from the sample analysis information system, and execute the sample type protocol responsive to a queue associated with a sample order assigned to the sample type via the sample data manager.

Systems and methods for managing a sample preparation and analysis system based on detected unique sample identities and locations is described. A method embodiment includes, but is not limited to, storing on a sample analysis information system a sample type and a sample type protocol for execution by a sample preparation system via a sample data manager; storing on the sample analysis information system an association between a unique identifier positioned on a sample container and the sample type with a sample logging manager; identifying the unique identifier at the sample preparation system with an identifier capture device of the sample preparation system; accessing from the sample analysis information system the sample type protocol based on the sample type associated with the unique identifier; and queuing a sampling procedure to execute the sample type protocol based on a sample order assigned to the sample type via the sample data manager.

A flow cytometer according to one or more aspects may include: a particle data acquisition unit that measures particles in a sample to acquire particle data including optical information of the particles; and a transmission unit that transmits at least one of the particle data and data on a particle distribution diagram of the particles, generated based on the particle data, to at least one of a hospital information system that supports hospital operations and a clinical laboratory information system that supports clinical test operations.

The devices, systems, and methods disclosed herein provide sample verification capabilities in a single device or system. Devices are disclosed herein. Systems including these devices are also provided. These devices and systems may be configured for verifying sample integrity prior to a subject leaving a sample collection site so that any further samples or other corrective action can occur without having to make a separate visit.