Body fluid sample carrier for use in a body fluid analyser and body fluid analyser using a body fluid sample carrier, wherein the body fluid sample carrier has a plurality of rack receptacles and a plurality of marker receptacles for receiving corresponding markers in order to improve the association between racks positioned on the carrier and the correct position on the carrier.

A method of reading machine-readable marks on a movable support and object of a sample instrument. The method includes capturing a first image of the moveable support as the moveable support moves from a first position to a second position using an image capture device; determining whether a first fiducial machine-readable mark on the moveable support is in the first image; determining, when the first fiducial machine-readable mark is in the first image, whether a first machine-readable mark on a first object coupled to the moveable support is in the first image at a predetermined position relative to the first fiducial machine-readable mark; and associating information decoded from the first machine-readable mark on the first object with a first location on the moveable support associated with the first fiducial machine-readable mark.

A sample handling system for handling samples is disclosed. The sample handling system comprises sample holders, each receives a sample container; a sample transport device for moving the sample holders; a control unit for controlling functionality of the sample handling system, and a monitoring system for monitoring the samples during movement. The monitoring system comprises a camera module for continuously capturing images of a part of the sample transport device, wherein the camera module is at a distance from the sample transport device such that the camera module has a free field of view to the sample transport device, and a processor for processing the captured images and determining an item of information about the sample transport device and/or the sample container and/or the sample from the captured images. The control unit retrieves the item of information from the processor. The controlling is based on the retrieved item of information.

The present invention describes an integrated incubator and image capture module that regulates the incubator atmosphere and obtains high-resolution digital images of sample specimens. The incubator has a cabinet type enclosure that enables the provision of a controlled environment to the contents of the incubator by having at least three ports on one face of the cabinet for the passage of sample containers. Additionally, an image capture module is located immediately adjacent to the incubator. In this regard, using at least three separate access/egress points for the sample containers streamlines operation of the system and enhances preservation of the incubator environment. Furthermore, locating the image capture module directly adjacent to the incubator reduces the amount of time a sample container is exposed to the external environment, thereby reducing the extent to which samples are exposed to potential contaminants and reducing the exchange of the lab and ambient atmospheres.

The automatic analysis system comprises an analysis device which introduces sample containers which have been placed at a predetermined placement location into an analysis unit to perform analysis on the samples, and a management device which has a function of transmitting identification information for a sample to said analysis device when an analysis request has been made for that sample. The analysis device comprises a sample information management unit which retains sample identification information transmitted from the management device as analysis-requested sample information and retains identification information for samples which have been analyzed by the analysis unit as analysis-completed sample information.

An analysis instrument comprises a sample receiving section for receiving samples provided by a plurality of users, an analysis section operable to receive an aliquot of each received sample, perform an analysis of each received aliquot, and generate an output based on the analysis, and a presentation section adapted to present the output in a human discernable format. The analysis instrument further includes an identification section adapted to autonomously generate an identifier unique to each user and each sample provided thereby and to supply each identifier for presentation by the presentation section in a human discernable format together with a portion of the output that corresponds with one or more samples provided by a user to which the identifier is unique. Each identifier consists of one or more graphic symbols, one or more colours, and/or one or more numbers.

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.

The present invention describes an integrated incubator and image capture module that regulates the incubator atmosphere and obtains high-resolution digital images of sample specimens. The incubator has a cabinet type enclosure that enables the provision of a controlled environment to the contents of the incubator by having at least three ports on one face of the cabinet for the passage of sample containers. Additionally, an image capture module is located immediately adjacent to the incubator. In this regard, using at least three separate access/egress points for the sample containers streamlines operation of the system and enhances preservation of the incubator environment. Furthermore, locating the image capture module directly adjacent to the incubator reduces the amount of time a sample container is exposed to the external environment, thereby reducing the extent to which samples are exposed to potential contaminants and reducing the exchange of the lab and ambient atmospheres.

A sample processing station includes two or more container holders on a platform that is rotatable about a central axis of rotation. Each holder is configured to rotate about a secondary axis of rotation. The station includes a capping/decapping mechanism to cap or decap a container held in one of the container holders and an elevator with a chuck guide that contact the container holder as the chuck is lowered by the elevator to position the chuck with respect to the cap of the container held in the holder and to hold jaws of the container holder in a closed position. In embodiment, the chuck guide includes a yoke with opposed arms and spindles located near distal ends of the arms that engage beveled shoulders of the container holder.

The present invention provides improved methods, facilities and systems for parallel processing of biological cellular samples in an efficient and scalable manner. The invention enables parallel processing of biological cellular samples, such as patient samples, in a space and time efficient fashion. The methods, facilities and systems of the invention find particular utility in processing patient samples for use in cell therapy.