An immunoassay apparatus may include: a sample dispenser part that dispenses a sample into a first reaction container; a reagent dispenser part that dispenses, into the first reaction container,: a solid-phase reagent containing a solid-phase carrier; a labeled reagent; and a releasing reagent that releases, from the solid-phase carrier, an immune complex including a target substance and a labeled substance; a measurement part that measures a signal based on the labeled substance in the immune complex in a second reaction container; a container supply part that stores a plurality of reaction containers; a transfer part that transfers the first reaction container so that the sample dispenser part and the reagent dispenser part perform a dispensing operation to the first reaction container, and that transfers the second reaction container so that the immune complex dispended from the first reaction container is dispensed into the second container.

Provided are a cell dispensing and storing apparatus and a method of the same. The method includes: moving a freezing container with a test tube in it and a temporary storage bottle containing sample cells into a dispensing area. Connect the temporary storage bottle with an injecting assembly. A dispensing clamp moves the test tube from the freezing container to a tube rack on a rotating platform. A rotating clamp removes a tube cover from the test tube. An injecting nozzle extracts the sample cells from the temporary storage bottle and dispenses the sample cells into the test tube. The rotating clamp puts the tube cover back on the test tube. The dispensing clamp moves the test tube back into the freezing container. A freezing clamp moves the freezing container into a freezer.

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.

A slide rack gripper apparatus is provided that simultaneously conveys a plurality of glass slides in the protection of a slide rack within a digital slide scanning apparatus. The slide rack gripper apparatus conveys the plurality of glass slides from a slide rack carousel to a scanning stage for processing. The slide rack gripper includes a first motor attached to a base configured to drive a finger mount attached to the base along a first linear axis. The slide rack gripper apparatus also includes a second motor attached to the finger mount and configured to drive opposing gripper fingers attached to the finger mount along a second linear axis. The second motor is also configured to drive individual gripper fingers along a third linear axis to move the gripper fingers toward each other and away from each other to grasp or release a slide rack.

Disclosed is a specimen measurement apparatus that includes a measurement unit configured to measure a specimen; a detector configured to detect at least one of a container that can store the specimen or a cap of the container; and a movement mechanism configured to move at least one of the container or the detector. In the specimen measurement apparatus, the detector detects at least one of the container and the cap in a state where the movement mechanism is moving the container relative to the detector.

The present invention provides a processing device with a high degree of flexibility in setting of preprocessing and which is capable of increasing the preprocessing efficiency, and an analysis system provided with the same. Setting receiving means (84d) receives, for each sample, setting of a plurality of types of preprocessing and a parameter for each preprocessing. A preprocessing execution section (84e) controls a plurality of preprocessing sections and a transport arm (24) so that a plurality of types of preprocessing set for each of different samples is performed simultaneously in parallel. The preprocessing execution section (84e) performs control in such a way that preprocessing is not to be performed on different samples at the same preprocessing section at the same.

A highly integrated, fully automatic chemiluminescence detection equipment and its operation method are disclosed. The chemiluminescence detection equipment comprises a control module, a first electrical machine, a reagent wheel disc tank, a sampling module, a washing module, a second electrical machine and a detection module. Compared with the traditional large-scale chemiluminescence detection equipment, the chemiluminescence detection equipment of the present invention has the advantage of high integration, and greatly reduces the overall volume and weight of the chemiluminescence detection equipment.

According to embodiments of the technology, an automated thermal desorption system includes a sample tube including a chamber to contain an analyte, visible indicia on the sample tube, a thermal desorption apparatus, and a sample tube monitoring system. The thermal desorption apparatus is configured to receive the sample tube and includes a heating device. The heating device is configured to heat the sample tube in the thermal desorption apparatus and thereby desorb the analyte from the sample tube. The sample tube monitoring system includes: an optical sensor configured to read the visible indicia on the sample tube and to generate an output signal corresponding thereto; and a controller configured to receive the output signal corresponding to the visible indicia from the optical sensor and to determine an orientation of the sample tube with respect to the thermal desorption apparatus based on the output signal.

The invention relates to an automated method for the optical analysis of structures, in particular for the analysis and determination of biological cellular structures, and to an apparatus for this purpose, wherein an electro-optical unit generates an electronic image of two- and three-dimensional structures present in the sample, a storage medium stores the image, a computer-controlled displacement device establishes an optimized image sharpness of the image by changing the distance between sample and the optical unit, wherein the displacement device is controlled by contrast analysis and color value detection, and a computer unit compares the images generated by the electro-optical unit of two- and/or three-dimensional structures with the known structures stored in a database, and the structures registered by the optical unit are assigned by means of an algorithm to characteristic grids, structures or patterns.

Provided are low flow groundwater fluid sampling systems and related methods of collecting fluid samples, including a low flow pump, flow cell, waste container and a communication device in communication with those components. In this manner, the low flow pump may be controlled to ensure a desired constant flow-rate is achieved, and a remote operator may monitor the status of fluid being pumped to the flow cell with the communication device, such as with a portable electronic device, including a smart phone. The system may alert the operator that fluid is ready to be collected for sampling, including at an off-site laboratory. Particularly useful applications are for monitoring groundwater quality and contamination.