A fully automatic test card conveying apparatus for an instant testing instrument is used for conveying a test card and includes a test card conveying arm, frame, push rod, buffer support, buffer cartridge, and card extraction mechanism. A first electric motor, second electric motor, first sliding rail, and second sliding rail are provided on the arm. The frame is connected in a sliding manner to the first sliding rail via a sliding block, and connected to the first electric motor via a first synchronization belt. A stepping motor is provided on the sliding block and an output end of the stepping motor is connected to the frame. The push rod is connected in a sliding manner with the second sliding rail, and connected to the second electric motor via a second synchronization belt.

A system for measuring optical signal detector performance includes an optical signal detector comprising a first detection channel having a first light source and a first sensor. The first detection channel is configured to emit and focus light generated by the first light source at a first detection zone, and to receive and focus light on the first sensor. The system also includes a controller operatively coupled to the optical signal detector and configured to determine an operational performance status of the optical signal detector based on at least one of (i) a first measured characteristic of light focused on the sensor while a first non-fluorescent surface portion is in the first detection zone and (ii) a second measured characteristic of light focused on the sensor while a void is in the first detection zone. The optical signal detector can be a fluorometer.

This sample rack conveying apparatus is provided with a pusher unit, a linear motion guide, and a conveyance drive mechanism. The pusher unit has a base portion, a moving member, and a base-side guide. The base portion is supported by the linear motion guide so as to be movable in a first guide direction. The moving member is provided with a pusher that pushes a sample rack. The base-side guide supports the moving member such that the moving member is movable in a second guide direction that crosses the first guide direction.

An automatic analysis device has a plurality of types of photometers having different quantitative ranges, and an analysis control unit for quantifying the desired component in specimens based on measurement values of one or more photometers selected from among the plurality of types of photometers. The analysis control unit: sets a switching region in an overlap region of respective quantitative ranges of the plurality of types of photometers, said switching region having a greater width than does the variation in quantitative values of the desired component based on the measurement values of photometers having the same specimen; compares the quantitative value of a quantitative range portion that corresponds to the switching region and the quantitative values of the desired component based on the measurement values of the photometers; and selects a photometer to be used in quantitative output of the desired component from among the plurality of types of photometers.

A switch for a conveying line for transporting a laboratory diagnostic vessel carrier is presented. The conveying line comprises a first line portion and a second line portion. The switch comprises a curved first guiding surface and a second guiding surface. The switch is moveable between a first position, in which the laboratory diagnostic vessel carrier is transportable along the curved first guiding surface from the first line portion to the second line portion, and a second position, in which the laboratory diagnostic vessel carrier is further transportable along the second guiding surface on the first line portion. A switch assembly and a conveying line are also disclosed.

The present invention relates to methods, devices and systems for associating consumable data with an assay consumable used in a biological assay. Provided are assay systems and associated consumables, wherein the assay system adjusts one or more steps of an assay protocol based on consumable data specific for that consumable. Various types of consumable data are described, as well as methods of using such information in the conduct of an assay by an assay system.

A fluorescence and/or chemiluminescence measuring device and method, able to achieve a series of actions synchronously including placing reaction cup, injection, extraction, reading, releasing reaction cup and light block, and no extra arm for getting and releasing reaction cup is needed. A sliding cartridge drives the reaction cup to perform movement to achieve the actions above in turn. Moreover, it maximally ensures a consistence of distance and relative height between each reaction cup and the reading photomultiplier device, so as the operation speed is faster and easier.

In accordance with embodiments, a transport mechanism transports a first sample container to a sample aspiration position. A setting part may set a second sample container, that accommodates a sample to be measured, with priority over a measurement of a sample in a first sample container. A nozzle may be capable of moving a sample from a first sample container at a sample aspiration position, and aspirating the sample from the second sample container. A detector may detect components of the sample. A controller may control a transport mechanism such that the first sample container moves to a position distant from the sample aspiration position, when the first sample container has been transported and when sample aspiration of the second sample container is required. A controller may execute control to move the nozzle above the sample aspiration position in state in which the first sample container is distant from the sample aspiration position.

A laboratory sample distribution system comprising a transport plane and a cleaning device for cleaning the transport plane is presented. The cleaning device is adapted to automatically clean the transport plane similar to sample container carriers moving also on the transport plane. A laboratory automation system comprising such a laboratory sample distribution system is also presented.

A full-automatic sample pretreatment device includes a frame module, a cap removing module, a blood-collection tube grasping module, a pipette module, a platform module, a handling module, a film sealing module, a magnetic solid phase extraction module, an SPE positive pressure extraction module and a conveyor belt waste transfer module. A conveyor belt waste transfer module is arranged at a bottom of the frame module, the cap removing module, the platform module and the magnetic solid phase extraction module are sequentially arranged in the middle of the frame module from left to right, and the blood-collection tube grasping module, the pipette module, the handling module and the film sealing module are arranged at an upper portion of the frame module. The magnetic solid phase extraction module and the SPE positive pressure extraction module are detachable and interchangeable components.