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.

A laboratory sample distribution system is presented. The system comprises carriers to carry sample containers. Each carrier comprises a magnetically active device. The system comprises a transport plane to support the carriers and electro-magnetic actuators stationary arranged below the transport plane. The actuators move the carriers on top of the transport plane by applying a magnetic force to the carriers. The system comprises a control device to control the movement of the carriers on top of the transport plane by driving the actuators such that the carriers move along corresponding transport paths simultaneously and independently from one another and a sensor to measure supply currents and/or supply voltages. The actuators are supplied with electrical energy based on the supply currents and/or the supply voltages. The system comprises a monitoring device coupled to the sensor. The monitoring device monitors the actuators temperature based on the measured supply currents and/or supply voltages.

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.

In examples, a method of controlling customer access to an assay system comprises (a) receiving a system identifier; (b) identifying said system identifier; and (c) utilizing information obtained from the system identifier to perform one or more operations selected from: (i) enabling full access to said system and/or a consumable used in said system; (ii) enabling partial access to said system and/or a consumable used in said system; or (iii) denying access to said system and/or a consumable used in said system.

A measurement portion includes a containment unit including a plurality of containers containing a liquid, a dispensing unit including a dispensing probe for dispensing the liquid, and a gauging portion for gauging the liquid dispensed by the dispensing unit. An excessive immersion determination portion determines whether an immersion of the dispensing probe is excessive immersion that exceeds a predetermined range. An input portion can select and set an operation of the measurement portion to be performed after the excessive immersion determination portion determines that the immersion is excessive immersion from a plurality of modes. A measurement control portion controls the measurement portion depending on a mode set by the input portion.

There is provided an automated analyzer which has plural liquid tanks connected with a dispensing probe and which can efficiently switch the operative liquid tank according to measurement item. The automated analyzer comprises: a liquid dispenser having a dispensing probe and a pump capable of aspirating and dispensing a liquid from and into an open end of the probe that is at one end thereof, the liquid dispenser being operative to cause the liquid aspirated in the probe from the open end and a probe internal liquid of the probe to be dispensed into aliquot receptacles; an internal liquid supply device having plural liquid tanks in which probe internal liquids corresponding to measurement items are stored, supply tubes for placing the liquid tanks in communication with the other end of the dispensing probe, and a selector valve mounted in front of the supply tubes and operative to selectively place the liquid tanks into communication with the probe, the supply device being operative to supply a probe internal liquid into the dispensing probe from one of the tanks; an input section for entering settings regarding operation of the liquid dispenser; and an operation controller for controlling operation of the liquid dispenser based on inputs from the input section. The analyzer makes measurements of different measurement items by switching the operative liquid tank in communication with the probe via the selector valve being an automatic valve under control of the operation controller.

A system for transporting a carrier vehicle using linear motors comprising a linear motor housing shaped to hold one or more linear motors includes a rectangular top plate. A left side plate is connected adjacent to a first longitudinal edge of the rectangular top plate and a right side plate is connected adjacent to a second longitudinal edge of the rectangular top plate. The linear motor housing further includes a plurality of coupling components operable to couple the linear motor housing to one or more adjacent linear motor housings in a manner that facilitates continuous propulsion of the carrier vehicle across the rectangular top plate of the linear motor housing and rectangular top plates corresponding to the one or more adjacent linear motor housings.

The present application describes a new device and method of use thereof, which allows identifying certain antigens and antibodies present in the blood. The device of the present invention is a closed device consisting of two parts, wherein the upper part has a chamber surrounded by LEDs illuminating the analysis plate, which is supported by the rotating platform. In turn, the rotating platform is connected to a motor that will promote the rotation thereof for mixing reagents with blood. After a period of time, the camera will capture and send the resulting image to a computer program that will analyze the sample, using image processing techniques.

A pipette tip supply mechanism includes: a pipette tip storage unit for storing a plurality of tapered shaped pipette tips; a belt for transporting a pipette tip supplied from an opening of the pipette tip storage unit; and a belt drive unit that drives the belt in a transport direction. The belt is inclined upwards toward the transport direction so that the pipette tip is rotatable around a longitudinal axis of the pipette tip on a surface of the belt and the pipette tip is rolled to orient the longitudinal axis of the pipette tip along the transport direction in conjunction with the drive of the belt in the transport direction.

The present invention is provided with: an automatic analysis device 200 for performing an analysis process to analyze a specimen that is to be analyzed; a specimen pre-processing module 100 for performing pre-processing to cause the specimen to enter a state in which the analysis process can be performed; a main conveyance line 161 for conveying a specimen container carrier 10 which accommodates the specimen that is to be analyzed and in which at least one specimen container can be mounted; and annular conveyance lines 111, 121, 131, 141, 151, 411 that are disposed adjacent to the main conveyance line 161 and that are moreover disposed so as to be capable of transferring the specimen container carrier 10 to and from the main conveyance line 161, the annular conveyance lines 111, 121, 131, 141, 151, 411 being capable of circulating and conveying the specimen container carrier 10 separately without the use of another conveyance line (e.g., a return line 162). This makes it possible to maintain flexibility in conveyance of specimens while suppressing increases in device surface area.