The object of the invention is to realize an automatic analyzer capable of suppressing an increase in cost without greatly changing the configuration even when the configuration of an inspection system is changed, and reducing burden of an operator. A pin to be fitted into a hole formed in a specimen container conveying unit is formed on a specimen container conveying unit mounting surface at a position below a specimen suction position, and it is possible to make relative positions between components of a specimen dispensing unit and the specimen container conveying unit at the time of a specimen dispensing operation, as well as driving conditions when moving each axis of the specimen dispensing unit identical even when the types of the specimen container conveying unit are different, and it is possible to ensure stability of the same specimen dispensing operation before and after changing the specimen container conveying unit. Although it is necessary for an operator to memorize a procedure of maintenance work relating to the specimen container conveying unit, work procedures relating to other units of the automatic analyzer are not changed and it is not necessary to memorize new maintenance procedures of the other units, and thus the burden of the operator can be reduced.

A laboratory sample container carrier handling apparatus is provided comprising a revolving device, a guiding surface, and a force-applying device, wherein the force-applying device is adapted to apply a force to a laboratory sample container carrier supplied to the revolving device to such an extent that the laboratory sample container carrier is forced against the guiding surface to such an extent that the laboratory sample container carrier rolls off at the guiding surface pushed by the revolving device. A laboratory automation system is also provided comprising such a laboratory sample container carrier handling apparatus and to a use of such a laboratory sample container carrier handling apparatus for handling a laboratory sample container carrier in, in particular such, a laboratory automation system.

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 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.

In order to increase efficiency, to minimize the size of the apparatus and in order to reduce the workload of the operator who runs the analyzer, the apparatus for the automated analysis of liquid samples, including a sample tray, at least two reagent trays, at least two reaction trays, and at least two measuring devices. The sample tray is arranged in the center of the analysis area, the at least two reaction trays are arranged adjacent to the sample tray, the at least two reagent trays are arranged adjacent to the reaction trays and the at least two measuring devices are arranged adjacent to the reaction trays. Between the sample disc and each of the at least two reaction trays there is a pipetting device. Between each of the at least two reagent trays and their corresponding reaction trays there is a pipetting device.

A gas chromatography system includes at least one gas chromatography subsystem including at least one injector port, and an autosampler. The autosampler includes a carousel tray mounted for rotation about a rotation axis and including arcuately extending first and second rows of sample reservoirs, a first sample transfer tower to extract samples from the first row, a second sample transfer tower to extract samples from the second row, and a control system operative to: selectively position the carousel tray relative to the first and second sample transfer towers to align the first and second sample transfer towers with a selected pair of the sample reservoirs of the first and second rows, respectively; draw samples from the selected pair using the first and second sample transfer towers; inject the sample drawn from the first row into the at least one injector port using the first sample transfer tower; and inject the sample drawn from the second row into the at least one injector port using the second sample transfer tower.

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.

The present invention provides a preprocessing device of a more compact structure, and an analysis system provided with the same. A preprocessing device (1) includes a container holding section (12), a filtration port (30), and a transport arm (24). The container holding section (12) holds a separation container (50) and a collection container (54). The filtration port (30) separates a sample by applying pressure to a sample in the separation container (50). The transport arm (24) transports the separation container (50) and the collection container (54) held by the container holding section (12) from a predetermined transport position. The container holding section (12) holds the separation container (50) and the collection container (54) in an annular or arch-shaped holding region formed on an outer circumference of the filtration port (30), and sequentially moves the separation container (50) and the collection container (54) to the transport position by shifting the separation container (50) and the collection container (54) in the circumferential direction of the holding region.

An automatic analyzer having no limitation on a range of a placeable position on a sample placement disk for patient specimens, emergency specimens, quality control samples, and calibration samples, and being capable of performing analysis while changing the number of simultaneously-measurable samples for each type of each specimen is provided. In the automatic analyzer, either a calibration sample dedicated disk or a patient specimen dedicated disk is placed in an analyzing unit 8 as a sample placement disk 19, and the analyzing unit 8 has a disk identifying unit 24 which identifies a type of the sample placement disk 19, and a computer 22 identifies the type of the sample placement disk 19 based on an identification result of the disk identifying unit 24, and performs analysis on a liquid sample based on the identified type of the sample placement disk 19.

The present disclosure relates to a rotatable tube rack holder for a tube rack rotator device, comprising: one or more plate(s) extending radially from an axis of rotation; one or more compartment(s) for tightly holding one or more tube rack(s) configured to hold a plurality of tubes, said compartment(s) is/are attached to at least one side of said plate(s); and one locking mechanism for each of said compartment and configured such that when said tube rack(s) holding a plurality of said tubes is/are placed inside said compartment, said tubes are restricted from moving in a direction perpendicular to said plate.