Coordinated conveyors in an automated system. A system comprises a plurality of conveyors, which each comprise a plurality of segments, and one or more stations. An instruction is received to perform an operation that requires at least one station to process at least a first item held by a first segment of a first conveyor and a second item held by a second segment of a second conveyor. In response to the instruction, one or both of the first and second conveyors are moved, such that the first segment and the second segment are aligned at the station. After alignment, one or more instruments of the station process the first item and the second item.

A qualitative and quantitative heavy metal analysis device and, more particularly, a qualitative and quantitative heavy metal analysis device implemented by a rotary platform are provided. The rotary platform device includes a main injection part which is positioned near a rotating shaft of a rotary platform, wherein the main injection part is configured to receive a fluid sample containing heavy metals, a pH adjusting part configured to adjust pH of the fluid sample, a detecting part coated with a chelating agent configured to initiate a color reaction with heavy metals in the fluid sample by spreading the pH-adjusted fluid sample into the detecting part, and a ruler for measuring a spreading distance of the color reaction, wherein the fluid sample moves from the main injection part through the pH adjusting part to the detecting part by a rotation of the rotary platform device.

Systems, methods, and devices for discretizing and analyzing fluidic samples are provided. In one aspect, a microfluidic array for discretizing a fluidic sample comprises one or more flow channels and a plurality of fluidic compartments in fluidic communication with the one or more flow channels. In another aspect, a system for discretizing and analyzing fluidic samples comprises a rotor assembly shaped to receive a microfluidic device.

A pretreatment apparatus includes a pretreatment container placement section where a pretreatment container which is housing a specimen holding member including a microchannel for holding a specimen is placed; a carrying mechanism for carrying the pretreatment container that is placed at the pretreatment container placement section; and a pretreatment section including a port where the pretreatment container that is carried by the carrying mechanism is placed, the pretreatment section being configured to perform pretreatment including a shaking process of shaking the pretreatment container to extract the specimen from the specimen holding member in the pretreatment container that is placed in the port.

A sample analysis system and a sample management method are provided. The sample analysis system includes: one or more analysis devices configured to test a sample; a scanning component configured to scan the sample to obtain scanning information before testing the sample by the analysis devices; an image information obtaining component configured to acquire image information of a region in the sample containing a sample identifier; a processor configured to identify the sample identifier of the sample according to at least one of the scanning information or the image information of the sample. The system can obtain the sample identifier of a sample in two ways, thus improving the efficiency of sample test.

Provided herein are devices and methods of processing a sample that include, in several embodiments, rotating one or more microfluidic chips that are mounted on a support plate using a motor driven rotational chuck. By spinning one or more of the microfluidic chips about a common center of rotation in a controlled manner, high flow rates (and high shear forces) are imparted to the sample in a controlled manner. Each microfluidic chip can be rotated 180° on the support plate so that the sample can be run back-and-forth through the microfluidic devices. Because the support plate can be driven at relatively high RPMs, high flow rates are generated within the microfluidic chips. This increases the shear forces on the sample and also decreases the processing time involved as the sample can quickly pass through the shear-inducing features of the microfluidic chip(s).

A pretreatment apparatus (100) for performing pretreatment of a sample is provided with a holder (610) for holding a container (10) containing a sample, a centrifugal separation device (600) for rotating the container (10) held by the holder (610) to perform a centrifugal separation, a temperature adjustment device (420) for adjusting the temperature of the sample in the container (10) in the holder (610), an input device (320) for receiving from a user a designated temperature that is adjusted by the temperature adjustment device (420), a controller (300) for controlling the temperature adjustment device (420) in accordance with the designated temperature received via the input device (320).

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.

This substrate for sample analysis, which transfers a sample-containing liquid by means of rotation and analyzes a specific substance in a sample, is provided with: a space which holds the sample-containing liquid in a substrate having a rotary shaft; a reaction chamber having an inlet and an outlet connected to the space; and a dried reagent disposed in the space of the reaction chamber. The space has a first end and a second end spaced apart from each other in a circumferential direction. The inlet and the outlet are arranged at the first end and the second end, respectively. The space has a capillary portion, and a first non-capillary portion which is connected to the capillary portion, is located at the second end, has an opening, and extends in a radial direction. The outlet is connected to the outer peripheral side of the first non-capillary portion.

Provided is a new analysis device capable of heating an analysis chip and reducing the size thereof. The analysis device (1) of the present invention includes a set unit (15) for setting an analysis chip, an accommodation chamber to be accommodated in the set unit (15), a blower fan (19) that blows air to the set analysis chip, a heating unit (20) that heats the air to be blown, a drive unit (16) that rotates the analysis chip, and an analysis unit that analyzes the analysis chip, wherein the accommodation chamber becomes an analysis chamber for the analysis chip when the set unit (15) is stored therein, the analysis portion is disposed in a position where the analysis chip is analyzed when the set portion (15) is accommodated in the accommodation chamber, and in the accommodation chamber, the direction of the air blown by the blower fan (19) and the rotation direction of the analysis chip rotated by the drive unit (16) are opposite to each other, or the direction of the air blown by the blower fan (19) is perpendicular to the rotation direction of the analysis chip rotated by the drive unit (16) and is toward the analysis chip