The invention allows a rack storage mode to be set in accordance with the situation in a facility. A testing system 1 includes a storage device 240 for storing a rack R holding containers A in which samples tested by the testing units 13 and 14 are accommodated, and the storage device 240 includes a table 130 capable of accommodating a plurality of racks R, a setting unit 230 for setting a first mode for starting storage of a plurality of racks R from a first end 130a of the table 130 and a second mode for starting storage of a plurality of racks R from a second end 130b of the table 130, and a moving device 102 for moving the rack R according to the mode set by the setting unit 230.

Disclosed is a testing apparatus comprising a disposal container body comprising: a first opening portion that faces upward to receive a used test piece dropped by a test piece transfer part of the testing apparatus, wherein the test piece transfer part is configured to transfer the used test piece to the first opening portion; and a second opening portion that faces laterally to receive a liquid waste and to which an end of a discharge pipe of the testing apparatus is inserted, wherein the discharge pipe is configured to transfer the liquid waste to the second opening portion.

Detection apparatus includes a microfluorometer having an objective, an excitation radiation source, and a detector. The detection apparatus also includes a fluidic system for delivering reagents from a reagent cartridge to a flow cell. The fluidic system includes a manifold body having a plurality of fluidic channels configured for fluid communication between the reagent cartridge and the flow cell. The fluidic system also includes a plurality of reagent sippers. The fluidic system also includes a valve configured to mediate fluid between reagent reservoirs and the flow cell. The detection apparatus also includes a flow cell latch clamp module having a clamp cover for holding the flow cell. The objective is configured to direct excitation radiation from the radiation source to the flow cell and to direct emission from the flow cell to the detector. The microfluorometer is movable to acquire wide-field images of different areas of the flow cell.

A cassette (130) configured to enable measurement of at least one biomarker value of a milk sample of an animal (100). The cassette (130) includes a tape distributing spool (131); a tape (170) with a plurality of dry sticks (180a, 180b, 180c), configured to indicate the biomarker value of the milk sample, and a top film (310) arranged to protect the dry sticks (180a, 180b, 180c) while rolled up on the tape distributing spool (131); a tape collecting spool (132), configured to collect used dry sticks (180a, 180b, 180c); and a top film reel (330), arranged to peel off and collect the top film (310) of the tape (170).

Aspects of the present disclosure include systems and methods. According to certain embodiments, provided is an integrated analysis system that includes a first module including a sample analysis component and a first internal container conveyor system. The integrated analysis system further includes a second module including a second internal container conveyor system. The first and second modules are positioned adjacent each other such that the first and second internal container conveyor systems are aligned and adapted to transport containers from the first module to the second module. Also provided are methods of analyzing and preparing samples (e.g., blood and body fluid samples), as well as components that find use within the analysis systems of the present disclosure.

The present invention provides a production-line-type high-throughput screening system, which relates to the field of biotechnology and testing equipment. The system comprises of four manipulators, three parallel conveyor belts with fixed slots, 2-DOF slipway and fixed fixtures, 96-channel pipetting system, coloring device, oscillating mixing device, microplate reader, well plates loading platform and well plates recycling platform. Manual operation takes five minutes to detect one 96-well plate, while this system can handle 20 96-well plates per minute. It expands the number of screening targets, making the screening process more clearly and concisely and liberating manual labor. The system makes effective contributions to the development of microbial breeding technology.

An apparatus for conveying a plurality of articles includes a transport belt, a bumper stopper, and a rotator. A motor moves the transport belt which is adapted to rotate the rotator as the belt conveys the plurality of articles. The stopper can move between first and second positions relative to the transport belt wherein the bumper stopper guides one article toward the rotator when the bumper stopper is in the first position. The bumper stopper allows the article to be conveyed to another location when the bumper stopper is in the second position. The transport belt can continue to convey other articles while the one article is temporarily held in place by the bumper stopper. The rotator is configured to rotate the article conveyed by the transport belt. The article can remain in contact with the transport belt while the rotator is rotating the article.

Aspects of the present disclosure include systems and methods. According to certain embodiments, provided is an integrated analysis system that includes a first module including a sample analysis component and a first internal container conveyor system. The integrated analysis system further includes a second module including a second internal container conveyor system. The first and second modules are positioned adjacent each other such that the first and second internal container conveyor systems are aligned and adapted to transport containers from the first module to the second module. Also provided are methods of analyzing and preparing samples (e.g., blood and body fluid samples), as well as components that find use within the analysis systems of the present disclosure.

Systems and methods are provided for processing a biological sample. In one embodiment, the method comprises receiving a sample vessel containing the sample; retrieving information from an information storage unit associated with the sample; using said information for selecting at least one cartridge front at least two or more different cartridges, each configured for use with a sample processing device; loading at least one or more reagents onto the cartridge, wherein the one or more reagents to be added are selected based at least in part on the information or instructions derived from the information; and placing the sample vessel in the cartridge.

An apparatus for conveying a plurality of articles (10) includes a transport belt (6), a bumper stopper (14), and a rotator (12). A motor moves the transport belt which is adapted to rotate the rotator as the belt conveys the plurality of articles. The stopper can move between first and second positions relative to the transport belt wherein the bumper stopper guides one article toward the rotator when the bumper stopper is in the first position. The bumper stopper allows the article to be conveyed to another location when the bumper stopper is in the second position. The transport belt can continue to convey other articles while the one article is temporarily held in place by the bumper stopper. The rotator is configured to rotate the article conveyed by the transport belt. The article can remain in contact with the transport belt while the rotator is rotating the article.