A laboratory distribution system is presented. The system comprises diagnostic laboratory container carriers and a conveyor. The conveyor comprises an endless drive defining a closed-loop conveyor pathway. The system comprises supporting elements attached to the endless drive. The supporting elements receive a container carrier and transport the container carrier in an upright position along a pathway section. The supporting elements are mounted pivotally about a horizontal pivot axis to the drive and structured such that a center of gravity of the supporting element with or without an empty or loaded container carrier is arranged below and vertically aligned with the pivot axis when the supporting element is in an upright position such that each supporting element is free to pivot about the associated pivot axis under the effect of gravitational forces acting on the supporting element for maintaining the supporting elements in an upright position while travelling along the path.

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.

A PCR amplification and product detection system is disclosed. The system utilizes a uniform and direct photonic heating subsystem to mediate reaction-by-reaction, high-throughput PCR amplification detectable by a fluorescence detection subsystem. Reaction-by-reaction temperature monitoring for dynamic feedback heat regulation is also disclosed. Also disclosed are methods for using the same.

A laboratory automated system can include a host conveyor assembly configured to transport a plurality of carriers and receptacles coupled thereto between at least a sample processing instrument and at least one assay instrument. The system includes an intermediate conveyor assembly configured to transport a plurality of carriers and receptacles coupled thereto from within sample processing instrument to the host conveyor assembly. The system also includes an intermediate conveyor assembly for each assay instrument configured to transport a plurality of carriers from host conveyor assembly to a respective processing position within the assay instrument. The intermediate conveyor assembly coupled to the assay instrument can include a buffer conveyor subassembly configured to receive carriers from the host conveyor assembly, and a spur conveyor assembly configured to transport a carrier to the processing position of the assay instrument.

Automatic device for the automated conduct of analyses, notably medical analyses, including: a storage zone for bottles, an automated sampling system for selectively sampling the content of a bottle among those present in the storage zone, a loading zone for introducing a new bottle into the automatic device, an unloading zone for collecting a bottle previously present in the storage zone, a bottle conveyor and storage system, configured selectively and individually to transport a bottle from a location in the storage zone to the unloading zone or from the loading zone to a location in the storage zone.

The present invention relates to a horizontal-flow-type apparatus for automatically transporting reagent cartridges. The apparatus includes: a magazine (110) in which a plurality of reagent cartridges (1) is stacked; a conveyer belt (120) having a plurality of separating projections (121) arranged in a conveying direction to horizontally separately convey the reagent cartridges (1); a driving motor (130) for driving the conveyer belt (120); a feeding unit (140) for feeding the reagent cartridges (1) stacked in the magazine (110) onto the conveyer belt (120); an examining unit (150) disposed over the front end of the conveyer belt (120) to examine the reagent cartridges (1); and reagent cartridge aligning members (161, 162) disposed in the conveying line of the conveyer belt (120), opposite to the examining unit (150), to align the reagent cartridges (1) in position.

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.

Provided is a biochemical reaction substrate which can achieve higher test sensitivity and shorter testing time in an allergy test, which can also reduce a required amount of blood or the like needed as a specimen and decrease the number of test steps, thereby facilitating performance of the test, and which is to be used in an allergy test in which infection risk of the test staff is reduced. A biochemical reaction substrate, including: a reaction plate; an absorber; a reaction plate storing portion for storing the reaction plate; an absorber storing portion for storing the absorber; a storage container having a heated portion; and a cover assembled to the storage container so as to cover at least a part of the reaction plate and the absorber stored in the storage container, wherein the reaction plate includes a reaction area in which a specific binding substance that specifically reacts with a substance to be tested in a specimen is immobilized, and a flow passage that connects the absorber and the reaction area, and wherein the cover includes an injection hole for injecting a specimen or the like into the reaction plate.

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 laboratory automated system includes a conveyor assembly, a dock that that is movable between first and second positions, a drive assembly for moving the dock between the first and second positons, and a diverter for diverting a sample receptacle carrier from the conveyor assembly to the dock. The dock includes a first carrier support portion having a planar surface for supporting the sample receptacle carrier as the dock moves between the first and second positions. The dock includes an upwardly extending second carrier support portion situated adjacent the first carrier support portion. The second carrier support portion has a contoured side surface. The dock includes one or more magnets fixedly contained within or disposed on the second carrier support portion to magnetically couple with a magnetic portion of the sample receptacle carrier.