A sample measurement system includes: a measurement unit that measures a sample stored in a sample container; a transport unit that transports a rack capable of holding sample containers via the measurement unit; a first transport-in/transport-out unit and a second transport-in/transport-out unit in each of which racks can be set alongside in a first direction, and that send the set racks to be transported to the measurement unit and receive the racks transported from the measurement unit; and a controller that controls the first transport-in/transport-out unit and the second transport-in/transport-out unit so that the racks are sequentially sent from the first transport-in/transport-out unit and the second transport-in/transport-out unit. The first transport-in/transport-out unit and the second transport-in/transport-out unit are disposed alongside in a second direction crossing the first direction, and each send the racks from one side in the first direction, and receive the racks from the other side.

A sample measurement system may include: a measurement unit that measures a sample in a sample container; a transport unit that transports a rack that can hold sample containers, via the measurement unit; a collection unit that is detachably provided with a tray in which racks can be set, and that collects the rack transported from the measurement unit by the transport unit and sets the rack in the tray; a storage that stores sample identification information, rack identification information, and tray identification information in association with each other; an input part; a display part; and a controller that, in a condition in which the input part receives input of the sample identification information or the rack identification information, causes the display part to display the tray identification information stored in association with the inputted sample identification information or the inputted rack identification information.

A scheduling system includes a receiving system and a transfer system. The receiving system receives a carrier carrying a biological sample. The transfer system transfers the sample carrier between biochemical reaction platform and detection platform, so that a sample in the sample carrier performs a biochemical reaction on the biochemical reaction platform, and a signal from the reacted sample can be detected on the detection platform. The present disclosure further provides a scheduling method, a scheduling control system, a biochemical analysis system and device, and a computer-readable storage medium. The present disclosure improves a degree of automation of sample carrier scheduling, and realizes simultaneous analysis of multiple sample carriers to improve a testing throughput.

A system for nucleic acid amplification is to synthesize amplified target nucleic acids or determine the presence of target nucleic acid. The mobile device of the system implements with an interface for controlling the reaction as well as optionally recording or delivering the reaction results or protocols to a cloud for sharing. In addition, current invention also discloses an airborne molecule detector integrating both air sampler and biochemical analysis component. The device can monitor the bioaerosols on real time. The reaction product can be used for nucleic acid sequencing as well. Furthermore, a pH test strip is used to replace a halochromic agent in a reaction mix for determining the nucleic acid amplification.

A transport system includes a sample rack configured to hold a sample and comprising a notch; a rack storage unit in which the sample rack is stored; a transport path arranged to transport the sample rack moved from the rack storage unit; and a regulating member configured to regulate movement of the sample rack from the rack storage unit toward the transport path, wherein the regulating member is provided at a position corresponding to the notch provided in the sample rack, and enters an interior of the sample rack from the notch and abuts an interior wall of the sample rack as the sample rack moves from the rack storage unit toward the transport path.

Methods and apparatus of inspection tools for inspecting impurities in vials are provided herein. In some embodiments, an inspection tool for inspecting impurities in vials includes: a table for inspecting a plurality of vials; one or more carts configured to move about the table to place the one or more carts in an inspection position, wherein each of the one or more carts includes a vial holder configured to hold a plurality of vials, and wherein each vial holder is configured to spin the plurality of vials on their own respective axes; and a camera configured to take images of the plurality of vials when the plurality of vials are disposed in the inspection position.

This automated analysis device is provided with a plurality of analysis units for analyzing a specimen, a buffer portion which holds a plurality of specimen racks on which are placed specimen containers holding the specimen, a sampler portion which conveys the specimen racks held in the buffer portion to the analysis units, and a control portion which, when performing a process to deliver the specimen racks to the plurality of analysis units, outputs synchronization signals to all the plurality of analysis units, wherein the analysis unit performs a delivery process starting from the synchronization signal, and the analysis unit performs a delivery process starting from the synchronization signal.

An embodiment of the disclosure is a rack adapted to engage a rack handler. The rack includes a rack body. The rack body has a bottom, a top opposite the bottom, and a receptacle that extends from the top toward the bottom. The receptacle is sized to receive the sample collection unit. The rack body has a first interior surface that extends from the bottom toward the top, and a second interior surface that extends from the bottom toward the top. The second interior surface is opposite to the first interior surface so as to at least partially define a slot along the bottom. The rack body also includes an interference groove in the slot along at least one of the first interior surface and the second interior surface. The slot and the interference groove are sized to engage a portion of the rack handler.

A sample analysis system includes a first measurement unit, a second measurement unit arranged to a downstream side of the first measurement unit, and an information processing section which obtains a measurement result of a sample. The information processing section determines, based on the measurement result of the sample measured by the first measurement unit, whether or not a retest of the sample by the first measurement unit is necessary. When the retest by the first measurement unit is necessary, the information processing section causes the sample container to be transported to a first sample supply position for the first measurement unit and causes the first measurement unit to perform measurement of the sample.

An automated system for preparing a biological sample containing biological species, and including a support plate wherein one or more through-wells are made, each through-well having two opposite accesses, a first access and a second access, the first access being separated from the second access by a filter-forming porous wall against which the biological sample that is to undergo lysis may be placed, and, for each well: a first mobile member, that can be actuated to move translationally along the axis of the well so as to become inserted across the first access thereof, a second mobile member, that can be actuated to move translationally along the axis of the well so as to become inserted across the second access thereof, stimulation means of mechanical and/or thermal type for stimulating each first mobile member and/or each second mobile member and/or the support plate.