Methods and systems for managing a petri-dish. Embodiments herein disclose a RFID tag affixed on the petri-dish, wherein the RFID tag has a thin formfactor, so as not to interfere in the use and operation of the petri-dish and a sufficiently large readability range. Embodiments herein disclose methods and systems for RFID based asset tracking of petri-dishes in a laboratory/pharmaceutical/manufacturing environment, wherein the movement of the petri-dishes are tracked automatically with minimal manual intervention.

Provided are a PCR tube that can reliably perform management of a sample, and an RFID sample management system and an RFID sample management method using the PCR tube. The PCR tube 40 includes a tube body 42 that has an opening at one end and has a collar part 46 around the opening, and a lid part 44 that is attachably and detachably mounted on the tube body 42 and seals the opening of the tube body 42 at the time of the mounting. An RFID tag 48 having a passive antenna built therein is provided at the collar part 46 or the lid part 44, and the antenna has directivity in a direction opposite to a bottom face 42a of the tube body 42.

A sample storage device may include: a storage chamber; paired rail sections separated in separating direction and extending in an extending direction; an antenna array substrate extending between the rail sections and having antennas; paired slide sections separated from each other in the separating direction and disposed at a position opposite to the antenna array substrate with respect to the rail sections and, so as to be slidable in the extending direction relative to the rail sections, respectively; a support plate transparent to radio waves, extending between the slide sections; and a storage box containable a plurality of containers each holding a sample and a radio tag, the storage box to be set on the support plate such that radio waves can be transmitted between the radio tag and corresponding one of the plurality of antennas.

A thin-walled microplate suitable for use in the Polymerase Chain Reaction (PCR) technique comprising a plurality of thin-walled tubes or wells arranged in a fixed array, each well having an upper portion with an open top and a lower, frustoconical portion having a substantially flat bottom.

A reaction vessel for a diagnostic analyzer comprising a plurality of processing stations. The reaction vessel comprises at least one sensor configured to measure at least one physical parameter associated with at least one of the processing stations of the diagnostic analyzer when disposed at the at least one of the processing stations, a memory configured to at least temporarily store at least one measurement value indicating the physical parameter provided by the sensor, a processing unit configured to control the sensor and to output measurement data including the measurement value from the memory, an interface configured to provide communication of the processing unit with an external electronic device, a power source configured to supply electric power to the sensor, the processing unit and the memory. The reaction vessel defines an internal volume. The sensor, the processing unit, the memory and the interface are arranged within the internal volume.

A reagent analyzer comprising an imaging system having a first field of view of a reagent test device and a second field of view of a fluid sample information indicator, and configured to capture a first image depicting the reagent test device and a second image depicting the information indicator; a mirror moveable between a first position outside the first field of view and a second position inside the first field of view and located between the imaging system and the reagent test device, the mirror in the second position reflecting light to produce the second field of view; and a processor executing instructions to: receive the first and second images; analyze the first image to determine calibration information from the information indicator; and analyze the second image to determine constituent presence/absence in the fluid sample applied to the reagent test device, using, in part, the determined calibration information.

A closure and a container assembly are disclosed. The closure includes a first visual identifier and a second visual identifier, wherein the second visual identifier is different from the first visual identifier. The first visual identifier may be a first color, and the second visual identifier may be a second color. At least one of the first and/or second visual identifier may include a fluorescent compound having a characteristic fluorescent spectra. The first visual identifier and the second visual identifier may be provided on the annular skirt of the closure. The fluorescent compound may be provided on at least one of the closure and the container assembly and can be used to facilitate automated visualization of the fluorescent compound under fluorescence excitation light.

The present invention relates to a nucleic acid amplification test apparatus, and an automatic sample analysis system having same and, more particularly, to a nucleic acid amplification test apparatus in which separation and purification, dispensation, amplification, and testing of samples are performed integrally, and an automatic sample analysis system having same. Disclosed in the present invention is a nucleic acid amplification test apparatus comprising: a housing (30) having an inner space (S1) isolated from the outside; a multi-well plate insertion unit (100) into which a multi-well plate (40) having a plurality of reaction tubes (1) accommodating a target nucleic acid solution is inserted through an automatic purification and dispensing apparatus (10); a sealing plate insertion unit (200) into which a sealing plate (50) having a sealing means for sealing the inlets of the plurality of reaction tubes (1); a fluorescence detection unit (400) disposed on an upper side of the sealing plate insertion unit (200) and detecting a target nucleic acid in the reaction tubes (1); and a temperature control block (500) disposed on a lower side of the multi-well plate insertion unit (100) and controlling the temperature of the reaction tubes (1), wherein the reaction tubes (1) are moved relatively so as to be adjacent to the sealing means to be then sealed by the sealing means.

An analytic plate or other substrate having a permanent etchable, laserable, and/or developable marking surface coating (referred to herein as an “etchable coating” or as a “developable coating”) that is present on at least a portion of any side or surface thereof and is used to deposit a permanent indicium thereon, and a method of using the analytic plate or substrate.