The present invention provides an automatic blood-sampling tube preparation system which can reduce the reading mistake of the information of the RFID tags by selectively taking out a blood-sampling tube required to an examination of a patient according to a doctor's instruction information from the blood-sampling tube containing section, writing the patient examination information on a RFID tag of the taken out tube on the basis of the instruction information, reading simultaneously all patient examination information from all RFID tags contained in the prepared container for every patient, and comparing the information read from the RFID tags with the instruction information to ensure accuracy.

A test tube for containing a liquid and electrically connected to a blockchain network is provided. The test tube includes a tube body, a cover, at least one overlay unit, a chipset and a detection module. The tube body contains the liquid. The cover is disposed at the top of the tube body and including at least one drip tube. The overlay unit covers the drip tube. The chipset is disposed on the tube body and includes a blockchain tracer. The blockchain tracer records the source of the liquid and a transportation history of the test tube in the blockchain network for tracing. The detection module is disposed on the tube body and electrically connected to the chipset, for measuring a liquid property of the liquid.

A control method and a control apparatus for a paraffin dispenser in an embedder, a paraffin dispenser and an embedder are provided. The control method includes: collecting information of a current mold so as to acquire an identification of the current mold; determining whether the identification of the current mold is correct; and controlling the paraffin dispenser to pour paraffin into the current mold, when it is determined that the identification of the current mold is correct.

Devices and methods for measuring the quantity of multiple analytes in a sample can include a device designed such that each of the analyte sensing elements is configured to measure the quantity of a predetermined analyte and machine executable instructions configured to select the proper analyte sensing element corresponding to the analyte to be measured.

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.

A method of obtaining and analyzing at least one tissue sample includes forming, in a tissue container, first tracking data associated with the at least one tissue sample. Second tracking data is formed, in a transport container. The second tracking data is associated with the at least one tissue sample. The at least one tissue sample is placed in the tissue container. The first and second tracking data from the tissue container and the transport container are scanned with an electronic scanning system to ensure that the first and second tracking data are both associated with the removed tissue sample.

An inter-hamming difference analyzer for a memory array having a plurality of sections is provided. The inter-hamming difference analyzer includes a controller, a storage device and a comparator. The controller is configured to obtain contents of the plurality of sections operating in a first operating condition and a second operating condition. The storage device is configured to store the contents of the plurality of sections corresponding to the first operating condition. The comparator is configured to obtain a plurality of inter-hamming differences of the plurality of sections according to the number of unlike bits between the content of a first section of the plurality of sections corresponding to the second operating condition and the contents of a plurality of sections other than the first section stored in the storage device.

A diagnostic and treatment assembly, configured to diagnose and treat cellular disease. The diagnostic and treatment assembly has a radio wave generator communicatively coupled to a carrier modulator and a radio wave amplifier. An impedance matching system is electrically coupled to the radio wave amplifier. A reflected wave sensor is electrically coupled to the impedance matching system. A radiator applicator is electrically coupled to the reflected wave sensor. A vector impedance analyzer is electrically coupled to the radio wave amplifier. An information collector data network is electrically coupled to the vector impedance analyzer. A data logger is communicatively coupled to the carrier modulator, the vector impedance analyzer, and the reflected wave sensor. The diagnostic and treatment assembly operates in a low-power mode to diagnose a cellular disease and in a high-power mode to treat the cellular disease.

An example medical diagnostic system includes one or more containers that are usable in a medical diagnostic test. Each container has an identification (ID) tag associated therewith. An ID tag of a container includes memory that is readable and writeable. The memory is for storing information relating to the container. Antennas are configured to communicate wirelessly with ID tags associated with the one or more containers. A control system is configured to store a location of the container based on an identify of the antenna, to select the antenna for communication with the ID tag, and to use the antenna to read at least some of the information from, or to write at least some of the information to, the memory on the ID tag.

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.