A conveyor assembly for transporting a carrier coupled to a receptacle to a processing station located within a housing of an instrument. The conveyor assembly includes a spur conveyor subassembly and a buffer conveyor subassembly for transporting the carrier from a host conveyor assembly to the spur conveyor subassembly. The spur conveyor subassembly includes (i) a rotatable diverter having at least one recess for receiving and moving the carrier between the buffer conveyor subassembly and the spur conveyor subassembly and (ii) a gripper configured to grasp the carrier and move it from the diverter to the processing position located within the housing of the instrument.

A conveyor assembly for transporting a carrier coupled to a receptacle to a processing station located within a housing of an instrument. The conveyor assembly includes a spur conveyor subassembly and a buffer conveyor subassembly for transporting the carrier from a host conveyor assembly to the spur conveyor subassembly. The spur conveyor subassembly includes (i) a rotatable diverter having at least one recess for receiving and moving the carrier between the buffer conveyor subassembly and the spur conveyor subassembly and (ii) a gripper configured to grasp the carrier and move it from the diverter to the processing position located within the housing of the instrument.

An automated conveyor assembly for transporting a carrier coupled to processing receptacle from (i) a carrier conveyor assembly to (ii) a processing position within an instrument, where the automated conveyor assembly includes a gripper configured to selectively grasp a carrier and move between (i) a first position and (ii) the processing position in the instrument. The automated conveyor assembly further includes a diverter defining a recess configured to receive a carrier, the diverter being rotatable between (i) a first position at which the recess is aligned with the carrier conveyor assembly and (ii) a second position at which the recess is aligned with the first position of the gripper.

The invention discloses a digital slide scanner sample identification device, and relates to the digital slide scanner for solving the problem that a bar code scanner can normally read a bar code label through the light contact, and the samples cannot be read due to the shielding of the bar code since the samples are stored in the digital slide scanner or scanning samples are stacked. The device comprises a digital slide scanner, and scanning samples; a near-field communication NFC read-write module is arranged in the digital slide scanner, and a NFC label is arranged on each scanning sample. By using the NFC technology, the NFC label data in a large amount of scanning samples can be read within short time, a feedback indication can be provided, and the working efficiency is greatly improved. The invention further discloses a digital slide scanner sample identification method.

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.

The present invention provides improved methods, facilities and systems for parallel processing of biological cellular samples in an efficient and scalable manner. The invention enables parallel processing of biological cellular samples, such as patient samples, in a space and time efficient fashion. The methods, facilities and systems of the invention find particular utility in processing patient samples for use in cell therapy.

To provide an automatic analyzer and a sample aspiration method in an automatic analyzer capable of analyzing a sample of further minute amount compared than before. In aspirating the sample, a sample dispensing mechanism 13, 14 is controlled so as to detect the liquid level L1, to thereafter allow a dispensing probe 13a, 14a of the sample dispensing mechanism 13, 14 to be dropped and stopped below the liquid level L1, to thereafter allow the dispensing probe 13a, 14a of the sample dispensing mechanism 13, 14 to be elevated and stopped, and to thereafter allow the dispensing probe 13a, 14a of the sample dispensing mechanism 13, 14 to be further dropped while aspirating the sample.

A memory device is provided. The memory device includes a memory array including a plurality of sections, and an inter-hamming difference analyzer. Each of the sections has an individual location in the memory array. The inter-hamming difference analyzer is configured to obtain a plurality of inter-hamming differences according to the number of unlike bits between content of each section of the plurality of sections corresponding to a first operating condition and content of another section of the plurality of sections corresponding to a second operating condition.

An embodiment of the invention relates to systems and methods for detecting the orientation of sample carriers using two or more RFID tags. One or two dimensional matrix of equally spaced RFID reader antennas may be positioned beneath or within an area on which racks are placed. The first RFID tag defines the origin of the sample carrier and its geometry. The second and additional RFID tags define the orientations of the sample carrier relative to the matrix of the RFID reader antennas. At least two of the tag antennas on the rack align uniquely with two antennas on the reader matrix. The system energizes each reader antenna and associates the RFID tags aligned with them to the RFID reader antenna's physical position.

A method is provided for associating an RFID tag to an RFID reader antenna in a laboratory device with a number N RFID reader antennae, the method including the steps of reading a unique identifier corresponding to each of a number M of RFID tag(s); registering received signal strength indications by each of the N RFID reader antennae of corresponding response signals from each RFID tag(s) and associating each RFID tag with the reader antenna having received the strongest received signal strength indication corresponding to the RFID tag. A laboratory device is also provided which is configured to perform the disclosed method.