According to an example aspect of the present invention, there is provided a method of information transmission in a system comprising at least one liquid handling device and at least one external device, the method comprising: in one or more of said at least one liquid handling device, producing a machine-readable code that contains information that is derived from a status or properties of the respective liquid handling device or information that has been stored in the respective liquid handling device; in said one or more of said at least one liquid handling device, displaying the respective code on a display that is integrated to a structure of the respective liquid handling device; reading the displayed code or one or more of the displayed codes by an external device.

A method and system for analyzing a sample potentially comprising a target, comprising: (i) activating one or more components of the sample analysis system in preparation for a sample, wherein the sample analysis system comprises a heating element, a centrifuge, a thermocycler, an imager, a user interface, and a processor; (ii) obtaining a sample potentially comprising a target; (iii) adding the obtained sample to a sample preparation receptacle, the sample preparation receptacle comprising one or more reagents configured to maximize success of the sample analysis; (iv) heating the sample preparation receptacle, with the added sample, in the heating element of the sample analysis system at a first temperature for a first heating period of time; (v) centrifuging the sample preparation receptacle, after heating, for a first period of time using the centrifuge of the sample analysis system; (vi) transferring at least a portion of the sample, after centrifugation, from the sample preparation receptacle to a sample analysis receptacle, the sample analysis receptacle comprising one or more reagents configured for a qPCR reaction specific to a selected target; (vii) obtaining, via the thermocycler and imager of the sample analysis system, a fluorescence curve during a qPCR reaction; (viii) analyzing, by the process of the sample analysis system, the obtained fluorescence curve to determine a presence or absence of the selected target in the sample; and (ix) reporting, to a user by the user interface of the sample analysis system, the presence or absence of the selected target in the sample; wherein one or more steps of the method are guided by interactive instructions provided by the sample analysis system.

Device (100) for attesting the operations of an in-vitro diagnostic device (50) comprising: a block (101) for capturing a plurality of frames of the tip (51); a block (102) for storing the plurality of frames; a block (103) for evaluating the right hooking of the tip (51) to the in-vitro diagnostic device (50); a block (104) for evaluating the volume of a liquid contained in the tip (51); a block (105) for carrying out verification before the operation of dispensing the liquid; a block (106) for carrying out a post-dispensing verification; blocks (107, 108) for emitting electronic signals; a block (109) for integrating a system for managing the errors; a block (110) for saving the data; a block (111) for communicating with the in-vitro diagnostic device (50).

This invention relates to a handheld mobile device which can analyze and measure whole blood, serum, urine or analytes which contain target agents such as mycotoxin, aflatoxin or cholera etc. with a easy to use reusable cartridge consisting of a cartridge head and cartridge body. The cartridge comprises four syringes, one of which being detachable. A waste reservoir is integrated with the syringes.

Systems and methods for safe collection and transportation of fluid samples for analysis are described to avoid exposure of hazardous materials to personnel during collection and transfer of samples to laboratory processing equipment. A system embodiment includes, but is not limited to, a sample module including an enclosure configured to separate a sample from an external environment; a filling station defining a compartment into which the sample module can be received, the filling station configured to direct a fluid sample into the sample module and to rinse fluid connections between the filling station and the sample module prior to decoupling of the sample module from the filling station; and a sample transfer station configured to receive the sample module and to transfer sample from the sample module and direct the sample into a sample container.

To provide a high-throughput automatic analysis apparatus at a lower cost. The automatic analysis apparatus includes an incubator which accommodates a plurality of reaction vessels; a specimen dispensing mechanism which dispenses a specimen into each of the plurality of reaction vessels; a mounting unit which mounts a dispensing tip on the specimen dispensing mechanism; a suction unit which sucks a specimen from a specimen vessel containing the specimen by means of the specimen dispensing mechanism having the dispensing mounted thereon; a discharging unit which is provided in the incubator and discharges the specimen from the specimen dispensing mechanism to the reaction vessel; a disposal unit which discards the dispensing tip; a sensor which detects whether the dispensing tip is mounted to the specimen dispensing mechanism; and a control unit which controls the specimen dispensing mechanism. The mounting unit, the suction unit, the discharging unit, and the disposal unit are arranged along a movement path of the specimen dispensing mechanism. The sensor is arranged so as to be able to detect the dispensing tip at a position sandwiched between any two of the mounting unit, the suction unit, the discharging unit, and the disposal unit.

Systems and methods are provided for recognizing various sample containers carried in a rack. The systems and methods are performed to identify sample containers in the rack and detect various characteristics associated with the containers and/or the rack, which are evaluated to determine the validity and/or types of the containers in the rack.

In an automatic analyzer where a plurality of types of separation column are selectively used for performing a chromatographic analysis, an automatic analyzer configured to install a separation column of an intended type at an aimed position, and a method for installing the separation column in the automatic analyzer are provided. Identification mechanisms, a computer, and a display unit are included. The identification mechanisms read identifiers included in separation columns when the separation columns are installed at installation positions. The computer determines whether identification information of the identifiers read by the identification mechanisms matches an installation pattern registered in advance or not. The display unit notifies an alarm when the identification information is determined not to match the installation pattern by the computer.

An object of the present disclosure is to provide a technique capable of acquiring an analysis target region and color information without causing a decrease in extraction accuracy of the analysis target region due to erroneous extraction of a color of a colored label, measuring a solution volume of the specimen, and determining a specimen type. The biological specimen analysis device according to the present disclosure creates a developed view by cutting out a partial region from a color image of a biological sample tube and connecting the partial region along a circumferential direction of the biological sample tube, and extracts a detection target region from the developed view (see FIG. 6B).

A system for biological analysis includes a housing, a block assembly within the housing having a sample block and a baseplate, a heated cover and a cover carrier. The sample block receives a sample holder comprising an RFID tag. A first drive mechanism generates relative movement between the sample block and the baseplate along a first axis. A second drive mechanism generates relative movement between the heated cover and the cover carrier along a second axis that is different from the first axis. Based on a first command the first drive mechanism releasably engages the sample block and operates the second drive mechanism to releasably engage the heated cover with the cover carrier. The system also includes first and second RFID antennas that receive RFID data from the sample holder RFID tag that is read by at least one RFID reader.