There is an apparatus (1) and a method for providing visual signals relating to a plurality of laboratory sample carriers (2). Laboratory sample carriers (2) are placed on corresponding carrier bays (6) of a tray (4) wherein each sample carrier (2) displays an identification code (5). A digital image of at least part of the tray (4) is taken with a digital camera (11). The digital image is processed with a processing device (13) to read the laboratory sample carrier identification codes (5) in the image. A visual signal emitting device (10) is activated to emit at least one visual signal for each occupied carrier bay (6) included in the image wherein the visual signal emitted for each carrier bay (6) is determined by the sample carrier identification code (5) read by the processing device (13) from a corresponding carrier bay part of the processed image.

A blood gas analyzer (1) for performing a measurement on analyte parameters in a blood sample, such as a whole blood sample, aspirated into the blood gas analyzer from a blood sample container comprises an output device, such as a monitor (30), for outputting instructions to a user of the blood gas analyzer for the user's handling of the one or more of the user-accessible parts of the blood gas analyzer, such as for maintenance purposes, and/or for replacement of sensor cassettes, gaskets, probes, solution packs, etc. A controller (8) is provided for receiving a signal, on the basis of which it is determined if an instruction, such as an animated video instruction, is to be presented to the user. In the affirmative, the controller selects one of a plurality of pre-stored sets of instructions for outputting at the output device.

The present invention provides a LAMP assay device that promotes isothermal RNA/DNA amplification applied to pathogen identification, comprising: a LAMP assay chamber (1); an electronics cabinet (4), a power supply means (7); and a top lid (2) for closing the LAMP assay chamber (1), wherein internally the device comprises: a metal cylindrical thermoblock (8) comprising openings (80) for positioning microtubes (81); a control board with central processing (14); a power electronics board (13); at least one heating element (10) in contact with the thermoblock (8) and adapted to heat the thermoblock (8) by induction; a temperature sensor (9) adapted to measure the temperature of the thermoblock (8); a plurality of RGB LEDs (12) positioned below the thermoblock (8) and adapted to excite each microtube positioned in the thermoblock (8); and a camera (11) positioned below the thermoblock (8) and adapted to capture images of each of the microtubes (81) positioned in the thermoblock (8). In addition, the invention provides a method for pathogen identification from a LAMP assay device.

Reagent cartridges and related systems and methods for controlling reagent temperature are disclosed. In accordance with an implementation, an apparatus includes a system and a reagent cartridge. The system includes a reagent cartridge receptacle, a non-contact temperature controller, a processor operatively coupled to the temperature controller. The reagent cartridge is receivable within the reagent cartridge receptacle and includes a flow cell assembly, a plurality of reagent reservoirs, and a manifold assembly. The manifold assembly includes a common fluidic line and a plurality of reagent fluidic lines. Each of the plurality of reagent fluidic lines is adapted to be fluidically coupled to a corresponding reagent reservoir and selectively couplable to the common fluidic line. The processor is to cause the temperature controller to change a temperature of at least one of the common fluidic line or one or more of the reagent fluidic lines.

A reagent strip is described. The reagent strip includes a substrate and at least one reagent pad positioned on the substrate. The substrate has a storage unit storing an authentication code. The authentication code has a lot value and a secondary value related to the lot value by a predetermined function assigned to the lot value.

A method of generating a process for specimen collection is provided. The process includes receiving information about a scheduled specimen collection, determining supplies to complete the scheduled specimen collection, adding the supplies to a toolkit, and generating a standard operating procedure comprising information about the scheduled specimen collection, supplies and toolkit.

Systems, methods, and collection devices are disclosed for rapid, local PCR testing. The system may include a PCR testing module, memory configured to store computer-executable instructions, and at least one computer processor configured to access the memory and execute the computer executable instructions to: (i) receive an order for a PCR diagnostic test; (ii) associate a sample collection device (SCD) received by the PCR testing module with the order for a PCR diagnostic test; (iii) instruct the PCR testing module to conduct the PCR diagnostic test on a biological specimen in the SCD received by the PCR testing module; and (iv) cause presentation of results of the PCR diagnostic test.

Systems and methods are disclosed for rapid PCR testing. Example embodiments may include a PCR testing module that includes a housing having a PCR machine disposed therein; a sample input station on the housing, wherein the sample input station is configured to receive a sample collection device (SCD) comprising a biological specimen sample provided by the patient; an SCD processing mechanism configured to transfer a lysed microportion of the biological specimen sample into a PCR sample tube attached to the SCD; at least one mechanism configured to separate the PCR sample tube from the SCD and transfer the PCR sample tube to the PCR machine; and a controller configured to (i) use the PCR machine to conduct a PCR test on contents of the PCR sample tube, and (ii) generate results of the PCR test.

A system for diagnostic testing may include a meter for performing a diagnostic test on a sample applied to a test media, the meter having a housing and an interface for receiving a signal representing coding information, and a container configured to contain test media compatible with the meter, the container having a coding element associated therewith. Additionally, the system may provide a mechanism for removing the meter from an interconnected test container and reattaching it to a new container using on-container coding methods that can recalibrate the meter for the new container of test strips.

A system for virus detection in a sample from a subject includes a microchip comprising at least one channel containing the sample from the subject and a mobile device. The sample is processed with nanoparticles and a catalyzer that are configured to generate gas bubbles in the presence of a target virus on a surface of the microchip. The mobile device includes a camera configured to acquire an image of the microchip containing the sample from the subject, a neural network configured to receive the acquired image and to generate a probability regarding the presence of the target virus in the sample from the subject based on the acquired image, and a display coupled to the neural network and configured to display the probability regarding presence of the target virus in the sample from the subject.