A cartridge reader controlled by processing means for carrying out a diagnostic test on a sample contained in a fluidic cartridge comprises a mechanical valve for isolating the sample with the cartridge. A system for actuating the mechanical valve comprises an actuation member configured to move the mechanical valve from an open position to a closed position and an armature connected to the actuation member. The armature is configured to engage an electromagnet, wherein the electromagnet can be switched between an active state in which it electromagnetically holds the armature and an inactive state in which it does not electromagnetically hold the armature. First biasing means arc disposed between the actuation member and a bearing surface, wherein the first biasing means is configured to bias the actuation member into a first position in which it actuates a mechanical valve in a fluidic cartridge inserted into the reader.

An incubation system includes an actuator, a platform, an incubation lid, and a dispenser. The actuator includes a motion disc and a shaft connected to the motion disc. The shaft extends away from the motion disc. The platform is connected to the shaft of the actuator in a manner allowing movement transmission. The platform has a through hole and a thermal conductive plate. One end of the through hole is sealed by the thermal conductive plate. The incubation lid is movably disposed over the platform. The platform is thermal insulating. The incubation lid has an opening allowing fluid communication, and the dispenser suspends over the thermal conductive plate of the platform.

A switchable hydrophilic surface is created by attaching electrochemically switchable hydrophilicity polymers to the surface of a microelectrode array. Ferrocene polymers are one example of electrochemically switchable hydrophilicity polymers. Activation of electrodes in the microelectrode array changes the oxidation state of metal ions which switches the polymers between hydrophobic and hydrophilic conformations. Selective activation of electrodes can create patterns of wettability on the microelectrode array that may be varied in real time. The switchable hydrophilic surface may be used to control solid-phase synthesis of polymers. Growing polymers may be selectively extended at locations on the microelectrode array that are hydrophilic. The pattern of hydrophobic and hydrophilic regions can be changed during sequential rounds of synthesis to create a variety of different polymers at different locations on the surface of the microelectrode array.

An infectious disease screening system (1) for screening for infectious diseases, such as COVID-19 disease. The system comprises an ultrasonic transducer (49) for generating ultrasonic waves to lyse cells in a biological sample. The system (1) comprises a controller which controls the ultrasonic transducer (49) to oscillate at an optimum frequency for cell lysis, a PCR apparatus (16) which receives and amplifies the DNA from the sample; and a detection apparatus (70) which detects the presence of an infectious disease in the amplified DNA and provides an output which is indicative of whether or not the detection arrangement (70) detects the presence of an infectious disease in the amplified DNA.

The present disclosure describes systems and devices capable of providing rapid polymerase chain reaction processes. A microfluidic card is insertable into a heating assembly. The heating assembly provides separate temperature zones to the card. The card includes a channel array that traverses repeatedly through the separate temperature zones so that a reaction mixture passing through the channel is subjected to thermal cycling.

A cartridge includes a substrate including a polymerase chain reaction (PCR) zone. The PCR zone includes a first heating region, a second heating region spaced away from the first heating region and a detection region. A microchannel is formed in the substrate. The microchannel receives a fluid flowing therethrough, the microchannel passing through the first heating region and second heating region to thermally cycle the fluid. The microchannel passes through the detection region after the fluid has been thermally cycled.

Methods and systems for sample target molecules are provided.

A reaction processing apparatus includes: a reaction processing vessel; a first fluorescence detection device that irradiates a sample with first excitation light and detects first fluorescence produced from the sample; and a second fluorescence detection device that irradiates a sample with second excitation light and detects second fluorescence produced from the sample. The wavelength range of the first fluorescence and the wavelength range of the second excitation light overlap at least partially. The first excitation light and the second excitation light flash at a predetermined duty ratio d. The phase difference between the flashing of the first excitation light and the flashing of the second excitation light is set within a range of 2π(pm−Δpm) (rad) to 2π(pm+Δpm) (rad) or within a range of 2π[(1−pm)−Δpm] (rad) to 2π[(1−pm)+Δpm] (rad), where pm=d−d2 and −pm =0.01*pm.

A fully integrated and disposable point-of-care device for detecting a target nucleic acid is provided. The device comprises: an extraction chamber adapted to receive a biological sample, wherein said extraction chamber comprises means to extract and lyse the sample to release nucleic acid; a first amplification chamber in communication with the extraction chamber, wherein said amplification chamber comprises means to trigger nucleic acid amplification of a target nucleic acid sequence to occur; and a detection chamber in communication with the amplification chamber, wherein said detection chamber comprises means to detectably label the target nucleic acid and means to detect a signal associated with labeled target nucleic acid, or a single chamber for amplification, detection and identification of multiple nucleic acid sequences.

A microfluidic device for amplifying a nucleic acid includes a cartridge and a control part. The cartridge includes a tank part and a plurality of first chambers. The control part is configured to control execution of a thermal cycle, count a number of repetitions of the thermal cycle for each of the first chambers and store a count value, acquire a fluorescence intensity of each of the first chambers for each thermal cycle, and reset the count value of a defective chamber of which the fluorescence intensity is not within a predetermined range, discharge the solution from the defective chamber, and fill the defective chamber with a new solution from the tank part.