A fluidic device for capturing or detecting a sample substance contained in a solution includes at least two continuous circulation flow channels selected from the group consisting of: a first type continuous circulation flow channel which is formed of a first circulation flow channel and a second circulation flow channel and which is configured to circulate the solution in the first circulation flow channel and then circulate the solution in the second circulation flow channel; and a second type continuous circulation flow channel which is formed of a third circulation flow channel and a fourth circulation flow channel and which is configured to circulate the solution in the third circulation flow channel and then circulate and mix the solution in both of the third and fourth circulation flow channels, wherein any one of the circulation flow channels has a capturing section which captures the sample substance, and/or a detecting section which detects the sample substance.

A solid reagent containment unit is formed by a support; a frame body fixed to the support and delimiting internally, together with the support, an analysis volume; a reagent-adhesion structure within the analysis volume; and at least one reagent cavity, which extends within the reagent-adhesion structure. The reagent-adhesion structure is of an adhesion material embossable at temperatures lower by 6-8° C. than its own melting point and has a melting point such as not to interfere with the analysis. The reagent cavity forms a retention wall, laterally surrounding the reagent cavity, and houses dried reagents. The adhesion material is chosen among wax, such as paraffin, a polymer, such as polycaprolactone, a solid fat, such as cocoa butter, and a gel, such as hydrogel or organogel.

The present invention provides a cartridge, a detection method, and a detection device capable of stabilizing the liquid level of a sample accommodated in a chamber in a predetermined state. A cartridge 20, that is rotated around a rotating shaft 42 for detecting a target substance, is provided with a chamber 100 in which a sample containing a target substance is stored. The chamber 100 includes a first region 110 in which a sample is stored, a second region 120 disposed at a position closer to the rotating shaft 42 than the first region 110, and a protrusion 130 protruding from a position between the first region 110 and the second region 120 to the inner side of the chamber 100.

A liquid handling device includes a common channel, a plurality of wells, a magnetic beads chamber and a plurality of valves. The plurality of valves are rotary membrane valves disposed on the circumference of a first circle. The magnetic beads chamber is disposed on a circumference of the second circle concentric with the first circle.

Devices and methods for immunomagnetic separation having a flexible inflatable processing chamber and magnetic array.

The present invention relates to the field of biomedical technology and discloses a cartridge and a testing device. The cartridge comprises a sample lysis compartment, a first sample mixing compartment and a first PCR compartment; a first valve is disposed between the sample lysis compartment and the first sample mixing compartment, the first valve controls the flowing or blocking of the sample between the sample lysis compartment and the first sample mixing compartment; a fourth valve is disposed between the first PCR compartment and the first sample mixing compartment, the fourth valve controls the flow or blocking of the sample between the first sample mixing compartment and the first PCR compartment; a first reagent is provided in the first sample mixing compartment. In the compartment, nucleic acids in the sample mix with the first reagent and is then sent to the first PCR compartment for amplification.

A method for extracting nucleic acids includes mixing a biological sample with a solid-phase substrate to produce a sample fluid. The nucleic acids in the sample fluid bind to the solid-phase substrate. The method also includes flowing the sample fluid in a fluid conduit to a trapping site. The trapping site may include a chamber. The method may further include applying a magnetic field to trap the solid-phase substrate of the sample fluid flowing through the fluid conduit at the trapping site. The method further includes flowing a wash buffer through the fluid conduit to remove impurities from the solid-phase substrate. The method further includes flowing an immiscible fluid through the fluid conduit to remove residual sample fluid and/or wash buffer. The method further includes flowing an elution buffer through the fluid conduit to elute nucleic acids from the solid-phase substrate.

A system for selective microcapsule extraction includes a non-planar core-shell microfluidic device. The non-planar core-shell microfluidic device generates microcapsules defining a core-shell configuration. A subset of the microcapsules contain aggregates, tissues, or at least one cell. A camera captures images of the microcapsules. A detection module includes a processor and a memory. The memory includes instructions that when executed by the processor causes the detection module to provide the images of the microcapsules as an input to a machine learning model. The machine learning model identifies microcapsules containing aggregates, tissues, or at least one cell. A force generator generates a force to extract the microcapsules. A microcontroller selectively activates the force generator to generate the force when the detection module identifies a microcapsule containing aggregates, tissues, or at least one cell to extract the microcapsule.

A hotplate device has a body with a platform for receiving a vessel that contains a sample to be heated. A heating element, arranged under the platform, provides heat to the platform, based on a set temperature and a measured temperature as sensed by at least one temperature sensor, proximate to the platform. A controller located in the body directs electrical power to the heating element. As a safety feature, a wireless communication feature allows a user to enter set temperature instructions from a mobile device when communication with the mobile device is enabled and established. A proximity feature, when enabled, allows the user to enter instructions only as long as the user remains in a predetermined proximity of the hotplate device.

A solid reagent containment unit is formed by a support; a frame body fixed to the support and delimiting internally, together with the support, an analysis volume; a reagent-adhesion structure within the analysis volume; and at least one reagent cavity, which extends within the reagent-adhesion structure. The reagent-adhesion structure is of an adhesion material embossable at temperatures lower by 6-8° C. than its own melting point and has a melting point such as not to interfere with the analysis. The reagent cavity forms a retention wall, laterally surrounding the reagent cavity, and houses dried reagents. The adhesion material is chosen among wax, such as paraffin, a polymer, such as polycaprolactone, a solid fat, such as cocoa butter, and a gel, such as hydrogel or organogel.