An embodiment includes a sample receiving region, a first diagnostic element that includes one or more colorimetric analysis regions, and a second diagnostic element that includes one or more lateral flow assay analysis regions. The embodiment also includes a first flow path that allows a portion of a liquid deposited at the sample receiving region to flow to the first diagnostic element. The embodiment also includes a second flow path that allows a portion of the liquid deposited at the sample receiving region to flow to the second diagnostic element.

A system for testing for an analyte includes a test strip. The test strip includes a first flow path. The test strip further includes a heating element in communication with a heating area of the first flow path, for heating a sample in the first flow path. The test strip further includes an e-gate, the e-gate in the first flow path, the e-gate separating the heating area from a detection area of the first flow path.

Various apparatus, systems, and methods for measuring a solution characteristic of a sample comprising microorganisms are disclosed. In one embodiment, a sensor apparatus is disclosed comprising a sample container comprising a sample chamber configured to receive the sample and a reference sensor component comprising a reference conduit having a reference conduit cavity defined therein. The reference conduit cavity can be at least partially filled with a reference buffer gel, buffer solution, or wicking component. A segment of the reference conduit can extend into the sample chamber. A reference electrode material can be positioned at a proximal end of the wicking component or extend partially into the reference conduit cavity. The sensor apparatus can also comprise an active sensor component having an active electrode in fluid contact with the sample. The sample in the sample chamber can be aerated through an aeration port defined along a surface of the sample container.

A nanopore-based sequencing chip can have a surface with an array of wells, with each well having a working electrode. Charge can be established within the wells by applying a voltage between the working electrodes and a counter electrode. The charge can then be trapped within the wells by sealing the wells with a membrane. The trapped charge can be used to facilitate pore insertion into the membranes.

The present invention discloses a method for preparing a micro-channel array plate, comprising the steps of : (1) arranging a first optical fiber glass rod and a second optical fiber glass rod closely, melting the two glass rods into a whole at a high temperature to obtain a melted glass rod, drawing the melted glass rod at least one time into a longer and thinner glass rod than the melted glass rod, and cutting the drawn glass rod into small pieces to obtain a micro-channel array plate blank, wherein the corrosion resistance of the first optical fiber glass rod and the second optical fiber glass rod to the same corrosive liquid is different; (2) corroding the micro-channel array plate blank by a corrosive liquid to obtain a micro-channel array plate crude product with through holes; and (3) conducting hydrophobic treatment on the micro-channel array plate crude product to obtain the micro-channel array plate.

The present invention relates to a blood components collection and separation media (1) comprising a substrate (3) having a maximal flow pore size enabling the retention of at least red cells on the surface of the substrate (3), the blood components collection and separation media (1) comprises boundary walls (7) forming a pattern (9) and being made of a hydrophobic resin, and the pattern (9) presenting: a collection zone (91); at least one storage zone (93) aimed at collecting at least one component of the whole blood sample (5); and at least one channel (95) connecting the collection zone (91) to the at least one storage zone (93), the channel (95) forming a bottleneck between the collection zone (91) and the storage zone (93). The present invention further relates to a blood components collection and separation device and a blood components separation and extraction process.

A microfluidic system includes a hydrophobic fluidic platform and a heater. The platform includes a plurality of electrode cells operably connected to a voltage source and a controller. The heater is configured to fuse first and second vesicles. The first and second vesicles encapsulate first and second DNA precursors, respectively. The fusing combines the first and second DNA precursors. In another embodiment, a microfluidic system includes a fluidic platform including a plurality of electrode cells, a vesicle mover, and a reaction facilitator. The vesicle mover is configured to move first and second vesicles to a selected cell of the plurality of electrode cells. The reaction facilitator is operably connected to the selected cell. A method includes providing a fluidic platform comprising a plurality of cells; moving first and second vesicles encapsulating first and second reagents, respectively, to a first cell; and fusing the first and second vesicles.

The object of the invention is a method of detecting genetic material in a biological sample in which the biological sample is loaded into the reaction cartridge (6) and then the reaction cartridge (6) is placed in the control device, the collected biological sample is taken to the isolation chamber (7), isolation of biological material from the tested sample by heating the isolation chamber (7), the isolated genetic material is moved into a plurality of reaction chambers (8.1, 8.2, 8.3, 8.4), genetic material is amplified by heating the reaction chambers (8.1, 8.2, 8.3, 8.4), lyophilized reagents for genetic material amplification together with lyophilized fluorescent tag intercalating with genetic material are present in the reaction chambers (8.1, 8.2, 8.3, 8.4), and signal detection from fluorescent tags is carried out along with the genetic material amplification stage.

A detection chip, a using method for the same, and a reaction system. The detection chip includes a first substrate, a micro-cavity defining layer, and a heating electrode. The micro-cavity defining layer is on the first substrate and defines a plurality of micro-reaction chambers. The heating electrode is on the first substrate and is closer to the first substrate than the micro-cavity defining layer, and is configured to heat a plurality of micro-reaction chambers. The orthographic projection of the plurality of micro-reaction chambers on the first substrate is within the orthographic projection of the heating electrode on the first substrate.

The present disclosure provides a microfluidic device, including a bottom substrate, an electrowetting-on-dielectric (EWOD) chip, a circuit board, a dielectric film, and a motor. The EWOD chip is disposed on the bottom substrate, and the circuit board is arranged on the EWOD chip. The circuit board includes a circuit area that is electrically connected to the EWOD chip, and the empty area is adjacent to the circuit area and the EWOD chip is exposed. The dielectric film is disposed on the empty area of the circuit board and covers the exposed EWOD chip. The motor is disposed under the bottom substrate, and one end of the motor has a magnetic structure, so that the magnetic structure can move closer to or away from the bottom substrate.