A microfluidic chip comprises: a first unit which has a channel for a cell sample to pass through and is configured to separate circulating tumor cells in the cell sample; a second unit, a front end of which communicates with a tail end of the first unit, and the second unit is configured to capture single cells from the separated circulating tumor cells and subject the captured single cells to closed lysis; and a gel layer which is provided at the second unit. The microfluidic chip is configured to implement the binding of a protein molecule of the single cell with an antibody in the gel layer after the single cell is lysed. A cell separation and western blotting method using the microfluidic chip comprises: lysing circulating tumor cells, capturing, and implementing the binding of a lysate with an antibody. A manufacture method of the microfluidic chip, comprises: manufacturing a first interlayer and a separation unit; manufacturing a second interlayer and pasting the second interlayer on a basal layer, and manufacturing a single-cell capture unit; and bonding the first interlayer with the separation unit and the second interlayer with the single-cell capture unit.

The present disclosure provides novel gravitational flow assays for detecting an antigen in a biological sample using DNA-capture sequences. Specifically, gravitational flow assays and methods of detecting viruses, including coronaviruses, are provided.

A lateral flow assay (LFA) device includes a capillary pad and a sample port that holds the sample fluid before a hole is made in a cavity surface of the sample port. The LFA device includes a breaker with a tip to make a hole in the cavity wall of the sample port causing the sample fluid held inside the compartment to be applied to the capillary pad after the start of a test.

To provide an immunochromatographic test device capable of accurate diagnosis even when an excess sample is introduced. Provided is the immunochromatographic test device consisting: a test strip; a lower housing including a plurality of support bases that support the test strip; and an upper housing including a dropping hole for dropping a sample into the test strip and a detection window in a direction in which the sample introduced from the dropping hole develops on the test strip, wherein a width of the support base that supports portion of the test strip exposed from the detection window is smaller than a width of the test strip, or wherein among the plurality of support bases, the width of the support base arranged on the lower housing between a position corresponding to the detection window and a position corresponding to the dropping hole is larger than the width of the test strip.

The present invention may provide a microfluidic device including a rotatable body; a first chamber positioned in a direction of an inner wall of the body; a second chamber positioned in a direction of an outer wall of the body from the first chamber; and a backflow prevention unit, and wherein a fluid is transferred from the first chamber to the second chamber, and wherein the backflow prevention unit prevents a backflow of the fluid from the second chamber to the first chamber.

Provided are methods and systems that relate to configuring a handheld analyzer. The handheld analyzer may receive an identifier from a dual design test cartridge. The parameter module disposed within the handheld analyzer may determine parameters corresponding to the received test cartridge identifier. The parameter module may then configure the handheld analyzer to perform a test with the dual designed test cartridge using the determined parameters. In an embodiment, the diagnostic test module may determine the test corresponding to the received cartridge identifier and the diagnostic test module configures the handheld analyzer to perform the determined test with the test cartridge. In another embodiment, the dual test cartridge comprises an outer enclosure and an inner enclosure. The outer enclosure comprises a parameter module capable of storing test cartridge identification and may be reused to store new test identifications.

A test strip system having containers and suitable carriers therefor. The test strip assembly is suitable for carrying out different types of chemical, biological or biochemical tests and evaluating them using a suitable analysis device. The test strip assembly has a first region having at least one container and a second region also having at least one container. The container of the first region has a flat transparent bottom, and the container of the second region has a V-shaped or U-shaped bottom.

A test device includes a housing and a carrier detachable from the housing. The housing includes a socket, and the carrier contains a testing element, and the carrier along with the testing element therein is capable of being inserted into the housing through the socket. The housing includes a blocking structure and a locking structure. The blocking structure and the locking structure are integrated to form a locking component. When the carrier is inserted into the housing, and a position of the carrier is locked by the locking structure, the carrier is abutted against the blocking structure. The carrier keeps stable after being inserted into the housing; and the carrier is located in the same position for each insertion.

The present invention concerns a method of measuring antimicrobial susceptibility of microbes using a suitable device or system. Also provided are a device and a system suitable for measuring antimicrobial susceptibility of microbes and use of the device and system to measure the antimicrobial susceptibility of microbes.

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.