Syphilis diagnosis multi-channel device with double-drive coupling operation function for hydrophobic substrate

Abstract

The invention relates to a syphilis diagnosis multi-channel device with a double-drive coupling operation function for a hydrophobic substrate, and belongs to the field of analysis and tests. By the aid of the syphilis diagnosis multi-channel device, the series difficult problems of polydimethylsiloxane (PDMS) which is inexpensive and is extremely easy to process when the polydimethylsiloxane is used for manufacturing syphilis diagnosis micro-fluidic chips can be solved. The scheme mainly includes that PDMS with original ecological surfaces is selected for the substrate, a chain-ring electromagnetic fixture with a miniature ultrasonic transducer sleeves a location adjacent a test sample liquid flow end point of a micro-fluidic chip and is positioned at the location adjacent to the test sample liquid flow end point of the micro-fluidic chip, and ultrasonic reduction machines are arranged at a sample injection end of the micro-fluidic chip, so that the ultrasonic wave intensity can be quickly reduced in short distances. The syphilis diagnosis multi-channel device has the advantages that interfacial tension difference can be formed at two ends of the chip, and force for driving test sample liquid flow to flow towards the end point along hydrophobic capillary channels can be provided by the difference, is coupled with mechanical pumping force of a micro-pump in the syphilis diagnosis multi-channel device and can be collaboratively operated with the mechanical pumping force.

Description

Technical field [0001] The invention relates to a multi-channel device for syphilis diagnosis for dual drive coupling operation of a hydrophobic substrate, which belongs to the field of analysis and testing. Background technique [0002] For the technical background of multi-channel microfluidic syphilis diagnosis, please refer to CN 200910160439.X and other invention patent applications. [0003] For the overall overview of microfluidic technology itself, you can refer to the monograph "Illustrated Microfluidic Chip Lab" published by the famous microfluidic expert Mr. Lin Bingcheng not long ago. This monograph has been published by Science Press. The past, present, and future prospects of microfluidic technology are all detailed and detailed long discussions. [0004] So, let's talk about the key issues of concern in this case. [0005] The basic structure of a microfluidic chip includes a substrate etched with tiny liquid flow channels and a cover sheet attached to it. The tiny liq...

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Problems solved by technology

[0007] But it's not that simple

[0008] First, this polydimethylsiloxane material, the material referred to by the acronym PDMS, is itself a strongly hydrophobic material. Microchannels are built on this material. If the microchannels are not targeted The modification operation of the surface of the channel, then, after the overall assembly is completed, that is, after the cover is covered, because the inner surface of the micro channel in the structure occupies most of the inner surface of the liquid flow channel, then the PDMS micro channel The strong hydrophobic characteristic of the inner surface of the channel is the decisive factor, which will make it very difficult for the polar liquid flow similar to the aqueous solution to pass through, and its flow resistance is so large that even ordinary micropumps are difficult to push. Of course, If the cover sheet also chooses to use the PDMS material, then the problem is basically the same, with little difference; therefore, in the prior art, it is necessary to modify and modify the inner surface of the microchannel on the PDMS material; then , is this modification operation for the inner surface of the PDMS microchannel very troublesome? That's not the problem. What constitutes a serious technical problem is another problem: the PDMS polymer molecules in the bulk phase of the PDMS material substrate have the characteristics of automatic diffusion and migration to the surface. The characteristics of polymer molecules diffusing and migrating to the surface automatically will make the modified state of the inner surface of the microchannel modified by the surface modification unable to maintain for a long enough time, and the microgroove after surface modification The maintenance time of the inner surface state of the channel is roughly only enough to complete the time required for the internal test experiment in the laboratory; in other words, the inner surface of the PDMS microchannel after surface modification or surface modification is formed after modification The surface state of the surface does not last long, but quickly tends to or changes back to the surface state before the surface modification, and returns to the original strongly hydrophobic surface stat

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