CN215575174U - Quantitative immune chip - Google Patents

Abstract

The utility model discloses a quantitative immune chip, which comprises a plurality of functional chambers arranged on a chip top plate; the functional chambers are connected through channels; the functional chamber comprises a quantitative groove, a fluorescence detection area, a waste liquid area and a cleaning pool; the channel comprises a detection channel and a waste liquid channel; the quantitative groove, the fluorescence detection area and the cleaning pool are sequentially arranged on the detection channel; the waste liquid area is arranged on the waste liquid channel; the inlet of the waste liquid channel is connected with the detection channel at the top of the quantitative groove; an inlet of the detection channel is provided with a sample inlet; the inlet of the waste liquid channel is arranged between the sample inlet and the quantitative groove; the tail end of the waste liquid channel is provided with a second driving force interface; the tail end of the detection channel is provided with a first driving force interface. The utility model can realize quantitative detection, has lower processing difficulty and is convenient for mass production and application.

Description

Quantitative immune chip

Technical Field

The utility model relates to the technical field of in-vitro diagnosis, in particular to a quantitative immune chip.

Background

The Point-of-Care Test (POCT) is the field with the fastest growth in the in vitro diagnosis industry, has the advantages of integration, miniaturization, and sample detection at any time and any place, thereby having the advantages of low price, simple operation and timely result report, but the testing result of the POCT has the defects of low precision and stability compared with a central laboratory. At present, the main detection technologies of POCT include immunochromatography and microfluidic. The immunochromatography technology is limited by the manufacturing process of raw materials (such as NC membranes), and has large batch-to-batch difference and large batch-to-batch difference. In contrast, microfluidic chips control the intra-and inter-lot variation of immunoassays by concentrating the basic operations of sample preparation, reaction, separation, and detection on one chip. The conventional POCT microfluidic chip generally has the problems of low production efficiency, incapability of quantifying samples, inapplicability of whole blood samples, complex process, low qualified rate of finished products, unstable control of air bag liquid and the like, and is difficult to quantify really.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the utility model discloses a quantitative immune chip, which aims to solve the problems of difficult quantification and complex process in the prior art.

In order to solve the technical problems, the utility model adopts the following technical scheme:

a quantitative immunity chip comprises a plurality of functional chambers arranged on a top plate of the chip; the functional chambers are connected through channels; the functional chamber comprises a quantitative groove, a fluorescence detection area, a waste liquid area and a cleaning pool; the channel comprises a detection channel and a waste liquid channel; the quantitative groove, the fluorescence detection area and the cleaning pool are sequentially arranged on the detection channel; the waste liquid area is arranged on the waste liquid channel; the inlet of the waste liquid channel is connected with the detection channel at the top of the quantitative groove; an inlet of the detection channel is provided with a sample inlet; the inlet of the waste liquid channel is arranged between the sample inlet and the quantitative groove; the tail end of the waste liquid channel is provided with a second driving force interface; the tail end of the detection channel is provided with a first driving force interface.

Furthermore, the sections of the quantitative tank and the cleaning tank are regular hexagons; the section of the fluorescence detection area is rectangular; the section of the sample inlet is conical.

Furthermore, the diameter of the top end of the cone is 8-12 mm, and the diameter of the lower end of the cone is 0.8-1.2 mm; the side length of the quantitative groove is 3-4 mm, and the height of the quantitative groove is 1-3 mm; the side length of the cleaning pool is 5 mm, and the height of the cleaning pool is 3-5 mm; the length of the fluorescence detection area is 12-15 mm, the width is 1-1.5 mm, and the height is 0.5-1 mm.

Further, the fluorescence detection area is of a dot matrix structure.

Further, a coating antibody, a fluorescent labeling antibody and an anti-antibody for immunoassay are fixed on the fluorescent detection area.

Furthermore, a chip bottom plate is sealed and connected below the chip top plate.

Further, the material of the chip top plate and the chip bottom plate is PC, PDMA, PMMA or PET.

Furthermore, the bottom heights of the cleaning pool and the quantification groove are both lower than the bottom height of the fluorescence detection area.

A detection method of a quantitative immune chip comprises the following steps:

adding a detection liquid into the sample inlet;

driving the detection liquid to the quantitative groove from the sample inlet;

when the liquid in the quantitative groove is full, the detection liquid in the quantitative groove is continuously driven to flow to the detection reaction area;

driving the detection liquid to mix in the detection reaction area;

and discharging the detection liquid into a cleaning pool after mixing is finished, and detecting a fluorescent signal.

Further, the method also comprises the step of driving redundant detection liquid in the quantification groove to the waste liquid area through the driving force if the volume of the detection liquid is larger than that of the quantification groove.

By adopting the technical scheme, the utility model has the following advantages:

1. the quantitative immune chip provided by the utility model realizes the quantification of liquid by combining a specific quantitative groove with a liquid driving device, and simultaneously accurately controls the incubation time of the liquid, a fluorescent marker and an envelope antibody.

2. The quantitative immune chip main body comprises a top plate and a bottom plate, wherein the top plate is provided with a plurality of functional cavities, structural functional cavities needing to be processed can be arranged on the top plate, and the bottom plate is only a smooth PVC film, so that the difficulty of the manufacturing process of the chip can be further reduced, the production efficiency is improved, quantitative detection can be realized, the processing difficulty is low, and the quantitative immune chip main body is convenient for mass production and application.

Drawings

FIG. 1 is a top view of a quantitative biochip according to the present invention;

FIG. 2 is an enlarged view of the fluorescent detection zone structure of the present invention;

FIG. 3 is a side view of the quantitative biochip of the present invention.

Reference numerals: 1-a first driving force interface; 2-a second driving force interface; 3-cleaning the pool; 4-fluorescent detection zone; 5-a waste liquid zone; 6-a quantitative groove; 7-sample inlet; 8-detection line; 9-quality control line; 10-liquid recognition site one; 11-liquid recognition site two; 12-liquid recognition site three; 13-a photoelectric sensor; 14-a light source generating module; 15-chip backplane.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

Structure of quantitative immune chip

As shown in fig. 1: a quantitative immune chip is formed by sealing a chip top plate integrating a plurality of functional chambers and a smooth and transparent chip bottom plate 15.

A detection channel and a waste liquid channel are arranged on the chip top plate, and the functional chamber comprises a quantitative groove 6, a fluorescence detection area 4, a waste liquid area 5 and a cleaning pool 3; the quantitative groove 6, the fluorescence detection area 4 and the cleaning pool 3 are sequentially arranged on the detection channel along the top end of the detection channel in a downward penetrating manner, a sample inlet 7 is arranged at the top end of the detection channel, and a first driving force interface 1 is arranged at the tail end of the detection channel; the waste liquid area 5 is arranged on a waste liquid channel, the top end of the waste liquid channel is arranged between the sample inlet 7 and the quantitative groove 6 and is communicated with the detection channel, and the tail end of the waste liquid channel is provided with a second driving force interface 2.

The functional chambers are communicated with each other in a space structure in a mode that the first driving force interface 1 and the second driving force interface 2 are externally connected with a driving source; the first driving force interface 1 and the second driving force interface 2 are connected with an external driving source, so that air in the detection channel and the waste liquid channel can be pumped away, and liquid is driven to flow through negative pressure in the channel.

The quantitative groove 6 has a preset volume, a liquid outlet of the liquid quantitative cavity is provided with a liquid identification site, liquid to be quantified flows into the liquid quantitative cavity from a liquid inlet of the liquid quantitative cavity, and the liquid identification site is reached after the liquid quantitative cavity is filled with the liquid quantitative cavity.

The liquid identification sites comprise upper sites for positioning the photoelectric sensors 13 and lower sites for positioning the light source generation modules 14, the upper sites and the lower sites are respectively arranged on two sides of the chip main body, and the positions of the liquid identification sites formed by the upper sites and the lower sites correspond to the liquid inlets or the liquid outlets of the corresponding functional chambers, so that the positioned light source generation modules, the corresponding liquid outlets or the liquid inlets and the photoelectric sensors are sequentially arranged in the vertical direction.

Wherein, a fluorescent reaction reagent is fixed at the fluorescent detection zone 4; the fluorescent detection region 4 is immobilized with a coating antibody, a fluorescent labeling antibody, an anti-antibody, and other auxiliary components for immunoassay in advance.

Further, the sample inlet 7 is a sample inlet with a conical cross section, the diameter of the top end of the cone is 8-12 mm, and the diameter of the lower end of the cone is 0.8-1.2 mm; the section of the quantitative groove 6 is a regular hexagon, the side length of the regular hexagon is 3-4 mm, and the height of the regular hexagon is 1-3 mm; the fluorescence detection area 4 is of a rectangular dot matrix structure, the length of the rectangle is 12-15 mm, the width of the rectangle is 1-1.5 mm, and the height of the rectangle is 0.5-1 mm; the cross-section of wasing pond 3 also is regular hexagon, and the width of wasing pond 3 is 4~6 mm, and length is 5 mm, highly is 3~5 mm.

What point out very much is that the bottom surface height of wasing pond 3 and quantitative groove 6 is less than the bottom surface height 2mm and the 1mm of fluorescence detection zone 4 respectively, lower bottom surface design, prevent the liquid in the quantitative groove 6 because the effect of inertia when liquid flows, initiatively flow in the fluorescence detection zone 4, it is excessive to lead to liquid in the fluorescence detection zone 4, prevent the liquid after the reaction of fluorescence detection zone 4 simultaneously, unable normal inflow washs pond 3, lead to liquid to remain, and then improve the quantitative accuracy of fluorescence detection zone 4 liquid and reduce the remaining of liquid, improve detectivity.

The data are limited to the embodiment, the utility model is not limited to the data in the embodiment, and the data are adjusted according to the reagent condition in other embodiments.

The quantitative immune chip is made of one of PC, PDMA, PMMA or PET, the material selected for the embodiment is PMMA, the chip bottom plate 15 is made of a transparent film, a transparent pressure-sensitive hydrophilic adhesive layer is coated on one side of the transparent film, and the chip bottom plate 15 and the top plate are sealed and connected through the hydrophilic adhesive layer to form an undetachable whole. In one embodiment, the transparent film may comprise a transparent polyester material.

Example two

Method for manufacturing quantitative immune chip

The quantitative immune chip can be manufactured by the current precision injection molding technology and assembly technology. The assembly is formed from two sealed elements: a top plate on which the microfluidic structure is formed, and an underlying film cover, as shown in fig. 3.

There are many materials that are suitable for both the top substrate and the transparent film of the chip, such as polymers, thermosets or thermoplastics, which should have good optical properties and good dimensional stability. For example, COC, PMMA, PC, PSU, SAN, PETG, PS, and PP may be used.

Most polymeric materials are hydrophobic. Thus, if a strongly hydrophobic material is chosen as the substrate for forming the microfluidic structure, a subsequent production step of a certain surface that confers hydrophilicity is necessary. For this purpose, it is proposed to use hydrophilic or at least non-hydrophobic (contact angle <90 °) plastics. This is true for PMMA, cellulose acetate, PC, COC and PS, as well as other known materials. A particularly preferred material is PMMA, in view of its good contact angle, optical properties and dimensional stability.

The top plate can be machined using a variety of techniques currently available and is extremely precise, allowing for low micro-dimensional tolerances. The currently most relevant technologies for the above-described functional structure forming steps are precision injection molding, hot film pressing, and soft etching printing.

The sealing step may be performed using a variety of known techniques, such as thermal compression bonding, adhesive bonding, plasma activated bonding, ultrasonic bonding, laser welding, and the like. The sealing step of this example uses a simple transparent film cover.

The cover is preferably a hydrophilic film. It is preferably transparent to enable accurate monitoring of fluid flow. Such as hydrophilic membranes, provide a very cost-effective way of simultaneously sealing and hydrophilizing the channels, avoiding surface treatment steps. In this case, the production technique consists of a standard lamination process, which may require pressure and temperature control. Other production techniques are embossing or pressing processes.

The above-described fluorescence detection zone can solidify a variety of dry reagent substances for various functions and purposes. The main components are a coating antibody and an anti-antibody for capturing a substance to be detected and a fluorescence labeling antibody for detecting the Wu to be detected. Because the reaction chamber has small size, less reagent dosage and low cost, the added components can quickly solubilize such as albumin, glutamate, glucose, sucrose, trehalose and other saccharides. Wettability controls such as Triton, Macol, Tetronic, Silwet, Zonyl, and the like.

The dried reagent may be coated into the fluorescence detection zone of the top plate by a variety of known techniques: the method of dispensing in a liquid state to the fluorescence detection region includes droplet dispensing, gel dispensing, jet dispensing, screen printing, selective spraying, and the like. The dispensing step is followed by a drying step.

The monoclonal antibody for the dry reagent and the goat anti-mouse IgG antibody are distributed to a detection line area at one end and a quality control line position at the other end of a reaction detection area in a micro-droplet form state to form two linear droplet arrays occupying a reaction chamber, the two linear droplet arrays are combined with a chip in a passive adsorption mode, and two thin linear dry reagent layers are formed after drying and serve as a detection line 8 and a quality control line 9.

The final manufacturing method and the resulting immuno-quantitative chip are extremely simple, requiring no embedded components such as electrodes or any form of multi-layer structure, indeed, the present manufacturing technique allows for low cost production, which can produce inexpensive disposable quantitative detection chips.

EXAMPLE III

Quantitative immune chip drive parameters (Pump pressure parameters, etc.)

The liquid driving device can be configured in various ways, such as an injection pump, a diaphragm pump and an air pump, and all that can drive the liquid to the predetermined area in the chip under the pressure effect falls within the protection scope of the present invention. The utility model is preferably an air pump known by the person skilled in the art, the pump parameters are preferably 4-6 psi, which generally comprises the whole of a pump chamber and an interface communicating with the chip, the movement of the pump chamber compresses the gas, creates a negative pressure in the cavity of the chip, when liquid is added into the sample inlet, the liquid reaches the third liquid identification site 12 through capillary action, the liquid in the sample inlet is driven to the quantitative groove through the first driving force interface and reaches the second liquid identification site 11, the air pump corresponding to the first driving force interface is stopped, and then driving redundant liquid at the sample adding port to a waste liquid area 5 to a liquid identification site through an air pump corresponding to the second driving force interface for three 12 signal changes, stopping the air pump corresponding to the second driving force interface, starting the air pump corresponding to the first driving force interface, and pumping the quantitative groove liquid into the fluorescence detection area 4 until a 10 signal change at the liquid identification site. The air pump corresponding to the first driving force interface drives liquid to reciprocate to mix and react the liquid, and reaction timing is carried out simultaneously. And after timing is finished, discharging the liquid into a cleaning pool of the detection channel, and simultaneously starting a detection light source to detect a fluorescence signal.

Example four

Quantitative chip analysis instrument

The embodiment of the utility model also provides an instrument with the quantitative immune chip, which comprises an instrument frame, a liquid driving device, a detection device and the immune quantitative chip in any embodiment, wherein the immune quantitative chip is arranged in the instrument frame, and the liquid driving device is connected with a liquid driving force interface of the quantitative chip; the detection device is used for receiving and processing detection signals of the quantitative chip. Preferably, the liquid driving device is an air pump, so that the instrument is miniaturized and portable.

A detection method of a quantitative immune chip comprises the following steps:

adding a detection liquid into the sample inlet;

driving the detection liquid to the quantitative groove from the sample inlet;

when the liquid in the quantitative groove is full, the detection liquid in the quantitative groove is continuously driven to flow to the detection reaction area;

driving the detection liquid to mix in the detection reaction area;

and discharging the detection liquid into a cleaning pool after mixing is finished, and detecting a fluorescent signal.

The present invention is not limited to the above embodiments, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention are included in the scope of the claims of the present invention which are filed as the application.

Claims (8)

1. A quantitative immune chip is characterized by comprising a plurality of functional chambers arranged on a top plate of the chip; the functional chambers are connected through channels; the functional chamber comprises a quantitative groove, a fluorescence detection area, a waste liquid area and a cleaning pool; the channel comprises a detection channel and a waste liquid channel; the quantitative groove, the fluorescence detection area and the cleaning pool are sequentially arranged on the detection channel; the waste liquid area is arranged on the waste liquid channel; the inlet of the waste liquid channel is connected with the detection channel at the top of the quantitative groove; an inlet of the detection channel is provided with a sample inlet; the inlet of the waste liquid channel is arranged between the sample inlet and the quantitative groove; the tail end of the waste liquid channel is provided with a second driving force interface; the tail end of the detection channel is provided with a first driving force interface.

2. The quantitative immune chip according to claim 1, wherein the cross sections of the quantitative groove and the cleaning pool are regular hexagons; the section of the fluorescence detection area is rectangular; the section of the sample inlet is conical.

3. The quantitative immune chip according to claim 2, wherein the conical shape has a diameter of 8-12 mm at the top end and a diameter of 0.8-1.2 mm at the bottom end; the side length of the quantitative groove is 3-4 mm, and the height of the quantitative groove is 1-3 mm; the side length of the cleaning pool is 5 mm, and the height of the cleaning pool is 3-5 mm; the length of the fluorescence detection area is 12-15 mm, the width is 1-1.5 mm, and the height is 0.5-1 mm.

4. The quantitative immuno chip of claim 1, wherein the fluorescence detection region is a dot matrix structure.

5. The quantitative immuno chip of claim 1, wherein the fluorescence detection region is immobilized with coating antibody, fluorescence labeling antibody and anti-antibody for immunoassay.

6. The quantitative immunization chip of claim 1 wherein a bottom chip plate is sealed under the top chip plate.

7. The quantitative immune chip of claim 6, wherein the material of the top and bottom chip plates is PC, PDMA, PMMA or PET.

8. The quantitative immune chip of claim 1, wherein the bottom surface of the washing pool and the bottom surface of the quantitative groove are lower than the bottom surface of the fluorescence detection area.

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