阅读说明：本技术 微流控芯片、微流控系统及操作方法 (Microfluidic chip, microfluidic system and operation method ) 是由 闵小平 葛胜祥 张师音 张东旭 付达 张建中 翁振宇 陈文堤 翁祖星 宋浏伟 张 于 2018-08-21 设计创作，主要内容包括：本发明涉及一种微流控芯片、微流控系统及操作方法。其中,微流控芯片包括反应模块和储存模块；所述反应模块包括反应腔,以及至少一条与所述反应腔连通的导流通道；所述储存模块包括至少一个储存腔,每一所述储存腔对应一所述导流通道,在所述储存腔的密封被破坏的状态下,所述储存腔与其对应的所述导流通道连通。本发明中的各储存腔相互独立,其内用于储存不同或相同的试剂,可以按照试验需求从储存腔进入反应腔进行反应,实现试剂的一体化储存和顺序释放。(The invention relates to a micro-fluidic chip, a micro-fluidic system and an operation method. The microfluidic chip comprises a reaction module and a storage module; the reaction module comprises a reaction cavity and at least one flow guide channel communicated with the reaction cavity; the storage module comprises at least one storage cavity, each storage cavity corresponds to one flow guide channel, and the storage cavities are communicated with the flow guide channels corresponding to the storage cavities in the state that the sealing of the storage cavities is damaged. The storage cavities are mutually independent and are used for storing different or same reagents, and the reagents can enter the reaction cavity from the storage cavities to react according to test requirements, so that the integrated storage and sequential release of the reagents are realized.)

1. A microfluidic chip is characterized by comprising a reaction module (1) and a storage module (2);

the reaction module (1) comprises a reaction cavity (11) and at least one flow guide channel (12) communicated with the reaction cavity (11);

the storage module (2) comprises at least one storage cavity (21), each storage cavity (21) corresponds to one flow guide channel (12), and the storage cavities (21) are communicated with the flow guide channels (12) corresponding to the storage cavities (21) in the state that the sealing of the storage cavities (21) is damaged.

2. The microfluidic chip according to claim 1, wherein the reaction module (1) further comprises a waste chamber (13) and a waste channel (14), a first end of the waste channel (14) is in communication with the reaction chamber (11), and a second end of the waste channel (14) is in communication with the waste chamber (13).

3. The microfluidic chip according to claim 2, wherein the bottom of the reaction chamber (11) is recessed, and the first end of the waste channel (14) is connected to the reaction chamber (11) via the bottom lowest point of the reaction chamber (11).

4. The microfluidic chip according to claim 2, wherein the second end of the waste channel (14) is higher than the reagent level in the reaction chamber (11).

5. The microfluidic chip according to claim 2, wherein the reaction module (1) comprises a gas flow channel (15), a first end of the gas flow channel (15) is communicated with the waste liquid chamber (13), and a second end of the gas flow channel (15) is used for being communicated with a gas device (4) to blow and pump gas into the waste liquid chamber (13).

6. The microfluidic chip according to claim 5, wherein the communication portion of the gas flow channel (15) and the waste liquid chamber (13) is higher than the communication portion of the waste liquid channel (14) and the waste liquid chamber (13).

7. The microfluidic chip according to claim 1, wherein the reservoir module (2) is disposed above the reaction module (1).

8. The microfluidic chip according to claim 1, wherein the reaction module (1) is provided with a mounting groove (16) at the top, and the mounting groove (16) is used for mounting the storage module (2).

9. Microfluidic chip according to claim 1, wherein the inlet (23) of the reservoir is located at the top of the reservoir module (2) and is sealed by a first sealing film (22), and the outlet (24) of the reservoir is located at the bottom of the reservoir module (2) and is sealed by a second sealing film.

10. Microfluidic chip according to claim 1, wherein a plurality of said reservoirs (21) are arranged side by side in said reservoir module (2), the inlet (23) of each reservoir being arranged at the top of said reservoir module (2) and sealed by a same first sealing film (22).

11. Microfluidic chip according to claim 1, wherein a plurality of said reservoirs (21) are arranged side by side in said reservoir module (2), the outlet (24) of each reservoir being located at the bottom of said reservoir module (2) and each being sealed by a second sealing membrane.

12. The microfluidic chip according to claim 1, wherein at least one of the plurality of reservoirs (21) is empty for injecting a sample during use of the microfluidic chip, and the remaining reservoirs (21) are pre-filled with reagents.

13. Microfluidic chip according to claim 1, characterized in that the outlet (24) of the reservoir has a smaller size than the inlet (23) of the reservoir.

14. The microfluidic chip according to claim 1, wherein the reservoir (21) is recessed at its bottom, and the outlet (24) of the reservoir is provided at the bottom of the reservoir (21).

15. Microfluidic chip according to claim 1, wherein the bottom of the reservoir module (2) is provided with a first chamfer (25) extending in the direction of the arrangement of the reservoir chambers (21), the outlets (24) of the reservoir chambers being provided at the first chamfer (25).

16. Microfluidic chip according to claim 1, wherein the upper part of the reservoir module (2) is provided with a vent (26), the vent (26) is in communication with the reservoir chamber (21), and a third sealing membrane is provided at the vent (26), the vent (26) connecting the reservoir chamber (21) with the outside air in a state where the third sealing membrane is broken.

17. The microfluidic chip according to claim 1, wherein the storage module (2) comprises:

a liquid storage module (27) in which a first liquid storage chamber (271) is provided; and

a solid storage module (28) having a solid storage cavity (281) therein;

the bottom of the liquid storage module (27) is inserted into the solid storage module (28), and the first liquid storage chamber (271) is communicated with the solid storage chamber (281) in a state that the seal of the outlet (276) of the first liquid storage chamber is broken; in a state where the seal of the outlet (282) of the solid storage chamber is broken, the solid storage chamber (281) communicates with the diversion passage (12) corresponding thereto.

18. The microfluidic chip according to claim 17, wherein the bottom of the liquid storage module (27) is provided with a second chamfered surface (273), and the outlet (276) of the first liquid storage chamber is provided on the second chamfered surface (273).

19. The microfluidic chip according to claim 17, wherein the vent hole (283) of the solid reservoir chamber is positioned on the same horizontal line as the outlet (276) of the liquid reservoir chamber in a state where the bottom of the liquid reservoir module (27) is inserted into the solid reservoir module (28).

20. The microfluidic chip of claim 17, wherein the bottom of the solid reservoir module (28) is provided with a third chamfer (284), and the outlet (282) of the solid reservoir chamber is provided at the third chamfer (284).

21. The microfluidic chip according to claim 17, wherein the solid storage chamber (281) is used for storing a solid lyophilized reagent, and the first liquid storage chamber (271) is used for storing a lyophilized reagent solution.

22. The microfluidic chip according to claim 17, wherein a second liquid reservoir chamber (272) is provided in the liquid reservoir module (27); in a state where the seal of the second liquid storage chamber (272) is broken, the second liquid storage chamber (272) communicates with its corresponding flow guide passage (12).

23. The microfluidic chip of claim 17, wherein the bottom of the liquid reservoir module (27) is provided with a recess (274), and the solid reservoir module (28) is disposed within the recess (274).

24. A microfluidic system comprising a microfluidic chip according to any one of claims 1 to 23.

25. Microfluidic system according to claim 24, comprising a laser (3) for breaking the seal of the storage chamber (21).

26. Microfluidic system according to claim 24, comprising gas means (4) for blowing at least the reagent of the storage chamber (21) towards the reaction chamber (11).

27. A method of operating a microfluidic system as claimed in claim 24, comprising:

a reagent storage step: sealing the outlet (24) of the storage chamber, placing the reagent in the storage chamber (21), sealing the inlet (23) of the storage chamber; and

and (3) a reagent release step: the laser is used to break the seal of the outlet (24) of the reservoir chamber to allow the reagent in the reservoir chamber (21) to flow to the reaction chamber (11).

28. The method of claim 27, wherein the microfluidic system is further characterized in that,

in the reagent storage step, a vent hole (26) of the storage cavity (21) is further sealed;

in the reagent releasing step, the seal of the vent hole (26) of the storage cavity (21) is further broken by laser.

29. The method of claim 27, wherein in the reagent releasing step, the gas is blown into the storage chamber (21) by the gas device (4) to facilitate the flow of the reagent in the storage chamber (21) to the reaction chamber (11).

30. A method of operating a microfluidic system according to claim 27, further comprising the step of reacting: the gas device (4) blows gas into the reaction cavity (11) from the bottom of the reaction cavity (11) to mix the reagents in the reaction cavity (11) in a vibration mode.

31. The method of claim 27, further comprising a waste liquid discharge step of providing a suction force by the gas device (4) to draw out waste liquid in the reaction chamber (11).

Technical Field

The invention relates to the field of microfluidics, in particular to a microfluidic chip, a microfluidic system and an operation method.

Background

Microfluidic technology can be said to be a research hotspot at present. It integrates biology, chemistry, machinery and other disciplines, and people can complete the whole experiment on a small chip, which can be said to be a great progress.

Point-of-care testing (POCT) refers to any test performed by a hospital professional or non-professional outside of a testing center, referred to as a bedside test for short. The integrated detector or portable instrument is used for implementing on-site convenient detection, the detection waiting time is reduced, the complex detection process is simplified, the traditional instrument equipment requiring higher maintenance cost is replaced, and the dependence of clinical application on high-end instruments and a central hospital detection center is relieved. POCT technology is currently becoming a research and development hotspot in the field of medical diagnostic technology.

The micro-fluidic chip technology provided in the early 90 s of the 20 th century can realize common reagent storage and release, uniform mixing, dilution, washing, reaction, result monitoring and other experimental steps in diagnosis and detection on one chip by matching with corresponding driving and detecting instruments and controlling the fluid, so that the whole detection system (the chip and the instrument) is small and exquisite and has high integration level, and on the premise of not losing detection sensitivity, the detection flow can be simplified, the requirements on detection personnel and environmental conditions are reduced, and the field detection is realized.

However, how to reasonably store and release liquid and lyophilized reagents in the chip is a very critical issue. The traditional storage mode is to store the reagent in a refrigerator or a cold storage independently and take out the reagent for testing when the test is carried out. Therefore, the microfluidic chip cannot be integrated and portable, POCT field detection is carried out, the use is very troublesome, and industrialization is difficult. The integrated storage, sequential release and reagent driving of the reagent are several key problems which must be solved in the industrialization process of the microfluidic chip. Moreover, most of the reagents in the immune and biochemical tests can be stored for a long time at normal temperature only after being freeze-dried, so that the storage and release of the freeze-dried reagents are very critical.

Disclosure of Invention

One of the purposes of the invention is to provide a microfluidic chip, a microfluidic system and an operation method, so as to solve the problem that the microfluidic chip cannot be integrated.

Some embodiments of the present invention provide a microfluidic chip comprising a reaction module and a storage module; the reaction module comprises a reaction cavity and at least one flow guide channel communicated with the reaction cavity; the storage module comprises at least one storage cavity, each storage cavity corresponds to one flow guide channel, and the storage cavities are communicated with the flow guide channels corresponding to the storage cavities in the state that the sealing of the storage cavities is damaged.

Optionally, the reaction module further comprises a waste liquid cavity and a waste liquid channel, a first end of the waste liquid channel is communicated with the reaction cavity, and a second end of the waste liquid channel is communicated with the waste liquid cavity.

Optionally, the bottom of the reaction chamber is recessed, and the first end of the waste liquid channel is communicated with the reaction chamber via the lowest point of the bottom of the reaction chamber.

Optionally, the second end of the waste channel is higher than the reagent level in the reaction chamber.

Optionally, the reaction module includes an air flow channel, a first end of the air flow channel is communicated with the waste liquid cavity, and a second end of the air flow channel is used for being communicated with a gas device so as to blow and pump air into the waste liquid cavity.

Optionally, a communication part of the airflow channel and the waste liquid cavity is higher than a communication part of the waste liquid channel and the waste liquid cavity.

Optionally, the storage module is disposed above the reaction module.

Optionally, the top of the reaction module is provided with a mounting groove, and the mounting groove is used for mounting the storage module.

Optionally, the inlet of the storage chamber is located at the top of the storage module and sealed by a first sealing membrane, and the outlet of the storage chamber is located at the bottom of the storage module and sealed by a second sealing membrane.

Optionally, a plurality of the storage cavities are arranged side by side in the storage module, and the inlet of each storage cavity is arranged at the top of the storage module and sealed by the same first sealing film.

Optionally, a plurality of the storage cavities are arranged side by side in the storage module, and the outlet of each storage cavity is arranged at the bottom of the storage module and is sealed by a second sealing film.

Optionally, at least one of the storage cavities is empty and used for injecting a sample in the use process of the microfluidic chip, and reagents are preset in the rest of the storage cavities.

Optionally, the outlet of the storage chamber is smaller in size than the inlet of the storage chamber.

Optionally, the bottom of the storage chamber is tapered, and the outlet of the storage chamber is disposed at the bottom tapered of the storage chamber.

Optionally, the bottom of the storage module is provided with a first chamfered surface extending along the arrangement direction of the storage cavities, and the outlets of the storage cavities are arranged on the first chamfered surface.

Optionally, the upper portion of storage module is equipped with the air vent, the air vent with storage chamber intercommunication, just the air vent is equipped with the third seal membrane, under the destroyed state of third seal membrane, the air vent will storage chamber communicates with its outside gas.

Optionally, the storage module comprises: the liquid storage module is internally provided with a first liquid storage cavity; the solid storage module is internally provided with a solid storage cavity; the bottom of the liquid storage module is inserted into the solid storage module, and the first liquid storage cavity is communicated with the solid storage cavity in a state that the seal of the outlet of the first liquid storage cavity is broken; and under the condition that the seal of the outlet of the solid storage cavity is damaged, the solid storage cavity is communicated with the flow guide channel corresponding to the solid storage cavity.

Optionally, the bottom of the liquid storage module is provided with a second inclined plane, and the outlet of the first liquid storage cavity is arranged on the second inclined plane.

Optionally, in a state where the bottom of the liquid storage module is inserted into the solid storage module, the vent hole of the solid storage cavity is located on the same horizontal line as the outlet of the liquid storage cavity.

Optionally, the bottom of the solid storage module is provided with a third oblique plane, and the outlet of the solid storage cavity is provided with the third oblique plane.

Optionally, the solid storage cavity is used for storing a solid freeze-drying reagent, and the first liquid storage cavity is used for storing a freeze-drying reagent dissolving solution.

Optionally, a second liquid storage cavity is arranged in the liquid storage module; and under the state that the seal of the second liquid storage cavity is damaged, the second liquid storage cavity is communicated with the corresponding flow guide channel.

Optionally, a groove is formed in the bottom of the liquid storage module, and the solid storage module is arranged in the groove.

Some embodiments of the present invention provide a microfluidic system comprising the microfluidic chip described above.

Optionally, the microfluidic system comprises a laser for breaking the seal of the reservoir.

Optionally, the microfluidic system comprises a gas device at least for blowing the reagent of the storage chamber towards the reaction chamber.

Some embodiments of the invention provide a method of operating a microfluidic system, comprising: a reagent storage step: sealing the outlet of the storage cavity, placing the reagent in the storage cavity, and sealing the inlet of the storage cavity; and a reagent release step: and breaking the seal of the outlet of the storage cavity by using a laser so as to enable the reagent in the storage cavity to flow to the reaction cavity.

Optionally, in the reagent storage step, the vent hole of the storage cavity is further sealed; in the reagent releasing step, the seal of the vent hole of the storage cavity is further broken by laser.

Optionally, in the reagent releasing step, the storage cavity is blown by a gas device, so that the reagent in the storage cavity can flow to the reaction cavity.

Optionally, the method of operating a microfluidic system further comprises a reagent reaction step: and blowing gas from the bottom of the reaction cavity to the reaction cavity through a gas device to vibrate and mix the reagent in the reaction cavity.

Optionally, the method of operating a microfluidic system further comprises a waste fluid removal step, wherein a suction force is provided by the gas device to draw waste fluid out of the reaction chamber.

Based on the technical scheme, the invention at least has the following beneficial effects:

in some embodiments, the reservoir module comprises at least one reservoir chamber; each storage cavity corresponds to a flow guide channel; the storage cavity is communicated with the corresponding flow guide channel in the state that the seal of the storage cavity is damaged; the storage cavities are mutually independent and are used for storing different or same reagents, and the reagents can enter the reaction cavity from the storage cavities to react according to test requirements, so that the integrated storage and sequential release of the reagents are realized.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention. In the drawings:

fig. 1 is an exploded view of a microfluidic chip according to some embodiments of the present invention;

FIG. 2 is a schematic view of a liquid storage module according to some embodiments of the present invention;

FIG. 3 is a schematic front view of a liquid storage module according to some embodiments of the present invention;

FIG. 4 is a schematic cross-sectional view of a storage module according to some embodiments of the present invention;

FIG. 5 is an exploded view of a storage module according to some embodiments of the present invention;

fig. 6(a) is a first schematic cross-sectional view of a storage module according to some embodiments of the invention;

fig. 6(b) is a second schematic cross-sectional view of a storage module according to some embodiments of the invention;

fig. 7(a) is an exploded view of a liquid storage module and a solid storage module according to some embodiments of the present invention;

fig. 7(b) is a schematic view of a combination of a liquid storage module and a solid storage module according to some embodiments of the present invention;

fig. 8(a) is a first schematic view of a liquid storage module according to some embodiments of the invention;

fig. 8(b) is a second schematic view of a liquid storage module according to some embodiments of the invention;

fig. 9 is a schematic view of a microfluidic system according to some embodiments of the present invention.

The reference numbers in the drawings:

1-a reaction module; 11-a reaction chamber; 12-a flow guide channel; 13-waste liquid chamber; 14-a waste channel; 15-an airflow channel; 16-mounting grooves;

2-a storage module; 21-a storage chamber; 22-a first sealing film; 23-an inlet of the storage chamber; 24-an outlet of the storage chamber; 25-a first chamfer; 26-a vent hole;

27-a liquid storage module; 271-a first liquid storage chamber; 272-a second liquid storage chamber; 273-a second chamfer; 274-grooves; 275-an inlet to a first fluid storage chamber; 276-an outlet of the first liquid storage chamber; 277-inlet of second liquid storage chamber; 278-an outlet of the second liquid storage chamber; 279-fourth sealing film;

28-a solid storage module; 281-a solid storage chamber; 282-outlet of solid storage chamber; 283-a vent of the solid storage chamber; 284-third chamfer;

3-a laser;

4-a gas device;

5-a magnet;

a, b, c, d, e, f, g, h, i, j, k, l-reagent chamber.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments. It is to be understood that the described embodiments are merely a few embodiments of the invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without any inventive step, are within the scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience in describing the present invention and for simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be taken as limiting the scope of the present invention.

As shown in fig. 1, some embodiments provide a microfluidic chip including a reaction module 1 and a storage module 2. The reaction module 1 and the storage module 2 are independent of each other and can be assembled into a single body.

In some embodiments, the reaction module 1 comprises a reaction chamber 11, and at least one flow guide channel 12 communicating with the reaction chamber 11.

In some embodiments, the reaction module 1 includes one or more reaction chambers 11, and each reaction chamber 11 is correspondingly communicated with at least one flow guide channel 12, so that several steps of biochemical reactions can be performed.

In some embodiments, the storage module 2 comprises at least one storage chamber 21, each storage chamber 21 being independent of the other and storing therein different or the same reagents. Each storage chamber 21 corresponds to a flow guide channel 12. In a state where the seal of the storage chamber 21 is broken, the storage chamber 21 communicates with its corresponding flow guide passage 12.

The reagent in each storage chamber 21 can enter the reaction chamber 11 from the storage chamber 21 to react according to the test requirement.

In some embodiments, an outlet is provided at a portion of each storage cavity 21 corresponding to the flow guide channel 12, and a sealing film is provided at the outlet, so that the storage cavity 21 can be communicated with the reaction cavity 11 by laser burning through the sealing film.

In some embodiments, the reaction module 1 is further provided with a vent hole communicated with the reaction chamber 11 to facilitate the gas in the reaction chamber 11 to be discharged, so that the reagent in the storage chamber 21 can better enter the reaction chamber 11.

In some embodiments, the reaction chamber 11 is in communication with one or more flow channels 12 to allow access to the reagents. The reaction chamber 11 is also in communication with a waste channel 14. The waste channel 14 may be connected to a gas device which can be pumped to drive the liquid reagent in the reaction chamber 11 out of the microfluidic chip or into the waste chamber 13 of the microfluidic chip.

In some embodiments, the reaction module 1 further comprises a waste liquid chamber 13 and a waste liquid channel 14, a first end of the waste liquid channel 14 is in communication with the reaction chamber 11, and a second end of the waste liquid channel 14 is in communication with the waste liquid chamber 13. Further, the second end of the waste channel 14 is higher than the first end of the waste channel 14, and the second end of the waste channel 14 is higher than the reagent level in the reaction chamber 11.

In some embodiments, the bottom of the reaction chamber 11 is concave, and the first end of the waste liquid channel 14 is communicated with the reaction chamber 11 via the lowest point of the bottom of the reaction chamber 11, so as to facilitate the complete discharge of the waste liquid in the reaction chamber 11.

In some embodiments, the reaction module 1 comprises a gas flow channel 15, a first end of the gas flow channel 15 is communicated with the waste liquid chamber 13, and a second end of the gas flow channel 15 is used for being communicated with the gas device 4 so as to blow and pump gas into the waste liquid chamber 13. Further, the first end of the air flow channel 15 communicates with the waste liquid chamber 13 via the top of the waste liquid chamber 13. The second end of the air flow channel 15 is higher than the first end of the air flow channel 15.

When the gas device 4 blows gas into the waste liquid chamber 13, the blown gas enters the reaction chamber 11. By controlling the blowing rate of the gas device 4, gas bubbles are formed in the liquid in the reaction chamber 11, the bubbles rise from the bottom to the top of the liquid and are broken, and the liquid is not blown out of the reaction chamber 11. With this, mixing of different reagents in the reaction chamber 11 can be achieved by multiple blows.

Meanwhile, the communication part of the waste liquid channel 14 and the waste liquid chamber 13 is positioned above the liquid level in the reaction chamber 11, so that the reagent in the reaction chamber 11 does not enter the waste liquid chamber 13 without being driven.

Further, a filter paper is arranged in the waste liquid cavity 13, and the filter paper is used for adsorbing and fixing waste liquid.

In some embodiments, the communication between the air flow channel 15 and the waste liquid chamber 13 is higher than the communication between the waste liquid channel 14 and the waste liquid chamber 13, so as to prevent waste liquid discharged from the reaction chamber 11 to the waste liquid chamber 13 from flowing to the air flow channel 15.

In some embodiments, the storage module 2 is disposed above the reaction module 1. The reagent in the storage chamber 21 is facilitated to flow to the reaction chamber 11 by gravity.

In some embodiments, the top of the reaction module 1 is provided with a mounting groove 16, and the mounting groove 16 is used for mounting the storage module 2.

In some embodiments, the inlet 23 of the reservoir is provided at the top of the reservoir module 2 and is sealed by a first sealing membrane 22, and the outlet 24 of the reservoir is provided at the bottom of the reservoir module 2 and is sealed by a second sealing membrane.

The first sealing film 22 has characteristics of dark color, opacity, air tightness and good moisture resistance, is easily burned through after being irradiated by laser, and can be formed by compounding multiple layers of films.

In some embodiments, as shown in fig. 5, a plurality of storage chambers 21 (liquid storage chambers) are arranged side by side in the storage module 2, with the inlets 23 of the storage chambers being provided at the top of the storage module 2 and sealed by a single first sealing film 22.

In some embodiments, a plurality of storage chambers 21 (liquid storage chambers) are arranged side by side in the storage module 2, and the outlet 24 of each storage chamber is provided at the bottom of the storage module 2, each sealed by a second sealing film.

The second sealing film has the characteristics of dark color, opacity, good air tightness and moisture resistance, is easy to burn through after being irradiated by laser, and can be formed by compounding multiple layers of films.

In some embodiments, the outlet 24 of the reservoir is smaller in size than the inlet 23 of the reservoir.

In some embodiments, the bottom of the storage chamber 21 is necked down and the storage chamber outlet 24 is disposed at the bottom of the storage chamber 21.

Optionally, the inner bottom of the storage cavity 21 is provided with a wedge-shaped inclined surface, so that when the gas device drives the liquid in the storage cavity 21, the whole liquid in the storage cavity 21 can be dried conveniently without residue.

In some embodiments, as shown in fig. 3 and 6(a), the bottom of the storage module 2 is provided with a first chamfer 25 extending along the arrangement direction of the storage cavities 21, and the outlets 24 of the storage cavities are provided on the first chamfer 25.

In some embodiments, the upper portion of the storage module 2 is provided with a vent hole 26, the vent hole 26 is communicated with the storage chamber 21, and a third sealing film is provided at the vent hole 26, and in a state where the third sealing film is broken, the vent hole 26 communicates the storage chamber 21 with the outside air.

The third sealing film has the characteristics of dark color, opacity, good air tightness and moisture resistance, is easy to burn through after being irradiated by laser, and can be formed by compounding multiple layers of films.

The first sealing film 22 may be a plastic film or an aluminum foil composite film, preferably an aluminum-plastic film, and has a good sealing effect.

The second sealing film and the third sealing film can be dark opaque plastic films, and the sealing is convenient to burn through by laser.

The materials used for the inner wall of each storage cavity 21 and each sealing film are biocompatible materials, can be contacted with the reagent for a long time, do not react with the reagent, have high air tightness, moisture resistance, oxygen resistance and other high barrier properties, and can store the reagent in a sealed manner for a long time.

The reagents in the storage cavities 21 in the storage module 2 can be replaced according to different experiments, and the main part of the experiment reaction is kept unchanged, so that the same microfluidic chip can meet the experiment requirements of different immunodiagnostics.

In some embodiments, as shown in fig. 7(a) and 7(b), the storage module 2 includes a liquid storage module 27, and a first liquid storage cavity 271 is disposed in the liquid storage module 27.

In some embodiments, as shown in fig. 7(a) and 7(b), the storage module 2 includes a solid storage module 28, and a solid storage chamber 281 is disposed in the solid storage module 28.

In some embodiments, the bottom of liquid storage module 27 is inserted into solid storage module 28, and first liquid storage chamber 271 communicates with solid storage chamber 281 in a state where the seal of outlet 276 of the first liquid storage chamber is broken; in a state where the seal of the outlet 282 of the solid storage chamber is broken, the solid storage chamber 281 communicates with its corresponding guide passage 12.

In some embodiments, the solid storage chamber 281 is used to store a lyophilized reagent in a solid state, and the first liquid storage chamber 271 is used to store a lyophilized reagent solution.

The freeze-dried reagent part is taken as a whole, so that the filling and industrialization of the reagent are facilitated, the flow work of a production line is facilitated, and the production efficiency is greatly improved.

The bottom of liquid reservoir module 27 is inserted into solid reservoir module 28 to form a unitary body, and when the laser burns through the sealed hole of outlet 276 of the first liquid reservoir chamber, the lyophilized reagent solution enters solid reservoir chamber 281. In order to exhaust air when the solution enters, a vent hole is formed in the upper portion of the solid storage cavity 281, and gas in the solid storage cavity 281 can be exhausted after the seal of the vent hole is burnt out by laser.

The freeze-drying reagent dissolving solution and the freeze-drying reagent are separately and independently stored, all the liquid and the freeze-drying reagent are sealed in different closed cavities, an independent liquid dissolving cavity is arranged above the freeze-drying reagent, the freeze-drying reagent and the liquid dissolving cavity are sealed in an embedded insertion mode, and the problems that the liquid and the solid reagent are not easily pre-installed on a chip and are stored for a long time can be solved.

In some embodiments, the bottom of the liquid storage module 27 is provided with a second chamfered surface 273, and the outlet 276 of the first liquid storage chamber is provided at the second chamfered surface 273.

In some embodiments, in a state where the bottom of the liquid storage module 27 is inserted into the solid storage module 28, the vent hole 283 of the solid storage chamber is located on the same horizontal line as the outlet 276 of the liquid storage chamber, so that two holes (the vent hole 283 of the solid storage chamber and the outlet 276 of the liquid storage chamber) located on the same horizontal line can be burned through together when the laser is burned through.

In some embodiments, the bottom of the solids storage module 28 is provided with a third chamfer 284, and the outlet 282 of the solids storage chamber is provided in the third chamfer 284.

The independent liquid storage module 27 and the independent solid storage module 28 can be formed by injection molding of plastic, and the plastic is made of a material which has good transparency, does not react with the reagent and can store the reagent for a long time.

In some embodiments, a second fluid reservoir chamber 272 is provided within the fluid reservoir module 27; in a state where the seal of the second liquid storage chamber 272 is broken, the second liquid storage chamber 272 communicates with its corresponding fluid passage 12.

The first liquid storage chamber 271 and the second liquid storage chamber 272 are integrated in the same liquid storage module 27.

The independent first and second liquid storage chambers 271 and 272 can hermetically store a liquid reagent. The liquid reagent in the second liquid reservoir 272 can be blown directly into the reaction chamber 11 by the gas means acting on the chip. The lyophilized reagent reservoir in the first liquid storage chamber 271 needs to be released into the solid storage chamber 281 to dissolve the solid lyophilized reagent in the solid storage chamber 281, and when the lyophilized reagent reservoir enters the solid storage chamber 281, the gas in the solid storage chamber 281 is discharged through the vent hole 283 of the solid storage chamber. Then, the reagent in the solid storage chamber 281 is blown into the reaction chamber 11 of the chip by the external gas to perform the reaction, and the vent hole 283 of the solid storage chamber needs to be temporarily blocked from the outside to prevent the gas from leaking out of the vent hole 283 of the solid storage chamber.

In some embodiments, at least one of the plurality of storage chambers 21, which is empty, is used for injecting a sample during the use of the microfluidic chip, and the rest of the storage chambers 21 are pre-filled with a reagent.

As shown in fig. 8(a), one of the plurality of independent second liquid storage cavities 272 is empty and is used for injecting a sample during the use of the microfluidic chip, and liquid reagents are preset in the other independent second liquid storage cavities 272.

The inlet 277 of the second liquid storage chamber for injecting the sample is sealed by a fourth sealing film 279 that is repeatedly stuck.

The second liquid storage chamber 272 for injecting the sample is empty inside and does not hold the reagent, so that there is no fear of long-term sealing performance and biocompatibility of the sealing film. At the time of use of the microfluidic chip, the fourth sealing film 279 at the inlet 277 is torn, the detection sample is added, and then the fourth sealing film 279 is sealed. The flow guide channel 12 may be directly connected below the second liquid storage chamber 272 for injecting the sample, and the injected sample is released to the reaction chamber 11 through the second liquid storage chamber 272 and the flow guide channel 12.

As shown in fig. 8(b), one of the independent first liquid storage chambers 271 may be empty for injecting a sample during the use of the microfluidic chip, and the liquid reagent may be preset in the remaining independent first liquid storage chambers 271.

The inlet 275 of the first liquid storage chamber for injecting the sample is sealed by a fourth sealing film 279 that is repeatedly stuck.

The first liquid storage chamber 271 for injecting the sample is empty, and the sample first enters the solid storage chamber 281 through the first liquid storage chamber 271, dissolves the lyophilized reagent in the solid storage chamber 281, and then enters the reaction chamber 11 through the outlet 282 of the solid storage chamber.

The storage chamber 21 may include a first liquid storage chamber 271, a second liquid storage chamber 272, and a solid storage chamber 281.

The inlets 23 of the storage chambers may include an inlet 275 of the first liquid storage chamber, an inlet 277 of the second liquid storage chamber, and an inlet of the solid storage module.

The storage chamber inlet 24 may include a first liquid storage chamber outlet 276, a second liquid storage chamber outlet 278, and a solids storage chamber outlet 282.

In some embodiments, as shown in FIG. 2, the bottom of the liquid storage module 27 is provided with a recess 274 and the solid storage module 28 is provided within the recess 274.

As shown in fig. 9, some embodiments provide a microfluidic system including the microfluidic chip described above.

In some embodiments, the microfluidic system comprises a laser 3, the laser 3 being used to break the seal of the reservoir 21.

Optionally, the laser 3 is controlled by the linear motor to move up and down, left and right, sealing films corresponding to holes in different chambers are burnt through, and liquid flow conduction and reagent release are achieved.

The distance of the laser 3 from the sealing film on the chip is fixed, so that the laser can burn through the films on the corresponding holes on the chip in sequence, the laser replaces the application of a traditional valve device, the liquid is released, the structure of the chip is simpler, and the chip is convenient to process and manufacture.

The size and the dimension of the laser 3 can be customized, the installation is convenient, the power can be adjusted, and the burn-through can be carried out aiming at different sealing films. The laser 3 can achieve burn-through of the sealing film within 1 second at a higher power and has no effect on the transparent microfluidic chip. Meanwhile, the positioning before burning through can be carried out by emitting light with low power.

In some embodiments, the microfluidic system comprises a gas device 4, the gas device 4 at least being adapted to blow the reagent of the storage chamber 21 towards the reaction chamber 11.

And blowing gas by using a gas device 4 to form positive pressure, and blowing the reagent into the reaction cavity 11 in the chip. The liquid in the chip is controlled by the gas device 4, so that the liquid flows into the reaction chamber 11 in sequence according to the sequence of experimental reactions to carry out relevant reactions.

The gas device 4 is used for driving to realize the transfer of the reagent among all chambers in the chip so as to complete the complicated experimental process. The method is simple and reliable, the chip can be made very simply and has small volume, and the industrialization of the whole method is facilitated.

The gas means 4 comprise a peristaltic pump, a hose and a vacuum cup. One end of the hose is connected to the peristaltic pump and the other end of the hose is connected to the vacuum cup, which forms a sealed connection when pressed against the vent hole in the storage chamber 21, connecting the storage chamber 21 to the space within the hose. When the peristaltic pump rotates to drive the gas in the hose, the gas in the storage cavity 21 is also driven, and further the reagent in the storage cavity 21 is driven to flow and enter the reaction cavity 11 for reaction.

The gas device 4 further comprises a motor which is in driving connection with the vacuum chuck. The vacuum chuck is driven by a motor to move the position. When it is pressed against the opening in the reservoir 21, the flow of the reagent in the reservoir 21 can be driven. It can also drive the transfer, mixing and other flows of reagents in other reaction chambers.

In some embodiments, the microfluidic system further comprises a movable magnet 5 located outside the microfluidic chip. When liquid in the reaction cavity 11 is pumped away, the magnet 5 can be close to the micro-fluidic chip to adsorb and fix the magnetic beads in the reaction cavity 11, so that the magnetic beads cannot flow away along with the liquid and are discharged into the waste liquid cavity 13, and the micro-fluidic chip can complete the processes of magnetic bead capture reaction, washing, elution and the like in the immunoreaction.

Some embodiments provide a method of operating a microfluidic system, comprising the steps of: the outlet 24 of the reservoir is sealed, the reagent is placed in the reservoir 21, and the inlet 23 of the reservoir is sealed.

The storage chamber 21 includes a first liquid storage chamber 271, a second liquid storage chamber 272, and a solid storage chamber 281.

The inner walls of the first liquid storage cavity 271, the second liquid storage cavity 272 and the solid storage cavity 281 can be formed by plastic injection molding, and after reagents are filled in the inner walls, a layer of plastic film or aluminum foil composite film is sealed on the surface of the opening by adopting methods such as hot pressing, laser welding, gluing and the like.

Sealing films are arranged at the vent hole of the liquid storage cavity (the first liquid storage cavity 271 and the second liquid storage cavity 272) and the outlet of the liquid storage cavity, liquid reagent is filled in from the inlet of the liquid storage cavity, and then the inlet of the liquid storage cavity is sealed by adopting methods such as hot pressing, laser welding, chemical bonding and the like. Thereby sealing the entire liquid storage chamber and completing the complete sealing of the liquid storage chamber.

The vent hole 283 of the solid storage chamber and the outlet 282 of the solid storage chamber are provided with sealing films, and the freeze-dried reagent is filled from the inlet of the solid storage chamber 281. Then, the inlet of the solid storage chamber 281 and the lower part of the first liquid storage chamber 271 are embedded together by using methods such as chemical agent bonding, laser welding and the like, and are glued at the embedding part, so that the solid storage chamber 281 is firmly sealed, and meanwhile, the solid storage chamber 281 and the first liquid storage chamber 271 are integrally formed.

Some embodiments provide methods of operating a microfluidic system, further comprising a reagent release step: the laser is used to break the seal of the outlet 24 of the reservoir chamber to allow the reagent in the reservoir chamber 21 to flow to the reaction chamber 11.

In some embodiments, during the reagent storage step, the vent 26 of the storage chamber 21 is further sealed; in the reagent releasing step, the seal of the vent hole 26 of the storage chamber 21 is further broken by laser.

In some embodiments, in the reagent releasing step, the gas is blown into the storage chamber 21 by the gas device 4, so that the reagent in the storage chamber 21 flows to the reaction chamber 11.

In some embodiments, the method of operating a microfluidic system further comprises a reagent reaction step: the gas is blown into the reaction chamber 11 from the bottom of the reaction chamber 11 by the gas device 4, so that the reagents in the reaction chamber 11 are vibrated and mixed.

In some embodiments, the method of operating a microfluidic system further comprises a waste fluid removal step, wherein a suction force is provided by the gas device 4 to draw out waste fluid from the reaction chamber 11.

A method of operation of an embodiment of a microfluidic system provided by the present disclosure is listed below.

In this embodiment, the microfluidic system includes a microfluidic chip including a plurality of flow guide channels 12, a reaction chamber 11, a waste chamber 13, a plurality of storage chambers 21, and a plurality of open sealing films.

When liquid needs to be fed, the motor drives the laser 3 to position the opening/hole of the corresponding storage cavity 21 and burn through the sealing film on the opening/hole. The peristaltic pump drives the hose to blow air into the storage chamber 21 to form a positive pressure, so that the liquid reagent is blown into the reaction chamber 11 from the storage chamber 21 through the diversion channel 12 or the liquid reagent enters the solid storage chamber 281 first, and the freeze-dried reagent is dissolved and then enters the reaction chamber 11 together.

If still need other reagents to enter into reaction chamber 11 in the time, can the motor drive laser instrument continue to burn through other seal membranes on corresponding mouth/hole on the storage chamber 21, continue to pass through the liquid entering reaction chamber 11 in other storage chambers 21 of peristaltic pump drive again, when blowing, can control in speed, can prevent to produce when liquid enters like this under the slow condition and splash, stop on the lateral wall of chip, and new liquid comes in later can be in the same place with original liquid mixture, just so realized the process of multiple liquid mixing reaction.

The pressure is applied in a flow channel where the suction cup of the gas device 4 is moved by the motor above the waste liquid chamber 13, because the bottom of the reaction chamber 11 is tangent to the waste liquid channel, the reaction chamber 11 and the waste liquid chamber 13 are connected by a waste liquid channel 14 of approximately s-shape.

When the hole on the waste liquid cavity 13 is blown by the gas device 4, positive pressure is generated, bubbles can be generated at the bottom of the reaction cavity 11, when the bubbles are generated in a plurality and can be broken in the rising process, vibration can be generated along with the breakage of the gas, and the liquid in the reaction cavity 11 is subjected to vibration mixing similar to mechanical vibration, so that the liquid among different species or the liquid and the magnetic beads are well blended and mixed.

When the gas device 4 is used for sucking the holes in the waste liquid cavity 13, negative pressure is generated, and meanwhile, the magnet is close to and adsorbs and fixes the magnetic beads in the reaction cavity 11, so that the liquid in the reaction cavity 11 can enter the waste liquid cavity 13, the waste liquid discharge process is realized, and the magnetic beads are reserved; furthermore, a piece of filter paper can be filled in the waste liquid cavity 13, and the waste liquid can be adsorbed and fixed by the filter paper after being discharged, so that a drainage function is realized.

The microfluidic chip provided by the disclosure can be applied to immunodiagnosis. The immunodiagnosis is mainly as follows:

and (3) performing radiation immunization: in vitro detection techniques that combine the high sensitivity, accuracy of radioisotope measurements with the specificity of antigen-antibody reactions.

Enzyme-linked immunosorbent assay: the enzyme reacts with the sample and the result is determined according to the degree of color change.

Colloidal gold: and (3) a coating process of adsorbing the protein and other high molecules on the surface of the colloidal gold particles. The polymer was visible to the naked eye after aggregation.

Emulsion turbidity: the antibody is adsorbed on latex particles to form an allergen, and the allergen and the antigen are subjected to a cross-linking reaction to form an antigen-antibody complex, so that the latex particles are aggregated.

Fluorescence immunization: the immunological method is combined with the fluorescent labeling technology to research the distribution of specific protein antigen in cells.

Chemiluminescence: combining the antigen and antibody with the sample, then capturing the reactant by the magnetic beads, adding the promoter, increasing the reaction luminescence speed and intensity, and further diagnosing.

In the actual operation of immunodiagnosis, the steps are complex, the repetitive work is too much, and the processes of mutual mixing, incubation, reaction, washing and the like of related reagents are involved, taking an acridine ester chemiluminescence experiment as an example, a sample and magnetic beads are mixed, incubated for 15 minutes, washed for three times, the part without specific binding is removed, the occurrence of non-specific reaction is prevented, then a luminescent reagent acridine ester is added, incubated for 10 minutes, washed for two times, finally an excitation liquid and a pre-excitation liquid are added, and finally the concentration of the sample is subjected to related qualitative and quantitative determination by collecting light. Based on this, it is crucial and necessary to be able to perform this series of reactions on one microfluidic chip.

The specific operation process of the chemiluminescence method performed by the microfluidic system including the microfluidic chip provided by the present disclosure is described in detail below as an example.

First, the storage chambers 21 are pre-filled with reagents, and for convenience of description, the storage chambers 21 shown in fig. 4 are respectively labeled as follows: the reagent kit comprises a reagent cavity a, a reagent cavity b, a reagent cavity c, a reagent cavity d, a reagent cavity e, a reagent cavity f, a reagent cavity g, a reagent cavity h, a reagent cavity i, a reagent cavity j, a reagent cavity k and a reagent cavity l. The reagents in each reagent chamber were as follows:

a reagent chamber: pre-excitation liquid; b, reagent cavity: a wash solution; c reagent chamber: a wash solution; d reagent chamber: a wash solution; e, reagent cavity: a sample reagent; f reagent chamber: freeze-drying the magnetic beads; g, reagent cavity: a buffer solution; h reagent chamber: freeze-drying acridinium ester; i reagent chamber: a wash solution; j reagent chamber: a wash solution; k reagent chamber: a wash solution; l reagent chamber: an excitation liquid.

The e-reagent chamber is the sample chamber and is initially empty. The top inlet 275 is sealed with a fourth reusable adhesive sealing membrane 279. In use, the fourth sealing membrane 279 is first torn open and a measured amount of sample is added to the e-reagent chamber using a pipetting device, and then the fourth sealing membrane 279 is resealed.

By controlling the movement of the laser 3, the second sealing film positioned to the upper vent hole 26 of the e-reagent chamber and the third sealing film of the lower vent hole 276 are burned through, wherein when the third sealing film of the lower vent hole 276 is burned through, the upper vent hole 283 of the F-reagent chamber is also burned through at the same time because the lower vent hole 276 and the upper vent hole 283 of the F-reagent chamber are in an aligned position.

Then the vacuum chuck aims at the air vent 26 on the e reagent cavity to blow air, the liquid sample in the e reagent cavity is released into the f reagent cavity to be dissolved with the freeze-dried magnetic beads, and when the reagent enters the f reagent cavity, the air is discharged through the air vent 283 of the f reagent cavity; after dissolution, the laser 3 burns through the sealing film of the outlet 282 on the reagent chamber, and the dissolved liquid is blown into the reaction chamber 11 through the diversion channel 12 by the vacuum chuck, and incubated in the reaction chamber 11 for 15 min. When blowing, the vent hole 283 at the upper part of the reagent chamber is blocked from the outside, and gas is prevented from leaking from the vent hole 283.

After the incubation, the sucker is aligned to the airflow channel 15 of the experimental reaction module 1, air is pumped, so that waste liquid enters the waste liquid cavity 13 from the reaction cavity 11 after the incubation is finished, and the magnet 5 can be added for adsorption, thereby ensuring that magnetic beads are left in the reaction cavity 11.

The releasing process is as above, the washing liquid in the reagent cavity b, the reagent cavity c and the reagent cavity d is sequentially released through the sucking disc, the magnetic beads in the reaction cavity 11 are washed and uniformly mixed to remove non-specific adsorption, the sucking disc blows air into the reaction cavity 11 through the airflow channel 15 in the washing process, bubbles are formed in the liquid in the reaction cavity 11 and are broken along with the rising of the bubbles to generate vibration, the uniform mixing of the liquid is realized, and the liquid after washing is sucked into the waste liquid cavity 13 through the sucking disc every time.

After the three times of washing, the buffer solution in the g reagent chamber was released into the h reagent chamber, dissolved with the lyophilized acridinium ester, and then blown into the reaction chamber 11 together for incubation for 10 minutes.

After the incubation is finished, the liquid in the reaction cavity 11 is sucked into the waste liquid cavity 13, the magnetic beads are left, and then the washing liquids in the reagent cavity i, the reagent cavity j and the reagent cavity k are released in sequence to carry out the non-specific washing process of the magnetic beads.

And finally, releasing the pre-excitation liquid and the excitation liquid in the reagent cavity a and the reagent cavity l in sequence to realize the acquisition of chemiluminescence and complete the whole experiment.

The method provided by the disclosure is simple and reliable, can complete the steps of storing liquid and freeze-dried reagents required by complex biochemical reactions, dissolving the freeze-dried reagents, sequentially releasing the reagents, mixing, carrying out multi-step transfer reactions and the like, meanwhile, the storage mode of the reagents is a mature sealing mode at present, and the chip can be correspondingly made very simple, thereby being very beneficial to the industrialization of the whole method.

Through the description of the various embodiments above, the present disclosure has at least the following beneficial effects:

the method is simple: the method is applicable to batch production and low in cost. The storage part of the reagent is separated from the reaction chip, the storage mode of the reagent is the mature sealing mode at present, the chip can be correspondingly and simply manufactured due to the fact that the storage and release part of the reagent is stripped, industrialization is facilitated, and the storage chamber and the chip are simple, so that batch cost is low.

The functionality is strong: the method can complete the steps of liquid and freeze-dried reagent storage, freeze-dried reagent dissolution, reagent sequential release, mixing, multi-step transfer reaction and the like required by complex biochemical reactions. Furthermore, the method becomes very versatile due to the storage of reagents and the separation of reaction chips. Since most biochemical reactions are mixed reactions of various reagents, the method can easily realize reagent change, reagent increase or reduction, and experiment step increase or reduction, and the chip and the storage chamber do not need to be greatly changed.

The reagent is reliable to preserve for a long time: and an independent storage cavity is adopted, so that the liquid reagent can be stored, and the freeze-dried reagent can be stored in a chimeric sticking mode. The packaging process is mature, and the reagent can be stored for a long time. Meanwhile, the freeze-dried reagent can be stored, so that the requirement on the storage environment of the reagent is reduced, the purpose of long-term storage of the reagent at normal temperature is favorably achieved, the whole reaction detection process is favorably carried out in a laboratory, and the field detection is realized.

The control is simple: the reagent is released in sequence only by sequentially burning through the sealing films on the corresponding holes of the storage chamber through the laser, the on-off function of the traditional valve is replaced, the structure of the chip is simpler, the extraction and the driving of the reagent only need the suction driving of a gas device, the control is simple, the reliability is high, and the complicated instrument design is avoided.

Batch manufacturing: the adopted materials are common materials, are low in price and easy to obtain, and the injection molding process is a common process in the medical appliance industry, so that batch production is easy to realize.

In the description of the present invention, it should be understood that the terms "first", "second", "third", etc. are used to define the components, and are used only for the convenience of distinguishing the components, and if not otherwise stated, the terms have no special meaning, and thus, should not be construed as limiting the scope of the present invention.

Finally, it should be noted that the above examples are only used to illustrate the technical solutions of the present invention and not to limit the same; although the present invention has been described in detail with reference to preferred embodiments, those skilled in the art will understand that: modifications to the specific embodiments of the invention or equivalent substitutions for parts of the technical features may be made; without departing from the spirit of the present invention, it is intended to cover all aspects of the invention as defined by the appended claims.