KR20230156554A - Microfluidic system - Google Patents

Abstract

The present invention relates to a microfluidic system that simply and precisely controls the flow rate of microfluidics, and more specifically, to a microfluidic system that includes one or a plurality of fluid reservoirs; a microfluidic chip having one or more microchannel outlets in communication with the fluid reservoir; One or more discharge tubes connected one to one to the micro-channel outlet; and a raising and lowering means for adjusting the height of the outlet end of the one or more discharge tubes. It relates to a microfluidic system that controls the flow rate of microfluid using potential energy, including a.

Description

Microfluidic system {Microfluidic system}

The present invention relates to a microfluidic system that simply and precisely controls the flow rate of microfluids, and more specifically, to a microfluidic system that controls the flow rate of microfluids using potential energy.

The microfluidic system uses only a small amount of samples and reagents, shortens the reaction time, and performs experiments under various conditions at once on one chip, enabling high-throughput screening with fewer reagents. It has advantages such as low energy consumption, high portability and speed, and excellent resolution and sensitivity.

In order to obtain the desired results in a microfluidic system, it is essential to precisely control the flow rate (i.e., the amount added per unit time) of the microfluid used. The transport of microfluid in a microfluidic system is divided into statistical transport and induced transport. It is done in two ways: (directed transport). Statistical transport is the movement of fluid through a diffusion mechanism caused by a concentration gradient, and since the initial fluid concentration (at the inlet) is generally determined, controlling the microfluidic flow rate is very difficult in practice. Induced transport moves the fluid by applying work to the fluid, and in most microfluidic systems, the flow rate is controlled by pressure control.

US 2019/0064158 (Microfluidic device, system and method) controls the flow rate of fluid by utilizing capillary force and gas pressure acting on the gas-liquid interface, and CN 103667057 (cell migration biological behavior after window based on microflow control chip) In the monitoring method, the flow rate of the microfluid is controlled by adding microfluid to the reservoir to generate a liquid level pressure difference. In CN 110479391 (low-voltage high-performance electroosmotic micropump chip based on solid-state tracked etched nanoholes), a high-performance electroosmotic pump is used to control the microfluidic flow rate.

This pressure control method not only requires expensive precision equipment (dedicated special valves, pumps, etc.), but also has the disadvantage that the reservoir mounted on the device must be strongly bonded, and it is difficult to control the flow rate of microfluidics 'intuitively'. .

Meanwhile, the siphon phenomenon, which uses atmospheric pressure to move liquid from a high place to a low place, is widely known, but to date, no case has been presented for applying this siphon phenomenon to a microfluidic system to control the flow rate of microfluidics.

US 2019/0064158 CN 103667057 CN 110479391

The purpose of the present invention is to provide a system and method that can finely control the flow rate of microfluidics in a simple and economical manner.

The present invention to achieve the above-mentioned purpose

One or more fluid reservoirs; a microfluidic chip having one or more microchannel outlets in communication with the fluid reservoir; One or more discharge tubes connected one to one to the micro-channel outlet; and a raising and lowering means for adjusting the height of the outlet end of the one or more discharge tubes. It is characterized as a microfluidic system that controls the flow rate of microfluid using potential energy.

As described above, according to the present invention, the flow rate of microfluid is controlled in a simple and simple manner by adjusting the height of the outlet side of the fluid discharge tube of the microfluidic chip.

According to the present invention, the flow rate of microfluid can be easily controlled by using a raising and lowering device that adjusts the height of the microfluidic discharge tube instead of the expensive precision equipment required in the conventional pressure control method.

According to the present invention, it is possible to precisely control the flow rate of microfluids in a simple and economical manner, so it can be used for chemical/bio research in various fields ranging from biology to polymers, chemistry, etc., such as diagnostic chips, organic synthesis, cell culture, and microreactors. It will be possible to significantly increase the accessibility and utilization of microfluidic systems, contributing to the activation of experimental or industrial use of microfluidic systems in medical settings, etc.

Figure 1a is a conceptual diagram showing the difference between the flow rate control method according to the prior art (A) and the present invention (B).
Figure 1b is a conceptual diagram showing that the flow rate can be controlled by height adjustment.
Figure 2 is a photograph and conceptual diagram of the microfluidic system according to the present invention manufactured to demonstrate fluid flow rate control.
Figure 3a is a conceptual diagram of a microfluidic chip for measuring microfluidic flow velocity.
Figure 3b is a photograph showing that the flow rate increases according to the height difference (ΔZ) at the outlet end of the discharge tube in the embodiment according to the present invention.
Figure 3c is a chart showing the correlation between the height difference (ΔZ) at the outlet end of the discharge tube and the flow rate in an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the attached drawings and examples. However, these drawings and examples are merely examples for easily explaining the content and scope of the technical idea of the present invention, and the technical scope of the present invention is not limited or changed thereby. Based on these examples, it will be obvious to those skilled in the art that various modifications and changes are possible within the scope of the technical idea of the present invention.

As described above, the present invention, in a microfluidic system having a microfluidic reservoir, a microfluidic chip, and a typical air pump or liquid pump type microfluidic flow rate control means, uses an outlet of the discharge tube instead of an air pump or liquid pump type microfluidic flow rate control means. It relates to a microfluidic system that has a lifting and lowering means for adjusting the side end height and controls the flow rate of microfluidic using potential energy. Since the present invention relates to controlling the flow rate of microfluidics in a microfluidic system, it is obvious to those skilled in the art that the present invention can be applied without restrictions on the specifications, characteristics, or uses of the microfluidic chip itself. will be.

In Figure 1a, the difference between the flow rate control method according to the prior art (A) and the present invention (B) is conceptually shown, and in Figure 1b, the flow rate control is possible by utilizing the so-called 'siphon effect' according to the present invention. .

In the present invention, the reservoir is a small container containing various solutions used in a microfluidic chip, and is installed one or more. As mentioned above, according to the prior art, air pressure by pump operation or pressurization by liquid supply is applied to the inside of the reservoir, so if there is a weak bond between the reservoir and the microfluidic chip, leakage of microfluid may occur, so it must be made quite firmly. It must be fixed. In contrast, in the present invention, since no pressurization occurs, there is no need to pay much attention to the coupling between the reservoir and the microfluidic chip.

In the present invention, the microfluidic chip, as is widely known, has one or a plurality of microchannel outlets that communicate with the fluid reservoir as a space where microreactions are performed. Since the present invention does not relate to the microfluidic chip itself, detailed description thereof will be omitted.

In the present invention, the discharge tube is one or a plurality of tubes connected one to one to the microfluidic outlet and is a discharge passage for the post-reacted microfluid supplied from the fluid reservoir and discharged to the outside through the passage of the microfluidic chip. According to the prior art, an exhaust tube is not essential, and even if an exhaust tube exists, its purpose is to collect the reaction liquid and has nothing to do with controlling the flow rate of the fluid.

In the present invention, the raising and lowering means is a device that adjusts the height of the outlet end of one or more discharge tubes. Since the outlet end of the actual discharge tube is generally located within a predetermined discharge container to contain the discharged reaction liquid, the raising and lowering means ultimately controls the height of the discharge container.

In the present invention, it is natural that the raising and lowering means can be implemented in various ways, such as manual or electric, as shown in FIGS. 1A and 2. For example, the raising and lowering means includes a mounting base on which the discharge container to which the outlet end of the discharge tube is connected is placed, an electric device that moves the mounting table up and down, and a control unit that controls the operation of the electric device in a predetermined manner. etc. can be achieved. At this time, the control unit preferably controls the driving of the electric device based on a correlation between height and flow rate defined in advance according to the type of microfluid discharged into the discharge tube and the standard of the discharge tube.

Depending on the purpose and characteristics of the microfluidic chip, there may be one or multiple discharge tubes connected one-to-one to the outlet. If there are multiple discharge tubes, some of the discharge tubes may be independently height controlled as needed. In other words, a method of controlling the individual microfluidic flow rate of the microfluidic system according to the present invention described above is possible by controlling the raising and lowering means.

Hereinafter, an example of manufacturing and testing a microfluidic system that controls the flow rate of microfluidic fluid using potential energy according to the present invention will be described.

[Example]

1. System composition

As shown in the photo attached to Figure 2, a microfluidic system according to the present invention was implemented.

In a system including a reservoir made of PDMS material with an inner diameter of 7 mm and a microfluidic chip with eight microchannel outlets, a discharge tube made of silicone material with an inner diameter of 0.5 mm was connected to the two outlets, and the height of the outlet end of the discharge tube was manually adjusted. did.

2. Microfluidic flow rate control test according to change in height at the outlet end of the discharge tube

In order to measure the flow velocity of microfluidics, the microfluidic chip itself was manufactured in the form of a 'flow velocity measuring device' as shown in Figure 3a. The flow measurement device is horizontal, and in the picture, the upper right inlet is connected to the reservoir, and the lower left outlet is connected to the discharge tube. The lower outlet end of the discharge tube can be adjusted in height by means of raising and lowering.

300㎕ of microfluid of 'distilled water + 20% magneta pigment' was placed in the reservoir, and photographs were obtained to confirm the change in flow rate by changing the height difference (ΔZ) between the bottom of the reservoir and the outlet end of the discharge tube (Figure 3b) The correlation between height difference (ΔZ) and microfluidic flow rate (Figure 3b) was analyzed.

Figure 3b is a photo of fluid flowing from top to bottom in a flow measurement device. The 'before' photo is a photo observed at each position at 0 seconds, and the 'after' photo is again taken exactly 1 second after 0 second. This is an observation photo. As can be seen roughly in the drawing, as the height difference (ΔZ) increases, the distance the fluid moves per unit time increases.

Using the data obtained in FIG. 3b, the fluid flow rate per minute according to the height difference (ΔZ) was subjected to linear regression analysis and shown in a graph in FIG. 3c. As can be seen in Figure 3c, in the height difference (ΔZ) range of 0 to 85.5 cm, linearity of approximately 98% was shown at Y = 0.25257 It was. The reason why different linear characteristics are shown before and after a height difference (ΔZ) of about 30 cm is due to the action of drag force as the shear stress between the fluid and the microchannel wall increases when the height difference (ΔZ) is less than about 30 cm in the environment of this example. investigated (not shown).

The results of this example prove that the microfluidic system of the present invention can control the flow rate of microfluidic at the micro/nano level by adjusting the height of the end of the discharge tube.

Claims (5)

One or more fluid reservoirs;
a microfluidic chip having one or more microchannel outlets in communication with the fluid reservoir;
One or more discharge tubes connected one to one to the micro-channel outlet; and
A microfluidic system that controls the flow rate of microfluid using potential energy, including; raising and lowering means for adjusting the height of the outlet end of the one or more discharge tubes.
In claim 1,
The means for raising and lowering is,
A microfluidic system that controls the flow rate of microfluid using potential energy, characterized in that the height of the outlet end of all of the one or plurality of discharge tubes is adjusted.
In claim 1,
The means for raising and lowering is,
A microfluidic system that controls the flow rate of microfluid using potential energy, characterized in that one or more discharge tubes are installed to adjust the height of the outlet end of each discharge tube.
The method of any one of claims 1 to 3,
The means for raising and lowering is,
Controlling the flow rate of microfluid using potential energy, characterized in that it includes a control unit controlled by the correlation between the height and flow rate defined in advance according to the type of microfluid discharged into the discharge tube and the specifications of the discharge tube. microfluidic system.
A method of controlling the individual microfluidic flow rate of the microfluidic system according to any one of claims 1 to 3 by controlling the raising and lowering means.