KR102470156B1 - Biosensor where fluid flows into the channel easily - Google Patents

Abstract

The present invention relates to a biosensor in which fluid flows easily into a channel, and includes a fluid storage case in which fluid is stored, a first membrane to which external pressure is applied, and a first membrane that is torn when external pressure is applied to a first region, A second membrane through which the fluid stored in the fluid storage case passes, a channel through which the fluid stored in the fluid storage case flows when the second membrane is torn, and a substrate forming a lower end of the channel, 1 characterized in that the fluid stored in the fluid storage case moves to the channel through the second membrane by applying pressure to the second region of the membrane, and the fluid in the fluid chamber is easily introduced into the channel to react with the sample can do.

Description

Biosensor where fluid flows into the channel easily}

The present invention relates to a biosensor through which a fluid can easily flow into a channel, and more particularly, to a biosensor capable of reacting with a sample by easily flowing a fluid within a fluid chamber into a channel.

As the demand for POCT for disease prevention and early diagnosis increases with the advent of an aging society, various on-site diagnostic kits such as biosensors using membranes and biosensors using microfluidic channels have been developed. It has been commercialized, and the demand for these products is also rapidly increasing. However, compared to the disease diagnosis accuracy and sensitivity of the ELISA-type disease diagnosis method performed by humans in clinical analysis laboratories such as large hospitals, there is still a problem in that the disease diagnosis accuracy and sensitivity of various on-site diagnosis kits are significantly lower.

One of the causes of low disease diagnosis accuracy and sensitivity is that blood distribution is heterogeneous, which impairs detection accuracy. It is difficult to achieve uniform blood distribution without additional and costly instrument design or human washing.

Therefore, there is a need to improve detection accuracy by simply washing unnecessary blood in the channel. In addition, when a reagent reacting with blood is supplied into the channel, there is no means for controlling the supply speed of the reagent, so a means for rapidly reacting the blood with the reagent is required.

Republic of Korea Patent Publication No. 10-2013-0033110 (2013.04.03)

Accordingly, an object to be solved by the present invention is to provide a biosensor capable of reacting with a sample by easily introducing fluid in a fluid chamber into a channel.

The present invention in order to achieve the above object, the fluid storage case in which the fluid is stored; a first membrane to which an external pressure is applied; a second membrane that is torn when the external pressure is applied to the first area of the first membrane and through which the fluid stored in the fluid storage case passes; a channel through which the fluid stored in the fluid storage case flows when the second membrane is torn; and a substrate forming a lower end of the channel, wherein a pressure is applied to a second region of the first membrane so that the fluid stored in the fluid storage case moves into the channel through the second membrane. Provided is a biosensor in which inflow into a channel is easy.

According to an embodiment of the present invention, a fluid pressure portion formed to press the second area of the first membrane is further included, and the amount of fluid passing through the second membrane is controlled according to the length or area of the fluid pressure portion. it is desirable to be

In addition, when a convex protrusion is formed on the substrate and the protrusion goes up into the channel, one end of the channel may be blocked to prevent fluid flowing into the channel from flowing into the one end.

According to another embodiment of the present invention, the distance between the first membrane and the second membrane is configured to be smaller than the inner depth of the fluid storage case so that the fluid in the fluid chamber can be easily introduced into the channel.

According to the present invention, the fluid in the fluid chamber can be easily introduced into the channel to react with the sample. In addition, according to the present invention, the flow rate of the fluid in the fluid chamber into the channel can be controlled. Furthermore, according to the present invention, the fluid introduced into the channel can flow in one direction to react with the sample.

1 is a configuration diagram of a biosensor through which fluid flows easily into a channel according to a preferred embodiment of the present invention.
2 is a configuration diagram of a biosensor through which fluid flows easily into a channel according to another preferred embodiment of the present invention.
3 illustrates a portion of the upper surface of a biosensor through which fluid flows easily into a channel according to a preferred embodiment of the present invention.
4 shows another internal structure of the fluid chamber 14 according to a preferred embodiment of the present invention.
5 is a view showing protrusions formed on a substrate in a biosensor according to a preferred embodiment of the present invention.
6 shows actual appearances of the membrane pressure unit 11 and the fluid pressure unit 12 of the biosensor according to a preferred embodiment of the present invention.
FIG. 7 shows an actual state in which the second membrane 21 of the biosensor according to a preferred embodiment of the present invention is torn.
FIG. 8 shows a state in which fluid flows out of the channel 30 to the second membrane 21 of the biosensor according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments in which a person skilled in the art can easily practice the present invention will be described in detail with reference to the accompanying drawings. However, these examples are intended to explain the present invention in more detail, and it will be apparent to those skilled in the art that the scope of the present invention is not limited thereto.

The composition of the present invention for clarifying the solution to the problem to be solved by the present invention will be described in detail with reference to the accompanying drawings based on a preferred embodiment of the present invention, but the same reference numerals are assigned to the components of the drawings. For components, even if they are on other drawings, the same reference numerals have been assigned, and it is made clear in advance that components of other drawings can be cited if necessary in the description of the drawings. In addition, in the detailed description of the operating principle of the preferred embodiment of the present invention, if it is determined that the detailed description of known functions or configurations related to the present invention and other matters may unnecessarily obscure the subject matter of the present invention, A detailed description thereof is omitted.

In addition, throughout the specification, when a part is 'connected' to another part, it is not only 'directly connected', but also 'indirectly connected' with another element in between. include In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase. As used herein, "comprises" or "comprising" excludes the presence or addition of one or more other components, steps, operations, or elements other than the recited components, steps, operations, or elements. I never do that.

Terms including ordinal numbers such as second and first may be used to describe various components, but the components are not limited by the terms. These terms are only used for the purpose of distinguishing one component from another. For example, a second element may be termed a first element, and similarly, a first element may be termed a second element, without departing from the scope of the present invention. The terms and/or include any combination of a plurality of related recited items or any of a plurality of related recited items.

The biosensor in the present specification includes a target material included in a sample and a fluid (reagent or buffer solution) in which a specific reaction can be induced, and is involved in converting this reaction into an electrical or optical signal, Preferably, the device is manufactured to detect the presence or absence of a target material.

1 is a configuration diagram of a biosensor through which fluid flows easily into a channel according to a preferred embodiment of the present invention.

Referring to FIG. 1 , the biosensor according to the present embodiment includes a first membrane 10, a fluid storage case 20, a second membrane 21, a channel 30, and a substrate 40. .

Referring to FIG. 1, FIG. 1(a) shows a state in which fluid is stored in the fluid chamber 14 of the fluid storage case 20. The fluid is stored in the fluid chamber 14 by the first membrane 10 and the second membrane 21, which are impervious membranes.

1(b) shows that when the pressure bar 100 presses the corresponding area of the first membrane 10 directly above the second membrane 21, the first membrane 10 is bent downward, and the second membrane (21) shows the torn state.

1(c) shows that when the pressure bar 100 presses another area of the first membrane 10 that is a certain distance away from the corresponding area immediately above the second membrane 21, the fluid stored in the storage case 20 It is shown that the fluid flows in both directions of the channel 30 through the hole 22 connected to the torn second membrane 21 .

The first membrane 10 is a flexible and elastic impervious membrane, and preferably has impermeable properties to fluids and gases. The first membrane 10 may be made of silicone or urethane.

The first membrane 10 is attached to cover the top of the fluid storage case 20 and seals the fluid storage case 20 so that the fluid stored in the fluid storage case 20 does not flow to the outside. In the drawing of the present invention, one first membrane 10 is shown to cover the top of the fluid storage case 20, but at least two or more first membranes 10 cover the top of the fluid storage case 20. can

The fluid stored in the fluid storage case 20 is preferably a fluid sample for blood washing, measurement, and reaction. The fluid may be a reagent, a buffer solution, or the like.

The fluid storage case 20 is made of an impermeable material and stores the fluid in the fluid chamber 14 . As the impervious material, PC (PolyCarbonate), PMMA (Poly Methyl Methacrylate), and COC (Cyclic Olefin Copolymer) are preferably used. In particular, COC has excellent mechanical strength, heat resistance, chemical resistance, and optical properties, and is a material that can be mass-produced using injection molding equipment.

In the fluid storage case 20 shown in FIG. 1, one fluid chamber 14 is shown, but at least two or more fluid chambers 14 may be formed in the fluid storage case 20. As for the hole 22 formed in the lower part of the fluid chamber 14, one hole 22 may be formed for each fluid chamber 140, or two or more holes 22 may be formed in one fluid chamber 140. It is also possible to become

The second membrane 21 is a membrane that seals the hole 22 formed in the lower portion of the fluid storage case 20 . Unlike the first membrane 10, the second membrane 21 is not flexible and is an impervious membrane that can be torn, and preferably has impermeable properties to fluids and gases. The second membrane 21 is preferably made of aluminum foil.

When the pressure rod 100 presses the corresponding area of the first membrane 10 right above the second membrane 21, the first membrane 10 is bent downward, and the second membrane 21 is torn. will lose

On the other hand, when the pressure bar 100 presses an area of the first membrane 10 that is a certain distance away from the corresponding area immediately above the second membrane 21, the fluid stored in the fluid storage case 20 is torn to the second membrane 21. It flows into the channel 30 through the hole 22 connected to the membrane 21 .

The channel 30 is a passage through which fluid flows formed between the lower portion of the fluid storage case 20 and the upper portion of the substrate 40 . The channel 30 serves to provide a space for reacting with a reagent while a sample injected from a sample inlet formed at one end moves to the other end. When two or more fluid chambers 14 are formed in the fluid storage case 20 or two or more holes 22 are formed, the number of channels 30 through which fluid flows may be two or more.

2 is a configuration diagram of a biosensor through which fluid flows easily into a channel according to another preferred embodiment of the present invention.

Referring to FIG. 2 , the biosensor according to the present embodiment includes a first membrane 10', a membrane pressure unit 11, a fluid pressure unit 12, a third membrane 13, a fluid storage case 20, It is composed of a second membrane 21 , a channel 30 , and a substrate 40 .

2(a) shows a state in which fluid is stored in the fluid chamber 14 of the fluid storage case 20. The fluid is stored in the fluid chamber 14 by the first membrane 10' and the second membrane 21, which are impervious membranes. In the biosensor of FIG. 2, a third membrane 13, which is a permeable membrane, is further disposed on the first membrane 10', which is an impermeable membrane.

The first membrane 10' is an impervious membrane that is not flexible and has low elasticity, and preferably has properties of impermeability to fluids and gases. The first membrane 10' is preferably made of aluminum foil.

The first membrane 10' is attached to cover the top of the fluid storage case 20 and seals the fluid storage case 20 so that the fluid stored in the fluid storage case 20 does not flow to the outside. The fluid storage case 20 and the first membrane 10' may be bonded to each other by thermal fusion, ultrasonic fusion, high frequency fusion, laser fusion, solvent fusion, double-sided adhesive tape or adhesive. The thermal fusion bonding is performed by heating the joint between the fluid storage case 20 and the first membrane 10' with a heat transfer plate, pressing them together in a molten state, and then cooling and combining them integrally. can be configured. Ultrasonic fusion is performed by irradiating ultrasonic waves to the joint between the fluid storage case 20 and the first membrane 10', and using heat generated by molecular vibration to compress and cool the surface of the adhesive portion in a molten state to integrally combine them. will be.

The fluid stored in the fluid storage case 20 is preferably a fluid sample for blood washing, measurement, and reaction. The fluid may be a reagent, a buffer solution, or the like.

Although one fluid chamber 14 is shown in the fluid storage case 20 shown in FIG. 2 , at least two or more fluid chambers 14 may be formed in the fluid storage case 20 . As for the hole 22 formed in the lower part of the fluid chamber 14, one hole 22 may be formed for each fluid chamber 140, or two or more holes 22 may be formed in one fluid chamber 140. It is also possible to become

The second membrane 21 is a membrane that seals the hole 22 formed in the lower portion of the fluid storage case 20 . The second membrane 21 is a non-flexible, tearable impermeable membrane, and preferably has properties impervious to fluids and gases. The second membrane 21 is preferably made of aluminum foil.

Although the first membrane 10' of FIG. 2 is an impervious membrane, it is different from the first membrane 10 of FIG. 1 in that it is not flexible and has low elasticity. In order to pump the fluid stored in the fluid storage case 20 so that it flows in both directions of the channel 30 through the hole 22 connected to the second membrane 21, the first membrane 10' is an impermeable membrane, It is preferable that it is a flexible and elastic membrane. However, it is difficult to find a material that is impermeable, flexible and elastic. Therefore, it is preferable to combine the flexible and elastic third membrane 13 with the first membrane 10' to configure as shown in FIG.

The third membrane 13 is a flexible and elastic permeable membrane and may be made of a silicon material.

2( b ) shows that when the pressure bar 100 presses the area 11 of the first membrane corresponding to right above the second membrane 21, the first membrane 10 is bent downward, and the second membrane (21) shows the torn state.

2(c) shows that when the pressure bar 100 presses the fluid pressure unit 12, the fluid stored in the fluid storage case 20 passes through the hole 22 connected to the torn second membrane 21 through the channel ( 30) is shown flowing in both directions.

The fluid pressure unit 12 applies pressure to the fluid stored in the fluid chamber 14 to move the fluid to the channel 30 through the second membrane 21 .

The channel 30 is a passage through which fluid flows formed between the lower portion of the fluid storage case 20 and the upper portion of the substrate 40 . When two or more fluid chambers 14 are formed in the fluid storage case 20 or two or more holes 22 are formed, the number of channels 30 through which fluid flows may be two or more.

3 illustrates a portion of the upper surface of a biosensor through which fluid flows easily into a channel according to a preferred embodiment of the present invention.

Referring to FIG. 3 , a membrane pressure unit 11, a fluid pressure unit 12, and a membrane exposed unit 15 are shown on the upper surface of the biosensor, and a channel 30 is formed below the upper surface. A sample is injected into the sample inlet so that the blood flows through the channel 30 .

A sample injected into the sample inlet may be a material including a target material. For example, the sample may be a secretion secreted from a living body. The specimen may be blood, plasma, serum, saliva, urine, and the like. As another example, the specimen may be a material obtained for research purposes. The sample may be a DNA sample, an RNA sample, etc. obtained at the scene of an incident, or a DNA sample, RNA sample, etc. extracted from animal cells and viruses.

A sample is injected into the sample inlet and flows through the channel 30 so that the sample touches the electrode 60 in the channel. On the other hand, by applying pressure to the membrane at the bottom of the membrane pressure unit 11, the second membrane 21 is torn, and by applying pressure to the fluid pressure unit 12, the fluid stored in the fluid chamber 14 is released from the second membrane. It may flow into the channel 30 through (21). The fluid flowing into the channel 30 may wash the sample in the channel 30 to form a uniform sample distribution or may react with the sample to facilitate measurement.

It is preferable to tear the second membrane 21 by applying pressure to the membrane at the bottom of the membrane pressure unit 11 using the pressure bar 100 .

Even if the second membrane 21 is torn, the fluid stored in the fluid chamber 14 may not sufficiently flow into the channel 30 through the second membrane 21 .

Therefore, by applying pressure to the fluid pressure unit 12, the fluid stored in the fluid chamber 14 can smoothly flow to the second membrane 21.

The fluid pressure unit 12 is disposed on the top of the membrane exposed surface 15 to apply pressure to the first membrane 10 or the third membrane 13 below.

Referring to FIG. 3, as the longitudinal length L and the width W of the fluid pressure portion 12 increase or the area of the fluid pressure portion 12 increases, the fluid stored in the fluid chamber 14 expands to the second membrane 21. It flows quickly to the channel 30 through. Therefore, by increasing or decreasing the length L, the width W, or the area of the fluid pressure unit 12, the flow rate of the fluid into the channel can be adjusted.

It is preferable to provide a space at one end of the channel 30 to react with the fluid (eg, reagent) stored in the fluid chamber 14 while the sample injected from the sample inlet moves to the other end of the channel. . The channel 30 serves as a passage for the sample to move and provides a space to react with reagents at the same time, but has a relatively wide diameter compared to other spaces in the channel 30, so that a reaction chamber, a space where the sample and reagent react, is formed. may be

4 shows another internal structure of the fluid chamber 14 according to a preferred embodiment of the present invention.

Referring to FIG. 4, the depth from the first membrane 10 covering the fluid chamber 14 to the bottom is D, and between the second membrane 21 and the first membrane 10 of the fluid chamber 14 If the distance of is d, the relationship D>d is satisfied.

When the distance d between the second membrane 21 and the first membrane 10 in the fluid chamber 14 is smaller than the depth D of the fluid chamber 14, the pressure bar 100 covers the area of the first membrane 10. When pressed, the second membrane 21 can be easily reached. That is, the smaller the distance between the second membrane 21 and the first membrane 10, the easier it is to tear the second membrane 21 using the pressure bar 100.

In addition, by reducing the distance between the second membrane 21 and the first membrane 10, pressure is applied to the first membrane 10 to release the fluid in the fluid chamber 14 through a hole connected to the torn second membrane 21 When flowing through 22 into channel 30, a strong pressure may be applied to the fluid.

5 is a view showing protrusions formed on a substrate in a biosensor according to a preferred embodiment of the present invention.

Referring to FIG. 5, a convex protrusion 50 is formed on the substrate 40, and when the protrusion 50 goes up from the substrate 40 into the channel 30 and comes into contact with the lower end of the fluid storage case 20, the channel ( Since one end of 30) is blocked, the flow of the fluid introduced into the channel is guided in the direction where the electrode 60 is located.

As a method for the protrusion 50 to go up into the channel 30 from the substrate 40, it may be pushed up by external pressure, the protrusion 50 may rise when fluid is sensed, or a separate driving unit may be provided. have.

It is preferable to further include a signal processing unit that measures and analyzes the amount of current transmitted through two or more contact pins contacting the electrode 60 and the electrode 60 to generate a sample analysis value. A capture molecule capable of specifically binding to a target material may be immobilized on one of the two electrodes, and the other electrode may be composed of an electrode material.

A biosensor is used to determine the presence or absence of the target material based on the potential difference between the two electrodes. A potential difference between the two electrodes may vary depending on whether the target material is bound to the capture molecules formed on the electrodes.

6 shows actual appearances of the membrane pressure unit 11 and the fluid pressure unit 12 of the biosensor according to a preferred embodiment of the present invention.

Referring to FIGS. 6 and 3 , a circular area corresponding to the membrane pressure unit 11 and a rectangular area corresponding to the fluid pressure unit 12 can be confirmed.

FIG. 7 shows an actual state of a torn state of the second membrane 21 of the biosensor according to a preferred embodiment of the present invention, which is the state of FIG. 2(b).

In comparison with FIG. 6 , it can be seen that the second membrane 21 under the membrane pressure unit 11 is punctured by the pressure.

FIG. 8 shows a state in which the fluid flows out to the channel 30 through the second membrane 21 of the biosensor according to a preferred embodiment of the present invention, which is the state of FIG. 2(b).

Referring again to FIG. 7, a passage (two lines) connected to the channel 30 is shown at the top of the membrane pressure part 11, whereas in FIG. 8, the passage passes through the perforated second membrane 21. As the fluid flows and the transparency changes, it can be confirmed that the passage is not visible.

As described above, the present invention has been described with specific details such as specific components and limited embodiments and drawings, but these are provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , Those skilled in the art in the field to which the present invention belongs can make various modifications and variations from these descriptions.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and it will be said that not only the claims to be described later, but also all modifications equivalent or equivalent to these claims fall within the scope of the spirit of the present invention. .

Claims (4)

a fluid storage case in which fluid is stored;
a first membrane covering an upper end of the fluid storage case and to which an external pressure is applied;
a second membrane that seals a hole formed in a lower portion of the fluid storage case, is torn when the external pressure is applied to a first area of the first membrane, and passes the fluid stored in the fluid storage case;
a channel through which the fluid stored in the fluid storage case flows when the second membrane is torn; and
Including a substrate forming the lower end of the channel,
Pressure is applied to a second region of the first membrane so that the fluid stored in the fluid storage case moves to the channel through the second membrane;
The biosensor, wherein the first membrane is a flexible impermeable membrane, and the second membrane is a tearable impermeable membrane.
According to claim 1,
Further comprising a fluid pressure portion formed to press the second region of the first membrane,
The amount of fluid passing through the second membrane is controlled according to the length or area of the fluid pressure unit,
The fluid pressure unit is disposed on the top of the first membrane exposed surface, characterized in that the flow of the fluid into the channel is easy biosensor.
According to claim 1,
A convex protrusion is formed on the substrate, and when the protrusion goes up into the channel, one end of the channel is blocked to block the fluid flowing into the channel from flowing to the one end. biosensor. According to claim 1,
A biosensor in which fluid flows easily into a channel, characterized in that a distance between the first membrane and the second membrane is smaller than an inner depth of the fluid storage case.

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