KR101413454B1 - Structure of Delaying time and Micro Device having the same structure for delaying time and methods of moving sample using micro device - Google Patents

Abstract

The present invention relates to a time delay structure for delaying a time for a sample to move due to the movement of a sample by a capillary force when a sample is introduced and includes a tree rejection having at least one trigger channel formed by bending a sample, And a stopper having at least one stop channel into which the sample is inserted and stopped at the end, wherein the end to which the sample introduced into the stop channel is discharged is three or more open.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a time delay structure and a microdevice having the same and a method of transferring a sample using the same,

The present invention relates to a microdevice which can be used in diagnostic and analysis apparatuses in various fields such as medicine and biotechnology because it can rapidly proceed the experimental research process with only a very small amount of sample or sample.

As the human society develops, the chemical industry is constantly developing, and chemical analysis technology is necessary to develop along with the development of this chemical industry. Chemical analysis techniques collectively refer to methods used to identify, detect, or determine the chemical composition of a substance.

For fast and accurate chemical analysis, development of a chemical analysis device is underway to automatically perform a chemical analysis that is dependent on the manual operation of the experimenter. Such a chemical analysis apparatus automatically mixes the sample with the reagent, reacts for a predetermined time, transfers the reagent to the detector, and outputs a signal proportional to the concentration of the measurement object by an electrical or optical signal Is performed automatically by one measurement system.

In recent years, innovative devices have been developed that finely implement these automatic analysis devices on very small chips, called micro devices.

Microdevice is a device that enables research in a laboratory in a very small size chip by integration of semiconductor technology, nanotechnology and biotechnology of microcircuits. It is a biochip that is being developed as a diagnostic and analysis device in various fields such as medicine and biotechnology.

The microdevice has a fine fluid channel to conduct various chemical analysis operations such as mixing with the reagents, reaction, and detection while guiding the fluid sample to the channel. Using microdevices for chemical analysis can simplify the chemical analysis process, as well as discard the microdevices once used and use new microdevices, eliminating the need for pre- and post-chemical analysis.

Particularly, a lap-on-a-chip, which is a type of microdevice, is a protein wrap-on-a-chip that analyzes and measures specific proteins in the blood, or a specific type of DNA (deoxyribonucleic acid ) And DNA lab-on-a-chip for analyzing and measuring DNAs have been put to practical use and widely used.

Conventional microdevices have a problem in that they do not have a structure for time to perform chemical analysis operations such as mixing, reaction, and detection with reagents, and thus can not effectively analyze reagents.

In addition, there is a problem that the reagent must be rapidly moved to the next step after analysis.

Korean Patent Publication No. 10-2011-0005963

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a method and apparatus for delaying time in a specific space inside a microdevice, A time delay structure capable of rapidly moving a sample to a next stage and sequentially controlling a flow of a plurality of fluids using a plurality of time structures, a micro device having the same, and a sample transfer method using the same.

A time delay structure (100) for delaying the time of movement of a sample by the movement of a sample by the capillary force of the sample of the present invention is provided with at least one trigger channel (111 And a stopper 120 having at least one stop channel 121 into which the sample is inserted and stopped at an end thereof, and a sample introduced into the stop channel 121 is discharged And the end portion is opened at three or more sides.

이하 인 것을 특징으로 한다.Further, the trigger channel 111 and the stop channel 121 have a height and a width of 500

Or less.

)이 90도 이상인 것을 특징으로 한다.Also, the outer surface of the stopper 120 and the outer surface of the stopper 120

) Is 90 degrees or more.

In addition, the stopper 120 has a V-shape or a U-shape around a portion where the sample of the trigger channel 111 is discharged.

The time delay structure 100 is characterized in that a sample passed through the trigger channel 111 meets an end of the stop channel 121 and a flow rate of the sample increases due to a chain reaction.

In the microdevice in which the sample of the present invention is introduced and the sample moves by the capillary force, the microdevice includes at least one sample inlet 11 into which the sample is introduced, a sample reaction unit 13 in a predetermined space to which the sample is inputted and reacted, , A stopper (110) having at least one trigger channel (111) in which a sample is injected and bent, a stopper (120) having at least one stop channel (121) And at least one sample discharge unit 12 through which the sample passed through the time delay structure 100 is discharged, and a sample introduced into the stop channel 121, The end portion to be discharged is opened to three or more sides.

이하 인 것을 특징으로 한다.Further, the trigger channel 111 and the stop channel 121 have a height and a width of 500

Or less.

)이 90도 이상인 것을 특징으로 한다.Also, the outer surface of the stopper 120 and the outer surface of the stopper 120

) Is 90 degrees or more.

The stopper 120 may have a V-shape or a U-shape around a portion of the trigger channel 111 where the sample is discharged.

Further, the time delay structures 100 are connected in series or in parallel.

In addition, the time delay structures 100 are connected in series or in parallel to sequentially control the flow of a plurality of fluids.

In the sample transfer method of the present invention, a sample input step (S10) for inputting a sample through a sample input port (110), a sample input through a sample input port (110) passes through the trigger channel (211) A sample delaying step (S20) in which a reaction occurs and a sample is stopped at an end of the stop channel; and a sample passing through the trigger channel (211) meets a sample located at an end of the stop channel (121) And discharging the sample to the channel 121 to gradually increase the discharging speed.

According to the present invention, it is possible to delay the time of flow of the sample including the tree rejection, effectively induce the reaction of the sample, and then to rapidly move the reacted sample to the next step through opening and closing of the stopper, So that the flow of a plurality of fluids can be sequentially controlled.

1 is a perspective view of a time delay structure according to a first embodiment of the present invention;
FIG. 2 is a partially enlarged view of a time delay structure according to the first embodiment of the present invention. FIG.
3 is a perspective view of a time delay structure according to a second embodiment of the present invention;
4 is an enlarged view of a portion of a time delay structure according to a second embodiment of the present invention.
5 to 8 are views and graphs showing the principle of stopping the sample in the stop channel of the present invention;
9 is a step diagram of a sample transfer method using the microdevice of the present invention

Hereinafter, the time delay structure according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a time delay structure 100 according to a first embodiment of the present invention.

In the time delay structure of the present invention, the sample is moved by the capillary force, and a channel through which the sample moves to a height at which the capillary force acts can be manufactured.

The object of the present invention is to provide a triple rejection (110) for delaying a time for a sample to react for a predetermined time, and after a predetermined time has elapsed, .

To this end, the time delay structure 100 of the present invention includes a tree reject 110 and a stop 120.

The tree reject 110 has at least one trigger channel 111 formed by bending the sample.

That is, a trigger channel 111 through which the sample passes is formed in the tree reject 110, and the sample reacts during the time passing through the trigger channel 111.

The trigger 110 is formed in a predetermined shape and a trigger channel 111 through which the sample introduced into the sample inlet 11 flows is formed in the trigger 110.

At this time, since the trigger channel 111 is bent inside the tree reject 110, the time is delayed until the sample is injected into the sample inlet 11 and discharged through the sample outlet 12 .

As shown in FIG. 1, the trigger channel 111 may be formed into a cochlear shape. However, the trigger channel 111 of the time delay structure 10 of the present invention is not limited to the shape of the cochlea but includes all the shapes that are longer than the straight distance from the sample inlet 11 to the sample outlet 12 In order to increase the delay time of the sample, if the length of the trigger channel 111 is increased, the distance of movement of the sample is increased, so that the delay time of the sample is increased. If the length of the trigger channel 111 is shortened, The delay time of the sample can be adjusted as desired by the user.

In addition, the moving speed of the sample varies depending on the cross-sectional area of the trigger channel 111. That is, if the cross-sectional area of the trigger channel 111 is large, the moving speed of the sample is fast, and if the cross-sectional area of the trigger channel 111 is small, the moving speed of the sample is slowed down.

Therefore, the trigger channel 111 can be formed in various ways, such as a length and a cross-sectional area of the trigger channel 111, in consideration of the reaction time required for the user to react the desired sample.

이하로 제작되어, 모세관력이 작용할 수 있는 것이 바람직하다.
At this time, the trigger channel 111 has a height of 500

Or less, so that capillary force can act.

The stopper 120 of the present invention will be described with reference to Fig.

The stopper 120 serves to temporarily stop the sample introduced through the sample inlet 11. For this, at least one stop channel 111 is formed in the stopper 120.

)이 90도 이상인 것을 특징으로 한다.2 shows a stop 120 according to a first embodiment of the present invention. The stop channel 121 is communicated from the sample inlet 110 to the sample outlet 12 and the end of the sample introduced into the stop channel 121 is open at least three sides, The outer edge of the end of the sample 121 of the sample 121 and the end of the stop 120

) Is 90 degrees or more.

라 하였을 경우,

가 90도 인 것이다. 하지만, 본 발명은 상기

가 90도 이상인 것을 뜻하며, 상기

가 90도 인 것에 한정되지 않는다.The angle formed between the end of the stop channel 121 at which the sample is discharged and the end surface of the stopper 120

However,

Is 90 degrees. The present invention, however,

Is 90 degrees or more,

Is not limited to 90 degrees.

Also, the stopper 120 has a V-shape or U-shape around the portion of the trigger channel 111 where the sample is discharged.

이하인 것을 특징으로 한다. 상기 정지채널(121)이 500

이상 일 경우, 모세관력이 작용하지 않아 상기 정지채널(121)의 단부에서 시료가 정지하지 않고 배출되게 된다.Further, the stop channel 121 has a height and a width of 500

Or less. When the stop channel 121 is 500

, The capillary force is not applied and the sample is discharged from the end of the stop channel 121 without stopping.

When a plurality of the stop channels 121 are formed in the stop 120 and the sample passing through the trigger channel 111 meets the stop channel 121, the sample is discharged through the stop channel 121 , The flow rate of the sample is increased by the chain reaction after passing through the trigger channel (111).

That is, after the sample passes through the trigger channel 111, the sample flows sequentially through the stop channel 121, and the flow rate of the sample gradually increases due to the chain reaction.

3 to 4, the time delay structure of the second embodiment of the present invention will be described in detail.

가 165도 인 것을 나타낸 것이다. 도 3에 나타난 바와 같이

가 90도 이상일 경우 상기 정지채널(121)의 시료가 끝단에서 멈추게 되며, 이와 같은 현상은 아래에서 상세히 설명하도록 한다.
The angle formed between the end of the stop channel 121 at which the sample is discharged and the end face of the stopper 120,

Is 165 degrees. As shown in FIG. 3

The sample of the stop channel 121 stops at the end, and this phenomenon will be described in detail below.

Hereinafter, a microdevice 10 according to an embodiment of the present invention will be described.

이하로 제작되어 모세관력이 작용되는 것이 바람직하다.The microdevice 10 according to the embodiment of the present invention means that the sample is moved by capillary force when a sample is put into the microdevice 10. For this purpose, all the channels through which the sample moves are 500

Or less, and the capillary force is preferably applied.

The microdevice 10 according to an embodiment of the present invention includes at least one sample inlet 11, a sample reaction unit 13, a plurality of time delay structures 100, and a sample discharge unit 12.

1, the sample reaction part 13 is located in the sample discharge part 12, and the sample reaction part 13 is located in the sample discharge part 11, There is also.

The time delay structure includes a tree reject 110 having at least one trigger channel 111 formed by bending the sample, and at least one stop channel 121 into which the sample is inserted and stopped at the end And a stop 120.

The sample discharge unit 13 discharges the sample having passed through the time delay structure 100.

라 하였을 경우,

가 90도 인 것이다. 하지만, 본 발명은 상기

가 90도 이상인 것을 뜻하며, 상기

가 90도 인 것에 한정되지 않는다.The angle formed between the end of the stop channel 121 at which the sample is discharged and the end surface of the stopper 120

However,

Is 90 degrees. The present invention, however,

Is 90 degrees or more,

Is not limited to 90 degrees.

The time delay structures 100 may be connected in series or in parallel.

When the time delay structures 100 are connected in series, they sequentially react while passing through the time delay structure 100 continuously positioned.

When the time delay structures 100 are connected in parallel, the flow of various samples can be sequentially controlled. That is, other samples may be put into each of the time delay structures 100, and the samples may be mixed with a time difference.

The operation principle in which the stop channel 111 of the present invention is operated will be described with reference to Figs. 5 to 8. Fig.

인 단면이 사각형인 채널로 형성될 수 있다. 즉, 상기 정지채널(121)의 단면이 사각형이며, 상기 정지채널(121)의 좌측면의 높이를 h1이라고 했을 경우, 상기 정지채널(121)의 하부면의 너비는 h2, 상기 정지채널(121)의 우측면의 높이를 h3, 상기 정지채널(121)의 상부면의 너비를 h4로 할 수 있다.As shown in FIG. 5, the height of each surface of the stop channel 121 is

May be formed as a channel having a rectangular cross section. That is, when the end surface of the static channel 121 is rectangular and the height of the left surface of the static channel 121 is h1, the width of the lower surface of the static channel 121 is h2, H3, and the width of the upper surface of the stop channel 121 may be h4.

인 사각 형상으로 제작될 경우, 상기 시료배출부(12)는 의 단면이 사각형이며, 상기 시료배출부(12)의 좌측면의 높이를 w1이라고 했을 경우, 상기 시료배출부(12)의 하부면의 너비는 w2, 상기 시료배출부(12)의 우측면의 높이를 w3, 상기 시료배출부(12)의 상부면의 너비를 w4로 명명할 수 있다.
In addition, the height of the surface of the sample discharging portion 12

When the height of the left side of the sample discharge portion 12 is w1 and the height of the sample discharge portion 12 is w1, The height of the right side surface of the sample discharge portion 12 is w3 and the width of the upper surface of the sample discharge portion 12 is w4.

6 illustrates the sample passing through the stop channel 121. As shown in FIG.

When the sample passes through the stop channel 121, the sample moves along the inside of the stop channel 121 due to the capillary phenomenon. If the adhesive force between the sample molecules and the stop channel 121 is stronger than the cohesive force between the sample molecules, a thin sample membrane is formed on the wall of the stop channel 121. Thereafter, due to the surface tension, .

, 채널의 표면장력을

, 채널단면과 시료의 단면과 이루는 각도를

라고 하였을 경우, 시료의 압력 P는 아래의 [식1]과 같이 나타낼 수 있다.When the sample passes through the channel (FIG. 6A), the pressure of the sample is P, the height of each side of the channel is

, The surface tension of the channel

, The angle between the channel section and the section of the sample

, The pressure P of the sample can be expressed as [Equation 1] below.

[Formula 1]

P: pressure of the sample h: height of each surface of the stop channel 121

: 정지채널(121)의 표면장력

: Surface tension of the stop channel 121

: 정지채널(121)의 면과 시료의 단면과 이루는 각도

: An angle formed between the surface of the stop channel 121 and the end surface of the sample

The pressure of the sample in the portion where the sample of the static channel 121 is discharged (FIG. 6B) can be expressed by the following equation (2).

[Formula 2]

,

,

,

,

P: pressure of the sample h: height of each surface of the stop channel 121

: 정지채널(121)의 표면장력

: Surface tension of the stop channel 121

: 정지채널(121)의 면과 시료의 단면과 이루는 각도

: An angle formed between the surface of the stop channel 121 and the end surface of the sample

: 정지채널(121)의 면과 정지부(120)의 단면과 이루는 외각

: An outer angle formed between the surface of the stop channel 121 and the end surface of the stopper 120

In addition, when the sample of the static channel 121 is discharged and passes through the wide channel, that is, the sample discharging portion 12 (FIG. 6C), the pressure can be expressed as [Equation 3].

[Formula 3]

P: pressure of the sample h: height of each surface of the stop channel 121

: 정지채널(121)의 면과 시료의 단면과 이루는 각도

: An angle formed between the surface of the stop channel 121 and the end surface of the sample

w: Height of each surface of the sample discharging portion 12

Therefore, when the pressure difference occurring in each step is plotted, it can be expressed as shown in FIG.

, 즉 정지채널(121)의 면과 정지부(120)의 단부가 이루는 외각이 90도 이상이어야 하는 것과, 채널 끝단에서 3면 이상의 방향에서 채널이 오픈되는 것을 기준으로 한다. Therefore, in order for the sample to stop at the end of the stop channel 121, the pressure difference generated in [Equation 2] must be reduced as much as possible

That is, the outer angle formed by the surface of the stop channel 121 and the end of the stop 120 should be 90 degrees or more, and that the channel is opened in three or more directions from the end of the channel.

가 165도 인 것을 도시화 한 것이다. 도 8에 나타난 정지채널(121)의 형태는 본 발명의 정지채널(121)의 제2 실시 예 불과하며,

가 90도 이상인 것을 의미한다.
Figure 8

Is 165 degrees. The shape of the stop channel 121 shown in Fig. 8 is only the second embodiment of the stop channel 121 of the present invention,

Is greater than 90 degrees.

FIG. 9 is a diagram showing a sample transferring method using the microdevice of the present invention.

A sample analysis method according to an embodiment of the present invention includes a sample injection step (S10), a sample delay step (S20), and a sample discharge step (S30).

The sample injecting step (S10) is a step of injecting the sample through the sample inlet (11).

In the sample reaction step S20, a sample is introduced into the trigger channel 111 and the stop channel 121 when a sample is injected through the sample inlet 11. The sample is injected into the stop channel 121, The pressure of the sample is lowered at the end of the stop channel 121, that is, at the portion where the sample is discharged, and the sample is stopped.

At this time, the time for the sample to react is determined through the trigger channel 111, and the time for which the sample reacts is determined by the length and size of the trigger channel 111, the viscosity of the sample, the contact angle, and the surface tension.

In the sample discharge step S30, when the sample passing through the trigger channel 111 reaches a sample located at the end of the stop channel 121, the sample is discharged from the sample discharge unit 12 through the stop channel 121, .

The stopper 120 is formed in a V shape or a U shape around a portion where the sample of the trigger channel 111 is discharged and a plurality of stop channels 121 are formed in the stopper 120 When the sample passing through the trigger channel 111 is brought into contact with the stop channel 121, the sample is discharged through the stop channel 121. After passing through the trigger channel 111, ), And the flow rate of the sample is increased by the chain reaction.

Therefore, according to the present invention, it is possible to effectively induce the reaction of the sample by delaying the time of flow of the sample including the tree rejection 110, and to rapidly move the reacted sample including the stopper 120 to the next step There is an effect that the flow of a plurality of fluids can be sequentially controlled by using the plurality of time structures 100.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. It goes without saying that the modification can be carried out.

10: Microdevice
11: Sample inlet
12: Sample outlet
100: time delay structure
110: Reject tree
111: Trigger channel
120:
121: Stop channel
S10 to S30: sample analysis step

Claims (12)

A time delay structure (100) for delaying a time of movement of a sample by a capillary force when a sample is introduced,
(110) having one or more trigger channels (111) formed to be bent so as to delay the time for discharging the introduced sample
(120) having at least one static channel (121) in which the injected sample is stopped at an end,
The one or more static channels (121) are sequentially disposed along the moving direction of the sample from a portion from which the sample of the trigger channel (111) is discharged,
Wherein the sample discharged from the tree rejection unit (110) sequentially reacts with a sample suspended in each of the ends of the at least one static channel (121).
The method according to claim 1,
The trigger channel 111 and the stop channel 121 have a height and a width of 500

The time delay structure < RTI ID = 0.0 >
The method according to claim 1,
The outer surface of the stopper 120 and the outer surface of the stopper 120

) Is greater than 90 degrees.
The method according to claim 1,
Wherein the stopper (120) has a V-shape or a U-shape around a portion of the trigger channel (111) from which the sample is discharged.
The method according to claim 1,
Wherein the end portion to which the sample introduced into the stop channel (121) is discharged is open to three or more sides.
In a microdevice in which a sample is introduced and a sample moves by a capillary force,
At least one sample inlet (11) into which a sample is injected;
A sample reaction part 13 in a predetermined space for injecting and reacting the sample;
(110) having one or more trigger channels (111) formed to be bent so as to delay a time for discharging the injected sample, and a stopper (120) having at least one stop channel (121) A plurality of time delay structures (100) comprising; And
At least one sample discharge portion (12) through which the sample passed through the time delay structure (100) is discharged;
Lt; / RTI >
The one or more static channels (121) are sequentially disposed along the moving direction of the sample from a portion from which the sample of the trigger channel (111) is discharged,
Wherein the sample discharged from the tree rejection unit (110) sequentially reacts with a sample suspended in each of the ends of the at least one static channel (121).
The method according to claim 6,
The trigger channel 111 and the stop channel 121 have a height and a width of 500

Wherein the time delay structure comprises a time delay structure.
The method according to claim 6,
The outer surface of the stopper 120 and the outer surface of the stopper 120

) Is greater than or equal to 90 degrees.
The method according to claim 6,
Wherein the stopper (120) has a V-shape or a U-shape around a portion where the sample of the trigger channel (111) is discharged.
The method according to claim 6,
Characterized in that the time delay structures (100) are connected in series or in parallel.
11. The method of claim 10,
Wherein the time delay structures (100) are connected in series or in parallel to sequentially control the flow of a plurality of fluids.
A sample injecting step (S10) of injecting the sample through the sample inlet 110;
The sample introduced through the sample inlet 110 is delayed and passed through the trigger channel 111 for a predetermined period of time, and the stop channel 111, which is sequentially disposed along the moving direction of the sample from the sample outlet portion of the trigger channel 111, A sample delay step S20 in which the sample is stopped at the end of the sample 121; And
The sample passing through the trigger channel 111 sequentially reacts with the sample stopped at the end of the stop channel 121 so that the sample suspended at the end of the stop channel 121 starts to be discharged. A sample discharge step S30;
And a sample transferring step of transferring the sample transferring material.

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