KR20190090537A - Diagnostic chip with initial movement distance adjustment function of diagnostic sample - Google Patents

Abstract

The present invention relates to a diagnostic chip having a function of adjusting an initial movement distance of a diagnostic sample, in which a vent hole is formed in an upper end of a flow channel where the diagnostic sample moves, and the diagnostic sample inputted through a diagnostic sample inlet is moved from the flow channel to an area where the vent hole is located, thereby automatically controlling the initial movement distance of the diagnostic sample. To this end, the diagnostic chip having a function of adjusting an initial movement distance of a diagnostic sample comprises: an upper plate; and a lower plate coupled to a lower portion of the upper plate and having a flow channel, through which the diagnostic sample moves, formed therein. The upper plate comprises: a diagnostic sample inlet connected to one end of the flow channel and receiving the diagnostic sample inputted therethrough; a diagnostic sample movement adjustment hole connected to the other end of the flow channel and formed to adjust movement of the diagnostic sample; a vent hole disposed between the diagnostic sample inlet and the diagnostic sample movement adjustment hole, connected to the flow channel, and configured to determine the initial movement distance of the diagnostic sample; and a vent hole opening/closing unit configured to open and close the vent hole.

Description

Diagnostic chip with initial movement distance adjustment function of diagnostic sample

The present invention relates to a diagnostic chip having an initial movement distance control function of a diagnostic sample. More specifically, a vent hole is formed at an upper end of a flow channel through which a diagnostic sample moves, and a diagnostic sample injected from a diagnostic sample inlet is disposed in a flow channel. The present invention relates to a diagnostic chip having an initial moving distance adjusting function of a diagnostic sample which can automatically control an initial moving distance of a diagnostic sample by moving to an area where a vent hole is located and stopping.

As the life expectancy of modern people increases, the types of diseases involved also vary, and various diagnostic devices and diagnostic systems have been developed for the prevention and diagnosis of diseases.

One of them, a diagnostic kit, examines or examines the presence of a single or a plurality of substances in a liquid sample, such as a urine or blood sample. Specifically, the modern diagnostic business field is integrated into one of the Point-Of-Care Testing (POCT). POCT is a test that is performed outside a centralized laboratory, and refers to equipment that can be used by the general public without expert knowledge. Currently, diagnostic fields are expanding from hospitals to field and individual.

For example, in a hospital, a patient may need to receive a large amount of antibiotics to fight infection, after which a small amount of blood may be collected to examine whether there is an adequate amount of antibiotics in the blood, In the case of a damaged overdose patient or an infant unable to communicate, examples of application include rapid investigation of the types of ingested drugs in the human body to ensure proper therapeutic administration.

In particular, rapid diagnostic tests, such as immunochromatographic assays, are used to identify diseases or detect changes in the healthcare field, and to quantitatively and quantitatively analyze trace amounts of analytes in a variety of fields, It is being developed in a simple way. In the field of health care, applications are being extended to pregnancy, ovulation, infectious diseases, drug abuse, acute myocardial infarction, and cancer.

In an embodiment of diagnosing a disease using a diagnostic kit, pretreatment is performed on a diagnostic sample, light is irradiated on the diagnostic sample, and the disease is diagnosed based on the optical information from the diagnostic sample, and the diagnostic sample is moved within the diagnostic kit. As a result, the time for preprocessing the diagnostic sample is not sufficient, and thus the optical information from the diagnostic sample is not accurate.

To this end, by providing a separate diagnostic sample movement control unit to control the movement of the diagnostic sample, which is to determine the movement of the diagnostic sample according to the moving speed according to the type of the diagnostic sample, and then control the diagnostic sample. The process is complicated and difficult.

Republic of Korea Patent Publication No. 10-2015-0016043 (Invention name: microfluidic device and its manufacturing method, published date: February 11, 2015)

The problem to be solved in the present invention is to form a vent hole in the upper end of the flow channel to which the diagnostic sample is moved, the diagnostic sample injected from the diagnostic sample inlet is moved to the area where the vent hole is located in the flow channel to stop the initial diagnosis sample It is to provide a diagnostic chip having an initial moving distance control function of a diagnostic sample that can automatically control the moving distance.

In order to solve the above problems, the present invention is coupled to the upper plate and the lower portion of the upper plate, and includes a lower plate formed with a flow channel for moving the diagnostic sample therein, the upper plate, one end of the flow channel A diagnostic sample inlet to be connected to the diagnostic sample inlet, a diagnostic sample movement control hole which is connected to the other end of the flow channel to control movement of the diagnostic sample, and the diagnostic sample inlet and the diagnostic sample movement control A vent hole disposed between the holes and connected to the flow channel to determine an initial movement distance of the diagnostic sample, and further including a vent hole opening and closing part for opening and closing the vent hole; It provides a diagnostic chip with distance control.

In the diagnostic chip having an initial movement distance control function of the diagnostic sample according to the present invention, a sample buffer unit disposed on the zero region of the flow channel and formed with a material for stabilizing the diagnostic sample moving from the diagnostic sample inlet And a preprocessor disposed on a first region of the flow channel, the preprocessor having a material for preprocessing the diagnostic sample moving from the sample buffer, and disposed on a second region of the flow channel. The apparatus may further include a test unit in which a material for testing the diagnostic sample moving from the test unit is formed, and a reference unit in which a reference material of the diagnostic sample is disposed on the third region of the flow channel and formed from the second region. .

In the diagnostic chip having an initial movement distance adjustment function of the diagnostic sample according to the present invention, the vent hole includes a first vent hole and a second vent hole disposed behind the first vent hole, and the vent hole opening and closing portion A first vent hole opening and closing portion for opening and closing the first vent hole, and a second vent hole opening and closing portion for opening and closing the second vent hole, the initial vent of the diagnostic sample by the first vent hole and the second vent hole The travel distance can be automatically controlled over two stages.

In the diagnostic chip having an initial movement distance control function of the diagnostic sample according to the present invention, a speed regulation pattern for controlling the movement speed of the diagnostic sample may be formed in the flow channel.

The diagnostic chip having the initial moving distance control function of the diagnostic sample according to the present invention has the following effects.

First, a vent hole is formed at the upper end of the flow channel through which the diagnostic sample moves, and the diagnostic sample injected from the diagnostic sample inlet moves to the area where the vent hole is located along the flow channel, and then stops automatically. Since it is possible to control, the control device and the control process for adjusting the initial moving distance of the diagnostic sample is omitted, there is an advantage that it is possible to more easily diagnose the disease.

Second, since the pre-processing can be sufficiently performed automatically on the diagnostic sample according to the position of the vent hole, there is an advantage that the optical information of the diagnostic sample can be detected more accurately.

Third, the vent hole is formed in connection with the flow channel, and the diagnostic sample or the microbubble in the flow channel exits the vent hole and is removed, thereby allowing the diagnostic sample to smoothly move in the flow channel, Since it is possible to prevent the optical information error that can occur, there is an advantage that the optical information detection of a more accurate diagnostic sample can be made.

1 is a view schematically showing a first embodiment of a diagnostic chip having an initial movement distance adjustment function of a diagnostic sample according to the present invention.
FIG. 2 is a diagram schematically illustrating an example of driving a diagnostic chip having an initial movement distance adjustment function of the diagnostic sample of FIG. 1.
3 is a diagram schematically illustrating a second embodiment of a diagnostic chip having an initial movement distance adjustment function of a diagnostic sample according to the present invention.
FIG. 4 is a diagram schematically illustrating an example of driving a diagnostic chip having an initial movement distance adjustment function of the diagnostic sample of FIG. 2.
FIG. 5 schematically illustrates a third embodiment of a diagnostic chip having an initial movement distance adjustment function of a diagnostic sample according to the present invention.

Hereinafter, preferred embodiments of the present invention in which the above-mentioned problems to be solved can be specifically realized will be described with reference to the accompanying drawings. In describing the embodiments, the same names and the same symbols are used for the same configurations, and additional description thereof will be omitted in the following.

Referring to FIGS. 1 and 2, a first embodiment of a diagnostic chip having an initial movement distance adjustment function of a diagnostic sample according to the present invention will be described.

As shown in Figures 1 to 2, the diagnostic chip having a function of adjusting the initial movement distance of the diagnostic sample according to the present invention is the upper plate 110, lower plate 120, sample buffer unit 131, pre-processing unit ( 132, a test unit 133, a reference unit 134, and a vent hole opening and closing unit 140.

The lower plate 120 is coupled with the lower portion of the upper plate 110, there is formed a flow channel 121 to move the diagnostic sample therein, the upper plate 110 and the lower plate 120 is optical It may be formed of a transparent material.

First, the sample buffer unit 131, the preprocessor 132, the test unit 133, and the reference unit 134 formed on the flow channel 121 will be described below.

The sample buffer unit 131 is formed at a position corresponding to the diagnostic sample inlet 111 of the zero region of the flow channel 121, that is, the flow channel 121. Sample buffer material for stabilizing the diagnostic sample S is formed in the sample buffer unit 131, and a plurality of sample buffer units 131 may be formed according to the type of the diagnostic sample S. The sample buffer material may be changed according to the type and target material of the diagnostic sample (S).

The preprocessor 132 is formed at a rear side with respect to the moving direction of the diagnostic sample S from the first region of the flow channel 121, that is, the zero region of the flow channel 121.

The pretreatment unit 132 is formed with a pretreatment material which is input from the diagnostic sample inlet 111 and pre-processes the diagnostic sample S that is buffered and moved in the zero area. The pretreatment unit 132 may be formed in plural numbers, and the pretreatment material may be changed according to the type of the diagnostic sample S and the target material.

The test unit 133 is formed at a rear side with respect to the moving direction of the diagnostic sample S from the second region of the flow channel 121, that is, the first region of the flow channel 121.

The test unit 133 is formed with a test material for testing the diagnostic sample S that is preprocessed and moved in the second area, and irradiates light to the diagnostic sample S that has passed through the test unit 133. Therefore, the disease diagnosis may be performed according to the light information emitted by the diagnosis sample S. FIG.

The test unit 133 may be formed in plural numbers according to the type of the diagnostic sample S, and the test substance may be changed according to the type of the diagnostic sample S and the target material.

The reference unit 134 is formed to be rearward with respect to the moving direction of the diagnostic sample S from the third region of the flow channel 121, that is, the second region of the flow channel 121.

The reference unit 134 is formed with a reference material for confirming a reference level of the diagnostic sample S that has been tested for diagnosing a disease in the third region. The reference sample 134 passes through the diagnostic sample ( By irradiating light to S) it is possible to check the reference level of the diagnostic sample (S) according to the light information emitted by the diagnostic sample (S).

The reference unit 134 may be formed in plural according to the type of the diagnostic sample S, and the reference material may be changed according to the type of the diagnostic sample S and the target material.

The upper plate includes a diagnostic sample inlet 111, a diagnostic sample movement control hole 113, and a vent hole 112.

The diagnostic sample inlet 111 is formed on the upper plate 110 and connected to one end of the flow channel 121, and the diagnostic sample S is connected to the flow channel through the diagnostic sample inlet 111. 121).

The vent hole 112 is formed on the upper plate 110 and is disposed between the diagnostic sample inlet 111 and the diagnostic sample movement control hole 113 to be connected to the flow channel 121. The initial moving distance of the diagnostic sample S is determined.

As shown in (a) of FIG. 2, the diagnostic sample S introduced from the diagnostic sample inlet 111 is moved to the vent hole 112 while the diagnostic sample movement control hole 113 is blocked. The vent hole 112 is blocked, whereby the movement of the diagnostic sample S is stopped.

For example, the position of the vent hole 112 is disposed behind the preprocessor 132, as shown in FIG. 2A, so that the diagnostic sample S is pretreated by the preprocessor 132. It can be sufficiently reacted with the material, the position of the vent hole 112 can be changed according to the initial moving distance to be adjusted.

That is, the diagnostic sample S introduced from the diagnostic sample inlet 111 moves to the region where the vent hole 112 is located along the flow channel 121 and then stops, thereby initially moving the diagnostic sample S. FIG. Since the distance can be automatically controlled, a control device and a control process for adjusting the initial moving distance of the diagnosis sample S are omitted, thereby making it easier to diagnose the disease.

In addition, as described above, the pretreatment may be sufficiently performed on the diagnostic sample S according to the position of the vent hole 112, so that the optical information of the diagnostic sample S may be more accurately detected.

In addition, the vent hole 112 is connected to the flow channel 121, and the diagnostic sample S or the fine bubbles in the flow channel 121 exit the vent hole 112 to be removed. Not only can the sample S proceed smoothly within the flow channel 121, but also prevents optical information errors that may occur due to the fine bubbles.

The diagnostic sample movement control hole 113 is formed on the upper plate 110 and is connected to the other end of the flow channel 121, and is equipped with a diagnostic chip having an initial movement distance adjustment function of the diagnostic sample according to the present invention. The movement control hole opening and closing unit 150 provided in the diagnostic kit controls the movement of the diagnosis sample S by opening and closing the diagnosis sample movement control hole 113.

As described above, the movement control hole opening and closing unit 150 opens and closes the diagnosis sample movement control hole 113 and is driven by the control of a control unit (not shown) provided in the diagnosis kit.

That is, as shown in (b) of FIG. 2, when the diagnosis sample S moves to an area where the vent hole 112 is located and stops, the vent hole 112 is opened and closed. 140 is blocked, and then the movement control hole opening and closing unit 150 opens the diagnostic sample movement control hole 113 to move the diagnosis sample S toward the diagnosis sample movement control hole 113. The other end of the flow channel 121 is moved.

Of course, when the diagnostic sample (S) moves, the movement control hole opening and closing unit 150 opens and closes the diagnosis sample movement control hole (113) according to the position of the diagnostic sample (S) of the diagnostic sample (S). You can also adjust the movement.

Referring to FIGS. 3 to 4, a second embodiment of a diagnostic chip having an initial moving distance adjusting function of a diagnostic sample according to the present invention will be described.

In the diagnostic chip having an initial movement distance control function of the diagnostic sample according to the present embodiment, the diagnostic sample S is provided with a sample buffer unit 231, a preprocessor 232, a test unit 233, and a reference unit 234. Moving inside the flow channel 221, the opening and closing of the diagnostic sample movement control hole 213 by the movement control hole opening and closing unit 250 can control the movement of the diagnostic sample (S) and the above-described first embodiment Since it is substantially the same, a detailed description thereof will be omitted.

However, the vent hole according to the present exemplary embodiment includes a first vent hole 212a and a second vent hole 212b positioned behind the first vent hole 212a. In addition, the vent hole opening and closing portion according to the present embodiment may include a first vent hole opening and closing portion 241 for opening and closing the first vent hole 212a and a second vent hole opening and closing portion 242 for opening and closing the second vent hole 212b. ).

Since the vent hole includes the first vent hole 212a and the second vent hole 212b, the initial movement distance of the diagnostic sample S may be automatically controlled over two stages.

That is, as shown in (a) of FIG. 4, the diagnostic sample S injected from the diagnostic sample inlet 211 in a state in which the diagnostic sample movement control hole 213 and the second vent hole 212b are blocked. ) Moves in the direction of the first vent hole 212a to block the first vent hole 212a, whereby the movement of the diagnostic sample S is stopped.

For example, the position of the first vent hole 212a may be disposed behind the preprocessor 232 to allow the diagnostic sample S to sufficiently react with the pretreatment material in the preprocessor 232. The position of the first vent hole 212a may be changed according to the first initial moving distance to be adjusted.

Subsequently, as illustrated in FIG. 4B, the first vent hole opening and closing portion 241 blocks the first vent hole 212a and the second vent hole opening and closing portion 242 opens the second vent hole ( By opening 212b, the diagnostic sample S moves in the direction of the second vent hole 212b to block the second vent hole 212b, whereby the movement of the diagnostic sample S is stopped.

For example, the position of the second vent hole 212b may be disposed behind the reference unit 234 to sufficiently detect the reference level of the diagnostic sample S, and the first vent hole 212a may be provided. Similarly, the position of the second vent hole 212b may be changed according to the second initial moving distance to be adjusted.

Subsequently, as illustrated in FIG. 4C, when the diagnostic sample S moves to an area where the second vent hole 212b is located and stops, the second vent hole 212b is stopped. The second vent hole opening and closing part 242 is blocked, and then the movement control hole opening and closing part 250 opens the diagnosis sample movement control hole 213, so that the diagnosis sample S has the diagnosis sample movement control hole ( 213 moves to the other end of the flow channel 221.

Of course, when the diagnostic sample (S) moves, the movement control hole opening and closing unit 250 opens and closes the diagnostic sample movement control hole (213) according to the position of the diagnostic sample (S) of the diagnostic sample (S) You can also adjust the movement.

A third embodiment of a diagnostic chip having an initial movement distance adjustment function of a diagnostic sample according to the present invention will be described with reference to FIG. 5.

In the diagnostic chip having an initial movement distance control function of the diagnostic sample according to the present embodiment, the diagnostic sample S is provided with a sample buffer unit 331, a preprocessor 332, a test unit 333, and a reference unit 334. By moving inside the flow channel 321, it is possible to adjust the initial moving distance of the diagnostic sample (S) by the vent hole 312, by opening and closing the diagnostic sample movement control hole 313 moving opening hole 350 Since the content of which the movement of the diagnostic sample S can be adjusted is substantially the same as the above-described embodiment, a detailed description thereof will be omitted.

However, the speed control pattern 322 is formed in the flow channel 321 according to the present embodiment.

The speed control pattern 322 is formed in the flow channel 321, the speed control pattern 322 may be formed in the area connected to the vent hole 312, as shown in FIG. It may be formed in a region where the moving speed of the sample S is to be slowed down.

The speed control pattern 322 is formed as a groove on the flow channel 321, thereby preventing the diagnosis sample S from moving in the flow channel 321, thereby increasing the moving speed of the diagnosis sample S. FIG. It can be adjusted.

By adjusting the moving speed of the diagnostic sample S by the speed control pattern 322, the diagnostic sample S may be stopped in the vent hole 312 region.

Alternatively, the speed control pattern 322 is positioned at a rear end of the sample buffer unit 331, the preprocessor 332, the test unit 333, and the reference unit 334. The sample buffer unit 331, the preprocessor 332, the test unit 333, and the reference unit 334 may be sufficiently reacted.

As described above, the present invention is not limited to the above-described specific preferred embodiments, and various changes and modifications may be made by those skilled in the art without departing from the scope of the present invention as claimed in the claims. And such variations are within the scope of the present invention.

110, 210: upper plate
111, 211, 311: Diagnostic sample inlet
112, 312: vent hole
212a: first vent hole
212b: second vent hole
113, 213, 313: Diagnostic sample movement control hole
120, 220, 320: lower plate
121, 221, 321: flow channel
322: speed control pattern
131, 231, 331: sample buffer section
132, 232, 332: preprocessing unit
133, 233, 333: test unit
134, 234, 334: reference section
140, 340: vent hole opening and closing portion
241: first vent hole opening and closing portion
242: second vent hole opening and closing portion
150, 250, 350: movement control hole opening and closing portion

Claims (4)

An upper plate; And
And a lower plate coupled to a lower portion of the upper plate and having a flow channel therein for moving a diagnostic sample therein.
The upper plate,
A diagnostic sample inlet connected to one end of the flow channel to which the diagnostic sample is input;
A diagnostic sample movement control hole connected to the other end of the flow channel to control movement of the diagnostic sample; And
And a vent hole disposed between the diagnostic sample inlet and the diagnostic sample movement control hole and connected to the flow channel to determine an initial moving distance of the diagnostic sample.
And a vent hole opening and closing unit for opening and closing the vent hole. The method of claim 1,
A sample buffer part disposed on a zero region of the flow channel, and having a material for stabilizing the diagnostic sample moving from the diagnostic sample inlet;
A preprocessor disposed on a first region of the flow channel, the preprocessor having a material for preprocessing the diagnostic sample moving from the sample buffer;
A test unit disposed on a second region of the flow channel, the test unit including a material for testing the diagnostic sample moving from the first region; And
And a reference unit disposed on the third region of the flow channel, the reference unit including a reference material of the diagnostic sample moving from the second region, the diagnostic chip having an initial movement distance control function of the diagnostic sample. . The method of claim 1,
The vent hole includes a first vent hole and a second vent hole disposed behind the first vent hole.
The vent hole opening and closing portion includes a first vent hole opening and closing portion for opening and closing the first vent hole and a second vent hole opening and closing portion for opening and closing the second vent hole,
The diagnostic chip having the initial movement distance control function of the diagnostic sample, characterized in that the first vent hole and the second vent hole can automatically control the initial movement distance of the diagnostic sample over two stages. The method of claim 1,
Diagnosis chip having a moving distance control function characterized in that the flow channel is formed with a speed control pattern for controlling the moving speed of the diagnostic sample.

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