KR101282160B1 - Test Method - Google Patents

Abstract

An inspection method is disclosed in which a plurality of lights can be incident on an inspection disc along an independent path without interfering with each other. The test method according to the present invention includes a test disc loading step in which a test chamber in which a test chamber in which a test chamber is connected is formed, a test chamber in which a sample is accommodated, a reagent chamber connected to the test chamber, and the test chamber and the test chamber are formed. A reagent loading step in which the accommodated reagent container is loaded, a reagent supplying step in which the reagent is supplied to the reagent chamber, and the test disc is rotated so that the sample and the reagent are mixed, and the sample mixed with the reagent is tested. An inspection disk driving step accommodated in a chamber, a light emission step in which a plurality of lights are emitted from a plurality of light sources spaced apart from one surface of the inspection disk, a light guide step in which the plurality of lights are guided to the plurality of inspection chambers, and the inspection The plurality of inspection chambers are transmitted by a plurality of light detection elements spaced apart from the back surface of the disk. And a light detecting step of detecting the plurality of lights.

Description

Test Method

The present invention relates to a test method, and more particularly, by rotating the test disk to mix the sample and reagents collected for the test, such as blood test, urine test, immune test, and detects the light passing through the test disk A test method for performing a test on a specimen.

Recently, a blood test apparatus using a disk-type microfluidic device (hereinafter referred to as an 'test disk') has been developed.

A plurality of chambers are formed inside the test disc, and the chambers contain blood and reagents. When the test disk is rotated, the blood is centrifuged into blood cells, red blood cells, and plasma, and the plasma and reagents extracted from the blood are mixed in one of the chambers. When light enters the chamber where plasma and reagents are mixed, a predetermined color is obtained, and blood can be analyzed by detecting absorbance according to the color change.

A blood test method using such a test disc has already been disclosed in "Korea Patent Publication No. 2010-075208; Apparatus and method for measuring the absorbance of a detection chamber of a microfluidic device". The patent discloses a blood test by rotating a test disc containing blood to mix blood and reagents, and irradiating light with the test disc to detect light passing through the test disc.

However, the disclosed patent uses a light emitting diode as a light source, and the light emitted from the light source emits the light toward the inspection disk. The light may be interfered with other adjacent light, thereby lowering the reliability of the blood test.

Republic of Korea Patent Publication No. 2010-075208 (published Jul. 02, 2010)

An object of the present invention is to provide an inspection method in which a plurality of lights can be incident on an inspection disc along an independent path without interfering with each other.

The test method according to the present invention includes a test disc loading step in which a test chamber in which a test chamber in which a test chamber is connected is formed, a test chamber in which a sample is accommodated, a reagent chamber connected to the test chamber, and the test chamber and the test chamber are formed. A reagent loading step in which the accommodated reagent container is loaded, a reagent supplying step in which the reagent is supplied to the reagent chamber, and the test disc is rotated so that the sample and the reagent are mixed, and the sample mixed with the reagent is tested. An inspection disk driving step accommodated in a chamber, a light emission step in which a plurality of lights are emitted from a plurality of light sources spaced apart from one surface of the inspection disk, a light guide step in which the plurality of lights are guided to the plurality of inspection chambers, and the inspection The plurality of inspection chambers are transmitted by a plurality of light detection elements spaced apart from the back surface of the disk. And a light detecting step of detecting the plurality of lights.

The inspection method may further include a condensing step of condensing the plurality of lights into each of the plurality of inspection chambers between the light guide step and the light detection step.

The inspection method may further include an optical focusing step in which the plurality of lights passing through the inspection chamber are focused to the plurality of light detection elements between the light guide step and the light detection step.

In the inspection method, in the light emission step, the plurality of light sources emit the plurality of light in the opposite direction of the inspection disc, and the light guide step is bent from the plurality of light sources and extended to the plurality of inspection chambers, respectively. The plurality of lights may be guided by a plurality of optical fibers, respectively.

In the loading of the test disc, the test disc may be linearly transferred on the plane of the test disc to align the test disc.

In the reagent supplying step, the reagent holder may be rotated on a plane of the reagent holder for supporting the reagent container in which the reagent is accommodated so that the position of the reagent container may be aligned.

The test method according to the present invention can improve the reliability of the test, there is an effect that can reduce the time required for the test.

1 is a plan view showing a part of a test disc used in the blood test apparatus according to the present embodiment.
2 is a perspective view showing a blood test apparatus according to the present embodiment.
3 is a perspective view showing the inside of the blood test apparatus according to the present embodiment.
Figure 4 is a side view showing the inside of the blood test apparatus according to the embodiment.
5 is an enlarged perspective view showing a test unit of the blood test apparatus according to the present embodiment.
6 is a front view showing a test part of the blood test apparatus according to the present embodiment.
7 is a flowchart showing a blood test method according to the present embodiment.
8 is a side view briefly showing a test operation of the blood test apparatus according to the present embodiment.

As described above, the present invention relates to a test method for rotating a test disk and performing a test on a sample collected for a test such as a urine test and an immune test in addition to a blood test. For the description of an embodiment of a blood test method using a blood test apparatus. Therefore, the blood test apparatus and blood test method described below will not be understood as limiting the scope of the present invention.

Hereinafter, a blood test apparatus according to the present embodiment will be described with reference to the accompanying drawings.

1 is a plan view showing a part of a test disc used in the blood test apparatus according to the present embodiment.

Referring to FIG. 1, a test chamber 10, a reagent chamber 12, and a test chamber 13 are formed in a test disc 10 used in the blood test apparatus according to the present embodiment.

The specimen chamber 11 is formed inside the test disc 10 to receive blood for examination. The reagent chamber 12 contains a reagent used for testing blood. The test chamber 13 is connected to the sample chamber 11 and the reagent chamber 12 and is formed at the edge of the test disk 10 so that blood and reagents may be mixed therein as the test disk 10 is rotated and driven. .

The specimen chamber 11, the reagent chamber 12, and the inspection chamber 13 may be provided in plural in the inspection disk 10. In FIG. 1, one specimen chamber 11, one reagent chamber 12, and one inspection chamber 13 are connected to each other, but one specimen chamber 11 and one reagent chamber 12 are connected to each other. The inspection chamber 13 may be modified to be connected. As such, a plurality of inspection chambers 13 may be formed in the inspection disk 10 to simultaneously perform a plurality of inspections.

In addition, the test disk 10 is a channel for allowing blood contained in the sample chamber 11 to be centrifuged into red blood cells and plasma as the test disk 10 is rotated, a temporary chamber for temporarily receiving plasma extracted from blood, and plasma. A channel for extracting from the red blood cells to be introduced into the test chamber 13, a channel for mixing blood and reagents, and a channel for allowing mixed blood and reagents to enter the test chamber 13 may be formed. Each channel may be provided with valves for controlling the flow of the fluid. Since these channels and valves are already known in addition to the above-mentioned prior art documents, detailed descriptions thereof will be omitted.

2 is a perspective view showing a blood test apparatus according to the present embodiment, Figure 3 is a perspective view showing the interior of the blood test apparatus according to the present embodiment, Figure 4 is a side view showing the interior of the blood test apparatus according to the present embodiment to be.

2 to 4, the blood test apparatus 100 according to the present exemplary embodiment includes a housing 101 forming an appearance, a reagent supply unit 200 and a reagent supply unit 200 disposed inside the housing 101. It includes an inspection unit 300 disposed below.

The housing 101 is provided so that the upper part can be opened and closed. That is, the upper end of the housing 101 is opened, and the cover 102 is installed on the upper portion of the housing 101 to be slidably driven forward and backward of the housing 101. The cover 102 may be provided with a handle 102a that provides the operator with convenience such as sliding driving of the cover 102. The front surface of the cover 102 may display an overall state of a device and input a command for operating the device. Touch screen 102b may be installed to enable it.

In addition, a tray 103 that is driven to slide in and out of the housing 101 is installed below the housing 101. The inspection unit 300 may be installed in the tray 103 to be drawn in and out of the housing 101 according to the sliding drive of the tray 103.

In this embodiment, the cover 102 that is slidingly driven on the upper portion of the housing 101 may be easily supplied with reagents, and the inspection unit 300 may be installed on the tray 103 that is slidingly driven to test the disk 10. ) Can be withdrawn.

On the other hand, the present embodiment is supplied with a reagent is contained in the reagent container 20, the reagent supply unit 200 includes a reagent support 210, a reagent supply module 220 and a reagent alignment module 230.

The reagent support 210 supports a plurality of reagent containers 20. The reagent support 210 may be provided in a circular plate shape, and a plurality of support holes may be formed in the reagent support 210 at uniform intervals in the circumferential direction. Therefore, the plurality of reagent containers 20 may be supported together on the reagent support 210.

The reagent supply module 220 may be provided in the form of a diaphragm pump made of a combination of a diaphragm and a solenoid. Diaphragm pumps have the advantage of preventing contamination of reagents and allowing reagents to be metered in per unit time.

In the above description, the reagent supply module 220 is described as being provided in the form of a diaphragm pump consisting of a combination of a diaphragm and a solenoid. In another embodiment, the reagent container 20 may be provided in the form of a flexible tube, a syringe (syringe), etc., in which a nozzle (not shown) is formed, and the reagent supply module 220 may provide the reagent container 20. Compressed or provided in the form of a solenoid, a hydraulic / pneumatic cylinder installed to increase the internal pressure of the reagent vessel 20, to compress each reagent vessel 20, or to increase the internal pressure of each reagent vessel 20 Incrementally, the reagent may be dispensed through a nozzle (not shown).

The reagent alignment module 230 rotates the reagent support 210 so that the reagent supported by the reagent support 210 is aligned on the upper side of the reagent chamber 12 of the test disc 10. The reagent alignment module 230 includes a driven pulley 231 protruding from the reagent support 210, a belt 232 connected to the driven pulley 231, a driving pulley 233 connected to the belt 232, and a main pulley ( 233 may be made of a combination of the rotating motor 234 to rotate.

5 is an enlarged perspective view of the test unit of the blood test apparatus according to the present embodiment, and FIG. 6 is a front view of the test unit of the blood test apparatus according to the present embodiment.

5 and 6, the inspection unit 300 includes a disc support 310, a disc alignment module 320 (see FIGS. 3 and 4), a disc rotation module 330, a plurality of light sources 350, and a plurality of light sources. A light guide 360 and a plurality of light detection elements 380.

The disc support 310 supports the test disc 10. The disk support 310 is provided in a circular plate shape and is disposed on the upper surface of the tray 103.

The disk alignment module 320 trays the disk support 310 so that the reagent chamber 12 is positioned at the position where the reagent is discharged, and the inspection chamber 13 is positioned at the position where the plurality of light is incident. Feeds straight in the sliding direction. The disc alignment module 320 is disposed in the direction in which the tray 103 slides and is coupled to the LM guide 321 and the disc support 310 which are coupled to the rail grooves 311 formed on the bottom surface of the disc support 310. The ball screw 322 to be coupled and the rotary motor 323 for rotating the ball screw 322 may be in the form of a linear actuator combined (see FIGS. 3 and 4).

The disk rotation module 330 is a plasma and red blood cells are centrifuged from the blood contained in the sample chamber 11, the blood containing the test disk 10 so that the plasma and reagents can be smoothly mixed with the centrifuged blood Rotate at relatively high speed (1700rpm ~ 1900rpm). In addition, the disk rotation module 330 rotates the inspection disk 10 at a relatively low rotation speed (500 rpm to 600 rpm) so that a plurality of light emitted from the plurality of light sources 350 can be incident to the inspection chamber 13. Let's do it. The disk rotation module 330 may be a rotation motor that is installed so that the output shaft supports the disk support 310.

Therefore, the inspection disk 10 may be formed with an alignment groove 14 to detect the position of the inspection disk 10, the side of the disk support 310 to detect the alignment groove 14 to detect the inspection disk 10 Sensor 340 for detecting the initial position of the) may be installed. In addition, although not shown, the number of revolutions of the test disc 10 and the speed of rotation of the test disc 10 may be detected by the disc rotation module 330, that is, an encoder directly connected to the rotary motor.

The plurality of light sources 350 are disposed below the test disc 10 supported by the disc support 310. The plurality of light sources 350 emit a plurality of lights. The plurality of light sources 350 emit light in a direction opposite to the inspection disk 10 supported by the disk support 310 so that the plurality of lights do not interfere with each other and enter the inspection disk 10. Emits. A light emitting diode (LED) may be used as the light sources 350. The plurality of light sources 350 may emit light having wavelengths of 620 nm, 540 nm, 500 nm, and 365 nm, respectively.

Here, the wavelengths of the light emitted from the plurality of light sources 350 may use light of various wavelengths depending on the inspection item in addition to the light of the above-mentioned wavelength, and thus, the wavelength of the light is not limited in the present embodiment.

The plurality of light guides 360 are disposed between the plurality of light sources 350 and the test disc 10 supported by the disc support 310. The plurality of light guides 360 ensure an independent path of each light so that any one light emitted from the plurality of light sources 350 is diffused and not interfere with other adjacent light. As the plurality of light guides 360, an optical fiber that is bent from the plurality of light sources 350 and extended to the test disc 10 supported by the disc support 310 may be used. The diameters of the plurality of light guides 360 may be provided as 1 to 2 mm, respectively.

In addition, a plurality of light collecting lenses 371 are disposed between the plurality of light guides 360 and the test disc 10 supported by the disc support 310, and the test disc 10 supported by the disc support 310. And a plurality of focusing lenses 372 may be disposed between the photodetectors 380.

The plurality of condenser lenses 371 allow the light emitted from the plurality of light guides 360 to be condensed into the respective specimen chambers 11. The plurality of focusing lenses 372 allow each light to be focused so that each light passing through the inspection disk 10 is aligned and incident on the center of each light detection element 380.

The plurality of photodetecting elements 380 are disposed above the inspection disk 10 supported by the disk support 310. The plurality of light detecting elements 380 detects a plurality of light passing through the respective specimen chambers 11. The light detected by the plurality of light detecting elements 380 is used to test blood by analyzing the light intensity. A photodiode, a charge coupled device (CCD), a complementary metal-oxide semiconductor (CMOS), or the like may be used as the photodetector.

Hereinafter, a blood test method using the blood test apparatus according to the present embodiment will be described.

7 is a flowchart showing a blood test method according to the present embodiment.

Referring to FIG. 7, blood is received in each specimen chamber 11 of the test disc 10, and the tray 103 is slidably driven and drawn out of the housing 101. The test disc 10 is supported by the disc support 310. When the test disc 10 is supported by the disc support 310 as described above, the tray 103 is slid and driven into the housing 101. (Step S110)

On the other hand, the cover 102 is slidingly driven to open the upper end of the housing 101. The reagent is accommodated in the reagent container 20 and supported by the reagent support 210. The reagent support 210 may be supported with a plurality of reagent vessels 20. In this case, different reagents may be respectively accommodated in the plurality of reagent containers 20 so that a plurality of lights may be emitted together to perform a plurality of inspections. When the reagent is supported on the reagent support 210 in this manner, the cover 102 is driven to slide so that the upper end of the housing 101 is closed. (Step S120)

When the plurality of reagent containers 20 are supported by the reagent supply unit 200 and the test disc 10 is supported by the test unit 300, the test disc 10 may be aligned, centrifugation of blood, and the reagent chamber 12 may be performed. Alignment of the reagent vessel 20 and alignment of each test chamber 13 with respect to the plurality of light sources 350 are performed.

That is, the test disc 10 is linearly conveyed in the direction in which the tray 103 is slid by the disc alignment module 320 so that its position is aligned. Accordingly, the test disc 10 is arranged such that the reagent container 20 is positioned above the reagent chamber 12 and the plurality of light sources 350 are positioned below the test chamber 13, respectively.

Subsequently, the test disc 10 is rotated at a relatively high rotational speed (for example, a rotational speed of 1890 rpm for 120 seconds) for a predetermined time. As the test disk 10 is rotated as described above, blood is centrifuged into plasma and red blood cells. Erythrocytes extracted from blood are stored in a temporary chamber.

On the other hand, alignment of the reagent container 20 with respect to the reagent chamber 12 is performed. That is, the reagent alignment module 230 rotates the reagent support 210 so that the reagent container 20 may be positioned above the reagent chamber 12. The reagent supply module 220 supplies the reagent contained in the reagent container 20 to the reagent chamber 12 (step S130).

In this way, when the reagent is supplied to the reagent chamber 12, the test disc 10 is rotated at a relatively high rotational speed (for example, a rotational speed of 1900 rpm for 20 seconds) for a predetermined time. As the test disc 10 is rotated, the plasma and the reagent are mixed in the mixing channel, and the mixed plasma and the reagent are received in the test chamber 13 (step S140).

Subsequently, the positions of the inspection chambers 13 with respect to the plurality of light sources 350 are aligned. That is, the disk rotation module 330 rotates the test disk 10 at a low speed (for example, 503 rpm) so that the test chambers 13 may be positioned above the light sources 350.

8 is a side view briefly showing a test operation of the blood test apparatus according to the present embodiment.

Referring to FIG. 8, when the plurality of inspection chambers 13 for the plurality of light sources 350 are aligned, the plurality of light sources 350 are emitted from the plurality of light sources 350. At this time, the plurality of light emitted from the plurality of light sources 350 is emitted in the opposite direction of the inspection disk 10. Therefore, the light emitted from the plurality of light sources can be prevented from interfering with the light adjacent to each other (step S150).

The plurality of lights may be guided by each of the light guides 360, that is, the optical fibers, and may be incident to each condenser lens 371 without interfering with adjacent light. (Step S160) The condenser lens 371 is Each light is focused and incident on each inspection chamber 13.

Subsequently, each light is incident to each inspection chamber 13, and the light passing through the inspection chamber 13 is aligned to the center of each photodetecting element 380 by the focusing lens 372 to each Incident to the light detection element 380. As described above, the plurality of lights are detected by the respective photodetecting elements 380. (Step S170) The light intensity detected by the plurality of photodetecting elements 380 is analyzed by the photo metric. Your blood test is done.

As described above, the blood test method according to the present exemplary embodiment may improve the reliability of the blood test because a plurality of lights may be incident on each test chamber 13 along an independent path without interfering with each other. In addition, the blood test according to the present embodiment can simultaneously test the blood contained in the plurality of test chambers using the plurality of lights, thereby reducing the time required for the blood test.

10: inspection disc 11: specimen chamber
12: reagent chamber 13: inspection chamber
14: alignment groove 20: reagent container
100: blood test device 200: reagent supply unit
210: reagent support 220: reagent supply module
230: reagent rotation module 300: inspection unit
310: disk support 320: disk alignment module
330: disk rotation module 340: sensor
350: light source 360: light guide
371 focusing lens 372 focusing lens
380: photodetector

Claims (6)

A test disc loading step of loading a test chamber in which a sample chamber containing a sample, a reagent chamber connected to the sample chamber, and a plurality of test chambers connected to the sample chamber and the reagent chamber are formed;
A reagent loading step of loading a reagent container containing a reagent;
A reagent supplying step of supplying the reagent to the reagent chamber;
A test disc driving step in which the test disc is rotated to mix the sample and the reagent, and the sample mixed with the reagent is received in the test chamber;
A light emitting step of emitting a plurality of lights from a plurality of light sources spaced apart from one surface of the test disc;
A light guide step of guiding the plurality of lights to the plurality of inspection chambers; and
And a light detection step of detecting the plurality of light passing through the plurality of inspection chambers by a plurality of light detection elements spaced apart from the back surface of the inspection disk. The method of claim 1, wherein between the light guide step and the light detection step.
And a condensing step of condensing the plurality of lights into each of the plurality of inspection chambers. The method of claim 1, wherein between the light guide step and the light detection step.
And an optical focusing step in which the plurality of lights passing through the inspection chamber are respectively focused on the plurality of light detection elements. The method of claim 1, wherein in the light emission step, the plurality of light sources emits the plurality of light in the opposite direction of the inspection disk,
And the light guiding step is to guide the plurality of lights by a plurality of optical fibers that are bent from the plurality of light sources and respectively extended to the plurality of inspection chambers. The method of claim 1, wherein the loading of the test disc
And the inspection disc is aligned so that the inspection disc is linearly transferred on the plane of the inspection disc. The method of claim 1, wherein the reagent supply step
And the reagent holder is rotated on a plane of the reagent holder for supporting the reagent container containing the reagent so that the position of the reagent container is aligned.

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