KR102300539B1 - Interface module for measurment of rt-pcr and rotational rt-pcr device - Google Patents

Abstract

The present invention relates to an interface module for measuring RT-PCR and a rotational RT-PCR device comprising the same. More specifically, the present invention relates to a rotational RT-PCR device comprising an interface module for measuring RT-PCR in which a plurality of barriers are installed in a spiral shape, and a heating block module having a slip ring. According to the present invention, verified PCR tubes are identically applied, thereby ensuring reliability.

Description

INTERFACE MODULE FOR MEASURMENT OF RT-PCR AND ROTATIONAL RT-PCR DEVICE

The present invention relates to an interface module for RT-PCR measurement and a rotary RT-PCR device including the same, and more particularly, a heating having a slip ring and an interface module for RT-PCR measurement in which a plurality of barriers are installed in a spiral form. The block module relates to a rotary RT-PCR device.

Polymerase Chain Reaction (PCR) is a molecular biological technology that replicates and amplifies a desired part of DNA. This technique can selectively amplify only specific DNA fragments of interest in a sample. In addition, the time required for amplification is short, and since it has high accuracy and can measure a small amount of DNA, it plays an important role in various fields such as molecular biology, medicine, criminal investigation, and classification of living things.

On the other hand, RT-PCR (Real time PCR) as a tool for confirming infectious diseases has established itself as a universal technology. As a screening device, the technology level of the RT-PCR device has stagnated through the development and optimization of bio-related technology, and the development of equipment by latecomers continues.

Most of the RT-PCR equipment is operated by a professional inspection institution, and the technology is concentrating on processing a large number of samples at the same time.

However, the difficulty of using the RT-PCR device for on-site diagnosis is that the extraction and fixation of extracting target DNA or RNA from the sample is performed using a separate automated equipment or manual operation is performed by skilled workers, making it difficult to use in the medical field. It cannot be easily performed by an expert. In addition, most automated equipment is designed to process many samples at the same time, so it is difficult to apply when the number of samples to be processed at one time is small, such as a primary medical institution.

Therefore, the entire process from DNA extraction process to real-time PCR is carried out in one step and the development of a device that can be performed without the intervention of an expert is required. The cost is high, on-site diagnosis is difficult, the measurement time and cost are high, so it is burdensome for general consumers to use it frequently, and it is difficult to confirm the measurement result quickly because the sample must be collected and processed.

Accordingly, there is a need for research and development of an interface module to efficiently perform the entire process from DNA extraction to real-time PCR.

Korean Patent Publication No. 10-2012-0031188

The present invention was conceived to solve the above problems, and by allowing droplets surrounded by different barriers in the interface tube module for RT-PCR to flow into the PCR tube through a one-way opening/closing valve, the diagnostic efficiency is increased, and It is possible to reduce contamination and increase the convenience of diagnosis. In addition, an object of the present invention is to provide an interface tube module for RT-PCR capable of measuring the entire process from sample preparation to measurement in an all-in-one manner, and a rotational RT-PCR device having the same.

The interface module for RT-PCR measurement according to an embodiment of the present invention includes a circular plate; a groove region located on the upper surface of the circular plate and having a space to contain droplets; a plurality of barriers formed independently of each other having the same number as the number of PCR tubes formed on the groove region; and an injection hole for a PCR tube located on the upper surface of the circular plate.

It further includes a circular separator detachably disposed in the center of the groove region, wherein the droplet in the groove region is located in a region separated by the plurality of barriers and the circular separator.

The outer surface of the circular separator and the respective ends of the plurality of barriers are in contact so that the droplets in the groove region are located in the separated regions.

The groove region and the injection hole for the PCR tube are connected by a flow path, and further include a one-way opening/closing valve positioned on the flow path, wherein the one-way opening/closing valve includes an outer tube; an opening/closing valve operably installed at one end of the outer tube; and an inner tube inserted into the outer tube from the other end of the outer tube.

When the length of the outer tube is defined as L1, the length at which the inner tube is inserted into the outer tube is defined as L2, and the diameter of the on-off valve is defined as r, the following range is satisfied.

L1-L2 < r/4

Each of the plurality of barriers may have a spiral shape.

A rotary RT-PCR device according to an embodiment of the present invention includes an interface module for RT-PCR measurement.

A rotary RT-PCR device according to an embodiment of the present invention includes a cartridge module for DNA extraction; an interface module located under the cartridge module for DNA extraction; PCR tube module located below the interface module; and a heating block module located under the PCR tube module, wherein current is transmitted to the heating block module by a slip ring.

The slip ring module includes a rotating part; a slip ring rotatably connected by the rotation shaft of the rotating part; first and second brushes connected to the slip ring; a heat transfer unit heated by the current transmitted by the first brush and the second brush; and a control unit for controlling the current.

According to the interface tube module for RT-PCR of the present invention and the RT-PCR device for rotation having the same, the plastic cartridge and the interface tube module do not include a separate precision device or electric part, so the manufacturing cost is simplified. can be reduced, and the instrument design is simplified. In addition, reliability can be secured by applying the same verified PCR tube.

1 shows a schematic diagram of a rotational RT-PCR device of the present invention.
2 shows a schematic diagram of a cartridge module and an interface module of the present invention.
3 shows a top schematic view of an interface module of the present invention;
4 is a diagram illustrating the operation of a separator in the interface module of the present invention.
5 shows the flow of droplets from the interface module of the present invention to the PCR tube module.
Figure 6 shows a picture when the droplet flows from the interface module of the present invention to the PCR tube module.
7 shows a schematic diagram of a one-way on-off valve of the present invention.
8 shows a schematic diagram of a one-way on-off valve of the present invention.
9 shows a schematic diagram of a one-way on-off valve of the present invention.
10 is a schematic diagram showing a case in which a slip is not used and a case in which a slip ring is used in the heater block module of the present invention.
11 shows a state in which the PCR tube module of the present invention is mounted on the heater block module.

In the following drawings, the same reference numerals refer to the same components, and the size of each component in the drawings may be exaggerated for clarity and convenience of description. Meanwhile, the embodiments described below are merely exemplary, and various modifications are possible from these embodiments. Hereinafter, what is described as "upper" or "upper" may include not only those directly above in contact, but also those above in non-contact. Terms such as first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. The singular expression includes the plural expression unless the context clearly dictates otherwise. Also, when a part "includes" a component, it means that other components may be further included, rather than excluding other components, unless otherwise stated. In addition, terms such as "...unit" and "module" described in the specification mean a unit that processes at least one function or operation.

The present invention relates to an interface tube module for RT-PCR and a rotating RT-PCR device having the same. It will also be described below with reference to the drawings. In the present invention, the interface module means an interface module for RT-PCR measurement.

1 shows a schematic diagram of a rotational RT-PCR device of the present invention. As shown in FIG. 1 , the rotary RT-PCR device may include a cartridge module 20 for DNA extraction, an interface module 30 , a PCR tube module 40 and a heating block module 50 . With respect to the movement of the magnet controlled by the support 10 in order to proceed with the extraction operation on the cartridge module 20 for DNA extraction, the cartridge module 20 for DNA extraction may be rotatably operated.

Figure 2 shows a schematic diagram of the cartridge module 20 and the interface module 30 for DNA extraction of the present invention. As shown in FIG. 2, the cartridge module 20 for DNA extraction and the PCR tube module 40 are composed of a combination of six tubes. On the other hand, the cartridge module 20 for DNA extraction and the PCR tube module 40 may be composed of a combination of eight tubes.

The extraction tube of the cartridge module of the present invention may include a tube for lysis buffer, a tube for magnetic beads, a tube for cleaning, and an elution tube. Here, the tube for Lysis Buffer can be treated with a solution containing a substance that dissolves the cell wall, and the tube for magnetic beads is a magnetic bead with high-density particles that are not chemically broken through the cell wall. It uses a magnetic substance that breaks the cell wall. Wash Buffer tube goes through Lysis Buffer tube and Magnetic Bead tube, and then washes with distilled water with the DNA chain inside the cell attached to the magnetic bead to remove foreign substances such as protein. can be removed The elution tube can be demagnetized so that the DNA can be separated from the beads and separated into free particles in solution. In addition, it is possible to have a tube for mixing the droplets 38 and a tube for using gelatin.

3 to 5 are schematic diagrams showing the interface module 30 of the present invention. As shown in FIG. 4 , the interface module 30 includes a circular plate 31 ; a groove region 32 positioned on the upper surface of the circular plate 31 and having a space to contain the droplet 38; a plurality of barriers 34 formed independently of each other having the same number as the number of PCR tubes formed on the groove region 32; an injection hole 35 for PCR tube located on the upper surface of the circular plate 31; A plurality of flow passages connecting the groove portion 32 and the injection hole 35 for the PCR tube; A plurality of one-way on/off valves 33 positioned on the plurality of passageways, in the center of the groove portion 32 and a circular separator 36 that is detachably disposed.

The groove region 32 of the present invention is located in the center of the upper surface of the circular plate 31 and has a predetermined depth with respect to the upper surface of the circular plate 31 to contain the droplets 38. A recess is formed. Here, the groove region 32 is formed to become deeper toward the center so that the droplet 38 is located in the center. The groove region 32 preferably has a circular shape, and contains the droplet 38, so that the droplet 38 of the groove region 32 flows outwardly by centrifugal force by the rotation of the rotary RT-PCR device.

A plurality of barriers 34 of the present invention are formed on the groove region 32, and form a partition to individually move the droplets 38 staying in the groove region 32 to the PCR tube. The number of the plurality of barriers 34 may have the same number as the number of PCR tubes, and the plurality of barriers 34 are formed in regions independent of each other. Here, it is preferable for the flow of the droplet 38 that the plurality of barriers 34 have a spiral shape, respectively. When the plurality of barriers 34 are in a straight shape, they form perpendicular to the direction of centrifugal force, so that the flow of the droplet 38 is difficult to be injected into the injection hole 35 for the PCR tube.

The circular separator 36 of the present invention is detachably disposed in the center of the groove region 32 . When the droplet 38 first moves to the groove region 32, the circular separator 36 does not contact the groove region 32 so that the droplet 38 is uniformly positioned in the groove region 32, and then As a result, the circular separator 36 is brought into contact with the groove region 32 by a moving means (not shown) of the circular separator 36 so that the droplets 38 in the groove region 32 are formed by the plurality of barriers 34 . ) and the circular separator 36 may be positioned in a separated area. The circular separator 36 may be of a shape having an empty space in the middle, a rotation shaft 37 is provided in the center space of the circular separator 36, and the outer surface of the circular separator 36 has a plurality of The barrier 34 comes into contact with the end in the direction toward the injection hole 35 for the PCR tube.

As shown in Fig. 4, the droplet 38 in the groove region 32 is located in the separated region. 4 (a) shows a state in which the droplet 38 is not dropped in the groove region 32, and FIG. 4 (b) shows a state in which the droplet 38 is dropped in the groove region 32, 4(c) shows that, in a state in which the droplet 38 is dropped into the groove region 32, the outer surface of the circular separator 36 and the respective ends of the plurality of barriers 34 are in contact with the groove region 32 ) in the droplet 38 is placed in a separate area.

As shown in FIG. 5 , the droplet 38 may be moved from the interface module 30 to the PCR tube module 40 . Fig. 5 (a) shows a state in which the droplet 38 is dropped into the groove region 32, Fig. 5 (b) shows a state in which the droplet 38 is rotated in the dropped state, and Fig. 5 (c) shows a state in which the droplet 38 is dropped. The droplet 38 shows a state in which it flows into the injection hole 35 for a PCR tube by centrifugal force, and FIG. 5( d ) shows a state in which the droplet 38 is injected into the PCR tube.

The interface module 30 of the present invention may be formed integrally with the PCR tube module 40 . The interface module 30 is rotatable at a speed of 300 rpm to 500 rpm. The rotation time may be 3 seconds to 6 seconds, and the acceleration or deceleration time may be 0.1 seconds to 0.5 seconds.

6 shows a picture when the droplet 38 flows from the interface module 30 of the present invention to the PCR tube module 40. As shown in FIG. 6 , the droplet 38 remains in the groove region 32 , and the droplet 38 is injected into the PCR tube by rotation of the RT-PCR device for rotation.

7 shows a schematic diagram of the one-way on-off valve 33 . As shown in FIG. 7 , the one-way on/off valve 33 includes an outer tube 33a and an inner tube 33b, and an on/off valve 33c is provided at one end of the outer tube 33a.

8 (a) shows a state in which the inner tube (33b) is inserted into the outer tube (33a) in the one-way on-off valve (33), and (b) is the inner tube (33b) in the one-way on-off valve (33) ) when the droplet 38 is injected into the inner tube 33b in a state in which the outer tube 33a is inserted, the opening/closing valve 33c provided at one end of the outer tube 33a is opened. indicates.

9 (a) is a cross-sectional view showing a state in which the inner tube (33b) is inserted into the inside of the outer tube (33a) in the one-way on-off valve (33), Figure 9 (b) is the inner tube in the one-way on-off valve (33) When the droplet 38 is injected into the inner tube 33b in a state in which 33b is inserted into the outer tube 33a, the on-off valve 33c provided at one end of the outer tube 33a is opened. A cross-sectional view of the state is shown, and FIG. 9( c ) is a right side view of the one-way on-off valve 33 .

When the diameter of the outer tube 33a is defined as R1, the diameter of the inner tube 33b is defined as R2, and the diameter of the on-off valve 33c is defined as r, the outer tube 33a of the present invention, the inner It is preferable for the tube 33b and the on/off valve 33c to have the following relational expression for smooth flow of the droplet 38 in one direction. When the on/off valve 33c is smaller than R2, which is the diameter of the inner tube 33b, the on/off valve 33c may open and close to the inside of the one-way on/off valve 33, which is not preferable.

R2 < r < R1

In addition, the length of the outer tube 33a is defined as L1, the length at which the inner tube 33b is inserted into the outer tube 33a is defined as L2, and the diameter of the on-off valve 33c is defined as r. When defining, L1-L2 is preferably smaller than r/2, L1-L2 is more preferably smaller than r/4, and L1-L2 is most preferably smaller than r/8. Outside the above range, the on/off valve 33c of the one-way on/off valve 33c may face inward instead of outward of the outer tube 33a, so that a reverse flow of the droplet 38 may occur.

The rotary RT-PCR device of the present invention includes a cartridge module 20 for DNA extraction; an interface module 30 positioned under the cartridge module 20 for DNA extraction; PCR tube module 40 located below the interface module 30; and a heating block module 50 located below the PCR tube module 40 .

Here, the heating block module 50 may use that the current is transmitted by the slip rings (51a, 52b). Fig. 10 (a) shows a state in which the electric wire flowing current by rotation is wound around the rotation shaft 37, and Fig. 10 (b) shows the electric current flowing by the slip rings 51a and 52b even by rotation is affected. indicates a state in which it is not received.

Since the rotary RT-PCR device of the present invention operates by rotation, the heat transfer unit provided in the hit block module should be designed so as not to be affected by rotation while receiving current.

11 shows a state in which the PCR tube module 40 of the present invention is mounted on the heating block module 50 . 11, the heating block module 50 includes a rotating unit 53; a first slip ring (51a) and a second slip ring (52b) rotatably connected by the rotation shaft (37) of the rotating part (53); a first brush (52a) and a second brush (52b) connected to the first slip ring (51a) and the second slip ring (52b); a heat transfer unit heated by the current transmitted by the first brush (52a) and the second brush (52b); and a control unit 54 for controlling the current. Since current is transmitted by the first brush 52a and the second brush 52b connected to the first slip ring 51a and the second slip ring 52b even by the rotation of the rotating part 53, the rotation type RT-PCR It can be heated by the heat transfer unit stably without being affected by the rotation of the device. In particular, since the heat block module operates in the mounted state of the PCR tube module 40, the slip rings 51a and 52b can be used when rotating. The heating block module 50 includes a heater, a thermistor sensor, and a Peltier element, and each power source and signal line must be connected. The control unit 54 supplies power or transmits a signal, and the control board may be installed in the rotary RT-PCR device.

The heat control of the present invention is designed to solve the non-uniformity of the temperature of the center and the outer part caused by using the existing flat-type heat block, and the heat flux can be equally applied by using the donut-type heat block module. Accuracy is improved. The lower part of the heat block module can use a heating coil, polyimide film, and Peltier heat control.

The technical idea should not be interpreted limited to the above-described embodiment of the present invention. Various modifications can be made at the level of those skilled in the art without departing from the gist of the present invention as claimed in the claims. Accordingly, such improvements and modifications fall within the protection scope of the present invention as long as it is apparent to those skilled in the art.

10 support
20 Cartridge module for DNA extraction
30 interface module
40 PCR tube modules
50 Heating Block Module
31 round plate
32 groove area
33 One-way on/off valve
33a outer tube
33b inner tube
33c on-off valve
34 barrier
35 Injection hole for PCR tube
36 Circular Separator
37 axis of rotation
38 drops
51a, 52b slip rings
52a, 52b brushes
53 rotating part
54 control

Claims (8)

round plate;
a groove region located on the upper surface of the circular plate and having a space to contain droplets;
a plurality of barriers formed independently of each other having the same number as the number of PCR tubes formed on the groove region;
Interface module for RT-PCR measurement, comprising a; injection hole for PCR tube located on the upper surface of the circular plate. The method according to claim 1,
RT-PCR measurement, characterized in that it further comprises a circular separator detachably disposed in the center of the groove region, wherein the droplets in the groove region are located in regions separated by the plurality of barriers and the circular separator for the interface module. 3. The method according to claim 2,
The interface module for RT-PCR measurement, characterized in that the outer surface of the circular separator and each end of the plurality of barriers are in contact so that the droplets in the groove region are located in the separated regions. The method according to claim 1,
The groove region and the injection hole for the PCR tube are connected by a flow path, and further include a one-way opening/closing valve located on the flow path,
The one-way on/off valve includes an outer tube; an opening/closing valve operably installed at one end of the outer tube; Interface module for RT-PCR measurement, characterized in that it comprises an inner tube inserted into the inside of the outer tube from the other end of the outer tube. The method according to claim 1,
The interface module for RT-PCR measurement, characterized in that each of the plurality of barriers has a spiral shape. A rotary RT-PCR device comprising an interface module for RT-PCR measurement according to any one of claims 1 to 5. cartridge module for DNA extraction;
An interface module for RT-PCR measurement of any one of claims 1 to 5 located below the DNA extraction cartridge module;
a PCR tube module located under the interface module for RT-PCR measurement; and
It includes; a heating block module located below the PCR tube module.
The heating block module is a rotary RT-PCR device, characterized in that the current is transmitted by a slip ring. delete

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