KR102666561B1 - Multi channel isothermal amplification system - Google Patents

Abstract

The present invention relates to a multi-channel isothermal amplification system, comprising: a heating block in which holes into which a plurality of sample tubes are inserted are formed in a row; An optical system that detects fluorescence signals of samples in the sample tubes by applying light of different wavelengths to each of the sample tubes inserted into the heating block; a heat sink that radiates heat from the heating block to the outside; and a Peltier module disposed between the heating block and the heat sink to exchange heat between the heating block and the heat sink.

Description

Multi-channel isothermal amplification system {MULTI CHANNEL ISOTHERMAL AMPLIFICATION SYSTEM}

The present invention relates to a multi-channel isothermal amplification system that can obtain results more quickly and efficiently through detection through light of various wavelengths.

With the advent of nucleic acid amplification technology, research is being actively conducted to detect bacteria, viruses, etc. to diagnose diseases. Nucleic acid amplification technology is a technology mainly used in the fields of molecular biology and biotechnology and is a method of detecting and analyzing small amounts of nucleic acids.

In general, PCR (Polymerase Chain Reaction) technology, which analyzes DNA and RNA using heat-stable enzymes to amplify nucleic acids, is widely used.

Conventional PCR repeats the process of separating double-stranded DNA into single-stranded DNA under high temperature conditions, lowering the temperature, binding a primer to the single strand, and allowing Taq polymerase to extend it into double-stranded DNA.

However, existing PCR shows only qualitative results of DNA amplified using electrophoresis on a gel at the end-point, and has several problems such as accuracy of quantitative detection.

Accordingly, real-time PCR was developed to enable quantitative analysis of nucleic acids by detecting in real time the intensity of the fluorescence signal proportional to the concentration of the amplified nucleic acid.

Real-time PCR is widely used in nucleic acid analysis because it allows confirmation and quantitative analysis in real time during the reaction cycle without performing electrophoresis of the amplified nucleic acid product on a gel.

There is a growing demand for technology that improves these prior technologies and enables more efficient and accurate diagnosis of a larger number of samples.

Patent Document 1: Republic of Korea Patent No. 10-0580639 (May 9, 2006)

The present invention was developed to solve the above-described problem. The multi-channel isothermal amplification system according to the present invention enables detection of light of various wavelengths through a multi-channel optical system for a plurality of sample tubes in the heating block. We aim to obtain accurate results for multiple samples more quickly and efficiently.

In addition, the multi-channel isothermal amplification system according to the present invention places a light source module at the bottom of the heating block where the sample tube is located and a detection module for detecting the fluorescence signal of the sample on the side of the heating block, so that the light source module and The aim is to provide a multi-channel isothermal amplification system that allows for more accurate measurement by preventing mutual interference of light between the detection modules.

In addition, the multi-channel isothermal amplification system according to the present invention is designed to further improve usability and portability by integrating the light source module and the detection module to make it more compact.

A multi-channel isothermal amplification system according to an embodiment of the present invention to solve the above-described problem includes a heating block in which holes into which a plurality of sample tubes are inserted are formed in a row; An optical system that detects fluorescence signals of samples in the sample tubes by applying light of different wavelengths to each of the sample tubes inserted into the heating block; a heat sink that radiates heat from the heating block to the outside; and a Peltier module disposed between the heating block and the heat sink to exchange heat between the heating block and the heat sink.

According to another embodiment of the present invention, the optical system includes a light source module that injects light from the bottom of the heating block toward the sample tube; and a detection module that detects a fluorescence signal from the sample at the side of the heating block.

According to another embodiment of the present invention, the heat sink may be disposed on the other side opposite to the side where the detection module is disposed to radiate heat from the heating block to the outside.

According to another embodiment of the present invention, the light source module includes an LED that irradiates light; an excitation filter that filters light emitted from the LED; and a first lens that focuses the light filtered by the excitation filter onto the sample in the sample tube.

According to another embodiment of the present invention, the detection module includes an emission filter that receives a fluorescence signal of the sample; a second lens transmitting the fluorescence signal filtered by the emission filter; and a light detection sensor that receives a fluorescent signal flowing through the second lens.

According to another embodiment of the present invention, the heating block includes a first heating block area where a plurality of the holes are formed in a row; and a second heating block region in which a plurality of the holes are formed in a line, and is spaced apart from each other in the longitudinal direction of the first heating block region by the distance between the holes, and is arranged in line with the first heating block region. It can be configured to include.

According to another embodiment of the present invention, each channel of the optical system moves in the longitudinal direction of the first heating block area and the second heating block area arranged in a row, and each channel of the optical system moves in the longitudinal direction of the first heating block area and the second heating block area. And, light of a set wavelength is sequentially incident on the sample tubes inserted into the holes of the second heating block area, thereby detecting the fluorescence signal of the sample in the sample tube.

The multi-channel isothermal amplification system according to the present invention enables detection of light of various wavelengths through a multi-channel optical system for multiple sample tubes in the heating block, providing accurate results for multiple samples more quickly and efficiently. It can be obtained.

In addition, the multi-channel isothermal amplification system according to the present invention places a light source module at the bottom of the heating block where the sample tube is located and a detection module for detecting the fluorescence signal of the sample on the side of the heating block, so that the light source module and By preventing mutual interference of light between the detection modules, it is possible to provide a multi-channel isothermal amplification system capable of more accurate measurement.

In addition, the multi-channel isothermal amplification system according to the present invention can further improve usability and portability by integrating the light source module and the detection module and making it more compact.

Figure 1 is a diagram illustrating a multi-channel isothermal amplification system according to an embodiment of the present invention.
Figure 2 is an internal perspective view of a multi-channel isothermal amplification system according to an embodiment of the present invention.
Figure 3 is a diagram showing a heating block of a multi-channel isothermal amplification system according to an embodiment of the present invention.
Figure 4 is a diagram for explaining in more detail the configuration of a multi-channel isothermal amplification system according to an embodiment of the present invention.
Figure 5 is a diagram for explaining the operation method of a multi-channel isothermal amplification system according to an embodiment of the present invention.
Figure 6 is a configuration diagram of a multi-channel isothermal amplification system according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the attached drawings. However, in describing the embodiments, if it is determined that specific descriptions of related known functions or configurations may unnecessarily obscure the gist of the present invention, detailed descriptions thereof will be omitted. Additionally, the size of each component in the drawings may be exaggerated for explanation and does not mean the actual size.

From now on, the configuration of a multi-channel isothermal amplification system according to an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a diagram illustrating a multi-channel isothermal amplification system according to an embodiment of the present invention, and FIG. 2 is an internal perspective view of the multi-channel isothermal amplification system according to an embodiment of the present invention.

In addition, Figure 3 is a diagram showing a heating block of a multi-channel isothermal amplification system according to an embodiment of the present invention, and Figure 4 illustrates the configuration of a multi-channel isothermal amplification system according to an embodiment of the present invention in more detail. Figure 5 is a diagram for explaining the operation method of the multi-channel isothermal amplification system according to an embodiment of the present invention.

The multi-channel isothermal amplification system according to an embodiment of the present invention includes a heating block 100, an optical system 200, a heat sink 300, and a Peltier module 400.

Holes 102 are formed in the heating block 100 into which a plurality of sample tubes 101 are inserted, and the holes 102 are also referred to as wells. At this time, the holes 102 are formed in a row. That is, the holes 102 are formed in a row in one direction on the heating block 100, and sample tubes 101 accommodating samples can be placed in the holes 102, respectively.

More specifically, the heating block 100 may be divided into a first heating block area 100A and a second heating block area 100B.

The first heating block area 100A has a plurality of holes 102 formed in a line, and similarly, a plurality of the holes 102 are formed in a line in the second heating block area 100B. 2 The heating block area 100B may be spaced apart from the first heating block area 100A by the distance between the holes 102 and the holes 102, and may be arranged in line with the first heating block area 100A. there is.

The optical system 200 makes light of each wavelength incident on the sample tubes 101 inserted into the heating block 100 and detects the fluorescence signal of the sample within the sample tube 101.

According to one embodiment of the present invention, the optical system 200 is configured to include four channels, and each channel transmits light of different wavelengths to the sample tube 101 inserted into the heating block 100. It may be configured to detect the fluorescence signal of the sample in the sample tube 101 and move sequentially.

More specifically, each channel of the optical system 200 may be composed of a light source module 210 and a detection module 220.

The light source module 210 injects light into the sample tube 101 from the bottom of the heating block 100, and the detection module 220 emits a fluorescence signal from the sample at the side of the heating block 100. can be detected.

More specifically, the light source module 210 includes an LED 211 that irradiates light, an excitation filter 212 that filters the light irradiated from the LED 211, and a light filtered by the excitation filter 212. It may be configured to include a first lens 213 that focuses light onto the sample within the sample tube 101.

In addition, the detection module 220 includes an emission filter 221 that receives the fluorescence signal of the sample, a second lens 222 that transmits the fluorescence signal filtered by the emission filter 221, and the second lens 222. It may be configured to include a light detection sensor 223 that receives a fluorescent signal flowing through the lens 222.

Meanwhile, the heat sink 300 radiates heat from the heating block 100 to the outside.

At this time, the heat sink 300 is disposed on the other side opposite to the side where the detection module 220 is disposed, and can effectively radiate heat from the heating block 100 to the outside.

More specifically, the heat sink 300 includes a first heat sink disposed to correspond to the first heating block area 110A of the heating block 100, and a second heating block area 110B of the heating block 100. It may be composed of a second heat sink disposed to correspond to.

Additionally, the Peltier module 400 may be disposed between the heating block 100 and the heat sink 300 to exchange heat between the heating block 100 and the heat sink 300.

As such, the multi-channel isothermal amplification system according to an embodiment of the present invention effectively cools the heat from the heating block 100 through the Peltier module 400 and more effectively dissipates heat through the heat sink 300. It can be done as much as possible.

That is, the multi-channel isothermal amplification system according to an embodiment of the present invention has this configuration, so that the optical system 200 consisting of the four channels is connected to the first heating block area 100A of the heating block 100. and moves in the longitudinal direction of the second heating block area 100B, and each channel of the optical system 200 is inserted into the hole of the first heating block area 100A and the second heating block area 100B. By sequentially incident light of a set wavelength on each of the sample tubes 101, the fluorescence signal of the sample within the sample tube 101 can be detected.

As such, the multi-channel isothermal amplification system according to the present invention can obtain accurate results more quickly and efficiently by detecting fluorescence signals through four channels for multiple sample tubes in the heating block.

In addition, in the embodiment of the present invention, an optical system consisting of four channels has been described, but the number of channels in the optical system can be changed as needed to enable faster and more efficient detection.

In addition, the multi-channel isothermal amplification system according to the present invention places a light source module at the bottom of the heating block where the sample tube is located and a detection module that detects the fluorescence signal of the sample on the side of the heating block, so that the light source By preventing mutual interference of light between the module and the detection module, it is possible to provide a multi-channel isothermal amplification system capable of more accurate measurement.

Figure 6 is a configuration diagram of a multi-channel isothermal amplification system according to an embodiment of the present invention.

Referring to FIG. 6, the multi-channel isothermal amplification system according to an embodiment of the present invention is configured to include an LCD touch panel to input a user's control command and detect a sample signal through the LCD touch panel. Information and related information can be displayed.

In addition, the multi-channel isothermal amplification system according to an embodiment of the present invention operates the main controller, the motor driver that operates the stepper motor, and the LED of the optical module. LED Driver, Temperature Sensor that detects the heat of the heating block 100, Peltier Control that controls the Peltier Module, Top Heater installed in the heating block ), a temperature sensor installed on the top heater, and a fan, and is controlled by the main controller.

In this way, the multi-channel isothermal amplification system according to the present invention can further improve usability and portability by integrating the light source module and the detection module and making it more compact.

In the detailed description of the present invention as described above, specific embodiments have been described. However, various modifications are possible without departing from the scope of the present invention. The technical idea of the present invention should not be limited to the above-described embodiments of the present invention, but should be determined not only by the claims but also by equivalents to the claims.

100: Heating block
100A: First heating block area
100B: Second heating block area
101: sample tube
102: hole
200: Optics
210: light source module
211: LED
212: excitation filter
213: first lens
220: detection module
221: emission filter
222: second lens
223: Light detection sensor
300: heat sink
400: Peltier module

Claims (7)

A heating block in which holes into which a plurality of sample tubes are inserted are formed in a row;
An optical system that detects fluorescence signals of samples in the sample tubes by applying light of different wavelengths to each of the sample tubes inserted into the heating block;
a heat sink that radiates heat from the heating block to the outside; and
A Peltier module disposed between the heating block and the heat sink to exchange heat between the heating block and the heat sink,
The optical system is,
a light source module that injects light from the bottom of the heating block toward the sample tube; and
a detection module that detects a fluorescence signal from the sample at a side of the heating block;
It includes four channels consisting of, and the heating block is,
a first heating block area where a plurality of the holes are formed in a row; and
A second heating block region in which a plurality of the holes are formed in a line, and is spaced apart from each other in the longitudinal direction of the first heating block region by the distance between the holes, and is arranged in line with the first heating block region. do,
Each channel of the optical system is,
It moves in the longitudinal direction of the first heating block area and the second heating block area arranged in a row, and each of the optical systems is connected to the sample tubes inserted into the holes of the first heating block area and the second heating block area. Detecting the fluorescence signal of the sample in the sample tube by sequentially incident light of each set wavelength,
The heat sink is,
It is disposed on the other side opposite to the side where the detection module is disposed to radiate heat from the heating block to the outside,
The light source module is,
LED that irradiates light;
an excitation filter that filters light emitted from the LED; and
a first lens that focuses light filtered by the excitation filter onto a sample in the sample tube;
The detection module is,
An emission filter that receives the fluorescence signal of the sample;
a second lens transmitting the fluorescence signal filtered by the emission filter; and
A multi-channel isothermal amplification system comprising: a light detection sensor that receives the fluorescent signal introduced through the second lens.
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