KR101813870B1 - Automatic analysis device for molecular diagnosis - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a molecular diagnostic automatic analyzer, and more particularly, to a molecular diagnostic automatic analyzer capable of continuously performing a series of processes such as nucleic acid extraction, amplification and analysis.
In particular, quantitative analysis and qualitative analysis can be carried out in a single reaction vessel, so that quantitative analysis and qualitative analysis can be performed simultaneously and economically and reliably in various molecular diagnostic fields at the same time.

Description

{AUTOMATIC ANALYSIS DEVICE FOR MOLECULAR DIAGNOSIS}

More particularly, the present invention relates to a molecular diagnostic automatic analyzing apparatus, and more particularly, to a molecular diagnostic automatic analyzing apparatus capable of performing nucleic acid extraction, amplification and detection automatically in a continuous process, ≪ / RTI >

Currently, the target gene testing methods widely used in molecular diagnostics are largely based on the quantitative method of measuring the degree of expression of the target gene and the copy number, the presence or absence of the target gene, and the genotype and genotyping (qualitative method).

DNA amplification techniques using polymerase chain reaction (PCR) are representative in quantitative testing, and DNA amplification techniques are widely used for research, development, and diagnosis in life sciences, genetic engineering, and medical fields.

Specifically, polymerase chain reaction (PCR) is a molecular biology technique for enzymatically replicating DNA without the use of living organisms.

PCR is recognized by molecular biologists as a method of choice for nucleic acid detection due to its incomparable amplification and precision capability.

In particular, the real-time PCR method utilizes a device in which a PCR unit and a spectrophotometer are integrated. After PCR, PCR amplification is performed without additional electrophoresis In the course of the process, amplification products of the target gene are monitored in real time to analyze the amount of DNA or RNA present or existing.

More specifically, a real-time PCR is a PCR method in which a fluorescent material is amplified by amplification of a target gene present in the specimen during the reaction, ) Is detected in real time and quantitatively analyzed to analyze the expression pattern of the target gene and the number of the gene quickly and accurately.

PCR has been used in the medical and biology laboratories to detect various problems such as detection of hereditary disease, identification of genetic fingerprint, diagnosis of infectious disease, cloning of gene, It is routinely used for paternity testing, genotyping confirmation, gene sequencing testing, and DNA computing.

During the qualitative examination, there is a DNA microarray method. A DNA microarray or a DNA chip analysis method refers to diagnosing various human diseases or genetic diseases by reading and analyzing a genotype through a DNA chip in which various kinds of probes are fixed.

For the purpose of reading and analyzing such a DNA chip, a DNA reader having a scanner for irradiating DAN chip with light and quantitatively analyzing fluorescence light generated from the DNA chip is used.

In particular, a microarray chip is a method using a oligonucleotide capable of detecting a target gene, a microarray-fixed chip using PNA or cDNA as a probe.

This is mainly because the amplification product after the PCR reaction is hybridized with the target microarray chip to bind with various kinds of probes (oligonucleotide, PNA or cDNA) immobilized on the chip solid surface (glass, plastic, membrane, It is useful for various types of genotype analysis because it can be judged by the method of confirming the fluorescence signal labeled with the amplification product. However, it has a disadvantage that the test procedure is complicated and takes a little time, A separate fluorescence analysis apparatus is required.

Recently, the concept of diagnosis and treatment of infectious diseases among the above-mentioned molecular diagnostic areas has been applied, so that the target gene test method of the analyte has a number of copy number for confirming the degree of infection through real-time PCR Quantitative information or qualitative information on the genotyping of microarray chips for appropriate treatment regimens through identification of infectious agents is required concurrently and in combination. For this purpose, real-time PCR and independent testing of microarray chips are used in parallel.

However, the combination of the above inspection methods merely conducts the experiments sequentially in different reactors and analyzes them, which requires a lot of labor and time and inconvenience.

In order to perform such a molecular diagnosis, a gene extraction process is required. Then, the extracted DNA sample must be manually transferred to an apparatus for gene amplification using a pipetting or a liquid handling module, There is an inconvenience in use because the device itself is present as a separate device.

Accordingly, there is a desperate need to develop advanced apparatuses that are economical in cost of equipment and are bulky enough to be used in the inspection center, while automating the inspection methods and the extraction process in a device.

The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to automatically perform a series of processes such as nucleic acid extraction, amplification and analysis, and to perform quantitative analysis and qualitative analysis And to provide a molecular diagnostic automatic analyzing apparatus capable of performing a molecular diagnostic.

It is another object of the present invention to provide a molecular diagnostic automatic analyzing apparatus capable of integrating extraction, qPCR, and genotyping analysis while having an advantage of reducing processing time.

According to one aspect of the present invention, there is provided a polymerase chain reaction (PCR) apparatus comprising a frame, a frame supported by the frame, a container mounting portion accommodating a plurality of containers, a reaction container, A first guide having a receiving hole to which a protector is mounted, a first guide which is separated from an upper portion of the moving plate and is supported by the frame, A quantitative analysis means for detecting in real time a fluorescence signal generated from a nucleic acid amplified sample and a magnetic bead transfer portion including a second guide having a magnet fixed at a position insertable therein; And a qualitative analysis means for detecting a fluorescence signal generated by hybridization with the adducted nucleic acid, It can provide an automated analysis device.

Specifically, the quantitative analysis and the qualitative analysis of the optical detection unit can be performed on the same reaction vessel, and the moving plate is movable in the horizontal direction to the frame, so that the first guide and the second guide are movable in the frame And can be independently raised and lowered at a fixed position in the horizontal direction with respect to the vertical direction.

As the first and second guides move up and down, the protector and the magnet provided in the container in the container holding part and the reaction container mounted in the reaction container mounting hole can be drawn in and out.

The protector is detachable from the receiving hole. The receiving hole is provided with a magnet around the inner circumferential surface thereof. The protector is coupled with the receiving hole by magnetic force, Can be mounted.

The first guide is lowered at a position where the receiving hole of the first guide corresponds to the protector and the coupling portion of the protector is inserted into the receiving hole, The protector is mountable.

The container mounting portion may include a first container into which a bio sample is injected and which includes a cell grinding reagent and a magnetic bead and is subjected to a lyse process and at least one container containing a washing buffer for washing the nucleic acid bonded magnetic beads provided from the first container And a second container.

At this time, the container mounting portion may be equipped with a protector storage container provided with a protector, a cartridge integrally coupled with a container portion including the first container and the second container.

A DNA chip is provided on the inner bottom surface of the reaction vessel, and an oil layer is provided on the upper surface of the reagent.

The reaction vessel may further include a cap which is coupled through an upper end opening of the reaction vessel and extends downward toward the inside of the reaction vessel so that the DNA chip is fixed to the lower end of the rod.

The module for polymerase chain reaction (PCR) comprises: a mounting block having a plurality of mounting holes for receiving the reaction container; a heating plate installed on one side of the mounting block for applying heat to the reaction container; And a heat sink for discharging the heat to the outside.

The quantitative analysis means and the qualitative analysis means of the optical detection unit respectively include first and second light source modules for providing light to the reaction vessel, a fluorescence detection means for detecting a fluorescence signal generated in the reaction vessel, Wherein the quantitative analysis means includes a first optical fiber for providing the light provided from the first light source module to the reaction container and transmitting the generated fluorescence signal to the first camera module, And the qualitative analysis unit is connected to a second optical fiber for providing the light provided from the second light source module to the reaction container and transmitting the generated fluorescence signal to the second camera module, The provision of light through each of the second optical fibers and the transmission of the fluorescent signal may be performed sequentially for one reaction container.

In the mounting block of the polymerase chain reaction (PCR) module in which the reaction container mounting hole is mounted, the end portion of the first optical fiber is connected to the reaction container And the end of the second optical fiber may be connected to the reaction vessel through an optical fiber fixing unit located on the lower surface of the reaction vessel mounting hole.

That is, the end of the first optical fiber may be located on the side of the reaction vessel, and the end of the second optical fiber may be located on the bottom of the reaction vessel.

A first optical fiber end fixing unit having an end fixed to an end of the first optical fiber and a second optical fiber end fixing unit having an end fixed to the end of the second optical fiber are spaced apart from each other in a horizontal direction, The second fiber end fixture may be sequentially positioned below the reaction vessel mounting hole of the PCR block by moving in the horizontal direction.

Also, by moving the PCR block, the first optical fiber end fixing part and the second optical fiber end fixing part can be sequentially positioned below the reaction container mounting hole.

According to the present invention, a series of processes such as nucleic acid extraction, nucleic acid amplification, and nucleic acid detection can be automatically and continuously performed using an automation apparatus.

In addition, according to the present invention, it is possible to perform quantitative analysis and qualitative analysis in a single reaction vessel. By obtaining a PCR reaction and a DNA chip signal in real time in a reaction vessel, somatic mutation, single base mutation Quantitative analysis and qualitative analysis can be carried out simultaneously and economically and reliably in various molecular diagnostic fields such as the human body.

1 is a process diagram showing an automated process by a molecular diagnostic automatic analyzer according to the present invention.
2 is a perspective view showing a molecular diagnostic automatic analyzing apparatus according to the present invention.
3 is a front view showing a molecular diagnostic automatic analyzing apparatus according to the present invention.
4 is a plan view showing a molecular diagnostic automatic analyzing apparatus according to the present invention.
5 is a side view showing a molecular diagnostic automatic analyzing apparatus according to the present invention.
FIG. 6 is an operational view for explaining a method of moving magnetic beads B using a magnet and a protector in a molecular diagnostic automatic analyzer according to the present invention.
FIG. 7 is a view for explaining a method in which a protector is mounted on a first guide in a molecular diagnostic automatic analyzing apparatus according to the present invention.
8 is a perspective view showing a cartridge of a molecular diagnostic automatic analysis apparatus according to the present invention.
9 is a perspective view showing a polymerase chain reaction module according to the present invention.
10 is a cross-sectional view showing an embodiment of a reaction vessel used in the molecular diagnostic automatic analyzer according to the present invention.
11 is a cross-sectional view showing another embodiment of the reaction vessel used in the molecular diagnostic automatic analyzer according to the present invention.
12 is a plan view showing an optical detector of a molecular diagnostic automatic analyzer according to the present invention.
13 is a front view showing an optical detector of the molecular diagnostic automatic analyzer according to the present invention.
14 is a perspective view showing an optical detector of the molecular diagnostic automatic analyzer according to the present invention.
15 is a view for explaining a configuration of an optical detector in a molecular diagnostic automatic analyzer according to the present invention.
16 is a view for explaining a first embodiment of a connection structure of a first optical fiber and a second optical fiber in a molecular diagnostic automatic analyzing apparatus according to the present invention.
17 is a view for explaining the second and third embodiments of the connection configuration of the first optical fiber and the second optical fiber in the molecular diagnostic automatic analyzing apparatus according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings so that those skilled in the art can easily carry out the present invention. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

In the drawings, the thickness is enlarged to clearly represent the layers and regions. In the drawings, for the convenience of explanation, the thicknesses of some layers and regions are exaggerated.

Hereinafter, the term "an upper (or lower)" or a "top (or lower)" of the substrate means that any structure is disposed or arranged in any manner, as long as any structure is provided or disposed in contact with the upper surface But is not limited to not including other configurations between the substrate and any structure provided or disposed on (or under) the substrate.

Hereinafter, a molecular diagnostic automatic analyzing apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

According to an aspect of the present invention, a moving plate 130, a magnetic bead transferring part 200, and an optical detecting part, to which a container mounting part capable of accommodating containers to be analyzed can be housed and a polymerase chain reaction module are combined, And a molecular diagnostic automatic analyzing apparatus for automatically performing the extraction and quantitative and qualitative analysis of the substance to be analyzed by a series of processes.

2 to 5 are schematic views of a molecular diagnostic automatic analyzing apparatus according to the present invention. The apparatus largely includes a frame 100, a moving plate 130, a magnetic bead conveyance unit 200, and an optical detection unit.

The frame 100 constitutes the body of the molecular diagnostic automatic analyzer and includes a top frame 110 constituting the base and a supporting frame (not shown) supporting the top frame 110. The upper plate 110 has a substantially rectangular plate shape and is fixedly supported on the support frame.

The moving plate 130 is mounted movably in a horizontal direction with respect to the upper plate 110. The moving plate 130 includes a container mounting portion 131 composed of a plurality of container receiving holes so that the cartridge 500 can be inserted therein And moves the position of the cartridge 500 and the reaction container 610 mounted on the container mounting portion 131. [

Specifically, the cartridge 500 includes a first container 521 for separating the nucleic acid through cell crushing and binding the magnetic beads B, and a second container 521 for removing the nucleic acid other than the nucleic acid bound to the magnetic beads B. A container portion 520 including at least one second container 522 and a second container 522 inserted into each of the first and second containers 521 and 522 so that the magnetic beads B are inserted directly into a magnet 210 The protector 220 may be integrally coupled to the protector storage container 510 so that the protector 220 is not coupled to the protector 220.

The transfer plate 130 also has a through hole 132 through which the mounting block 630 of the polymerase chain reaction (PCR) module 600 can be coupled. The module may contain a reaction vessel 610 that is simultaneously subjected to an elution process and a nucleic acid amplification process.

The PCR module 600 is integrally coupled to the moving plate 130 in such a manner that the mounting block 630 is disposed in the through hole 132 and is transported together with the moving plate 130. The moving plate 130 is configured to guide the slide movement by the position varying means 140.

The mounting block 630 is formed with a reaction container mounting hole 631 through which the reaction container 610 can be received. Therefore, the moving plate 130 is provided with a container mounting portion 131 composed of a plurality of container holding holes and a mounting hole 631 in which the reaction container 131 is accommodated.

The container accommodating portion 131 is formed by arranging a plurality of container accommodating holes in rows and columns in a line in a row and a row direction. The container accommodating holes formed along the moving direction of the moving plate 130 (X direction) And corresponds to the cartridge 500.

Thus, the container mounting portion 131 is provided with a plurality of cartridges 500 (Y direction), and a rear side of each of the cartridges 500 is equipped with a corresponding reaction container mounting hole 631 are formed. Accordingly, the molecular diagnostic automatic analyzing apparatus according to the present invention can simultaneously analyze a plurality of bio samples.

The container accommodating portion 131 is formed by arranging a plurality of container accommodating holes in rows and columns in a line in a row and a row direction. The container accommodating holes formed along the moving direction of the moving plate 130 (X direction) And corresponds to the cartridge 500.

Thus, the container mounting portion 131 is provided with a plurality of cartridges 500 (Y direction), and a rear side of each of the cartridges 500 is equipped with a corresponding reaction container mounting hole 631 are provided so that a plurality of bio-samples can be simultaneously analyzed.

The container holding holes of the container mounting portion 131 corresponding to one cartridge 500 are formed along the direction of movement of the moving plate 130 by the protective container 510, the first container 521, The protector storage container 510, the first container 521 and the second container 522 can be separately mounted, and the protector storage container 510, the first container 521, And the second container 522 are integrally joined in a line.

The moving plate 130 slides in a state in which the cartridge 500 and the reaction container 610 are accommodated and the stop positions of the cartridge 500 and the reaction container 610 between the respective processes are set in advance, As shown in FIG.

Here, the structure of the position varying means 140 is a common technique such as a rail or an LM guide, and a step motor or the like is used together.

The magnetic bead transferring part 200 is formed by combining the magnetic beads B and the magnetic beads B between the first and second containers and the reaction container in the cartridge 500 using the magnet 210 and the protector 220 And is configured to move the nucleic acid.

FIG. 6 illustrates an operation principle of extracting and transporting nucleic acid using a magnet and a protector in the automatic diagnostic apparatus for molecular diagnostics according to an embodiment of the present invention.

6 (a), the cell is pulverized while agitating in a first container 521 having a cell grinding reagent, a magnetic bead (B) and a bio sample, (521). Therefore, even if the protector 220 is first drawn into the first container 521 in this state, the magnetic bead B does not stick to the protector 220.

6 (b), when the magnet 210 is drawn into the protector 220 that is drawn into the first container 521 after the cell crushing process is completed, the magnetic force of the magnet 210 is combined with the nucleic acid The magnetic beads B stick to the outer surface of the protector 220.

 In this state, when the protector 220 and the magnet 210 are pulled together to the outside of the first container 521, the magnetic beads B combined with the nucleic acid are attached to the outer surface of the protector 220 and are pulled out together.

The protector 220 and the magnet 210 in this state are drawn into the second container 522 and the magnetic beads B combined with the nucleic acid are transferred to the second container 522. At this time, when the magnet 210 is pulled out, the magnetic beads B bonded to the nucleic acid attached to the protector 220 are dispersed into the cleaning buffer in the second container 522, and then the protector 220 is drawn out The magnetic beads B bound to the nucleic acid remain in the second container 522 and are not drawn out.

The protector 220 can transfer the magnetic beads B coupled with the nucleic acid between the containers together with the magnets 210 while preventing the magnetic beads B from being directly attached to the magnets 210. [

The nucleic acid bound to the magnetic beads B, that is, the magnetic beads B and the magnetic beads B bonded to the nucleic acid by this principle is transferred from the first container 521 to the second container 522, 522, and from the second vessel 522 to the reaction vessel 610.

The magnetic bead transfer unit 200 includes a magnet 210, a first guide 311 having a receiving hole to which the protector 220 is detachably mounted, And a second guide 312 positioned above the first magnet 311 and having the magnet 210 fixed thereon.

The magnet 210 is aligned corresponding to a position where the magnet 210 can be inserted into the protector 220 at the time of descent. The first and second guides 311 and 312 can be independently provided at positions fixed in the horizontal direction with respect to the frame and the elevating operation unit 300 can control the elevation of the first and second guides 311 and 312 do.

According to an aspect of the present invention, the protector 220 is provided in a state of being housed in a protector storage container 510 included in the cartridge 500 or a separately formed protector storage container 510, Is inserted into the receiving hole of the container mounting portion 131 of the moving plate 130 and is stood.

The first guide 311 is lowered at a position aligned with the upper portion of the protector storage container 510 and is used after the protector 220 is coupled to the first guide 311 through the protector coupling portion 314.

When the analysis of the injected bio sample is completed, the protector 220 is separated from the second guide 311, and a new protector 220 is used for the new bio sample.

The magnet 210 is fixed to the second guide 312. The movement of the magnet 210 can be controlled in such a manner that the second guide 312 is lifted and lowered by the lifting operation portion 300 so that the magnet 210 is drawn into or pulled out of each container of the container portion 520 of the cartridge 500 .

The magnet 210 is rotated by a protector (not shown) that receives the magnet 210 so that the magnetic bead B is not directly coupled to the magnet 210 220, respectively.

The protector 220 is in the shape of a hollow cylinder with its lower end closed and the magnet 210 has a bar shape having a magnetism capable of being inserted into the hollow of the protector 220.

The first guide 311 is provided with a receiving hole 311a through which the upper end of the protector 220 can be inserted and fixed. A plurality of receiving holes 311a are formed along the longitudinal direction (Y direction) of the first guide 311 and are arranged in line in the upper part of the respective container accommodating holes of the container mounting portion 131 and the respective reaction container mounting holes 631 And can be located in an aligned position. Therefore, when the protector 220 is mounted on the receiving hole 311a, the protector 220 can be positioned above each container to be inserted into each of the containers.

7, a magnet 313 is provided around the inner circumferential surface of the receiving hole 311a of the first guide 311, and a magnet 323 provided on the inner circumferential surface of the receiving hole 311a is formed on the outer circumferential surface of the upper end of the protector 220. [ A coupling portion 314 composed of a magnetic body coupled to the coupling portion 313 is formed. The coupling portion 314 may be formed of a thin steel plate or the like which surrounds the upper end of the protector 220.

When the upper end of the protector 220 is received in the receiving hole 311a at a position where the first guide 311 is lowered at a position aligned with the upper portion of the protector storage container 510, The protector 220 is coupled to the first guide 311.

At least the upper end of the protector 220 accommodated in the protector storage container 510 is exposed to the outside of the protector storage container 510 so that the protector 220 can be easily and effectively attached to the accommodation hole 311a.

While the above-described form is preferred, the manner in which the protector 220 is provided and coupled to the first guide 311 is variable.

The magnet 210 may be inserted into the hollow of the protector 220 on the upper portion of the first guide 311. The magnet 210 may be inserted into the hollow of the protector 220, (312).

The elevating operation part 300 is provided for elevating and lowering the first and second guides 311 and 312 so that the first and second guides 311 and 312 can be raised and lowered on the frame 100 And a driving unit 302 for providing a vertical force to the first and second guides 311 and 312. Since the lifting operation part 300 is used in an automation system, detailed description is omitted.

The automatic analyzer for molecular diagnostics according to the present invention is characterized in that the protector 220 and the magnet 210 are moved in the vertical direction with the first guide 311 and the second guide 312 being stationary, (521) and the nucleic acid to which the magnetic beads (B) bind from the second container (522).

That is, when the container 520 and the reaction container 610 move to the predetermined stop position between the processes by the moving plate 130, the result of the lysis process is extracted from the first container 521, 522, and the result of the cleaning process is extracted from the second vessel 522 and received in the reaction vessel 610.

8 shows a cartridge 500. The cartridge 500 includes a container 520 in which a first container 521 and at least one second container 522 are continuously arranged and coupled, The protector storage container 510 is formed integrally with the protector storage container 510. The protector storage container 510 may be formed separately from the container portion 520, and in this case, the cartridge 500 may be made of only the container portion 520.

Cell packing reagents and magnetic beads (B) are stored in the first container (521) of the container part (520). The magnetic bead (B) is preferably a hydrophilic magnetic bead. When the biosample is injected, the nucleic acid is separated from the bio sample through cell crushing, and the nucleic acid and the magnetic bead (B) are combined.

The cleaning vessel is stored in the second vessels 522 and the magnetic beads B bonded to the nucleic acid are transferred to the second vessel 522 to perform cleaning to remove the biomaterial other than the nucleic acid bound to the magnetic beads B. [ . It is preferable that a plurality of second containers 522 are provided to increase the purity of the nucleic acid.

FIG. 9 shows a module 600 for PCR of the molecular diagnostic automatic analyzer according to the present invention.

9, the PCR module 600 includes a mounting block 630 in which a plurality of reaction container mounting holes 631 are formed in which the reaction container 610 can be housed, And a heating plate 620 installed on one side of the mounting block 630 and applying heat to the reaction container 610 for nucleic acid amplification.

The heating plate 620 is most preferably but not limited to a Peltier element that is easy to respond instantaneously to changes in temperature. For example, it is possible to apply any device that can respond instantaneously as needed when heating or cooling is required.

The PCR module 600 includes a heat sink 650 for discharging the heat generated in one side of the heating plate 620 to the outside, And further includes a blowing fan 660 for cooling.

2 and 3 (only the PCR module for one side is shown and the other PCR module is omitted for the sake of convenience in FIG. 2 and FIG. 3), the module 600 for the PCR (PCR) And the mounting block 630 is disposed in the through hole 132 of the moving plate 130 and is coupled to the moving plate 130. The polymerase chain reaction (PCR) module 600 is transferred along with the transfer plate 130 in the X direction.

FIG. 10 shows a reaction vessel used in a molecular diagnostic automatic analyzer according to an embodiment of the present invention.

The reaction vessel 610 is provided with an amplification reagent for allowing nucleic acid elution and amplification to take place in the same reaction vessel without liquid handling and is capable of suppressing the evaporation of the amplification reagent on the surface of the amplification reagent, An oil layer C for further removal can be formed.

When the oil layer (C) is formed in the reaction vessel in which the oil layer (C) is formed, hydrophilic magnetic beads are used for the magnetic beads (B). The oil layer C serves to prevent the evaporation of the amplification reagent and the like, and can prevent the material from being injected into the anti-container 620 in addition to the hydrophilic magnetic beads combined with the nucleic acid.

A DNA chip 624 on which a probe of a target nucleic acid is immobilized is provided on an inner flat bottom surface of the reaction vessel 610. The reaction vessel 610 is formed of an at least partially transparent material so that fluorescence signal can be detected.

Meanwhile, FIG. 11 illustrates a reaction vessel used in the automatic diagnostic apparatus for molecular diagnostics according to another embodiment of the present invention.

The reaction vessel 610 'is equipped with a cap 620', in which the amplification reagent is stored so that elution and amplification of the nucleic acid can take place in the same reaction vessel without liquid handling. The cap 620 'is coupled through the reaction vessel top opening.

The cap 620 'includes a head 621', a tube coupling portion 622 'protruding from the lower side of the head 621', a rod 623 'extending downward from the tube coupling portion 622' And a DNA chip 624 'to which a probe of a target nucleic acid is fixed at the end of the rod 623'. The reaction vessel 610 ', including the cap 620', is formed of an at least partially transparent material to enable fluorescence signal detection.

The molecular diagnostic automatic analyzing apparatus according to the present invention further includes a cap mounting portion for coupling the cap 620 'through the upper opening of the reaction container 610' when the reaction container 610 'shown in FIG. 11 is used .

The mounting portion of the cap 620 'is fixed to the top plate 110 of the frame 100 at a position spaced apart from the first and second guides 311 and 312 and includes a cap guide detachably mounted, . The cap guide is adjusted by the cap guide lifting means.

The cap guide may be formed in the same manner as the first guide 311. The cap guide elevating means can be configured similar to the elevating operating portion of the magnetic bead transferring portion. At this time, the cap storage container mounting portion on which the cap storage container for housing the cap 620 'is mounted may be provided on the moving plate 130, and the cap storage container may be formed integrally with the cartridge.

The cap guide operates after the movable plate 130 and the magnetic bead transfer unit 200 are operated and the magnetic beads B coupled with the nucleic acid are transferred into the reaction vessel 620 '. That is, when the magnetic beads B coupled with the nucleic acid are transferred to the reaction vessel 620 ', the moving plate 130 operates to move the reaction vessel 620' to the lower portion of the cap mounting position of the cap mounting portion, And the cap 620 'is coupled to the reaction vessel 610'.

Hereinafter, an example of a probe system provided for generating a fluorescence signal in the reaction vessels 610 and 610 'will be described.

The present invention can simultaneously perform quantitative analysis of reaction products amplified by polymerase chain reaction (PCR) in a specific reaction vessel and qualitative analysis of the reaction products from a biochip to which a probe of a target gene is immobilized.

Specifically, a target probe-reporter probe connector is provided in the reaction vessel, and the DNA chip is planted with a target nucleic acid having a different sequence in a different region, and a capture probe is connected to the end of the target nucleic acid sequence. The target probe-reporter probe link is provided in an amplification reagent.

The probe of the target nucleic acid sequence may comprise at least one substance selected from a peptide, a protein, a nucleic acid, a PNA (peptide nucleic acid), an Aptamer and an antibody.

The target probe comprises a sequence complementary to the target nucleic acid sequence to be detected and the reporter probe is linked to the end of the target probe and comprises a sequence that is non-complementary to the target nucleic acid sequence that is detected. Therefore, when the amplification and hybridization reaction is started, the amplification primer and the target probe are respectively bound to the complementary sequence region of the target nucleic acid.

An extension reaction is started from the amplification primer and the target probe hybridized by a polymerase having nuclease activity is cleaved. The first fluorescence end emitted while the target probe is cut away is spaced apart from the second quencher, thereby generating the first fluorescence signal.

The polymerase having the nuclease activity cleaves all the target probes and releases them. As a result, the reporter probes hanging at the ends of the target probes are also released into the reaction solution.

The released reporter probe is hybridized to the complementary sequence region of the capture probe contained in the DNA chip. Hybridized reporter probes act as primers and initiate extension reactions.

The extended strand of the reporter probe loosens the structure of the capture probe to separate the second fluorescence end contained in the capture probe and the second extinction agent to generate a second fluorescence signal. Here, it is preferable that the first and second fluorescent signals have different wavelengths.

The first fluorescence signal can be detected and the quantitative analysis becomes possible, and the second fluorescence signal can be detected and qualitative analysis becomes possible.

However, the molecular diagnostic automatic analyzing apparatus according to the present invention is not limited by the reaction vessel and the probe system of the above-described embodiments, and the DNA chip is contained in the reaction vessel. When providing the light source, the first and second fluorescence signals for quantitative analysis Various reaction vessels having a probe system designed to express the second fluorescence signal respectively in qualitative analysis can be used.

A molecular diagnostic automatic analyzing apparatus according to the present invention comprises quantitative analysis means (410) for detecting a fluorescence signal generated from a nucleic acid-amplified biosample sample in real time, and a sample analyzer And a qualitative analysis unit 420 for detecting a fluorescence signal generated by hybridization with the target nucleic acid and performing qualitative analysis. The optical detection unit enables quantitative analysis and qualitative analysis in the same reaction vessel without liquid handling.

12 to 14 illustrate the positional relationship between the optical detector and the PCR module according to an embodiment of the present invention.

12 to 14 show the structure in which the optical detecting unit is located on the front surface of the PCR module, but the present invention is not limited thereto.

The optical detection unit including the quantitative analysis unit and the qualitative analysis unit can be located at the upper part, the upper part, the lower part and the lower part of the extraction driver and the PCR module. desirable.

As described above, the optical fibers communicating with the reaction vessel mounting hole 631 are placed on the side of the CDC camera module 419, and a laser module for irradiating light of a specific wavelength is provided to analyze a sample passed through the PCR module have.

Details of quantitative analysis and qualitative analysis through the optical detection unit will be described with reference to FIG.

First, the configuration of the quantitative analysis means 410 and the qualitative analysis means 420 will be described.

The quantitative analysis unit 410 includes a first light source module 411, a first expander module lens 412, a first EX filter 413 and a first EM filter 417, a first imaging lens 418, And a camera module 419.

The first light source module 411 is used to irradiate light of a specific wavelength into the reaction vessel 610, and the quantitative analysis unit 410 may use an LED light source.

The first expander module lens 412 may include a plurality of lenses for concentrating, parallelizing, and uniformizing the light provided by the first light source module 411. The first EX filter 413 serves to filter light so that light of a specific wavelength is provided to the reaction vessel

The first EM filter 417 transmits a fluorescence signal of a specific wavelength for filtering the fluorescence signal emitted from the fluorescent material inside the reaction vessel and the first imaging lens 418 transmits the fluorescence signal of the specific wavelength from the first EM filter 417 And forms an image of an incoming fluorescent signal on the first camera module. The first camera module detects a fluorescent signal and converts the digital signal for image processing.

The quantitative analysis means 410 detects fluorescence signals of a specific wavelength amplified in proportion to the amplification of the nucleic acid in real time and enables quantitative analysis.

The qualitative analysis unit 420 includes a second light source module 421, a second expander module lens 422, a second EX filter 423 and a second EM filter 427, a second imaging lens 428, And a second camera module 429.

The qualitative analyzing means 420 uses a laser module for irradiating light of a specific wavelength as the second light source module 421 and a second expander module lens 422, a second EX filter 423, a second EM filter 427, the second imaging lens 428 and the second camera module 429 are connected to the first expander module lens 412, the first EX filter 413 and the first EM filter 417 of the quantitative analysis means 410, The first imaging lens 418 and the first camera module 419 are the same.

As the first and second camera modules, a CCD camera module, a CMOS camera module, and the like may be used, but the present invention is not limited thereto.

According to an aspect of the present invention, the quantitative analysis unit 410 and the qualitative analysis unit 420 are paths for providing the light irradiated from the light source modules 411 and 421 to the reaction container 610, respectively, Respectively, and optical fibers 415 and 425 connected to collect the reflected fluorescence signals and pass them to the camera module.

The optical fiber connected to the quantitative analysis means 410 is referred to as a first optical fiber 415 and the optical fiber connected to the qualitative analysis means 425 is referred to as a second optical fiber 425. [

The first optical fiber 415 and the second optical fiber 425 receive the fluorescence signal reflected from the reaction vessel and the optical fiber strand provided to the reaction container 610 by the light provided from the respective light source modules 411 and 421, And the optical fiber strand in which the light provided in the light source module is provided to the reaction container is connected between the first and second EX filters 413 and 423 and the reaction container 610, ) Are connected between the first and second EM filters 417 and 427 and the reaction vessel 610. The first and second EM filters 417 and 427 are used to collect the fluorescence signal.

The quantitative analysis means 410 and the qualitative analysis means 420 in the molecular diagnostic automatic analyzing apparatus according to an aspect of the present invention may include a plurality of first optical fibers 415 corresponding to each of the plurality of reaction vessels 610, (425).

For example, in the case of a plurality of reaction vessels mounted on the moving plate 130, the first optical fiber 415 is disposed corresponding to each reaction vessel. Quantitative analysis of a plurality of reaction vessels 610 is performed by one quantitative analysis means 410 by successively providing light to a plurality of reaction vessels 610 through respective first optical fibers 415 and detecting fluorescence signals. As shown in FIG.

The qualitative analysis means 420 can also perform qualitative analysis on a plurality of reaction vessels 610 with one quantitative analysis means 410 on the same principle.

Hereinafter, the optical connection structure of the quantitative analysis means 410 and the qualitative analysis means 420 and the reaction vessel will be described.

16 shows an example of the optical connection configuration of the optical detector according to the first embodiment in the molecular diagnostic automatic analyzing apparatus according to the present invention.

16 shows a configuration in which a first optical fiber 415 and a second optical fiber 425 are fixedly connected to a polymerase chain reaction (PCR) module 600.

The first light source module 411 of the quantitative analysis means 410 provides the light to the reaction container 610 and the fluorescent light signal reflected from the reaction container 610 to the first camera module 419 The end of the first optical fiber 415 is disposed on the side of the reaction vessel 610.

To this end, an optical fiber mounting plate 640 is coupled to the mounting block 630 of the polymerase chain reaction (PCR) module 600 opposite to the mounting position of the heating plate 620, and the mounting block 630 The insertion hole 642 into which the first optical fiber 415 is inserted is formed at a side position of the reaction container mounting hole 631 of the first optical fiber 415. The insertion hole 642 extends to the mounting block 630 and communicates with the reaction container mounting hole 631. The end of the first optical fiber 415 is located on the side of the reaction vessel 610 and the light provided from the first light source module 415 is provided to the reaction vessel 610 and the fluorescent signal is transmitted to the first camera module 419 It is possible to provide.

An optical fiber fixing portion 632 is formed on the bottom surface of the reaction container mounting hole 631 of the polymerase chain reaction (PCR) module 600 to support the end of the second optical fiber 425, And the end portion is disposed on the lower surface of the reaction vessel 610. The end of the second optical fiber 425 is positioned on the lower surface of the reaction vessel 610 and the light provided from the second light source module 425 is supplied to the reaction vessel 610 and the fluorescent signal is transmitted to the second camera module 419 It is possible to provide.

The first optical fiber 415 and the second optical fiber 425 of the quantitative analysis unit 410 and the qualitative analysis unit 420 are integrally connected to the polymerase chain reaction (PCR) module 600, Qualitative analysis can be performed.

17 is a view for explaining an optical connection configuration according to another embodiment of the optical detector in the molecular diagnostic automatic analyzer according to the present invention. The same reference numerals are used for components having the same functions as those of the example shown in Fig.

17A, the optical detecting section according to the second embodiment differs from the optical detecting section according to the first embodiment in that the ends of the first optical fiber 415 and the ends of the second optical fiber 425 are spaced apart from each other Respectively. The end of the first optical fiber 415 is fixed to the first optical fiber end fixing part 634a and the end of the second optical fiber 425 is fixed to the second optical fiber end fixing part 634b.

The reaction vessel 610 is moved to a position above the first and second optical fiber end fixing portions 634a and 634b while the module 600 for the PCR reaction is moved by the moving plate 130. [ Quantitative analysis is performed while the reaction vessel 610 is positioned above the first optical fiber end fixing part 634a and then the module 600 for PCR is moved by the moving plate 130, Qualitative analysis can be performed while the reaction vessel 610 is positioned above the optical fiber end fixing portion 634b.

17 (b), the optical detecting portion according to the third embodiment has an end portion of the first optical fiber 415 and an end portion of the second optical fiber 425, as in the optical detecting portion of the second embodiment, The end of the first optical fiber 415 is fixed to the first optical fiber end fixing portion 634a and the end of the second optical fiber 425 is fixed to the second optical fiber end fixing portion 634b do.

However, unlike the optical detector of the second embodiment, the PCR module 600 is stopped at a predetermined position during quantitative and qualitative analysis, and the first and second optical fiber end fixing parts 634a and 634b And moves to the lower part of the reaction vessel 610. [ The first and second optical fiber end fixing portions 634a and 634b move in a state where the moving plate 130 is stopped, that is, the positional movement of the PCR module 600 is stopped, The quantitative analysis unit 410 and the qualitative analysis unit 420 perform quantitative analysis and qualitative analysis. The optical detector according to the third embodiment includes position adjusting means (not shown) for horizontally moving the first and second optical fiber end fixing portions 634a and 634b at a lower position of the polymerase chain reaction (PCR) ).

The optical connection between the optical detector and the PCR module 600 using the optical fiber can provide a flexible mechanism for providing the optical signal and detecting the fluorescence signal.

Hereinafter, the operation of the molecular diagnostic automatic analyzer according to the present invention will be described.

Referring to FIG. 1, the molecular diagnostic automatic analyzing apparatus according to the present invention performs molecular diagnosis while automatically performing a lysis process, a washing process, an elution and amplification process, and a detection process. The bio-sample injection process proceeds to the previous step. The detection process will be described by taking the optical detector according to the first embodiment as an example.

In the bio-sample injection step, the bio sample is injected into the first container 521 of the cartridge 500 in which the cell grinding reagent and the magnetic beads B are stored. Such a bio-sample injection process may be performed by the experimenter himself or by using a separate automated apparatus.

The cartridge 500 in which the bio sample is injected is mounted on the container mounting portion 131 of the moving plate 130 and the molecular diagnostic automatic analyzer operates to automatically perform the subsequent process. At this time, the protector 220 is accommodated in the protector storage container 510 in the cartridge 500, and the cleaning buffer is accommodated in the second container 521. The reaction vessel mounting hole 631 is equipped with a reaction vessel 610 into which an amplification reagent for elution and amplification is injected.

When the molecular diagnostic automatic analyzing apparatus is operated, the moving plate 130 is slid by the position changing means 140. At this time, the position of the protector 220 accommodated in the cartridge 500 is adjusted so as to be aligned under the first guide 311. The first guide 311 is lowered so that the upper end of the protector 220 is inserted into the receiving hole 311a and the protector 220 is inserted into the receiving hole 311a through the magnetic force, Respectively. In this state, the first guide 311 is lifted and the protector 220 is pulled out from the cartridge 500.

At this time, a lysis process is performed in the first container 521, and the nucleic acid is separated from the bio sample through the cell crushing, and the nucleic acid binds to the magnetic bead (B).

Next, the moving plate 130 is moved to adjust the position so that the first container 521 is aligned with the lower portion of the protector 220 of the first guide 311. The protector 220 is inserted into the first container 521 while the first guide 311 is lowered and the second guide 312 is lowered so that the inside of the protector 220 inserted into the first container 521 The magnet 210 is inserted.

The magnetic beads B bonded to the nucleic acid in the first container 521 are attached to the outer surface of the protector 200. [ The first and second guides 311 and 312 rise simultaneously and the magnetic beads B bonded to the nucleic acid are transferred to the outside of the first container 521 while maintaining the state of the magnet 210 in the protector 220. [ .

Thereafter, the moving plate 130 is moved to adjust the position of the second container 522 so as to be aligned with the lower portion of the protector 220, and the first and second guides 311 and 312 simultaneously descend to form the second container 522 The protector 220 and the magnet 210 coupled thereto are inserted. Then, when the second guide 312 is lifted and separated from the protector 220, the magnetic beads B coupled with the nucleic acid attached to the protector 220 are dispersed in the cleaning buffer in the second container 522, The first container 311 is operated to draw the protector 220 out of the second container 522.

In the second vessel 521, a cleaning process is performed. In the second container 522, a biomaterial other than the nucleic acid bound to the magnetic beads B is separated from the magnetic beads B. In particular, it is preferable to provide a plurality of second containers 522 in order to increase the purity of the nucleic acid.

That is, a plurality of the second vessels 522 are constructed and the washing process is performed stepwise several times. The magnetic beads B bonded to the nucleic acid from the first container 521 to the second container 522 may be transferred from the second container 522 to the second container 522 in the same process as the process, The magnetic beads B bonded to the nucleic acid are transported to the second container 522 located at the bottom of the container.

Next, nucleic acid-bound magnetic beads B having been subjected to the washing process are transferred from the second container 522 to the reaction container 610 of the polymerase chain reaction (PCR) module 600 in which the amplification reagent is stored . The transfer process of the magnetic beads is as described above.

In the reaction vessel 610, the nucleic acid is eluted to separate the magnetic beads (B) from the nucleic acid, and the polymerase chain reaction (PCR) module 600 is controlled to perform nucleic acid amplification while controlling the temperature. At this time, the quantitative analysis unit 410 detects the fluorescence signal of a specific wavelength generated from the nucleic acid to be amplified in real time using the first optical fiber 415.

The nucleic acid amplified by the qualitative analysis means 420 is then hybridized with a probe of a target nucleic acid immobilized on the DNA chip using the second optical fiber 425 to detect a fluorescence signal of a specific wavelength.

The molecular diagnostic automatic analyzing apparatus according to the present invention can be used for analyzing the reaction products amplified by using the real time PCR reaction in one reaction container 610 by using the optical detection unit including the quantitative analysis unit 410 and the qualitative analysis unit 420 Qualitative analysis and qualitative analysis of the reaction product can be performed simultaneously from a DNA chip on which a probe of a target gene is immobilized.

Accordingly, a series of processes such as nucleic acid extraction, nucleic acid amplification, and nucleic acid detection can be automatically and continuously performed using an automated apparatus, and quantitative and qualitative analysis can be performed economically in various molecular diagnostic areas.

While the present invention has been particularly shown and described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is therefore to be understood that such changes and modifications are intended to be included within the scope of the present invention unless they depart from the scope of the present invention.

100: frame
110: top plate
130: moving plate, 131: container mounting portion, 132: through hole
140: position variable means
200: magnetic bead transfer part, 210: magnet, 220: protector
300: elevating operation part, 311: first guide, 312: second guide, 311a: receiving hole, 313: magnet, 314:
500: Cartridge, 510: Protector storage container, 521: First container, 522: Second container
A module for polymerase chain reaction (PCR) 610 a reaction container 620 a heating plate 630 a mounting block 631 a reaction container mounting hole 640 an optical fiber mounting plate 650 a heat sink 660 a blowing fan

Claims (17)

frame;
A container mounting portion supported by the frame and capable of accommodating a plurality of containers,
A moving plate coupled with a module for polymerase chain reaction (PCR), including an applicator and a reaction vessel mounting hole;
A first guide supported by the frame and spaced apart from the upper portion of the moving plate and having a receiving hole into which a protector is removably mountable, a first guide disposed at an upper portion of the first guide and capable of being inserted into the protector A magnetic bead feeder including a second guide having a magnet fixed thereto; And
And an optical detection unit including quantitative analysis means and qualitative analysis means,
Wherein the receiving hole is provided with a magnet around an inner circumferential surface thereof,
Wherein the protector is mounted on the receiving hole by being magnetically coupled to the receiving hole by an engaging portion formed of a magnetic material provided on an outer circumferential surface of the protector,
Molecular diagnostic automatic analyzer.
The method according to claim 1,
Wherein the quantitative analysis means of the optical detection unit detects fluorescence signals generated from a sample sample to be amplified in a nucleic acid in real time and the qualitative analysis means detects fluorescence signals generated by hybridization with a target nucleic acid attached to the surface of the DNA chip, , ≪ / RTI >
The quantitative analysis and the qualitative analysis are performed on the same reaction vessel,
Molecular diagnostic automatic analyzer.
The method according to claim 1,
Wherein the moving plate is movable in the horizontal direction to the frame,
Wherein the first guide and the second guide are independently movable up and down at a position fixed in a horizontal direction with respect to the frame,
Molecular diagnostic automatic analyzer.
The method of claim 3,
As the first and second guides move up and down,
And a protector and a magnet that can be inserted into and withdrawn from the reaction container,
Molecular diagnostic automatic analyzer.
delete delete The method according to claim 1,
And a protector storage container provided with the protector can be mounted on the container mounting portion,
The first guide is lowered at a position where the receiving hole of the first guide corresponds to the protector,
Wherein a protruding portion of the protector is inserted into the receiving hole,
Molecular diagnostic automatic analyzer.
The method according to claim 1,
The container mounting portion includes:
A first container into which a bio sample is injected and which comprises a cell lysing reagent and a magnetic bead; And
And at least one second container receiving a wash buffer to wash nucleic acid bonded magnetic beads provided from the first container.
Molecular diagnostic automatic analyzer.
9. The method of claim 8,
Wherein the container mounting portion includes a protector container having a protector, a container having a first container and a second container,
Molecular diagnostic automatic analyzer.
The method according to claim 1,
The polymerase chain reaction (PCR)
A mounting block having a plurality of mounting holes for receiving the reaction container;
A heating plate installed on one side of the mounting block to apply heat to the reaction vessel; And
And a heat sink attached to the heating plate to discharge heat to the outside.
Molecular diagnostic automatic analyzer.
The method according to claim 1,
Wherein the reaction vessel is provided with a DNA chip on the inner bottom surface thereof and an oil layer is provided on the upper surface of the reagent,
Molecular diagnostic automatic analyzer.
The method according to claim 1,
In the reaction vessel,
Further comprising a cap which is coupled through an upper end opening of the reaction vessel and extends downward toward the inside of the reaction vessel and on which the DNA chip is fixed on the lower end of the rod,
Molecular diagnostic automatic analyzer.
The method according to claim 1,
The quantitative analysis means and the qualitative analysis means of the optical detection unit respectively include first and second light source modules for providing light to the reaction vessel, a fluorescence detection means for detecting a fluorescence signal generated in the reaction vessel, A first camera module and a second camera module,
Wherein the quantitative analysis means is connected to a first optical fiber for providing the light provided from the first light source module to the reaction container and for transmitting the generated fluorescence signal to the first camera module,
Wherein the qualitative analysis means is connected to a second optical fiber for providing the light provided from the second light source module to the reaction container and for transmitting the generated fluorescence signal to the second camera module,
Wherein the first optical fiber and the second optical fiber supply light and the fluorescence signal are sequentially transmitted to one reaction container,
Molecular diagnostic automatic analyzer.
14. The method of claim 13,
In a mounting block in which a reaction container mounting hole for mounting the reaction container of the polymerase chain reaction (PCR) module is formed,
The end of the first optical fiber is connected to the reaction vessel through an insertion hole penetrating the reaction vessel mounting hole on the other side opposite to the position of the heating plate installed on one side,
Wherein an end of the second optical fiber is connected to a reaction vessel through an optical fiber fixing unit located on a lower surface of the reaction vessel mounting hole,
Molecular diagnostic automatic analyzer.
15. The method of claim 14,
Wherein an end of the first optical fiber is located on a side surface of the reaction vessel,
And an end of the second optical fiber is positioned on a lower surface of the reaction vessel,
Molecular diagnostic automatic analyzer.
14. The method of claim 13,
A first optical fiber end fixing unit having an end fixed to an end of the first optical fiber and a second optical fiber end fixing unit having an end fixed to the end of the second optical fiber,
Wherein the first optical fiber end fixing part and the second optical fiber end fixing part move in the horizontal direction and are sequentially positioned below the reaction container mounting hole of the PCR block,
Molecular diagnostic automatic analyzer.
14. The method of claim 13,
A first optical fiber end fixing unit having an end fixed to an end of the first optical fiber and a second optical fiber end fixing unit having an end fixed to the end of the second optical fiber,
Wherein the first optical fiber end fixing part and the second optical fiber end fixing part are sequentially positioned below the reaction container mounting hole by moving the PCR block,
Molecular diagnostic automatic analyzer.

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