JPH10323177A - Device for extracting and purifying dna - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device for extracting and purifying a DNA, enabling to fully automatically and inexpensively extract and purify an extranuclear gene DNA (plasmid DNA) replicated and proliferated with transformants. SOLUTION: A divided injection unit 10 can horizontally be moved on a rail 19b with a moving device, the device 1 is provided with tube racks 11, 12 capable of being moved in horizontal and vertical directions. Filter tubes for extracting and purifying the DNA are arranged on the tube racks 11, 12. A waste liquid vat 44 and a recovering vat 47 are arranged below the tube racks 11, 12. Suction ports to be connected to a vacuum pump are arranged in the waste liquid vat 44 and the recovering vat 47.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to a method for producing D
The present invention relates to a DNA extraction and purification apparatus for extracting and purifying NA in a short time.

[0002]

2. Description of the Related Art Conventionally, as a method for extracting and purifying plasmid DNA (extranuclear gene) from a transformant transformed with Escherichia coli or the like, a boiling method [BOILING METHOD (Holmes, DS)] has been proposed.
And M. Quigley, 1981, Anal. Biochem. 114: 193)] and the alkaline lysis method [ALKALINE LYSIS METHOD (Birnboim,
HC and J. Doly, 1979, Nucleic Acids Res. 7: 151
3)] etc. are performed. However, these methods use dangerous reagents such as phenol and chloroform and are laborious.

Further, as a method of obtaining a purified sample of high purity, there is a method of extracting and purifying plasmid DNA by cesium chloride density gradient centrifugation. This method is typical of high-purity purification, but it takes a long time to carry out, and the number of sample treatments is about 10 at a time. In addition, equipment that automates the conventional method has been developed, but such equipment is generally expensive and has drawbacks such as a small number of processed samples, so there is no practical problem. Was.

[0004]

The transformation method is a basic technique for genetic manipulation and is indispensable for the research and development of life science or biotechnology. Therefore, the transformants obtained by this method (particularly,
E. coli, etc.) from extranuclear gene DNA
It has been desired to extract and purify, with high safety, in a short time and with high purity under high safety.

[0005] The present invention has been made in view of the above-mentioned problems, and provides a DNA capable of fully and inexpensively extracting and purifying extranuclear gene DNA (plasmid DNA) replicated and amplified by a transformant from an overnight culture. An object of the present invention is to provide an extraction and purification device.

[0006]

An object of the present invention is to provide a box-shaped first tube rack having an open top, forming a hole in the bottom of the first tube rack, and forming a first filter tube in the hole. And a box-shaped second tube rack having an open top is provided, a hole is formed in the bottom of the second tube rack, a second filter tube is inserted into the hole, and the first tube rack is inserted. A second tube rack on top of or a first tube rack on top of the second tube rack to form a vacuum chamber between the bottom of one tube rack and the bottom of the other tube rack Then, the decompression chamber is depressurized by a vacuum device, and the extract in the tube rack above the decompression chamber is
This is achieved by a DNA extraction / purification apparatus, wherein the DNA is collected in a filter tube of a tube rack on the lower side of the decompression chamber via the tube rack.

Another object of the present invention is to provide a box-shaped tube rack having an open top, forming a hole in the bottom of the tube rack, inserting a filter tube into the hole, and providing a waste liquid having an open top. A vat is provided, the tube rack is placed on the waste vat, a decompression chamber is formed between the bottom of the tube rack and the bottom of the waste vat, and the decompression chamber is depressurized by a vacuum device. A DNA characterized in that a drainage liquid in an upper tube rack is collected in a waste vat through the tube rack.
This is achieved by an extraction and purification device.

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, an embodiment of a DNA extraction / purification apparatus of the present invention will be described with reference to the drawings.

FIG. 1 is an overall view of a DNA extraction / purification apparatus 1 according to the present invention. This extraction and purification device 1 comprises a main body 2 and a wagon 3. The main body 2 is provided with a connection port 7 for connecting pipes to the operation panel 4, a door 5, a vacuum pressure gauge 6, and a wagon 3 on the front surface. A power switch 8 is provided on the side of the main body 2, and a power cord 9 is provided behind the power switch. Although not shown, the door 5 is provided with a door open / close detection switch.

FIG. 2 and FIG. 3 show the internal structure of the main body 2.
The main body 2 includes a dispensing unit 10 and a first tube rack 1
1, a second tube rack 12, a reservoir 13, and a tip stand 14. The dispensing unit 10 includes the main body 2
Can move laterally through the interior. To explain this mechanism, as shown in the plan view of FIG.
Has a ball nut 15a attached to the main bracket 10a and screwed to a ball screw 15b. When the motor 16 is driven, the ball screw 15b is rotated by the rotation of the belt 17, and the dispensing unit 10 is guided by the guide plates 18a,
It moves laterally along rails 19a and 19b attached to 18b.

The dispensing unit 10 has a height adjusting motor 20 mounted on a main bracket 10a. As shown in FIG. 5, a ball screw 21a is mounted on the shaft of the height adjusting motor 20, and a ball nut 2 integrally mounted on the sub-bracket 10b is mounted on the ball screw 21a.
1b is screwed. When the height adjusting motor 20 is driven, the dispensing section 22 attached to the sub-bracket 10b shown in FIG. 3 is lowered.

As shown in FIG. 5, in the dispensing unit 10, a ball screw 24a is mounted on a shaft of a dispensing motor 23, and a ball nut 24b integrally mounted on a piston mounting stay 25a is screwed to the ball screw 24a. I agree.
When the dispensing motor 23 is driven, the stay 25a moves up and down, and the piston shaft 26a of the six cylinders 26 also moves up and down accordingly. The cylinder 26 sucks and discharges a reagent for extracting and purifying DNA. Also, stay 25
a further lowers, the lower surface of the stay 25a becomes a rod 27a.
Hit the upper end of the The rod 27a is attached to a detaching plate 27c of the pipette tip 28. The detaching plate 27c pushes down the pipette tip 28, and the pipette tip 28 comes off.

At the side of the cylinder block 26c that supports the cylinder 26, six tube presence / absence confirmation sensors 29 for judging the presence / absence of a tube are mounted. The tube presence / absence confirmation sensor 29 uses a reflective photoelectric element. Further, as shown in FIG. 3, a liquid level sensor 30 is attached to one of the cylinders 26. This liquid level sensor 30
Detects a sudden change in air pressure during the discharging operation and determines the liquid level (see Japanese Patent Application Laid-Open No. Hei 5-232124).

As shown in FIG. 3, the first transfer device A transfers the first tube rack 11 in a vertical direction, and the tube rack 11 is detachably attached to the grip portion 32. The grip portion 32 is slidably fitted to the guide plate 33 and is screwed to a ball screw 34 extending parallel to the guide plate 33. When the drive motor 35 attached to the lower part of the guide plate 33 is driven, the grip part 32 moves up and down along the guide plate 33 integrally with the tube rack 11.

The second transfer device B includes a second tube rack 1
The tube rack 12 is detachably attached to the holding portion 37. The grip 37
It is slidably fitted to the guide plate 38 and is screwed into a ball screw 39 (see FIG. 2) extending parallel to the guide plate 38. Drive motor 40 attached to the lower part of guide plate 38
Is driven, the gripper 37 moves the guide plate 38 up and down.
The third transfer device C transfers the second tube rack 12 in the horizontal direction, and the guide plate 38 is slidably fitted on the slider plate 41. When the drive motor 42 disposed at the end of the slider plate 41 is driven, the guide plate 38 moves in the horizontal direction along the slider plate 41 by the transmission force of a belt (not shown).

As shown in FIG. 6, the first tube rack 1
The outer shapes of the first and second tube racks 12 are the same except for the positions of the handles 11a and 12a attached to the grips 32 and 37 described above. Therefore, the numbers and arrangement positions of the holes a and b formed on the bottoms thereof are the same, and when these are overlapped, the positions of the holes a and b coincide with each other in the vertical direction. As shown in FIGS. 7 and 8, rubber tubes 11b and 12b are attached to the bottoms of the tube racks 11 and 12, respectively. In addition, each tube rack 11, 12
Are provided with passages 11c and 12c. This passage 1
1c and 12c penetrate the inner walls from the bottoms of the rubber frames 11b and 12b and the tube racks 11 and 12.

As shown in FIG. 3, the first tube rack 1
A waste vat 44 is provided below 1. As shown in FIG. 7, a suction port 44a connected to a solenoid valve 50a via a waste water trap 46 of the wagon 3 is provided at the bottom of the waste liquid vat 44. Further, on the side of the waste liquid vat 44, suction ports 44b, 44c connected to the electromagnetic valves 50b, 50c, respectively, are provided. These solenoid valves 50a
-50c are connected to a vacuum pump 45 provided in the wagon 3.

As shown in FIG. 7, the DNA extraction apparatus 1 has a recovery vat 47 adjacent to the waste vat 44. The collection bat 47 is provided with a collection rack 48 provided with a hole c at the same position as the hole b of the second tube rack 12,
The collection tube 49 is accommodated in the hole c, and the lid of the collection tube 49 is accommodated in the hole d provided on the side of the hole c.
This collection tube 49 is placed in the tube rack 1
The location of the filter tube 54 in 2, that is, the location corresponding to the hole b, and the shape of the hole c are substantially the same as the shape of the collection tube 49. A suction port 47a connected to the solenoid valve 50d is provided at the bottom of the collection vat 47. The solenoid valve 50d is connected to the vacuum pump 45.
A magnetic sensor 47 electrically connected to a sequencer 60 (see FIG. 12) is provided at the bottom of the collection vat 47.
b, and a magnet 48 is provided at the bottom of the collection rack 48.
a is attached. These places are located in the collection rack 48.
Are arranged at one or a plurality of locations so as to correspond to when they are arranged at a predetermined location. The filter tubes 51 and 54 and the collection tube 49 provided in the tube racks 11 and 12 and the collection pad 47 in FIG.
Are arranged in a large number, but only one tube 49, 51, 54 is shown in the figure for simplicity.

As shown in FIG. 6, the first tube rack 1
At the bottom of 1, a large number of holes a are drilled as described above,
As shown in FIG. 8, the first filter tube 51 is inserted into this hole.
Is inserted. As shown in FIG. 9, the filter tube 51 includes a top 51a and a bottom 51b, and a lower portion of the bottom 51b is inserted through the hole a of the tube rack 11. The filter tube 51 is usually cylindrical and has a size of φ10 to 20 mm and a length of 30 to 5 mm.
It is desirable to use a thing of 0 mm.

A filter 52 is provided on the flange portion 51c of the first filter tube 51. FIG. 10 is a cross-sectional view of the filter 52. Trap filter 52a
Is a layer mainly for collecting and lysing cells such as Escherichia coli which is a transformant. The material is preferably a glass fiber filter, a polyethylene resin filter, a non-woven fabric filter, or the like, and preferably has a property of three-dimensionally collecting cells such as Escherichia coli.

The membrane filter 52b is a layer for mainly filtering and removing unnecessary substances such as coagulated proteins and chromosomal DNA. As the material, cellulose acetate, polyvinylidene fluoride, and the like are preferable, and it is preferable that the material has characteristics of being biologically inert and having low protein adsorption. The filter tube 5 is inserted into the hole a of the tube rack 11.
A portion where 1 is not provided is airtightly closed with a black blind plug.

FIG. 11 shows a filter 55 provided in the second filter tube 54 supported in the hole of the second tube rack 12. Second filter tube 5
4 is the same shape as the first filter tube 51,
Only the filter 55 is different. Glass fiber filter 55
a and 55b are layers mainly for assisting plasmid adsorption. The material is preferably a fine borosilicate glass fiber or the like, and preferably has characteristics of being inert to a biochemical liquid.

The glass powder layer 55c is mainly made of DN
A layer for A adsorption. As the material, a silica matrix or the like is preferable, and the sedimentation velocity in water is 0.25 cm / mi.
It is preferable to have characteristics of n or less. The function and material of the membrane filter 55d are the same as those of the first filter tube 51. Note that a portion where the filter tube 52 is not provided in the hole b of the tube rack 12 is airtightly closed with a black blind plug.

The sections 13a to 13a of the reservoir 13 shown in FIG.
3f is for injecting a reagent for extracting and purifying DNA and a washing solution. The details will be described later.

FIG. 12 is a system diagram of a DNA extraction / purification apparatus. A sequencer 60, which is a control unit, is electrically connected to the operation panel 4, the dispensing unit 10, and the vacuum transfer units D such as the tube racks 11, 12. Further, the vacuum transport section D is connected by a pipe to a drain trap 61 disposed on the wagon 3. Further, the vacuum transport section D and the vacuum pump 45 are connected by piping via a chemical trap 62.

The configuration of the apparatus for extracting and purifying DNA according to the embodiment of the present invention has been described above. Next, the operation of the apparatus will be described.

Before operating the DNA extraction / purification apparatus 1 in FIG. 1, the door 5 is opened and the first filter tube 5 is opened.
1, second filter tube 54, collection tube 49,
The reagent and the pipette tip 28 are set in a predetermined place. As a sample, a transformant culture was used in advance as shown in FIG.
Are collected in a filter tube 51 shown in FIG. This allows the host microorganism to be transformed into E. coli [E. Coli HB101 (ATCC 33
694), which is referred to as Hanahan's method (Hanahan, D.,
1983, J. Mol. Biol., 166, 577).

First, the power switch 8 of the DNA extraction / purification apparatus 1 is turned on. At this time, if the door 5 is properly closed, a door open / close detection switch (not shown) detects the door 5 and locks the door 5 with, for example, an interlock solenoid. Then, the dispensing unit 10, the first tube rack 11 and the second tube rack 12 are arranged at the initial positions shown in FIG. The arrangement of the tube racks 11 and 12 at this time is schematically shown in FIG. As shown in the figure, the tube racks 11 and 12 are moved to levels 0 to 3 by driving the transfer devices A and B described above.
(The levels are 0, 1, 2, and 3 in order from the lower scale.) Up and down movements are performed in four stages, and in the initial state, they are arranged at the height of level 2. The DNA extraction / purification device 1 releases the lock of the door 5 after the completion of the movement of the initial position.

The door 5 of the DNA extraction / purification apparatus 1 is opened, and the filter tubes 51 and 54, the collection tube 49 and the pipette tip 28 are arranged at predetermined positions as shown in FIG. After a predetermined reagent is injected into the compartments 13a to 13f of the reservoir 13, the door 5 is closed and a start key provided on the operation panel 4 is pressed.

When the start key is pressed, the DNA extraction / purification apparatus 1 checks the set state. That is, in the tube presence / absence confirmation operation, the tube racks 11 and 12 are arranged at the level 3 position as shown in FIG. Then, the dispensing unit 10 shown in FIG. 8 is reciprocated to the left and right in the horizontal direction.
Check for the presence of 1,54.

The contents of the check are the tube rack 1 shown in FIG.
In the case where the filter tubes 51 and 54 are inserted in the crosses 1 and 12, the set patterns of the filter tubes 51 and 54 in the tube racks 11 and 12 are the same, or the set pattern conforms to the rules of the apparatus. Make sure that In this case, the tube racks 11, 1
Since the holes a and b other than the crosses 2 are closed with black blind plugs, the difference in the color reflectance between the filter tubes 51 and 54 and the blind plugs is determined by a tube presence / absence confirmation sensor 29.
Is detected, and the set pattern of the filter tubes 51 and 54 is determined. If the set pattern is not possible, an error occurs and the system enters a pause state. If the set pattern is good, the operation proceeds to the reagent liquid amount confirmation operation.

In the reagent liquid amount checking operation, the height adjusting motor 20 is driven, the sub-bracket 10b is lowered, and the first row of pipette tips 28a of the tip stand 14 is mounted. Next, the dispensing unit 10 is transported, and the pipette tip 28a is inserted into the reagent in the first column 13a of the reservoir 13, and the liquid level sensor 30 determines the amount of the reagent. The dispensing unit 10 is transferred to the tip stand 14 again, and the pipette tip 28a is removed and returned to the original position.
Then, similarly, the second row of pipette tips 28b is used to define the first section.
The liquid amount of the reagent 3b is measured, and sequentially measured from the third row to the sixth row, and it is checked whether the amount of each reagent is sufficient for the number of the filter tubes 51 and 54. Note that the pipette tips 28a to 28f are used corresponding to the sections 13a to 13f. When the amount of the reagent is more than the specified value and the set pattern is good, lysis and unnecessary protein or chromosomal DN
The step of denaturing A and, if necessary, degrading unnecessary RNA.

In the step of lysing, denaturing unnecessary proteins and chromosomal DNA, and decomposing unnecessary RNA as necessary, as shown in FIG. 13C, the tube rack 11 is moved to the level 0 position, that is, the waste vat 44. It is placed in contact with the top. Since the rubber 11b is attached to the bottom of the tube rack 11, their contact portions are kept airtight.
Then, the vacuum pump 45 is operated for 2 minutes to suck air from the valve 44a, and a liquid other than E. coli is filtered from the filter tube 51.

The tube racks 11, 12 are transferred from the position shown in FIG. 13C to the position shown in FIG. That is, the DNA extraction / purification apparatus 1 raises the tube rack 11 to the position where the reagent of level 3 is added by automatic control,
The tube rack 12 is moved down to level 1 and further transferred to the left. Here, in the dispensing unit 10, the pipette tip 28a sucks the lysis reagent from the section 13a,
100 to 400 μl of the lysis reagent is placed in a filter tube 5.
1 to the trap filter 52a, and
Leave for a minute. In this step, the transformant is lysed,
The extranuclear gene (plasmid DNA) is eluted out of the cell.
Also, in this step, unnecessary R
Digest NA. Lysozyme (lysozyme)
yme), and those containing ribonuclease A as an RNase.

Next, an impurity filtration step using the first filter tube 51 is performed. In this step, the dispensing unit 10 is moved and the pipette tip 28b is moved to the section 13b.
The reagent for complete solubilization of the sample is aspirated and added to the trap filter 52a of the filter tube 51. The sample was completely solubilized by being left at room temperature for 5 minutes. As a reagent for complete solubilization of the sample, 400 μl of 0.2N sodium hydroxide / 1% sodium lauryl sulfate solution was added.

Next, the dispensing unit 10 is moved and the 3M potassium acetate (p
H4.8) is aspirated, and 300 μl is added to the trap filter 52 a of the filter tube 51. Then, it is left at room temperature for 5 minutes to neutralize the basic solution,
Coagulation treatment is performed on cell constituent proteins and chromosomal DNA.

Thereafter, the steps of adsorbing, washing and eluting the DNA with the second cartridge for DNA extraction and purification are performed. In this step, the dispensing unit 10 is moved and the pipette tip 28d is used as a reagent for adsorbing DNA in the section 13d.
Aspirate M sodium iodide NaI or 10 M sodium thiocyanate (NaSCN) and add to filter tube 51. Here, the tube racks 11, 12 are transferred to the position B in FIG. That is, the tube rack 12 is lowered to the level 0 position, and the tube rack 11 is similarly lowered to the level 2 position.

In this state, the tube rack 11 and the tube rack 12 overlap to form a decompression chamber E, and the tube rack 12 and the waste vat 44 overlap to form a decompression chamber F, as shown in FIG. A rubber frame 11b is provided at the bottom of the tube rack 11, and the contact surface between the rubber frame 11b and the tube rack 12 is kept airtight. Further, since the rubber 12b is attached to the bottom of the tube rack 12, the contact surface between the rubber 12b and the waste vat 44 is kept airtight.

Then, the vacuum pump 45 is operated for 10 minutes to suck air from the suction ports 44a and 44c. The tube filter 51 of the tube rack 11 is
The air is sucked by the suction port 44c through the ventilation hole 12c provided on the side of the second side. Thus, the plasmid extract is collected from the first filter tube 51 to the second filter tube 54.

At this time, the plasmid DNA is adsorbed on the glass powder layer 55c of the second filter tube 54.
In this step, when the sample in the first filter tube 51 is transferred by vacuum suction to the second filter tube 54, only the pressure in the space F may be reduced. However,
If there is a pressure difference between the decompression chambers E and F at the beginning of evacuation or when the vacuum is released, the sample in the transferred second filter tube 54 may leak into the waste vat 44. Therefore, a passage 12c is provided in the tube rack 12,
The decompression chambers E and F are decompressed to the same pressure.

Next, as shown in FIG. 14C, only the tube rack 11 is raised to level 3 and
open the solenoid valve 50a connected to the tube rack 1
The second filter tube 54 is sucked by a vacuum pump for 2 minutes. Thus, the sodium iodide in the filter tube 54 is filtered by suction.

In the cleaning step, as shown in FIG.
FIG. 1 shows the arrangement of the tube rack 11 and the tube rack 12.
The state of C of 4 is turned upside down. That is, the tube rack 12 is moved to the right, the tube rack 11 is lowered to level 0, and the tube rack 12 is further moved to level 3.
And move it to the left. Then, the pipette tip 28e of the dispensing unit 10 puts 10 mM Tris-hydrochloric acid (p
H8.0) 1 mM EDTA 0.2 M NaCl 5
Add 1000 μl of 0% ethanol.

Next, as shown in FIG. 15B, the tube rack 11 is lowered to level 0,
2 is lowered to level 2. The electromagnetic valves 50a and 50b are opened, and the cleaning liquid is suctioned from the suction ports 44a and 44b by a vacuum pump for 15 minutes, and the cleaning liquid is discharged from the filter tube 54 to the filter tube 51. At this time, since the tube racks 11 and 12 are upside down from the state shown in FIG. 7, the passage 11c of the tube rack 11 and the suction port 44b communicate with each other, so that the filter tube 5
The cleaning liquid of No. 4 is suctioned under vacuum. Thereafter, a second washing step is performed. The contents are the same as in the above paragraph 0042, and the volume of the washing buffer is 500 ml. Next, as shown in FIG. 15C, the tube rack 12 is raised to level 3,
Transfer to the right. Then, the pipette tip 28f of the dispensing unit 10 fills the filter tube 54 with distilled water / 10 mM Tris-hydrochloric acid (pH
8.0) Add 50-200 μl of 1 mM EDTA.

The solenoid valve 50a is opened to discharge the waste liquid from the filter tube 54, and the liquid is sucked and discharged by the vacuum pump 45. Then, as shown in FIG. 16, the tube rack 12 is lowered to level 0, the solenoid valve 50d is opened, and DN
A is collected from the filter tube 54 into the collection tube 49 disposed in the collection vat 47 to collect the plasmid DNA.
When the collection rack 48 is not provided or is displaced from a predetermined position, an alarm is issued at the start, but when the collection tube 48 is forgotten to be inserted into the collection rack 48, the operation is continued. Is performed. However, the hole c of the collection rack 48 is
Can be recovered in the hole c, so that the plasmid DNA may be transferred later.

As described above, according to the present embodiment, the plasmid DNA required for the gene recombination technique can be fully automatically extracted and purified in a short time (about 2 hours). In addition, since extraction and purification of DNA is performed by vacuum suction using a filter, it is possible to provide low-cost and high-purity plasmid DNA.

Although the embodiments of the present invention have been described above, the present invention is, of course, not limited thereto, and various modifications can be made based on the technical concept of the present invention.

For example, in the above-described embodiment, the first tube rack 11 can be transferred only in the vertical direction, and the second tube rack 12 can be transferred in the horizontal direction and the vertical direction. However, both may be transferable in both directions.

[0048]

As is clear from the above, according to the present invention, extranuclear gene DNA (plasmid DNA) replicated and amplified in a transformant can be obtained without using a centrifuge.
A large amount of sample can be extracted and purified from the overnight culture solution in a short time. In addition, since extraction and purification of DNA is performed by vacuum suction using a filter, it is possible to provide low-cost and high-purity plasmid DNA.

[Brief description of the drawings]

FIG. 1 is an overall perspective view of a DNA extraction / purification apparatus according to an embodiment of the present invention.

FIG. 2 is a side view of a main body of the DNA extraction / purification apparatus.

FIG. 3 shows X in FIG. 2 of the main body of the DNA extraction / purification apparatus.
It is a longitudinal cross-sectional view in the X-ray direction.

FIG. 4 is a plan view of a main body of the DNA extraction / purification apparatus.

FIG. 5 is an enlarged side view of a dispensing unit of the DNA extraction / purification apparatus.

FIG. 6 is a plan view of a lower portion of the main body of the DNA extraction / purification apparatus.

FIG. 7 is a schematic sectional view of a vacuum transfer section of the DNA extraction / purification apparatus.

FIG. 8 is a schematic sectional view of a lower part of a main body of the DNA extraction / purification apparatus.

FIG. 9A is a plan view of the filter tube as viewed from above and below. FIG. 9B is a partially cutaway cross-sectional view of the filter tube.

FIG. 10 is an enlarged cross-sectional view of a filter provided in a first filter tube.

FIG. 11 is an enlarged sectional view of a filter and the like disposed in a second filter tube.

FIG. 12 is a system diagram of the DNA extraction / purification apparatus of the present invention.

FIGS. 13A to 13C show a first tube rack and a second tube rack;
It is the schematic which shows arrangement | positioning of a tube rack.

FIGS. 13A to 13C show a first tube rack and a second tube rack.
It is the schematic which shows arrangement | positioning of a tube rack.

15A to 14C show a first tube rack and a second tube rack.
It is the schematic which shows arrangement | positioning of a tube rack.

FIG. 16 is a schematic view showing an arrangement of a first tube rack and a second tube rack.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 DNA extraction / purification apparatus 2 Main body 10 Dispensing unit 11 1st tube rack 11c passage 12 2nd tube rack 12c passage 13 reservoir 14 chip stand 29 tube existence confirmation sensor 44 waste vat 45 vacuum pump 47 recovery vat 47b magnetic sensor 48 recovery rack 48a Magnet 50a to 50d Solenoid valve 51 First filter tube 52 Filter 52b, 55d Membrane filter 54 Second filter tube 55 Filter 55a, 55b Glass fiber filter 55c Glass powder layer A First transfer device B Second transfer device C Third transfer apparatus

Continued on the front page (72) Inventor Takamaro Ishii 2-2-112 Asahicho, Nerima-ku, Tokyo Inside Tommy Seiko Co., Ltd.

Claims (7)

[Claims] 1. A box-shaped first tube rack having an open top is provided, a hole is formed in the bottom of the first tube rack, a first filter tube is inserted into the hole, and the top is opened. A box-shaped second tube rack is provided, a hole is formed in the bottom of the second tube rack, a second filter tube is inserted into the hole, and a second tube rack is stacked on the first tube rack. Together or by overlapping the first tube rack on the second tube rack to form a decompression chamber between the bottom of one tube rack and the bottom of the other tube rack. The pressure is reduced, and the extract in the tube rack above the decompression chamber is collected in the filter tube of the tube rack below the decompression chamber via the tube rack. DNA extraction and purification apparatus. 2. A first transfer device for transferring the first tube rack in the vertical direction, a second transfer device for transferring the second tube rack in the vertical direction, and at least one of the first tube rack and the second tube rack. 2. The DNA extraction device according to claim 1, further comprising a third transfer device for transferring any one of the transfer devices in a lateral direction, and control means for controlling the first to third transfer devices and the vacuum device. Purification equipment. 3. The filter provided in the first filter tube includes at least a trap filter and a membrane filter, and the filter provided in the second filter tube includes at least a glass fiber filter, a glass powder layer, and a membrane filter. The DNA extraction / purification apparatus according to claim 1, which comprises: 4. At least one of the first tube rack and the second tube rack is provided with a passage penetrating from the bottom wall of the tube rack to the inner wall, and communicates the vacuum device and the decompression chamber via the passage. D according to claim 1, comprising
NA extraction and purification equipment. 5. A tube presence / absence confirmation sensor for judging whether said first filter tube and said second filter tube are arranged regularly according to said first tube rack and said second tube rack. Item 2. The DNA extraction / purification apparatus according to Item 1. 6. A box-shaped tube rack having an open top is provided, and a hole is formed in the bottom of the tube rack.
A filter tube is inserted into the hole, a waste vat having an open top is provided, the tube rack is overlapped on the waste vat, and a decompression chamber is provided between the bottom of the tube rack and the bottom of the waste vat. A DNA extraction / purification apparatus, comprising: forming a vacuum chamber, depressurizing the decompression chamber by a vacuum device, and collecting a discharged liquid in a tube rack above the decompression chamber into a waste vat via the tube rack. 7. The DNA extraction / purification apparatus according to claim 6, further comprising a transfer device for superimposing the tube rack on the waste vat, and a control device for controlling the transfer device and the vacuum device. .