JP5239552B2 - Reaction vessel plate and reaction processing method - Google Patents

Description

  INDUSTRIAL APPLICABILITY The present invention relates to a reaction vessel plate suitable for performing various analyzes and analyzes in the field of medical analysis and chemistry in the field of biological analysis, biochemical analysis, or chemical analysis in general, and a method for processing the reaction vessel plate. The present invention relates to a reaction processing method.

A micro multi-chamber apparatus is used as a small reaction apparatus used for biochemical analysis or normal chemical analysis. As such an apparatus, for example, a microwell reaction vessel plate such as a microtiter plate in which a plurality of wells are formed on a flat substrate surface is used (see, for example, Patent Document 1).
Moreover, as a trace liquid weighing structure capable of quantitatively handling a trace amount of liquid, a first channel and a second channel, a third channel opening in the channel wall of the first channel, A structure having a fourth channel having a property of opening the channel wall of the two channels and connecting one end of the third channel and the second channel so that capillary attraction is relatively difficult to work than the third channel. Some are provided (see, for example, Patent Documents 2 and 3). According to the trace liquid weighing structure, after the liquid introduced into the first flow path is drawn into the third flow path, the liquid remaining in the first flow path is removed, and the volume of the third flow path is increased. A corresponding volume of liquid can be weighed into the second flow path.
JP-A-2005-177749 JP 2004-163104 A JP 2005-114430 A Japanese Patent No. 3454717

When the conventional microwell reaction container plate is used, the upper surface of the reaction container plate is open to the atmosphere. Therefore, foreign matter may enter the sample from the outside, and conversely, the reaction product may contaminate the external environment.
Further, in the trace liquid weighing structure disclosed in Patent Documents 2 and 3, liquid introduction ports are formed at both ends of the first flow path and at both ends of the second flow path. It is possible that the reaction products are open and pollute the external environment through these ports.
Therefore, the present invention has an object to provide a reaction vessel plate that can prevent entry of foreign matter from the outside of the reaction vessel plate and environmental pollution to the outside, and a reaction processing method using the reaction vessel plate. It is.

  The reaction container plate according to the present invention includes a sealed reaction container, a reaction container flow path connected to the reaction container, a sealed container provided separately from the reaction container, and one end from below the sealed container. A protruding flow path protruding upward, and when the sealed container is used, the protruding flow path is inserted from the bottom surface of the sealed container so that the sealed container flow path is connected to the sealed container. Provided as a recess at the bottom of the container, the bottom is a penetrable part that can penetrate through the projecting channel when using the sealed container, and accommodates the projecting channel that penetrates the penetrable part and connects to the sealed container A protrusion flow path accommodating portion, a syringe for feeding a liquid, and a switching valve for connecting the syringe to a reaction container flow path or a sealing container flow path. The inner diameter of the flow path housing part is approximately the same diameter, and the protruding flow path can be penetrated. The portion accommodated in the protruding flow path accommodating portion after penetrating the portion is the same length as the depth of the protruding flow path accommodating portion or shorter than that, and the reaction vessel, the reaction vessel flow channel, the sealing vessel, and the seal are sealed. The stop container flow path is a closed system.

  In the reaction container plate of the present invention, the sealing container and the sealing container flow path are separated when the sealing container is not used. When the sealed container and the sealed container flow path are connected since the sealed container is not used, for example, a liquid such as a reagent or dilution water or a powdered solid such as a reagent is sealed in the sealed container in advance. When stored, the liquid or solid may enter the sealed container flow path, and the stored liquid may evaporate through the sealed container flow path. In the present invention, when the sealing container is not used, such a problem does not occur because the sealing container and the sealing container flow path are separated.

  The sealing container and the sealing container flow path are connected by the protruding flow path that is one end of the sealing container flow path penetrating the bottom surface of the sealing container. The problem with this structure is that, after the projecting channel has penetrated the bottom surface of the sealing container, the liquid in the sealing container is sucked from the tip of the projecting channel more than the suction port at the tip of the projecting channel. Since the lower liquid cannot be sucked, the volume below the tip of the protruding flow path becomes a dead volume. Furthermore, in order to mix a plurality of liquids such as sample liquids and reaction reagents in the sealed container, it is also possible to stir the sealed container by repeatedly sucking and discharging the liquid from the tip of the protruding channel. Although it is conceivable, the liquid below the tip of the protruding flow path is difficult to stir, and the liquid in the sealed container becomes poorly mixed, making accurate analysis impossible. Therefore, in the present invention, a protruding channel housing portion is provided as a recess at the bottom of the sealing container, and the protruding channel penetrates the bottom surface of the protruding channel housing portion when the sealing container is used. While the flow path is connected, the protruding flow path is accommodated in the protruding flow path accommodating portion. The inner diameter of the protruding flow path accommodating portion and the outer diameter of the protruding flow path are substantially the same, and is the length of the protruding flow path accommodated in the protruding flow path accommodating portion equal to the depth of the protruding flow path accommodating portion? Make it shorter. By doing so, since the volume below the tip of the protruding flow path is small, the dead volume is reduced, and most of the liquid in the sealed container can be stirred.

  “The inner diameter of the protruding flow path accommodating portion and the outer diameter of the protruding flow path are substantially the same diameter” means that the inner diameter of the protruding flow path accommodating portion is slightly larger than the outer diameter of the protruding flow path. In addition, the gap between the protruding channel housing portion and the protruding channel is preferably 1 mm or less. If the gap between the protruding channel housing portion and the protruding channel is 1 mm or less, the amount of liquid that is difficult to stir is negligible because it is very small.

  The reaction container plate of the present invention includes a plurality of sets of the sealing container, the sealing container channel, and the protruding channel, and the switching valve can connect the syringe to any of the sealing container channels. It can also be. Then, different liquids and powdered solids can be stored separately in the plurality of sealed containers. Thereby, it becomes possible to accommodate a diluent and a reagent separately, or to accommodate several types of reagents separately, and the use of a reaction container plate increases. In addition, since each sealed container can be connected to the syringe via the sealed container channel and the switching valve, the liquid can be stirred in each sealed container.

  A first state in which the penetrable portion is opposed to the projecting channel above the projecting channel so that the sealed container channel can be easily connected to the sealed container when the sealed container is used; It is preferable to further include a sealed container holding mechanism that descends from the first state and holds each of the protruding flow paths in the second state in which the protruding flow path is accommodated in the protruding flow path accommodating portion. Then, the analyst simply pushes the sealed container downward, and the protruding channel automatically penetrates the bottom surface of the sealed container, the sealed container and the sealed container channel are connected, and the state is maintained. Is done.

  The second penetrable portion is provided at a position where the sealed container does not come into contact with the liquid, and one end penetrates the second penetrable portion when the sealed container is used and is connected to the sealed container. It is preferable to further include a sealed container air vent channel serving as a second protruding channel. Then, when the liquid is injected into the sealing container or the liquid is sucked from the sealing container, the gas can be circulated between the sealing container and the sealing container air vent channel. It is possible to smoothly inject liquid into the liquid and suck liquid from the sealing container.

  An example of the sealing container is a sample container for containing a sample liquid. If the sealing container is used as a sample container, it is not necessary to prepare a container for containing the sample separately.

  In this case, the sample container is hermetically sealed by a sealing member, and the sealing member can be penetrated by a member having a pointed end and can be sealed by an elastic force even after the member is pulled out. It is preferable that it contains. If it does so, a sample liquid can be inject | poured in a sample container via a sealing member, and it can prevent that the sample liquid after injection | pouring leaks out of a sample container.

  Moreover, you may make it the sample pretreatment liquid or the reagent be previously accommodated in the said sealing container. This eliminates the need to dispense the sample pretreatment liquid or reagent into the sample container.

It is preferable that the sealing container also includes a gene amplification container for performing a gene amplification reaction. Then, when a gene is analyzed using the reaction container plate of the present invention, a sample solution containing only a trace amount of the gene to be measured is amplified and analyzed on the reaction container plate by a gene amplification reaction. The accuracy can be increased.
The gene amplification reaction includes a PCR method and a LAMP method. Focusing on the PCR method for amplifying DNA, a method of directly performing a PCR reaction from a sample such as blood without pretreatment has also been proposed. In the nucleic acid synthesis method for amplifying a target gene in a sample containing a gene, the gene inclusion body in the sample containing the gene or the sample containing the gene itself is added to the gene amplification reaction solution, The target gene in the sample containing the gene is amplified when the pH of the reaction solution is 8.5 to 9.5 (25 ° C.) (see Patent Document 4).

In the reaction container plate of the present invention, examples of the switching valve for connecting the syringe to the main channel or the sealed container channel include a rotary valve.
In that case, a port connected to the syringe may be arranged at the center of rotation of the rotary valve. Then, the flow path configuration is simplified.
Furthermore, the rotary valve may be configured such that a syringe is disposed on the rotary valve. Then, the flow path between the port and the syringe can be shortened or eliminated, and the structure is simplified. Furthermore, the area on the switching valve can be used effectively, and the planar size of the reaction vessel plate can be reduced as compared with the case where the syringe is arranged in an area different from that on the switching valve.

As a specific flow path configuration example of the reaction container plate of the present invention, the reaction container plate further includes a reaction container air vent flow path connected to the reaction container, and the reaction container flow path is formed on the bonding surface of two bonded members. A groove formed or a through-hole formed in the groove and the substrate and connected to the syringe; a metering channel having a predetermined capacity branched from the main channel; and one end of the metering channel An injection channel connected to the channel and connected at the other end to the reaction vessel, the main channel and the reaction vessel air vent channel can be sealed; In the liquid introduction pressure state when the liquid is introduced into the main flow path and the metering flow path and the purge pressure state when the liquid in the main flow path is purged, the liquid is not passed. Than under pressure Mention may be made of those passing through the serial liquid.
Here, “the injection channel is formed thinner than the metering channel” means that when the injection channel is composed of a plurality of channels, the plurality of channels constituting the injection channel are It means that each is formed narrower than the measuring channel.

  A reaction processing method using the reaction container plate according to the present invention is a reaction processing method using the reaction container plate of the present invention in the above-described flow path configuration example, and is applied to the main flow path and the measurement flow path with the introduction pressure. The liquid is filled, gas is allowed to flow in the main channel, and the liquid in the main channel is discharged while the liquid remains in the metering channel, and the main channel is set to a positive pressure greater than the introduction pressure. Alternatively, the liquid in the metering channel is injected into the reaction vessel through the injection channel by setting the inside of the reaction vessel to a negative pressure or both the positive pressure and the negative pressure.

According to the above reaction processing method, since the reaction container plate of the present invention having the above-described flow path configuration is used, entry of foreign matters from the outside of the reaction container plate and environmental contamination of the liquid to the outside can be prevented. Can do.
Furthermore, since a reaction container air vent channel connected to the reaction container is provided, gas is introduced between the reaction container and the reaction container air vent channel when the liquid is injected into the reaction container through the injection channel. Can be distributed. Thereby, the liquid can be smoothly injected into the reaction vessel. The reaction container air vent channel is an injection method in which when the liquid is injected into the reaction container, the gas in the reaction container is sucked from the reaction container air vent channel to decompress the inside of the reaction container to inject the liquid. It can also be used.

In the flow channel configuration example, a contact angle of the injection flow channel with respect to water droplets is 90 degrees or more, and an area of a boundary between the injection flow channel and the measurement flow channel is 1 to 10000000 μm ² (square micrometer). preferable. Then, when the liquid is introduced into the main channel and the metering channel, the liquid is less likely to enter the injection channel, and the introduction pressure when introducing the liquid into the main channel and the metering channel can be increased. .
Here, when the injection flow path is constituted by a plurality of flow paths, the area means an area of a boundary between each of the plurality of flow paths constituting the injection flow path and the measurement flow path.

  A plurality of the reaction vessels may be provided, each of the reaction vessels may be provided with the metering channel and the injection channel, and the plurality of metering channels may be connected to the main channel. If it does so, a liquid can be sequentially introduce | transduced into a some measurement flow path, and a liquid can be simultaneously inject | poured into a several reaction container via an injection | pouring flow path after that.

  The other end of the injection channel is disposed at the tip of a convex portion that protrudes from the inner upper surface of the reaction vessel, and the tip of the convex portion may be thinner than the base end portion. . If it does so, the liquid inject | poured into a reaction container through an injection | throwing flow path will become easy to dripping at a reaction container.

  The reaction vessel may be made of a light-transmitting material so that optical measurement can be performed from the bottom or above. Then, the liquid in the reaction vessel can be measured optically without moving to another vessel.

  The reaction container plate of the present invention includes a syringe and a switching valve, and can be connected to the syringe by switching the switching valve between the reaction container, the reaction container flow path, the sealing container, and the sealing container flow path that are a closed system. Therefore, liquid or gas can be circulated through these flow paths without drawing out the reaction container flow path or the sealing container flow path to the outside. Can prevent environmental pollution.

1A and 1B are diagrams showing an embodiment of a reaction vessel plate. FIG. 1A is a schematic plan view, and FIG. 1B is a sectional view taken along a line AA in FIG. FIG. 4 is a schematic cross-sectional view of the reaction vessel air vent channels 19 and 21, the liquid drain space 29, the air drain space 31 and the bellows 53, and FIG. FIG. FIG. 2 is an exploded sectional view showing this embodiment and a schematic exploded perspective view of the switching valve. FIG. 3 is a schematic view showing the vicinity of one reaction vessel of this embodiment, where (A) is a plan view, (B) is a perspective view, and (C) is a cross-sectional view. 4A and 4B are enlarged views of the sample container accommodating portion and the sample container. FIG. 4A is a plan view of the sample container accommodating portion, FIG. 4B is a cross-sectional view at the BB position in FIG. ) Is a plan view of the sample container, (D) is a cross-sectional view at the CC position in (C), (E) is a cross-sectional view in which the sample container is disposed in the sample container housing portion at the first holding position, and (F). FIG. 5 is a cross-sectional view in which a sample container is disposed in a sample container housing portion at a second holding position. 5A and 5B are enlarged views of the reagent container housing part and the reagent container. FIG. 5A is a plan view of the reagent container housing part, FIG. 5B is a cross-sectional view taken along the DD line in FIG. ) Is a plan view of the reagent container, (D) is a cross-sectional view at the EE position of (C), (E) is a cross-sectional view in which the reagent container is arranged in the reagent container housing portion at the first holding position, (F) FIG. 6 is a cross-sectional view in which the reagent container is disposed in the reagent container housing portion at the second holding position. 6A and 6B are enlarged views of the air suction container housing portion and the air suction container. FIG. 6A is a plan view of the air suction container housing portion, and FIG. 6B is the FF position in FIG. (C) is a plan view of the air suction container, (D) is a cross-sectional view at the GG position of (C), and (E) is a diagram showing the air suction container in the air suction container housing portion. FIG. 6F is a cross-sectional view in which the air suction container is disposed in the air suction container housing portion in the second holding position.
An embodiment of the reaction vessel plate will be described with reference to FIGS.

  The reaction vessel plate 1 includes a plurality of reaction vessels 5 having openings on one surface of the vessel base 3. In this embodiment, 6 × 6 reaction vessels 5 are arranged in a staggered manner. A reagent 7 and wax 9 are accommodated in the reaction vessel 5.

  The material of the container base 3 including the reaction container 5 is not particularly limited. However, when the reaction container plate 1 is used as disposable, it is preferable that there is a material available at a low cost. As such a material, for example, a resin material such as polypropylene and polycarbonate is preferable. When the substance in the reaction vessel 5 is detected by absorbance, fluorescence, chemiluminescence, bioluminescence or the like, it must be formed of a light transmissive resin so that optical detection can be performed from the bottom side. Is preferred. In particular, when fluorescence detection is performed, the container base 3 is made of a material such as a resin having a low autofluorescence property (a property of generating less fluorescence from itself) and a light transmitting resin, such as polycarbonate. Is preferred. The thickness of the container base 3 is 0.2 to 4.0 mm (millimeters), preferably 1.0 to 2.0 mm. From the viewpoint of low autofluorescence for fluorescence detection, the container base 3 is preferably thinner.

  Referring to FIGS. 1 and 3, the flow path base 11 is disposed on the container base 3 so as to cover the arrangement region of the reaction containers 5. The channel base 11 is made of, for example, PDMS (polydimethylsiloxane) or silicone rubber. The thickness of the channel base 11 is, for example, 1.0 to 5.0 mm. The flow path base 11 has a groove on the joint surface with the container base 3. The groove and the surface of the container base 3 form a main channel 13, a metering channel 15, an injection channel 17, reaction vessel air vent channels 19 and 21, and drain space air vent channels 23 and 25. The main channel 13, the metering channel 15 and the injection channel 17 constitute a reaction vessel channel. A concave portion 27 disposed on the reaction vessel 5 is also formed on the joint surface of the flow path base 11 with the vessel base 3. In FIG. 1A and FIGS. 3A and 3B, only the groove and the concave portion of the flow path base 11 are illustrated.

  The main flow path 13 is composed of a single flow path and is formed to be bent so as to pass through the vicinity of all the reaction vessels 5. One end of the main flow path 13 is connected to a flow path 13 a formed of a through hole provided in the container base 3. The flow path 13a is connected to a port of a switching valve 63 described later. The other end of the main channel 13 is connected to a liquid drain space 29 formed in the container base 3. The dimensions of the grooves constituting the main flow path 13 are, for example, a depth of 400 μm (micrometer) and a width of 500 μm. In addition, the main flow path 13 has a predetermined length downstream of the position where the measurement flow path 15 is connected, for example, a 250 μm portion is formed to be narrower than other portions, for example, the width is 250 μm. It is.

  The measuring channel 15 is branched from the main channel 13 and provided for each reaction vessel 5. The end of the measuring channel 15 opposite to the main channel 13 is disposed in the vicinity of the reaction vessel 5. The depth of the groove constituting the measuring channel 15 is 400 μm, for example. The measuring channel 15 has an internal capacity of a predetermined capacity, for example, 2.5 μL (microliter). The width dimension of the part connected to the main flow path 13 of the measurement flow path 15 is larger than the narrow part of the main flow path 13 described above, for example, 500 μm. Thereby, the flow resistance of the main flow path 13 is larger than that of the measurement flow path 15 in the portion where the measurement flow path 15 is branched with respect to the liquid flowing from one end of the main flow path 13. The liquid flowing from one end of the main channel 13 first flows into the metering channel 15, and after the metering channel 15 is filled with the liquid, it flows downstream through the narrowed portion of the main channel 13. It has become.

An injection channel 17 is also provided for each reaction vessel 5. One end of the injection channel 17 is connected to the metering channel 15. The other end of the injection channel 17 is connected to a recess 27 disposed on the reaction vessel 5 and led to the reaction vessel 5. The injection channel 17 is formed with a dimension that maintains liquid tightness in the reaction vessel 5 in a state where there is no pressure difference between the reaction vessel 5 and the injection channel 17. In this embodiment, the injection channel 17 is composed of a plurality of grooves, and the dimensions of the grooves are, for example, a depth of 10 μm, a width of 20 μm, a pitch of 20 μm, and 13 grooves in a width region of 500 μm. Is formed. Here, the area of the boundary between the groove constituting the injection channel 17 and the metering channel 15, that is, the cross-sectional area of the groove constituting the injection channel 17 is 200 μm ² . The recess 27 has a depth of, for example, 400 μm, and the planar shape is a circle smaller than the reaction vessel 5.

  A reaction vessel air vent channel 19 is provided for each reaction vessel 5. One end of the reaction container air vent channel 19 is connected to a recess 27 disposed on the reaction container 5 at a position different from the injection channel 17 and disposed on the reaction container 5. The reaction container air vent channel 19 is formed with a dimension that maintains liquid tightness in the reaction container 5 in a state where there is no pressure difference between the reaction container 5 and the reaction container air vent channel 19. The other end of the reaction vessel air vent channel 19 is connected to the reaction vessel air vent channel 21. In this embodiment, the reaction vessel air vent channel 19 is composed of a plurality of grooves, and the dimensions of the grooves are, for example, a depth of 10 μm, a width of 20 μm, a pitch of 20 μm, and 13 in a 500 μm width region. Grooves are formed.

  In this embodiment, a plurality of reaction vessel air vent channels 21 are provided. A plurality of reaction vessel air vent channels 19 are connected to each reaction vessel air vent channel 21. The reaction container air vent channel 21 is for connecting the reaction container air vent channel 19 to an air drain space 31 formed in the container base 3. The dimensions of the grooves constituting the reaction vessel air vent channel 21 are, for example, a depth of 400 μm and a width of 500 μm.

  The drain space air vent channel 23 is for connecting the liquid drain space 29 to a port of a switching valve 63 described later. One end of the drain space air vent channel 23 is disposed on the liquid drain space 29. The other end of the drain space air vent channel 23 is connected to a channel 23 a formed of a through hole provided in the container base 3. The flow path 23a is connected to a port of a switching valve 63 described later. The dimensions of the grooves constituting the drain space air vent channel 23 are, for example, a depth of 400 μm and a width of 500 μm.

  The drain space air vent channel 25 is for connecting the air drain space 31 to a port of a switching valve 63 described later. One end of the drain space air vent channel 25 is disposed on the air drain space 31. The other end of the drain space air vent channel 25 is connected to a channel 25 a formed of a through hole provided in the container base 3. The flow path 25a is connected to a port of a switching valve 63 described later. The dimensions of the grooves constituting the drain space air vent channel 25 are, for example, a depth of 400 μm and a width of 500 μm.

  A flow path cover 33 (not shown in FIG. 1A) is disposed on the flow path base 11. The flow path cover 33 is for fixing the flow path base 11 to the container base 3. A through hole is formed in the flow path cover 33 at a position on the reaction vessel 5.

  Referring to FIG. 1 and FIGS. 4 to 6, the sample container storage unit 36, the reagent container storage unit 38 and the air suction are placed in the container base 3 at a position different from the arrangement region of the reaction container 5 and the drain spaces 29 and 31. A container container 40 is formed. A sample container 35 is accommodated in the sample container accommodating portion 36, a reagent container 37 is accommodated in the reagent container accommodating portion 38, and an air aspirating 39 is accommodated in the air aspirating container accommodating portion 40. The sample container 35, the reagent container 37, and the air suction container 39 constitute a sealed container for the reaction container plate of the present invention.

  As shown in FIG. 4, a sample channel 35 a penetrating from the bottom to the back surface of the sample container housing portion 36 and a sample container air vent penetrating from the front surface to the back surface are disposed in the container base 3 near the sample container housing portion 36. A flow path 35b is formed. Three locking claws 35 c for holding the sample container 35 are arranged on the surface of the container base 3 around the opening of the sample container housing portion 36.

At the bottom of the sample container housing portion 36, a protruding flow path 35d is provided that forms one end of the sample flow path 35a protruding upward.
On the surface of the container base 3 in the vicinity of the sample container accommodating portion 36, a second protruding flow path 35e that forms one end of a sample container air vent flow path 35b protruding upward is provided.

  An annular packing 35f is provided on the outer peripheral side surface of the base end portion of the projection flow path 35d and the outer peripheral side surface of the base end portion of the second projection flow path 35e. For example, it is formed of an elastic material such as silicone rubber or PDMS.

  The sample container 35 disposed in the sample container housing portion 36 includes a sample container main space 35g for storing a sample, and a sample container air venting space 35i on a protruding portion on the upper side surface of the sample container 35 body. . A groove serving as a sample container air vent channel 35 h is formed between the sample container main space 35 g and the sample container air vent space 35 i on the upper surface of the sample container 35. The sample container 35 is integrally formed of a resin material such as polypropylene or polycarbonate.

  A film 35k made of, for example, aluminum is attached to the entire upper surface of the sample container 35, and the upper surface of the sample container main space 35g and the upper surface of the sample container air vent space 35i are sealed and formed on the upper surface of the sample container 35. A sample container air vent channel 35h is formed covering the upper surface of the groove.

  The groove for forming the sample container air vent channel 35h is formed by, for example, one or a plurality of pores having a width of 5 to 200 μm and a depth of 5 to 200 μm. This is for keeping the liquid tightness of the sample container main space 35g in a state where there is no pressure difference in the container air vent space 35i.

  A projecting channel housing portion 35p for housing the projecting channel 35d is provided as a recess at the bottom of the sample container main space 35g. The bottom surface of the projecting channel housing portion 35p is closed by a penetrable member 35q that can penetrate through the projecting channel 35d. The penetrable member 35q may be a thin film made of aluminum or the like, or may be a thin resin film integrally formed with the sample container 35. The bottom surface of the sample container 35 on the side of the sample container air vent space 35i is closed by a penetrable member 35l that can be penetrated by the second protruding flow path 35e. The second penetrable member 35l may also be a thin film made of, for example, aluminum, or may be a thin resin film integrally formed with the sample container 35. Thereby, the space inside the sample container 35 including the sample container main space 35g, the sample container air vent space 35i, and the sample container air vent channel 35h is sealed.

  A septum 41, which is an elastic member, is formed on the film 35k. The septum 41 is formed of, for example, an elastic material such as silicone rubber or PDMS, and can penetrate through the tip of the dispensing device, and can close the hole formed after the dispensing device is pulled out by elasticity. A septum stopper 43 for fixing the septum 41 is disposed on the septum 41. The septum stopper 43 has an opening on the sample container 35. In this embodiment, the reagent 45 is stored in advance in the sample container main space 35g. In FIG. 4, the septum stopper 43 is fixed to the sample container main body by a locking claw provided on the septum stopper 43, but the number of locking claw provided on the septum stopper 43 is arbitrary. The septum stopper 43 may be fixed to the sample container main body by any method. For example, the septum stopper 43 may be fixed to the sample container main body by an adhesive.

  Locking grooves 35 m and 35 n are formed on the side surface of the sample container 35. The locking grooves 35m and 35n are for holding the sample container 35 in the sample container housing portion 36 at the first holding position or the second holding position by the locking claw 35c. The locking groove 35m is formed below the locking groove 35n, and is for holding the sample container 35 at the first holding position (see (E)). The locking groove 35n is for holding the sample container 35 at the second holding position (see (F)). The locking claw 35c and the locking grooves 35m and 35n constitute a sealed container holding mechanism for the reaction container plate of the present invention. However, the sealing container holding mechanism is not limited to the one constituted by the locking claw 35c and the locking grooves 35m and 35n, and the sample container 35 (sealing container) is held at the first holding position and the second holding position. Any configuration may be used as long as it can be held.

  In the state where the sample container 35 is in the first holding position (first state), as shown in (E), the penetrable member 35q and the protruding flow path 35d are arranged to face each other, and the penetrable member 35l. And the second protrusion channel 35e are arranged to face each other. From the first state, the sample container 35 can be moved to the second holding position by pushing the sample container 35 toward the container base 3 and lowering it.

  When the sample container 35 is moved to the second holding position (second state), as shown in (F), the protruding flow path 35d penetrates the penetrable member 35q and is accommodated in the protruding flow path accommodating portion 35p. Then, the sample container main space 35g and the sample container channel 35a are connected. At this time, the bottom surface of the protruding flow path accommodating portion 35p is pressed against the packing 35f, thereby preventing liquid leakage. In this second state, the projection channel 35d is completely accommodated in the recess provided as the projection channel accommodating portion 35q, and 1 mm is provided between the projection channel 35d and the projection channel accommodating portion 35q, for example. There are only the following very small gaps. That is, with reference to FIG. 7, (1) the inner diameter D1 of the protrusion flow path accommodating portion 35p and the outer diameter D2 of the protrusion flow path 35d are substantially the same diameter, and D1 is slightly larger. The length L2 of the flow path 35d is equal to or less than the depth L1 of the protruding flow path accommodating portion 35p. For this reason, the dead volume below the suction / discharge port at the tip of the projection channel 35d is reduced. Further, when the solution in the sample container 35 is agitated by repeatedly sucking and discharging the liquid from the tip of the projection channel 35d, even if liquid stagnates around the projection channel 35d, the amount is very small. It can be ignored and does not result in poor agitation.

  In the second state, the second protruding flow path 35e penetrates the penetrable member 35l and is inserted into the sample container air vent space 35i, and the sample container air vent space 35i and the sample container air vent path 35b are connected. Is done. The lower surface of the sample container air vent space 35i is pressed against the packing 35f, and the sample container air vent space 35i and the sample container air vent channel 35b are connected with high airtightness to prevent air leakage.

  If the sample container 35 is arranged at the first holding position, the reaction container plate can be stored in a state where the sample container 35 and the sample container flow path 35a are separated, so that the reagent 45 and the dilution 45 are diluted in the sample container main space 35g. Even if a liquid solid such as water or a powdery solid such as a reagent is enclosed and stored in advance, the liquid or solid does not enter the sample container channel 35a during storage.

  Furthermore, in the first holding position, the sample container main space 35g and the sample container air vent space 35i are sealed, so that liquid such as the reagent 45 and dilution water may be sealed in the sample container main space 35g in advance. The liquid can be prevented from evaporating.

Next, the reagent container 37 and the reagent container storage unit 38 will be described with reference to FIG.
The reagent container housing portion 38 has the same structure as the sample container housing portion 36 described with reference to FIG. That is, a reagent channel 37a, a reagent container air vent channel 37b, a locking claw 37c, a projection channel 37d, a second projection channel 37e, and packings 37f and 37f are provided.

  The reagent container 37 has the same structure as the sample container 35 described with reference to FIG. However, the reagent container 37 does not include the septum 41 as compared with the sample container 35, and includes a cover 47 instead of the septum stopper 43. That is, the reagent container 37 includes a reagent container main space 37g, a reagent container air vent channel 37h, a reagent container air vent space 37i, penetrable members 37j and 37l, a film 37k, locking grooves 37m and 37n, and a cover 47. I have. The cover 47 is for preventing the film 37k affixed on the upper surface of the reagent container main body from being damaged. Dilution water 49 is accommodated in the reagent container main space 37g. In FIG. 5, the cover 47 is fixed to the reagent container main body by a locking claw provided on the cover 47, but the number of the locking claw provided on the cover 47 is arbitrary. Further, any method may be used for fixing the cover 47 to the reagent container main body. For example, the cover 47 may be fixed to the reagent container main body with an adhesive.

  Similarly to the sample container 35, the reagent container 37 is also arranged in the reagent container housing portion 38 at the first holding position (see (E)) and the second holding position (see (F)). The connection between the reagent container 37 and the reagent container channel 37a and the reagent container air vent channel 37b is the same as the connection between the sample container 35, the sample container channel 35a and the reagent container air vent channel 35b described with reference to FIG. It is.

  If the reagent container 37 is arranged at the first holding position, the reaction container plate can be stored in a state where the reagent container 37 and the reagent container flow path 37a are separated, so that the reagent or dilution water is stored in the reagent container main space 37g. Even if a liquid such as 49 or a powdery solid such as a reagent is enclosed and stored in advance, the liquid or solid does not enter the reagent container channel 37a during storage.

  Furthermore, in the first holding position, the reagent container main space 37g and the reagent container air vent space 37i are sealed, so that a liquid such as a reagent or dilution water 49 may be sealed in the reagent container main space 37g in advance. The liquid can be prevented from evaporating.

Next, the air suction container 39 and the air suction container housing 40 will be described with reference to FIG.
The air suction container container 40 has the same structure as the reagent container container 38 described with reference to FIG. That is, an air suction channel 39a, an air suction container air vent channel 39b, a locking claw 39c, a projection channel 39d, a second projection channel 39e, and packings 39f and 39f are provided.

  The air suction container 39 has the same structure as the reagent container 37 described with reference to FIG. That is, the air suction container 39 includes an air suction container main space 39g, an air suction container air vent channel 39h, an air suction container air vent space 39i, penetrable members 39j and 39l, a film 39k, and a locking groove. 39m, 39n, and a cover 47. Liquid and solid are not accommodated in the air suction container main space 39g and are filled with air.

  Similarly to the sample container 35 and the reagent container 37, the air suction container 39 is also arranged in the air suction container housing portion 40 at the first holding position (see (E)) and the second holding position (see (F)). The The connection between the air suction container 39, the air suction container channel 39a, and the air suction container air vent channel 39b is the same as that of the sample container 35, the sample container channel 35a, and the reagent container air vent flow described with reference to FIG. This is the same as the connection of the path 35b.

  1 and 2, the syringe 51 is provided on the surface of the container base 3 at a position different from the arrangement region of the reaction vessel 5, the drain spaces 29, 31, and the container accommodating portions 36, 38, 40. It has been. The syringe 51 is formed by a cylinder 51a formed in the container base 3, a plunger 51b disposed in the cylinder 51a, and a cover body 51d. A syringe channel 51c penetrating from the discharge port provided at the bottom of the cylinder 51a to the back surface is formed in the container base 3.

  The cover body 51d has flexibility in the sliding direction of the plunger 51b, and is connected to the cylinder 51a and the plunger 51b. The cover body 51d is for blocking the portion of the inner wall of the cylinder 51a that the plunger 51b contacts with the atmosphere outside the cylinder 51a while maintaining airtightness, and is surrounded by the cylinder 51a, the plunger 51b, and the cover body 51d. A sealing space 51e is formed. The end of the cover body 51d on the side connected to the cylinder 51a is fixed to the upper end of the cylinder 51a with a cylinder cap 51f while ensuring airtightness. The end of the cover body 51d on the side connected to the plunger 51b is connected to the upper surface of the plunger 51b with an adhesive while ensuring airtightness. However, the method and position of connecting the cover body 51d to the cylinder 51a and the plunger 51b are not limited to this.

  Thus, the cover body 51d is connected to the cylinder 51a and the plunger 51b to form a sealed space 51e surrounded by the cylinder 51a, the plunger 51b, and the cover body 51d, so that the space between the cylinder 51a and the plunger 51b is formed. Therefore, it is possible to prevent foreign substances from entering and environmental contamination of the liquid to the outside. Since the cover body 51d is flexible in the sliding direction of the plunger 51b, the sliding operation of the plunger 51b is possible.

  In this embodiment, the plunger 51b and the cover body 51d are formed by separate members, but the plunger and the cover body may be integrally formed. An example of the integrally formed plunger and cover material is silicone rubber.

  The container base 3 is also provided with a bellows 53 at a position different from the arrangement region of the reaction container 5, the drain spaces 29 and 31, the containers 35, 37, and 39 and the syringe 51. The bellows 53 has an internal space sealed, and the internal capacity is passively variable by expanding and contracting. For example, the bellows 53 is disposed in a through hole 53 a provided in the container base 3.

  A container bottom 55 is attached to the back surface of the container base 3 at a position different from the arrangement region of the reaction containers 5. An air vent channel 53 b is provided in the container bottom 55 at a position communicating with the bellows 53. The bellows 53 is in close contact with the surface of the container bottom 55. The container bottom 55 is for guiding the flow paths 13a, 23a, 25a, 35a, 35b, 37a, 37b, 39a, 39b, 51c, 53b to a predetermined port position.

The container base 3 container and the bottom 55 are provided with a syringe air vent channel 53 c having one end connected to the sealed space 51 e and the other end made a bellows 53. Illustration of the syringe air vent channel 53c in FIG. 1 (A) is omitted.
Thus, since the syringe air vent channel 53c having one end connected to the sealed space 51e and the other end bellows 53 is provided, the sealed space 51e is blocked from the atmosphere outside the reaction vessel plate 1. When the plunger 51b slides, the pressure change in the sealed space 51e accompanying the change in the internal capacity of the sealed space 51e can be alleviated, and the plunger 51b can be slid smoothly.

  A rotary switching valve 63 including a disc-shaped seal plate 57, a rotor upper 59, and a rotor base 61 is provided on the surface of the container bottom 55 opposite to the container base 3. The switching valve 63 is attached to the container bottom 55 by a lock 65.

The seal plate 57 is provided in the vicinity of the peripheral edge thereof, and is connected to any of the flow paths 13a, 35a, 37a, 39a, and the flow paths 23a, 25a, 35b, A through groove 57b connected to at least two of 37b, 39b, and 53b and a through hole 57c provided in the center and connected to the syringe flow path 51c are provided.
The rotor upper 59 includes a through hole 59a provided at the same position as the through hole 57a of the seal plate 57, a groove 59b provided on the surface corresponding to the through groove 57b of the seal plate 57, and a through hole provided in the center. A hole 59c is provided.
The rotor base 61 is provided with a groove 61a on its surface for connecting two peripheral holes 59a and 59c disposed at the center and the peripheral portion of the rotor upper 59.

The syringe channel 51c is connected to one of the channels 13a, 35a, 37a, 39a by the rotation of the switching valve 63, and at the same time, the air vent channel 53b is connected to the channels 23a, 25a, 35b, 37b, 39b. Connected to at least one of them.
In the position of the switching valve 63 shown in FIG. 1A, the syringe flow path 51c is not connected to any of the flow paths 13a, 35a, 37a, 39a, and the air vent flow path 53b is also connected to the flow paths 23a, 25a. , 35b, 37b, 39b are not connected to the initial position.

  In the reaction vessel plate 1, the injection channel 17 is formed so as to maintain the liquid tightness of the reaction vessel 5 with no pressure difference between the reaction vessel 5 and the injection channel 17. The reaction vessel air vent channel 19 is also formed so as to maintain the liquid tightness of the reaction vessel 5 in the state where there is no pressure difference between the reaction vessel 5 and the reaction vessel air vent channel 19. The main flow path 13 of the reaction container flow path, the liquid drain space 29 to which the main flow path 13 is connected, and the drain space air vent flow path 23 can be sealed by switching the switching valve 63. The containers 35, 37, and 39 are sealed with a septum 41 or a film 47. The flow paths 35 a, 35 b, 37 a, 37 b, 39 a, 39 b connected to the containers 35, 37, 39 can be sealed by switching the switching valve 63. One end of the air vent channel 53b is connected to the bellows 53 and sealed. Thus, the container and flow path inside the reaction container plate 1 are formed in a closed system. Even when the air vent channel 53b is connected to the atmosphere outside the reaction vessel plate 1 without the bellows 53, the air vent channel 53b is switched to the reaction vessel by switching the switching valve 63. Since it can block | block with the flow paths other than the container inside the plate 1 and the air vent flow path 53b, the container and flow path in which a liquid is accommodated or a liquid flows can be made into a closed system.

FIG. 8 is a sectional view showing the reaction processing apparatus for processing the reaction container plate 1 shown in FIG. Since the structure of the reaction vessel plate 1 is the same as that shown in FIG.
The reaction processing apparatus includes a temperature adjustment mechanism 67 for adjusting the temperature of the reaction vessel 5, a syringe drive unit 69 for driving the syringe 51, and a switching valve drive unit 71 for switching the switching valve 63.

  9 to 15 are plan views for explaining the operation of introducing the sample liquid from the sample container 35 into the reaction container 5. This operation will be described with reference to FIGS. 1 and 9 to 15.

  In a state where the sample container 35, the reagent container 37, and the air suction container 39 are held at the first holding position, a dispensing device having a sharp point (not shown) is used to penetrate the septum 41 on the sample container 35, for example. Dispense 5 μL of the sample solution into the sample container 35. After dispensing the sample solution, pull out the dispensing device. The through hole of the septum 41 when the dispensing instrument is pulled out is closed by the elasticity of the septum 41.

  The sample container 35, the reagent container 37, and the air suction container 39 held at the first holding position are pushed into the container base 3 and moved to the second holding position. Thereby, the sample container main space 35g and the sample container channel 35a, the sample container air vent space 35i and the sample container air vent channel 35b, the reagent container main space 37g and the reagent container channel 37a, the reagent container air vent space 37i and the reagent The container air vent channel 37b, the air suction container main space 39g, the air suction container channel 39a, the air suction container air vent space 39i, and the air suction container air vent channel 39b are connected with airtightness. Before dispensing the sample liquid into the sample container 35, the sample container 35, the reagent container 37, and the air suction container 39 are pushed into the container base 3 and moved to the second holding position, and then the sample container 35 is moved. The sample solution may be dispensed inside.

The syringe drive unit 69 is connected to the plunger 51 b of the syringe 51, and the switching valve drive unit 71 is connected to the switching valve 63.
As shown in FIG. 9, the switching valve 63 is rotated from the state of the switching valve 63 shown in FIG. 1A to connect the sample flow path 35a and the syringe flow path 51c, and the sample container air vent flow path 35b is aired. It connects with the extraction flow path 53b. At this time, the air vent channels 37b and 39b are also connected to the air vent channel 53b. For example, 45 μL of the reagent 45 is accommodated in the sample container 35.

  The plunger 51b of the syringe 51 is slid to mix the sample liquid and the reagent 45 in the sample container 35. Thereafter, the mixed solution in the sample container 35 is sucked into the flow path in the switching valve 63, the syringe flow path 51c, and the syringe 51 by, for example, 10 μL. At this time, since the sample container 35 is connected to the bellows 53 via the air vent channels 35e, 35d, 35b, the switching valve 63 and the air vent channel 53b, the gas capacity in the sample container 35 is changed. The bellows 53 expands and contracts. Further, the sliding of the plunger 51b deforms the cover body 51d, and the internal capacity of the sealed space 51e (see FIG. 1C) changes. Since the sealed space 51e is connected to the bellows 53 via the syringe air vent channel 53c, the bellows 53 expands and contracts even when the internal capacity of the sealed space 51e changes. Even in the operation process described below, the bellows 53 expands and contracts with the change in the internal capacity of the sealed space 51e due to the sliding of the plunger 51b.

  As shown in FIG. 10, the switching valve 63 is rotated to connect the reagent channel 37a and the syringe channel 51c, and the reagent container air vent channel 37b is connected to the air vent channel 53b. For example, 190 μL of dilution water 49 is accommodated in the reagent container 37. The mixed solution sucked into the flow path in the switching valve 63, the syringe flow path 51 c and the syringe 51 is injected into the reagent container 37, and the syringe 51 is slid to mix the mixed liquid and the dilution water 49. For example, all of the diluted mixed solution is sucked into the flow path in the switching valve 63, the syringe flow path 51c, and the syringe 51, that is, 200 μL. At this time, since the reagent container 37 is connected to the bellows 53 via the air vent channels 37e, 37d, 37b, the switching valve 63 and the air vent channel 53b, the gas capacity in the reagent container 37 is changed. The bellows 53 expands and contracts.

  As shown in FIG. 11, the switching valve 63 is rotated to connect the flow path 13 a connected to one end of the main flow path 13 and the syringe flow path 51 c, and the flow connected to the liquid drain space 29 and the air drain space 31. The paths 23a and 25a are connected to the air vent channel 53b. The syringe 51 is driven in the pushing direction to send the diluted mixed solution sucked into the flow path in the switching valve 63, the syringe flow path 51 c, and the syringe 51 to the main flow path 13. The diluted mixed liquid injected from the flow path 13a side into the main flow path 13 fills the metering flow path 15 in order from the flow path 13a side and reaches the liquid drain space 29 as indicated by the embossments and arrows. In the introduction pressure state when the diluted mixture is introduced into the main channel 13 and the metering channel 15, the injection channel 17 allows gas to pass but does not allow the diluted mixture to pass. The gas in the metering channel 15 moves into the reaction vessel 5 through the injection channel 17 as the metering channel 15 is filled with the diluted mixed solution. As this gas moves, a part of the gas in the reaction vessel 5 moves to the reaction vessel air vent channels 19 and 21. Furthermore, the gas in the flow path from the reaction container air vent flow path 19 to the bellows 53 sequentially moves to the bellows 53 side (see white arrow). Further, when the diluted mixed liquid is injected into the liquid drain space 29, the gas in the flow path from the liquid drain space 29 to the bellows 53 sequentially moves toward the bellows 53 (see the white arrow). As a result, the bellows 53 expands.

  As shown in FIG. 12, the switching valve 63 is rotated to connect the air suction channel 39a and the syringe channel 51c, and the air suction container air vent channel 39b is connected to the air vent channel 53b. The syringe 51 is driven to the suction side, and the gas in the air suction container 39 is sucked into the flow path in the switching valve 63, the syringe flow path 51 c, and the syringe 51. At this time, since the air suction container 39 is connected to the bellows 53 via the air vent channels 39e, 39d, 39b, the switching valve 63 and the air vent channel 53b, the pressure inside the air suction container 39 is reduced. As a result, the bellows 53 contracts (see the white arrow).

  As shown in FIG. 13, the switching valve 63 is rotated to connect the flow path 13a and the syringe flow path 51c, and connect the flow paths 23a and 25a to the air vent flow path 53b as in the connection state of FIG. The syringe 51 is driven in the pushing direction, and the flow path in the switching valve 63, the syringe flow path 51c, and the gas in the syringe 51 are sent to the main flow path 13 to purge the diluted mixed liquid in the main flow path 13 (open arrow) reference). In the purge pressure state at this time, the dilute mixed liquid does not pass through the injection flow path 17, and therefore the dilute mixed liquid remains in the measuring flow path 15 (see embossing). The purged diluted liquid mixture is accommodated in the liquid drain space 29. Further, when the diluted mixed liquid is injected into the liquid drain space 29, the gas in the flow path from the liquid drain space 29 to the bellows 53 sequentially moves toward the bellows 53 (see the white arrow). As a result, the bellows 53 expands.

  As shown in FIG. 14, the switching valve 63 is rotated to connect the air suction flow path 39a and the syringe flow path 51c as in the connection state of FIG. 12, and the air suction container air vent flow path 39b is vented. Connect to the flow path 53b. The syringe 51 is driven to the suction side, and the gas in the air suction container 39 is sucked into the flow path in the switching valve 63, the syringe flow path 51 c, and the syringe 51. At this time, the bellows 53 contracts as described with reference to FIG. 12 (see the white arrow).

  As shown in FIG. 15, the switching valve 63 is rotated to connect the flow path 13a and the syringe flow path 51c, and connect the flow path 25a to the air vent flow path 53b. This connection state differs from the connection state shown in FIGS. 11 and 13 in that the liquid drain space 29 to which the downstream end of the main flow path 13 is connected is not connected to the flow path in the switching valve 63. The syringe 51 is driven in the pushing direction. Since the downstream end of the main flow path 13 is not connected to the bellows 53, the inside of the main flow path 13 is pressurized larger than the liquid introduction pressure and the purge introduction pressure. As a result, the diluted mixed solution in the metering channel 15 is injected into the reaction vessel 5 through the injection channel 17. After the diluted mixed solution is injected into the reaction vessel 5, a part of the gas in the main channel 13 flows into the reaction vessel 5 through the metering channel 15 and the injection channel 17. At this time, the reaction vessel 5 is connected to the bellows 53 via the reaction vessel air vent channels 19 and 21, the air drain space 31, the drain space air vent channel 25a, and the air vent channel 53b. The gas between the bellows 53 sequentially moves toward the bellows 53 (see the white arrow). As a result, the bellows 53 expands.

After the switching valve 63 is connected as shown in FIG. 1 and the container, flow path and drain space inside the reaction container plate 1 are sealed, the reaction container 5 is heated by the temperature control mechanism 67 to melt the wax 9. Thereby, the diluted mixed solution injected into the reaction vessel 5 enters under the wax 9, and the diluted mixed solution and the reagent 7 are mixed and reacted. Thus, according to the reaction container plate 1, the reaction process can be performed in a closed system.
Before injecting the diluted mixed solution into the reaction vessel 5, the reaction vessel 5 is heated by the temperature control mechanism 67 to melt the wax 9, and the wax 9 is injected when the diluted mixed solution is injected into the reaction vessel 5. May be melted. In this case, the diluted mixed solution injected into the reaction vessel 5 immediately enters under the wax 9, and the diluted mixed solution and the reagent 7 are mixed and reacted. Even if the connection state of the switching valve 63 is the state shown in FIG. 15, the sealed system is secured by the bellows 53. If the switching valve 63 is brought into the connection state shown in FIG. 1 after the diluted mixed solution is injected, the container, flow path and drain space inside the reaction container plate 1 can be sealed. Here, the timing for switching the switching valve 63 to the connected state in FIG. 1 may be any timing from immediately after the injection of the diluted mixed solution to the end of the reaction of the diluted mixed solution and the reagent 7, or the diluted mixed solution and the reagent 7. It may be after the completion of the reaction.
Thus, according to the reaction vessel plate 1, the reaction process can be performed in a closed system, and a closed system can be formed before and after the reaction process.

  In this embodiment, the grooves for forming the flow paths 13, 15, 17, 19, 21, and 23 are formed in the flow path base 11, but the present invention is not limited to this, and the flow of these is not limited. A groove for forming all or part of the path may be formed on the surface of the container base 3.

  FIG. 16 is an enlarged schematic cross-sectional view showing the vicinity of the reaction vessel in another embodiment of the reaction vessel plate. This embodiment is the same as the above-described embodiment described with reference to FIGS. 1 to 15 except that a flow path spacer is disposed between the container base and the flow path base.

  A flow path spacer 73 is disposed on the container base 3 so as to cover the arrangement region of the reaction containers 5, and a flow path base 11 and a flow path cover 33 are further disposed in that order. The channel spacer 73 is made of, for example, PDMS or silicone rubber. The thickness of the channel spacer 73 is, for example, 0.5 to 5.0 mm. The flow path spacer 73 includes a convex portion 75 protruding into the reaction container 5 for each reaction container 5. The convex portion 75 has a substantially trapezoidal cross section. For example, the base end has a width of 1.0 to 2.8 mm, the tip has a width of 0.2 to 0.5 mm, and the tip has a base end. It is thinner than Further, the surface of the convex portion 75 is subjected to super water repellent treatment. However, the surface of the convex portion 75 may not necessarily be subjected to the water repellent treatment.

Further, the flow path spacer 73 is provided with an injection flow path 77 formed of a through hole penetrating from the tip end portion of the convex portion 75 to the opposite surface for each position where the convex portion 75 is formed. The inner diameter of the injection channel 77 is, for example, 500 μm. The opening on the flow channel base 11 side of the injection flow channel 77 is connected to the injection flow channel 17 of the flow channel base 11. In this embodiment, the channel base 11 is not provided with the recess 27 as compared with the above-described embodiment described with reference to FIGS.
Further, the flow path spacer 73 is also provided with a reaction container air vent flow path 79 including a through hole for communicating the reaction container air vent flow path 19 of the flow path base 11 and the reaction container 5.

  Although not shown, the channel spacer 73 includes both end portions of the main channel 13, end portions of the reaction vessel air vent channel 21 on the air drain space 31 side, and both ends of the drain space air vent channels 23 and 25. The part is provided with a through hole, and the flow paths 13, 21, 23, 25 are connected to the containers 29, 31 or the flow paths 23 a, 25 b provided in the container base 3.

  In this embodiment, the end of the injection flow channel 77 opposite to the injection flow channel 15 (the other end of the injection flow channel) is disposed at the tip of a convex portion 75 formed to protrude from the inner upper surface of the reaction vessel 5. Therefore, the liquid injected into the reaction vessel 5 through the injection flow channels 15 and 77 can be easily dropped into the reaction vessel 5.

  Further, when the liquid is discharged from the tip of the convex portion 75 through the injection channel 77, the tip of the convex portion 75 is adjusted so that the liquid droplet formed at the tip of the convex portion 75 contacts the side wall of the reaction vessel 5. If it arrange | positions in the side wall vicinity of the reaction container 5, a liquid can be inject | poured in the reaction container 5 along the side wall of the reaction container 5, and a liquid can be inject | poured in the reaction container 5 more reliably. However, the formation position of the convex portion 75 may be a position where a droplet formed at the tip of the convex portion 75 does not contact the side wall of the reaction vessel 5.

FIG. 17 is an enlarged schematic cross-sectional view showing the vicinity of a reaction vessel of still another embodiment of the reaction vessel plate.
This embodiment further includes a protrusion 81 inside the reaction vessel 5 as compared to the embodiment described with reference to FIG. The tip of the protrusion 81 is disposed below the tip of the protrusion 75. Thereby, it becomes easy to guide the droplet formed at the tip of the convex portion 75 into the reaction vessel 5. In particular, it is particularly effective if a hydrophilic treatment is applied to at least the tip surface of the protrusion 81.

FIG. 18 is a schematic cross-sectional view showing, in an enlarged manner, the vicinity of the reaction vessel of another embodiment of the reaction vessel plate.
In this embodiment, compared to the embodiment described with reference to FIG. 17, the stepped portion 83 formed on the side wall of the reaction vessel 5 and the upper surface of the reaction vessel 5 are formed on the upper surface of the stepped portion 83 with a gap. Further provided is a convex ridge 85. The step part 83 and the protruding line part 85 are formed in an annular shape when viewed from above. The tip of the ridge 85 is disposed at a distance from the side wall of the reaction vessel 5.
Since the tip of the ridge 85 is spaced from the upper surface and side surface of the reaction vessel 5, the liquid contained in the reaction vessel 5 reaches the upper surface of the reaction vessel 5 along the side wall of the reaction vessel 5. Can be prevented. This effect is particularly effective when a water-repellent treatment is performed on at least the tip of the ridge 85.

The configuration provided with the step portion 83 and the convex strip portion 85 shown in FIG. 18 can also be applied to the embodiment shown in FIG.
Moreover, in each Example demonstrated with reference to FIG.16, FIG.17 or FIG. 18, the groove | channel for forming the flow path 13,15,17,19,21,23 is formed in the flow path base 11. FIG. However, the present invention is not limited to this, and the grooves for forming all or part of the flow paths are the surface of the flow path spacer 73 on the flow path base 11 side, the container base 3 of the flow path spacer 73. It may be formed on either the side surface or the surface of the container base 3.

In addition, regarding the syringe 51, a part of the cylinder 51 a may be formed by a part of the switching valve 63.
19A and 19B are diagrams showing still another embodiment of the reaction vessel plate. FIG. 19A is a schematic plan view, and FIG. 19B is a sectional view taken along the line H-H in FIG. Schematic cross-sectional view including the cross section of the passage 17, the reaction container air vent channels 19, 21, the liquid drain space 29, the air drain space 31, and the bellows 53, (C) is an enlarged view of the vicinity of the syringe 51 and the bellows 53. It is a schematic sectional drawing shown. 20A and 20B are schematic exploded views of the switching valve, in which FIG. 20A is a plan view and a cross-sectional view of a seal plate, FIG. 20B is a plan view and a cross-sectional view of a rotor upper, and FIG. A cross-sectional view is shown.

In this embodiment, the cylinder 87 a of the syringe 87 is formed of a resin material such as polypropylene or polycarbonate, and is integrally formed with the rotor upper 91 of the switching valve 95.
The syringe 87 is formed by a cylinder 87a disposed in a through hole formed in the container base 3 and the container bottom 55, a plunger 87b disposed in the cylinder 87a, and a cover body 87d.

  The cover body 87d has flexibility in the sliding direction of the plunger 87b, and is connected to the cylinder 87a and the plunger 87b. The cover body 87d is for shutting off the portion of the inner wall of the cylinder 87a that contacts the plunger 87b while maintaining airtightness from the atmosphere outside the cylinder 87a. The cover body 87d is surrounded by the cylinder 87a, the plunger 87b, and the cover body 87d. A sealing space 87e is formed.

  The end of the cover body 87d on the side connected to the cylinder 87a is fixed to the upper end of the cylinder 87a with a cylinder cap 87f while ensuring airtightness. Further, the end of the cover body 87d on the side connected to the plunger 87b is connected to the upper surface of the plunger 87b with an adhesive while ensuring airtightness. However, the method and position for connecting the cover body 87d to the cylinder 87a and the plunger 87b are not limited thereto. The plunger and the cover body may be integrally formed. An example of the integrally formed plunger and cover material is silicone rubber.

  As described above, the cover body 87d is connected to the cylinder 87a and the plunger 87b to form a sealed space 87e surrounded by the cylinder 87a, the plunger 87b, and the cover body 87d, so that the space between the cylinder 87a and the plunger 87b is formed. Therefore, it is possible to prevent foreign substances from entering and environmental contamination of the liquid to the outside. Since the cover body 87d has flexibility in the sliding direction of the plunger 87b, the sliding operation of the plunger 87b is possible.

The syringe air vent channel 53c and the switching valve 95 will be described with reference to FIG.
The switching valve 95 is formed by a disc-shaped seal plate 89, a rotor upper 91 and a rotor base 93. The switching valve 95 is attached to the container bottom 55 by a lock 65.

  The seal plate 89 is provided in the vicinity of the peripheral edge portion thereof, and is connected to any of the flow paths 13a, 35a, 37a, 39a, and the flow paths 23a, 25a, 35b, A through groove 89b connected to at least two of 37b, 39b, and 53b and a through hole 89c provided at the center and into which the cylinder 87a is inserted are provided. A fluororesin layer (not shown) is formed on the surface of the seal plate 89 facing the container bottom 55.

  The rotor upper 91 corresponds to a cylindrical cylinder 87 a provided at the center of one surface thereof, a through hole 91 a provided at the same position as the through hole 89 a of the seal plate 89, and a through groove 89 b of the seal plate 89. Then, a groove 91b provided on the surface, a through hole 91c provided in the groove 91b, and a through hole 91d provided in the center are provided. The through hole 91d is provided at the bottom of the cylinder 87a and constitutes a discharge port of the cylinder 87a.

  The rotor upper 91 is also formed with a syringe air vent channel 53c formed of a through hole penetrating from the upper end surface of the cylinder 87a to the back surface of the rotor upper 91. A cutout is formed in the upper end surface of the cylinder 87a from the inner wall of the cylinder 87a to the syringe air vent channel 53c. By this notch, as shown in FIG. 19C, the sealing space 87e and the syringe air vent channel 53c communicate with each other with the upper end surface of the cylinder 87a covered with the cover body 87d.

  The rotor base 93 has a groove 93a for connecting the through hole 91a and the through hole 91d formed in the rotor upper 91 on the surface to be bonded to the back surface of the rotor upper 91, and a syringe air vent formed in the rotor upper 91. A groove 93b for connecting the flow paths 53c and 91c is provided.

As shown in FIG. 19, the seal plate 89, the rotor upper 91, and the rotor base 93 are arranged such that a cylinder 87 a is inserted into a through hole 89 c of the seal plate 89 and overlapped to form a switching valve 95.
The through hole 91d of the rotor upper 91 that constitutes the discharge port of the cylinder 87a is connected to the through hole 89a of the seal plate 89 through the groove 93a of the rotor base 93 and the through hole 91a of the rotor upper 91.
The sealing space 87e (see FIG. 19) is connected to the through groove 89b of the seal plate 89 through the syringe air vent channel 53c, the groove 93b of the rotor base 93, the through hole 91c and the through groove 91b of the rotor upper 91. The

The flow path connection will be described with reference to FIGS. 19 and 20.
Through the rotation of the switching valve 95, the through hole 91d of the rotor upper 91 constituting the discharge port of the cylinder 87a is one of the flow paths 13a, 35a, 37a, 39a via the groove 93a, the through hole 91a, and the through hole 89a. Connected to.
At the same time as the through hole 91d is connected to any of the flow paths 13a, 35a, 37a, 39a, the air vent flow path 53b is connected to the flow paths 23a, 25a, 35b, 37b, through the through grooves 89b, 91b. It is connected to at least one of 39b. At this time, the sealing space 87e is connected to the air vent channel 53b via the cylinder air vent channel 53c, the groove 93b, the through hole 91c, and the through grooves 89b and 91b.

According to this embodiment, the flow path between the syringe 87 and the switching valve 95 can be eliminated, and the flow path configuration is simplified.
Further, when there is a seam in the flow path, liquid or gas leakage may occur at the seam part, or a liquid pool may occur at the seam part. In this embodiment, since the cylinder 87a and the rotor upper 91 are integrally formed, there is no joint between the flow path between the syringe 87 and the switching valve 95, and leakage and liquid pool between the syringe 87 and the switching valve 95 are generated. Can be eliminated.
In addition, when a liquid puddle occurs at the joint, there is a concern about the volume reduction of the liquid to be pumped, or liquid carry-over, contamination, or concentration fluctuation due to mixing of the liquid in the puddle with another liquid to be pumped. In this embodiment, these concerns between the syringe 87 and the switching valve 95 can be eliminated.

  Further, when a syringe is arranged on the switching valve, if a flow path 51c is formed between the syringe 51 and the switching valve 63 as shown in FIG. 1, a cylinder is formed in the portion where the flow path 51c is formed. In the embodiment shown in FIG. 19, since there is no flow path between the syringe 87 and the switching valve 95, the capacity of the cylinder 87a can be reduced even if the cylinders 51a and 81a have the same planar size. It can be made larger than the cylinder 51a.

When the cylinder 87a is formed with the same capacity as the cylinder 51a, the height of the cylinder 87a is the same plane size as the cylinder 51a and lower than the cylinder 51a, or the plane size of the cylinder 87a is the same height as the cylinder 51a. It can be made smaller than the cylinder 51a.
For example, even when the upper end surface of the cylinder 51a has to be arranged so as to protrude from the upper surface of the entire reaction container plate 1 due to the limitation of the planar size of the entire reaction container plate 1, the height of the cylinder 87a is the same as that of the cylinder 51a. Further, since the planar size can be lower than that of the cylinder 51a, the upper end surface of the cylinder 87a can be disposed at the same position as the upper surface of the entire reaction vessel plate 1 or at a position lower than that. As a result, there is a problem when the upper end surface of the cylinder protrudes from the upper surface of the entire reaction container plate, for example, a problem when stacking and storing a plurality of reaction container plates, or a problem such as an increase in packaging of the reaction container plate. Can be eliminated.
Further, if the plane size of the cylinder 87a is made smaller than that of the cylinder 51a with the same capacity as the cylinder 51a, the plane size of the entire reaction vessel plate 1 can be reduced.

  The embodiments of the present invention have been described above, but the present invention is not limited to these, and the shape, material, arrangement, number, dimensions, flow path configuration, etc. are examples, and are described in the claims. Various modifications are possible within the scope of the present invention.

For example, the bellows 53 connected to the air vent channel 53b may have another structure as long as the capacity is a variable capacity member whose internal capacity is passively variable. Examples of such a structure include a bag-like material made of a flexible material and a syringe-like material.
Further, the capacity variable member such as the bellows 53 may not necessarily be provided.
In addition, if the containers 35, 37, and 39 do not contain a liquid such as a reagent in advance, it is not always necessary to provide the flow paths 35e, 37e, and 39e made of pores in a part of the air vent flow path.

Further, in the above embodiment, the air vent channels 35b, 37b, 39b provided in communication with the containers 35, 37, 39 as sealing containers are connected to the air vent channel 53b via the switching valve 63. However, the air vent channel provided in communication with the sealing container may be directly connected to the outside of the reaction container plate or a capacity variable part such as the bellows 53.
Moreover, you may use the cap which can be opened and closed as a sealing method of the containers 35, 37, and 39.

Moreover, in the said Example, although the container base 3 is formed with one component, the container base may be formed with several components.
The reagent in the reaction vessel 5 may be a dry reagent.
In addition, the reagent may not be stored in advance in the sample container 35 or the reaction container 5.
In the above embodiment, the dilution water 49 is stored in the reagent container 37, but the reagent may be stored instead of the dilution water 49.

  Further, the container base 3 may be provided with a gene amplification container for performing a gene amplification reaction. For example, if the reagent container 37 is emptied, it can be used as a gene amplification container.

In addition, if a reagent for performing a gene amplification reaction is accommodated in the reaction container 5, the gene amplification reaction can be performed in the reaction container 5.
Further, when a gene is contained in the liquid introduced into the main flow path 13, a probe that reacts with the gene may be provided in the reaction vessel 5.

Moreover, in the said Example, although the syringe 51 is arrange | positioned on the switching valve 63, the position which arrange | positions the syringe 51 is not limited on the switching valve 63, and may be anywhere.
In the above embodiment, the rotary switching valve 63 is used as the switching valve. However, the switching valve is not limited to this, and various flow path switching valves can be used. A plurality of switching valves may be provided.

  In the above embodiment, when the liquid filled in the metering channel 15 is injected into the reaction vessel 5 through the injection channel 17, the inside of the main channel 13 after air purge is pressurized to supply the liquid to the reaction vessel 5. However, the reaction treatment method of the present invention is not limited to this. For example, by changing the flow path configuration so that the inside of the reaction vessel air vent channel 21 can be made negative pressure using the syringe 51, and by making the inside of the reaction vessel air vent channel 21 and thus the reaction vessel 5 inside negative pressure. You may make it inject | pour into the reaction container 5 through the injection flow path 17 the liquid with which the measurement flow path 15 was filled. Alternatively, a separate syringe may be prepared so that the liquid is injected into the reaction vessel 5 with a positive pressure in the main channel 13 and a negative pressure in the reaction vessel 5.

  Moreover, in the said Example, although the one main flow path 13 was provided and all the measurement flow paths 15 were connected to the main flow path 13, a flow path structure is not limited to this. For example, a plurality of main channels may be provided, and one or a plurality of metering channels may be connected to each main channel.

In the reaction vessel plate of the present invention, the main channel can be sealed, but an example can be given in which the main channel can be sealed by opening and closing both ends of the main channel. Here, “the both ends of the main channel can be opened and closed” means that other space is connected to the end of the main channel, and the end of the other space opposite to the main channel can be opened and closed This includes cases where For example, in the above embodiment, the flow path 13a, the liquid drain space 29, the drain space air vent flow path 23, and the flow path 23a correspond to the other spaces.
In the reaction vessel plate of the present invention, the reaction vessel air vent channel can be sealed, but the end of the reaction vessel air vent channel opposite to the reaction vessel can be opened and closed. An example in which the reaction vessel air vent channel can be hermetically sealed can be given. Here, “the end of the reaction vessel air vent channel opposite to the reaction vessel can be opened and closed” means that the other end of the reaction vessel air vent channel opposite to the reaction vessel This includes a case where a space is connected and the end of the other space opposite to the reaction vessel air vent channel can be opened and closed. For example, in the above embodiment, the air drain space 31, the drain space air vent channel 25, and the channel 25a correspond to the other space.
In such an aspect, after the liquid is introduced into the main channel and the metering channel, the liquid in the main channel is then purged, and the liquid remaining in the metering channel is injected into the reaction vessel, Both ends of the main channel and the end of the reaction vessel air vent channel opposite to the reaction vessel are closed to seal the main channel and the reaction vessel air vent channel.

  The present invention can be used for measurement of various chemical reactions and biochemical reactions.

It is a figure which shows one Example of reaction container plate, (A) is a schematic top view, (B) is a cross section in the AA position of (A), a bellows, drain space, a measurement flow path, an injection flow path FIG. 4C is a schematic sectional view to which a section of the sample container air vent channel is added, and FIG. 5C is a schematic sectional view showing the vicinity of the syringe 51 and the bellows 53 in an enlarged manner. It is sectional drawing which decomposes | disassembles and shows the Example, and a schematic exploded perspective view of a switching valve. It is the schematic which shows the one reaction container vicinity of the Example, (A) is a top view, (B) is a perspective view, (C) is sectional drawing. It is the figure which expanded and showed the sample container accommodating part and sample container of the Example, (A) is a top view of a sample container accommodating part, (B) is sectional drawing in the BB position of (A), (C) is a plan view of the sample container, (D) is a cross-sectional view at the C-C position in (C), (E) is a cross-sectional view in which the sample container is arranged in the sample container accommodating portion at the first holding position, (F) ) Is a cross-sectional view in which the sample container is disposed in the sample container housing portion at the second holding position. It is the figure which expanded and showed the reagent container accommodating part and reagent container of the Example, (A) is a top view of a reagent container accommodating part, (B) is sectional drawing in the DD position of (A), (C) is a plan view of the reagent container, (D) is a cross-sectional view at the EE position of (C), (E) is a cross-sectional view in which the reagent container is arranged in the reagent container housing portion at the first holding position, (F) ) Is a cross-sectional view in which the reagent container is arranged in the reagent container housing portion at the second holding position. It is the figure which expanded and showed the container part for air suction and the container for air suction of the Example, (A) is a top view of the container part for air suction, (B) is FF position of (A) (C) is a plan view of the air suction container, (D) is a cross-sectional view at the GG position of (C), and (E) is the air suction container accommodating portion. Sectional drawing arrange | positioned in the 1st holding position, (F) is sectional drawing which has arrange | positioned the air suction container in the air suction container accommodating part in the 2nd holding position. It is a figure for demonstrating the relationship between the magnitude | size of a protrusion flow path, and the magnitude | size of a protrusion flow path accommodation part, (A) is sectional drawing of the reaction container centering on a protrusion flow path accommodation part, (B) is a protrusion flow. Sectional drawing of a path | route, (C) is sectional drawing which shows the state in which the protrusion flow path was accommodated in the protrusion flow path accommodating part. It is the schematic sectional drawing which showed the reaction processing apparatus for processing a reaction container plate with the reaction container plate. It is a top view for demonstrating the operation | movement which introduce | transduces a sample liquid into a reaction container from a sample container. FIG. 10 is a plan view for explaining the operation following FIG. 9. It is a top view for demonstrating the operation | movement following FIG. It is a top view for demonstrating the operation | movement following FIG. It is a top view for demonstrating the operation | movement following FIG. It is a top view for demonstrating the operation | movement following FIG. It is a top view for demonstrating the operation | movement following FIG. It is a schematic sectional drawing which expands and shows the reaction container vicinity of the other Example of the reaction container plate. It is a schematic sectional drawing which expands and shows the reaction container vicinity of the further another Example of the reaction container plate. It is a schematic sectional drawing which expands and shows the reaction container vicinity of the further another Example of the reaction container plate. FIG. 10 is a diagram showing still another embodiment of the reaction vessel plate, (A) is a schematic plan view, (B) is a cross section at the H-H position of (A), a metering channel 15, an injection channel 17, Schematic cross-sectional view including cross sections of the reaction vessel air vent channels 19 and 21, the liquid drain space 29, the air drain space 31, and the bellows 53, (C) is a schematic diagram illustrating the vicinity of the syringe 51 and the bellows 53 in an enlarged manner. FIG. It is a schematic exploded view of the switching valve of the embodiment, (A) is a plan view and a sectional view of a seal plate, (B) is a plan view and a sectional view of a rotor upper, (C) is a plan view of a rotor base. And a sectional view is shown.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Reaction container plate 3 Container base 5 Reaction container 11 Flow path base 13 Main flow path 15 Metering flow path 17 Injection flow path 19, 21 Reaction container air vent flow path 35 Sample container (sealing container)
35a Sample container flow path (sealing container flow path)
35b Sample container air vent channel 35c, 37c, 39c Locking claw (sealing container holding mechanism)
35d, 35e, 37d, 37e, 39d, 39e Protruding channel 35l, 35q, 37l, 37q, 39l, 39q Penetrable member 35p, 37p, 39p Protruding channel accommodating portion 35m, 35n, 37m, 37n, 39m, 39n Stop groove (sealing container holding mechanism)
37 Reagent containers (sealing containers)
37a Reagent container flow path (sealing container flow path)
37b Reagent container air vent channel 39 Air suction container (sealing container)
39a Air suction container channel (sealing container channel)
39b Air suction container air vent channel 41 Septum (elastic member)
51, 87 Syringe 51a, 87a Cylinder 51b, 87b Plunger 51d, 87d Cover body 51e, 87e Sealing space 53 Bellows (capacity variable part)
53c Syringe air vent channel 63, 95 Switching valve 73 Channel spacer 75 Protrusion 77 Injection channel 79 Reaction vessel air vent channel

Claims (15)

A sealed reaction vessel;
A reaction vessel channel connected to the reaction vessel;
A sealed container provided separately from the reaction container;
One end is a projecting channel protruding upward from below the sealing container, and the projecting channel is inserted from the bottom surface of the sealing container when the sealing container is used. A sealed container flow path to be connected;
Provided as a recess at the bottom of the sealing container, the bottom surface is a penetrable part that can be penetrated by the projecting channel when the sealed container is used, and accommodates the projecting channel that penetrates the penetrable part. A projecting channel housing portion for connecting the sealing container and the sealing container channel;
A syringe for feeding liquid;
A switching valve for connecting the syringe to the reaction vessel channel or the sealing vessel channel,
A reaction container plate that mixes a plurality of liquids in the sealed container by sucking and discharging liquid from the tip of the protruding flow path by the syringe and stirring the liquid in the sealed container. ,
The outer diameter of the projection channel and the inner diameter of the projection channel housing part are substantially the same diameter, and the portion accommodated in the projection channel housing part after the projection channel penetrates the penetrable part is a projection. The length is the same as or shorter than the depth of the flow path container,
The reaction vessel, the reaction vessel channel, the sealing vessel and the sealing vessel channel are closed systems ,
further
From the first state in which the penetrable part is opposed to the protruding flow path above the protruding flow path, the sealing container is moved from the first state in which the protruding flow path is received in the protruding flow path receiving portion. It is lowered into the sealing container, the first state and the second state in the reactor plate that further comprise a sealed container holding mechanism for holding respectively.   2. The reaction container plate according to claim 1, wherein a gap between the projection channel and the projection channel housing part is 1 mm or less in a state where the projection channel is contained in the projection channel housing unit. A second penetrable portion is provided at a position that does not come into contact with the liquid stored in the sealing container,
A sealing container air vent channel, wherein one end of the sealing container is a second projecting channel that penetrates the second penetrable portion and is connected to the sealing container when the sealing container is used. The reaction container plate according to any one of 1 to 2 . The reaction container plate according to any one of claims 1 to 3 , wherein the sealing container includes a sample container for containing a sample liquid. The sample container is sealed with a sealing member,
The reaction container plate according to claim 4 , wherein the sealing member includes an elastic member that can be penetrated by a member having a tip and can seal the sample container by an elastic force even after the member is pulled out. The reaction container plate according to any one of claims 1 to 5 , wherein a sample pretreatment liquid or a reagent is previously stored in the sealing container. The reaction container plate according to any one of claims 1 to 6 , wherein the sealing container includes a gene amplification container for performing a gene amplification reaction. The reaction vessel plate according to any one of claims 1 to 7 , wherein the switching valve is a rotary valve. The rotary valve has a port connected to the syringe at the center of rotation,
The reaction container plate according to claim 8 , wherein the syringe is disposed on the rotary valve. A reaction vessel air vent channel connected to the reaction vessel;
The reaction vessel flow path is a groove formed on a bonding surface of two bonded members, or a main flow path that is formed of a through hole formed in the groove and the substrate, and connected to the syringe;
A metering channel having a predetermined capacity branched from the main channel, and an injection channel having one end connected to the metering channel and the other end connected to the reaction vessel,
The main channel and the reaction vessel air vent channel can be sealed,
The injection channel is formed narrower than the metering channel, and the liquid introduction pressure state when the liquid is introduced into the main channel and the metering channel, and the purge when the liquid in the main channel is purged The reaction container plate according to any one of claims 1 to 9 , wherein the liquid is not passed in a pressure state but the liquid is passed in a pressurized state. The contact angle with water droplet of the injection channel is not less than 90 degrees, the injection channel and the metering channel reactor plate according to claim 1 0 area boundary is 1～10000000Myuemu ² of. Comprising a plurality of said reaction vessel, equipped with them the metering channel and the injection channel for each reaction vessel, the claim 1 0 or 1 1 in which a plurality of the measurement channel is connected to the main channel Reaction vessel plate. The other end of the injection channel is disposed at the tip of a convex portion formed to protrude from the inner upper surface of the reaction vessel, and the tip of the convex portion is thinner than the base end portion. reactor plate according to the 1 0 1 2 any one of. The reaction vessel reactor plate according to any one of claims 1 to 1 3 are configured at its bottom or optically measured light transmissive to allow the material from above. A reaction treatment method using the reactor plate according to any one of claims 1 0 to 14,
Filling the main channel and the metering channel with the introduction pressure,
Discharging the liquid in the main channel while allowing the gas to flow in the main channel and leaving the liquid in the metering channel;
By setting the inside of the main channel to a positive pressure greater than the introduction pressure, the inside of the reaction vessel to a negative pressure, or both the positive pressure and the negative pressure, Injecting the liquid into the reaction vessel.

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