JP2016144780A - Reaction device for forming microdroplet and electric field agitation method using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a reaction device that can form and agitate a dome-shaped microdroplet in a micro-volume container such as a microplate and a microchannel chip.SOLUTION: In a reaction device including micro-volume containers 1 which enables agitation by an electric field agitation method, each micro-volume container 1 has a bottom surface 5 and side walls 3 arranged along an outer periphery of the bottom surface 5, and a pedestal 6 having a height lower than that of the side walls 3 is installed at an inner boundary between the bottom surface 5 and the side walls 3 so as to prevent a solution 2 poured onto the bottom surface 5 from contacting with the side walls 3, whereby, when the solution 2 is poured until exceeding the height of the pedestal 6, a dome-shaped droplet 2 is formed and then agitated by applying a fluctuation electric field to the droplet 2.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a reaction device that has a minute volume container capable of forming dome-shaped minute droplets (microdrops) and can be used as a microtiter plate, a microchannel chip, or the like. Further, the present invention is characterized in that a minute droplet of a solution or a reaction liquid is formed in a minute volume container included in the reaction device, and the droplet is vibrated by applying a variable electric field to the droplet. The present invention relates to an electric field stirring method and a reaction promoting method. Furthermore, this invention relates to the electric field stirring system which has the said reaction device and a fluctuation electric field application apparatus.

  A microtiter plate (microplate) is an instrument for experiment and inspection in which a large number of microcapacity containers are aligned vertically and horizontally by forming a large number of wells on the plate. When a microtiter plate is used, a large number of reactions can be performed simultaneously in a large number of microcapacity containers on the plate. For this reason, it is used in clinical tests for diagnosing a large number of specimens simultaneously, scientific experiments for processing a large number of samples simultaneously, and the like. In particular, microtiter plates are often used for ELISA (Enzyme-Linked ImmunoSorbent Assay) that detects proteins in a specimen by antigen-antibody reaction. For example, in a sandwich ELISA method using a microtiter plate, first, an antibody that binds to a protein to be detected is fixed to the bottom surfaces of a plurality of microvolume containers of the microtiter plate. Next, a solution of each specimen and a solution of a primary antibody that binds to a protein to be detected (a protein that binds to an epitope different from that of the protein to which the antibody immobilized in the microvolume container binds), In addition to each minute volume container, an antigen-antibody reaction is performed. As a result, a complex of minute volume container-antibody-protein-1 primary antibody is formed in the minute volume container. Here, an enzyme-labeled secondary antibody that can bind to the primary antibody is added and bound to this complex. Then, after washing the unbound secondary antibody, a coloring reagent is added to cause color development. As a result, only the minute volume container to which the specimen containing the target protein is added develops color, and it is possible to simultaneously test a large number of specimens as to whether or not the specimen contains the target protein.

  On the other hand, a microfluidic chip uses a microfabrication technology to form a microchannel and a microcapacity container on a substrate, and in this microchannel and microcapacity container, mixing and reaction of chemical substances and biological substances, Separation, purification, detection, etc. are performed. In such a fine channel or a minute volume container, a fluid phenomenon that is completely different from that of a normal scale occurs. Therefore, a special reaction can be performed using this phenomenon. For example, in a Y-shaped fine channel where two inflow channels intersect to form one outflow channel, the solution A is supplied to one inflow channel and the solution B is supplied to the other inflow channel at a constant flow rate. If it flows in, in the outflow path where two inflow paths crossed and became one, it will become a laminar flow divided into two layers, without A solution and B solution mixing. Utilizing this phenomenon, chemical substances can be separated by a partitioning action between liquid phases. However, when viewed from the opposite side, there is a problem that it is difficult to mix the two solutions in the Y-shaped fine channel.

The present inventors have previously developed an electric field stirring method (also referred to as a non-contact stirring method) that stirs a droplet by applying a varying electric field to the droplet to vibrate the droplet. Has been found to be applicable to nucleic acid hybridization, ELISA, cell culture and the like (Patent Document 1).
This electric field agitation method requires formation of a dome-shaped droplet in order to apply a fluctuating electric field and vibrate. However, as shown in FIG. 5, in the conventional microtiter plate or the microcapacity container (1) in the microfluidic chip, the molecules of the solution (2) are attracted to the side wall (3) to form a meniscus (4). Therefore, the dome-shaped droplet cannot be formed, and it has not been assumed at all to stir by the electric field stirring method. In addition, since the amount of solution contained in the microtiter plate or microfluidic container in the microfluidic chip is very small, the solution scatters even if the solution is stirred by applying vibration, and the solution is stirred by a normal method. It was difficult to do.

JP 2010-119388 A

Conventional microcapacity containers have a problem that it is difficult to agitate the contained solution.
Therefore, in view of the above-described conventional situation, the present invention aims to develop a reaction device capable of forming a minute dome-shaped droplet (microdrop) and to enable stirring by an electric field stirring method. .

  In order to solve the above problems, the present inventors have conducted intensive research. As a result, in a reaction device having a minute volume solution, the minute volume container has a bottom surface and side walls arranged on the outer periphery of the bottom surface, and is poured onto the bottom surface. When the solution is poured beyond the height of the pedestal, a pedestal having a lower height than the side wall is provided at the inner boundary between the bottom surface and the side wall so that the solution does not come into contact with the side wall. It has been found that minute droplets (microdrops) can be formed, and the present invention has been completed.

That is, the present invention includes the following first invention related to a reaction device, the following second invention related to an electric field stirring method, the following third invention related to a reaction promoting method, and the following fourth related to an electric field stirring system. Invention.
1st invention is the reaction device which has a micro capacity | capacitance container, a micro capacity container has a bottom face and the side wall distribute | arranged to the outer periphery, A bottom surface is prevented so that the solution poured on the bottom face may not contact a side wall. A pedestal having a height lower than that of the side wall is provided at the inner boundary portion between the side wall and the side wall so that a dome-shaped droplet can be formed when the solution is poured up to the height of the pedestal. It relates to a reaction device.
The reaction device of the first invention is preferably a reaction device used for electric field agitation in which a fluctuation electric field is applied to droplets to perform agitation.
The above reaction device is preferably a reaction device further having an electrode for applying a varying electric field.
In the above reaction device, the pedestal may be a reaction device formed using a water-repellent material.
In the reaction device, the reaction device is preferably a ring-shaped pedestal having a width of 10 μm or more and a length of 30% or less of the width of the bottom surface.
In the above reaction device, the reaction device preferably has a droplet volume of 0.1 μl or more and less than 2000 μl.
In the above reaction device, the shape of the bottom surface can be circular.
In the above reaction device, a reaction device in which a plurality of minute volume containers are aligned vertically and horizontally can be used.
Moreover, in said reaction device, it can be set as the reaction device which further has a microchannel connected with a micro capacity | capacitance container.
And in this case, it can be set as the reaction device which provided the microcapacity container in the part which two or more microchannels cross | intersect.
A second invention relates to an electric field stirring method characterized in that a droplet is formed in a microcapacity container included in the reaction device of the first invention, and the droplet is vibrated by applying a varying electric field to the droplet. .
In the third invention, a droplet is formed in a micro-capacity container included in the reaction device of the first invention, and a fluctuation electric field is applied to the droplet to thereby vibrate the droplet and promote the reaction of the reaction solution. It is related with the reaction promotion method characterized by these.
A fourth invention relates to an electric field agitation system comprising the reaction device of the first invention and a variable electric field applying device that applies a variable electric field to droplets formed in a microcapacity container included in the reaction device.

In the reaction device of the first invention, since a pedestal having a height lower than that of the side wall is provided at the inner boundary portion between the bottom surface and the side wall of the microvolume container, the solution poured into the bottom surface does not contact the side wall. When the poured solution exceeds the height of the pedestal, there is no force to attract the molecules of the solution to the pedestal or the side wall in the part beyond the pedestal, and droplets can be formed by the surface tension of the solution, so that the micro volume There is an effect that minute droplets can be formed in the container. And the reaction device of 1st invention has the effect that it becomes possible to stir the solution in the micro capacity | capacitance container which a reaction device has by applying a fluctuation electric field.
The electric field agitation method of the second invention and the electric field agitation system of the fourth invention are such that a fluctuating electric field is applied to minute droplets formed in a minute volume container possessed by the reaction device of the first invention, whereby the surface of the droplets and Since the Coulomb force which fluctuates periodically is applied to the internal charges and the droplets vibrate, there is an effect that the solution in the microcapacity container included in the reaction device can be stirred.
The reaction promoting method of the third invention uses the reaction device of the first invention to form a minute droplet of the reaction solution in a minute volume container possessed by the reaction device, and applies a varying electric field to the droplet. Thus, the reaction solution in the minute volume container is stirred, and the reaction solution can be promoted. Moreover, the reaction promotion method of the third invention provides an effect that a reaction field that has not existed in the past can be provided by stirring by applying a varying electric field, and a reaction that cannot be obtained by the conventional method can be obtained.

It is a figure which shows one Embodiment of the reaction device of this invention. FIG. 1A shows a cross-sectional view of a microcapacity container included in the reaction device, and FIG. 1B shows a plan view of the microcapacity container included in the reaction device. It is a figure which shows one Embodiment of the reaction device of this invention made into the microtiter plate. FIG. 2 (A) shows a plan view of a microtiter plate in which a plurality of minute capacity containers are aligned vertically and horizontally, and FIG. 2 (B) shows a sectional view thereof. It is a figure which shows one Embodiment of the reaction device of this invention which has a micro capacity | capacitance container and the microchannel connected to it. FIG. 3A shows a plan view of a reaction device having a microcapacity container and a microchannel connected to the container, and FIG. 3B shows a cross-sectional view thereof. It is a figure which shows an example of the state which applied the fluctuation | variation electric field to the droplet and vibrated the droplet. FIG. 4A shows a cross-sectional view in a state where the charge accumulated in the electrode is minimum, and FIG. 4B shows a cross-sectional view in a state where the charge accumulated in the electrode is maximum. It is a figure which shows the microcapacity container in the conventional microtiter plate and a microfluidic chip | tip.

1. Reaction device of the present invention The reaction device of the present invention has a microcapacity container, the microcapacity container has a bottom surface and side walls arranged on the outer periphery thereof, and a solution poured onto the bottom surface A pedestal with a height lower than the side wall is provided at the inner boundary between the bottom surface and the side wall so as not to contact the side wall, so that when the solution is poured beyond the height of the pedestal, a dome-shaped minute Simple droplets can be formed.
Here, the reaction device may be any device as long as it has a minute volume container and performs reaction, mixing, stirring, etc. of the solution in the container. Examples of reaction devices include, but are not limited to, microtiter plates (microplates), microfluidic chips, PCR reaction tubes, and the like.

One embodiment of the reaction device of the present invention is shown in FIG. FIG. 1A shows a cross-sectional view of a minute capacity container portion of the reaction device, and FIG. 1B shows a plan view of the minute capacity container of the reaction device. As shown in FIG. 1 (A), the microcapacity container (1) of the reaction device of the present invention has a bottom surface (5) and a side wall (3) arranged on the outer periphery thereof. A pedestal (6) is provided at the inner boundary portion.
When the solution (2) is poured into the bottom surface (5) of the minute volume container (1), the volume of the solution (2) increases in contact with the bottom surface (5) and the pedestal (6). However, when the liquid level of the solution (2) exceeds the height of the pedestal (6), it becomes impossible to contact the pedestal (6), and the force that attracts the liquid molecules of the solution (2) to the pedestal (6). The center of the solution (2) rises due to the surface tension of the solution (2) and forms a fine droplet (microdrop) having a dome-shaped liquid surface.

  The reaction device of the present invention can thus form a minute dome-shaped droplet in the interior of a minute volume container. Here, the “droplet” refers to a solution whose center is raised by surface tension. . The “solution” may be any solvent or any other substance mixed in the solvent, such as a synthetic compound, a natural compound, a chemical substance such as a metal microparticle, a biomolecule such as a nucleic acid, a protein, a lipid, This includes biological samples such as cells, microorganisms, viruses, and living tissues mixed in a solvent.

In the present invention, the “bottom surface” means a portion that is horizontal when viewed as a whole, the “side wall” refers to a portion that stands vertically when viewed as a whole, and the “bottom surface” and the “side wall” are clear. There is no need to have a borderline.
The shape of the bottom surface of the microcapacity container included in the reaction device of the present invention may be any shape as long as it can hold a liquid droplet. For example, the shape is not limited to these, but a circle, a rectangle, a square, etc. It can be. Moreover, as long as it can hold | maintain a droplet, it may be a shape with an unevenness | corrugation.
When the bottom surface has a circular shape, it is preferable because droplets that are close to a hemisphere can be formed and droplets that do not collapse easily even when subjected to large vibrations. Here, the “circular” is a shape including not only a perfect circle but also an ellipse.

  The minute volume container which the reaction device of the present invention has is characterized in that a pedestal having a height lower than that of the side wall is provided at the inner boundary portion between the bottom surface and the side wall. Here, the “inner boundary portion” between the bottom surface and the side wall refers to a peripheral region of the boundary portion between the bottom surface and the side wall inside the minute capacity container. The “pedestal” may be any structure as long as the droplets are present so as not to contact the side wall. However, the pedestal does not need to be present so that the droplet does not come into full contact with the side wall. If the droplet can be formed, a part of the pedestal is interrupted, so that a small part of the droplet is formed. It may be in contact with the side wall. In particular, when connecting to a microchannel described later, a part of the pedestal may be interrupted at that portion.

However, when there is no inflow / outflow path for the content liquid such as a microtiter plate or the like, it is preferable that the liquid droplet does not completely contact the side wall in order to facilitate the formation of the liquid droplet. It is preferable that the ring-like shape is continuous without being interrupted along the inner boundary portion between the bottom surface and the side wall. Here, the ring shape includes not only a round ring but also a shape of a square ring or the like that matches the shape of the side wall.
When the pedestal is in a ring shape, the width of the pedestal is preferably 10 μm or more from the viewpoint of preventing droplets from coming into contact with the side walls, and from the viewpoint of reducing the area occupied by the pedestal in the minute volume container, The width of the pedestal should be 30% or less of the width of the bottom surface, more preferably 10% or less. Here, “the width of the bottom surface” refers to the shortest length of the shape of the bottom surface. For example, when the bottom shape is an ellipse, the “bottom width” means the minor axis of the ellipse, and when the bottom shape is a rectangle, the “bottom width” is the length of the shorter side. Means.
The height of the pedestal is preferably at least 20 μm or more so that droplets can be formed. The height of the pedestal is preferably 70% or less of the height of the side wall so that the height of the formed droplet does not exceed the height of the side wall.

If the pedestal is made of a highly hydrophilic material, the pedestal should be made of a water-repellent material because the droplets that exceed the height of the pedestal may be attracted to the upper side of the pedestal, causing the droplets to collapse. It is preferable to form them. Moreover, it is good also considering only the upper side of a base as a water-repellent material, without making the whole base into a water-repellent material.
Such a water-repellent material is not limited to these, but for example, a fluorine resin such as polytetrafluoroethylene, a silicon resin such as organopolysiloxane, a polyolefin such as polypropylene, or the like may be used. it can.

The upper side of the pedestal may be parallel to the bottom surface, but may be inclined with respect to the bottom surface. A petri dish with the upper side of the pedestal parallel to the bottom surface is preferable in terms of easy manufacture. On the other hand, a petri dish formed by inclining the upper side of the pedestal with respect to the bottom surface so that the height of the pedestal increases as it approaches the side wall is affected by the action of gravity even when liquid droplets protrude from the upper side of the pedestal. Since the force acts in the direction in which the droplets gather at the center, it is preferable in that the droplets are easily formed. When the pedestal is inclined, the upper side of the pedestal is preferably inclined by 20 degrees or more with respect to the bottom surface.
The side surface of the pedestal, where the pedestal is in contact with the droplet, can be perpendicular to the bottom surface, and can be inclined with respect to the surface perpendicular to the bottom surface. When the side surface of the pedestal is inclined 20 degrees or more to the side wall side with respect to the surface perpendicular to the bottom surface, meniscus can be made difficult to occur.

The pedestal can be manufactured by integral molding together with the bottom surface and the side wall, or can be manufactured by separately molding only the pedestal portion and fitting it into a minute capacity container composed of the bottom surface and the side wall. Further, the pedestal may be provided with a pedestal portion by forming the side wall into a shape that is bent stepwise.
The volume of the droplet is preferably 0.1 μl or more and less than 2000 μl in order to form a droplet that can be efficiently stirred.

The reaction device of the present invention is preferably provided with an electrode for applying a varying electric field to the droplet. The electrode may be arranged at any position as long as a varying electric field can be applied to the droplet to vibrate the droplet, but it is efficient to arrange the electrode at a position close to the droplet. However, if an electrode is arranged at a position in contact with the droplet, an electrochemical reaction occurs between the droplet and the electrode, so the droplet and the electrode need to be in non-contact.
If one electrode for applying a varying electric field is provided in the reaction device, the droplet can be vibrated. However, a varying electric field can also be applied using a set of anode and cathode.

The reaction device of the present invention can be a microtiter plate (microplate) in which a plurality of microcapacity containers are aligned vertically and horizontally.
One embodiment of the reaction device of the present invention as a microplate is shown in FIG. FIG. 2A shows a plan view of a microtiter plate in which a plurality of minute capacity containers are arranged vertically and horizontally, and FIG. 2B shows a cross-sectional view thereof. As shown in FIG. 2 (A), the reaction device (7) of the present invention, which is a microtiter plate, is provided with minute volume containers (1) aligned vertically and horizontally. And as shown in sectional drawing of FIG. 2 (B), the base (6) is provided in the inner boundary part of the bottom face (5) and side wall (3) of each micro capacity | capacitance container (1), Fine droplets (2) can be formed. An electrode (8) is provided below the reaction device (7) so that a varying electric field can be applied to each droplet (2). The reaction in the droplet (2) can be promoted by stirring the droplet (2) with a varying electric field. If a reaction such as ELISA is performed using this reaction device (7), clinical tests on a plurality of samples can be performed simultaneously and in a short time.

When the reaction device of the present invention is a microtiter plate, an electrode can be provided in the lower part as shown in FIG. 2B, but a variable electric field can be applied by installing an electrode in the upper part. . In this case, it is preferable to use an electrode having a plurality of convex portions on the flat plate electrode, and the convex portions existing at positions corresponding to the respective microcapacity containers, as the electrodes installed on the upper portion. In such an electrode, the electric charges at the convex portions are concentrated due to the edge effect, and the electric field is unevenly distributed under the plurality of convex portions, so that it is possible to efficiently apply the varying electric field to the droplets.
When the reaction device of the present invention is a microtiter plate, as shown in FIG. 2 (B), the side walls of the respective microcapacity containers may be separated from each other. It may be integrated with the side wall.

The reaction device of the present invention can be a reaction device further having a microchannel connected to a minute volume container.
One embodiment of the reaction device of the present invention having a microcapacity container and a microchannel connected to it is shown in FIG. FIG. 3A shows a plan view of a reaction device having a microcapacity container and a microchannel connected to it, and FIG. 3B shows a cross-sectional view thereof. As shown in FIG. 3 (A), the reaction device (7) of the present invention is formed with Y-shaped microchannels (9, 9 '), and the microchannels become two inflow channels. (9) intersects to form a micro flow path (9 ′) that becomes one outflow path. In the case of such a Y-shaped micro-channel, when the A solution is introduced into one inflow channel and the B solution is introduced into the other inflow channel at a constant flow rate, the two inflow channels intersect with each other. In the resulting outflow path, the A solution and the B solution are not mixed, and the laminar flow is divided into two layers. Thus, the Y-shaped fine channel has a problem that the two solutions do not mix. Therefore, a microcapacity container (1) is provided at a location where these microchannels intersect, and an electrode (8) is provided below the microcapacity container (1) as shown in FIG. While forming droplets in the capacity container (1), a varying electric field is applied by the electrode (8) so that the droplets can be stirred. Thereby, the two solutions flowing in from the two microchannels (9) can be mixed and allowed to flow out to the microchannel (9 ′).

Since the reaction device of the present invention can form minute droplets inside the minute volume container, it can be suitably used in an electric field stirring method in which a varying electric field is applied to the droplets to perform stirring. Accordingly, the present invention provides a reaction device for electric field stirring.
Details of the electric field stirring method will be described below.

2. Electric field agitation method of the present invention The electric field agitation method of the present invention is a method in which a droplet is formed in a microcapacity container included in the reaction device of the present invention, and a droplet is vibrated by applying a varying electric field to the droplet. Is a method of stirring.
Here, the “fluctuating electric field” means an electric field whose intensity varies periodically. Due to this fluctuating electric field, a Coulomb force acts on the charge on the surface or inside of the droplet, and the droplet is vibrated by periodically changing the Coulomb force.

  FIG. 4 is a diagram illustrating an example of a state in which a droplet is vibrated by applying a varying electric field to the droplet. FIG. 4A shows a cross-sectional view in a state where the charge accumulated in the electrode is minimum, and FIG. 4B shows a cross-sectional view in a state where the charge accumulated in the electrode is maximum.

In FIG. 4 (A), a droplet (2) is formed in a minute volume container composed of a bottom surface (5), a side wall (3), and a pedestal (6). Since the droplet (2) is polarized, a negative charge (10) exists on the surface of the droplet (2). In addition, some molecules dissolved in the liquid droplet (2) are negatively charged.
In order to apply a fluctuating electric field to the droplet (2), the upper electrode (11), the lower electrode (8), the high-voltage amplifier (12), the function generator (13), and a lead wire for electrically connecting them ( 14) is used. In this fluctuating electric field applying device, a signal generated by a function generator (13) is boosted by a high-voltage amplifier (12), and this voltage is applied to an electrode (11) installed in the upper part of the petri dish and an electrode (8) installed in the lower part of the petri dish. ) From each pair of terminals. When a positive voltage is supplied to the upper electrode (11), a negative voltage having an opposite sign is supplied to the lower electrode (8), so that a positive charge ( 15) is accumulated, while negative charges (10 ') are accumulated in the lower electrode (8). The signal is a signal that changes periodically, and is a signal biased to the positive side with respect to the upper electrode (11). Therefore, positive charge (15) always accumulates in the upper electrode (11), and The amount varies periodically. On the other hand, negative charges (10 ′) are always accumulated in the lower electrode (8), and the amount thereof changes periodically. FIG. 4A shows the case where the absolute value of the voltage signal supplied to the upper electrode (11) and the lower electrode (8) is minimized, and the charge accumulated in both electrodes is minimized. It is in a state.

  In FIG. 4A, an electric field is generated by the positive charge (15) accumulated in the upper electrode (11). In this electric field, the Coulomb force acts on the negative charge (10) existing in the droplet (2) in the direction toward the positive charge (15) accumulated in the electrode (11). An electric field is also generated by the negative charge (10 ') accumulated in the lower electrode (8), and in this electric field, the negative charge (10) present in the droplet (2) has a lower electrode (8). ), The Coulomb force acts in a direction to repel the negative charge (10 ′) accumulated in the above. In FIG. 4A, since the electric charges accumulated in the upper electrode (11) and the lower electrode (8) are small, the Coulomb force that pulls the droplet (2) upward is small.

  On the other hand, in FIG. 4 (B), the absolute value of the voltage signal supplied to the upper electrode (11) and the lower electrode (8) is the maximum, and accumulated in the upper electrode (11). The positive charge (15) and the negative charge (10 ′) accumulated in the lower electrode (8) are the largest. For this reason, the droplet (2) is caused by the Coulomb force acting on the droplet (2) by the electric field generated by the positive charge (15) of the upper electrode (11) and the electric field generated by the negative charge (10 ′) of the lower electrode (8). The Coulomb force that works in 2) is also at its maximum. As a result, the droplet (2) is greatly attracted to the upper part, and the central part has a raised shape.

Since the positive charge (15) accumulated in the electrode (11) periodically changes in accordance with the voltage signal supplied to the electrode, it is between the state of FIG. 4 (A) and the state of FIG. 4 (B). Periodic round trips will occur. For this reason, the droplet (2) vibrates according to this cycle.
The liquid inside the droplet is stirred by the periodic vibration of the droplet (2). The amplitude of the vibration of the droplet is small compared to mechanical shaking, and the droplet (2) does not have to worry about scattering. And since the speed (period) of vibration of a droplet is very large compared with mechanical shaking etc., a droplet (2) can be stirred efficiently.
In addition, by controlling the intensity, frequency, waveform, etc. of the varying electric field to be applied, it is possible to adjust the degree of vibration of the droplets and the degree of stirring of the droplets to a suitable level.

  In the electric field agitation method of the present invention, the applied variable electric field may have any voltage, period, and waveform conditions as long as the droplet is vibrated. The voltage of the varying electric field to be applied varies depending on the size of the droplet, but is preferably 0.35 to 2.5 kv / mm in order to produce a sufficient stirring effect. Moreover, it is preferable that the signal for generating the fluctuation electric field to apply is 0.1-800 Hz. A square wave, a sine wave, a triangular wave, a sawtooth wave, or the like can be used as a signal for generating a fluctuation electric field to be applied. However, in order to increase the stirring efficiency, a square wave with a large instantaneous change is used. Is preferred. In addition, it is preferable to use a sine wave when stirring is performed by a motion that generates a wave in the droplet. As a signal for generating a fluctuating electric field, a positively biased waveform can be used as in the example of FIG. 4, but a waveform that inverts between plus and minus or a negatively biased waveform can also be used. .

3. Reaction promotion method of the present invention The reaction promotion method of the present invention is a method in which a minute droplet of a reaction solution is formed in a minute volume container included in the reaction device of the present invention, and a variable electric field is applied to the droplet. It is a method characterized by accelerating the reaction of the reaction solution by vibrating the droplet.
The “reaction solution” used in the reaction promotion method of the present invention is a solution containing a solvent such as water and a chemical substance, a biomolecule, a biological sample, etc., and any solution can be used as long as it causes a reaction. Examples of the “reaction solution” include, but are not limited to, for example, a reaction solution having one or more kinds of chemical substances that cause a chemical reaction or chemical decomposition, a reaction solution having an antigen and an antibody, blood, etc. And a reaction solution having an antibody that reacts with a protein in the biological sample, and a reaction solution having a DNA, a primer, a nucleotide, and a DNA polymerase.

In the reaction promotion method of the present invention, the reaction solution in the minute volume container is formed by forming minute droplets of the reaction solution in the minute volume container of the reaction device of the present invention and applying a varying electric field to the droplets. It stirs and there exists an effect that the reaction of a reaction solution can be accelerated | stimulated.
In addition, the reaction promotion method of the present invention provides an effect that a reaction field that has not existed in the past can be provided by stirring by applying a varying electric field, and a reaction that cannot be obtained by the conventional method can be obtained.

4). Electric field agitation system of the present invention The electric field agitation system of the present invention has the reaction device of the present invention and a variable electric field application device that applies a variable electric field to minute droplets formed in a minute volume container included in the reaction device. It is characterized by.
Here, as the “fluctuating electric field applying device”, any device can be used as long as it can apply a fluctuating electric field to a specific place, and a plurality of devices are combined. Also good. As the fluctuating electric field applying device, for example, it is preferable to use a device having a voltage amplifier, a function generator that supplies a signal to the voltage amplifier, and an electrode that is supplied with the fluctuating voltage generated by the voltage amplifier and generates an electric field.

  The reaction device, electric field agitation method, reaction acceleration method, and electric field agitation system of the present invention are extremely useful in the field of clinical examinations or research apparatuses because they enable rapid ELISA and nucleic acid detection. .

DESCRIPTION OF SYMBOLS 1 Minute volume container 2 Solution, droplet 3 Side wall 4 Meniscus 5 Bottom surface 6 Base 7 Reaction device 8 Lower electrode 9, 9 'Micro flow path 10, 10' Negative charge 11 Upper electrode 12 High voltage amplifier 13 Function generator 14 Lead wire 15 plus charge

Claims (13)

In a reaction device having a minute volume container,
The micro-capacity container has a bottom surface and side walls disposed on an outer periphery of the bottom surface,
In order to prevent the solution poured on the bottom surface from coming into contact with the side wall, a pedestal having a height lower than that of the side wall is provided at an inner boundary portion between the bottom surface and the side wall, thereby allowing the solution to flow into the pedestal. A reaction device characterized in that a dome-shaped droplet can be formed when poured to a height exceeding the height.   The reaction device according to claim 1, wherein the reaction device is used for electric field stirring in which a fluctuation electric field is applied to the droplet to perform stirring.   The reaction device according to claim 1, further comprising an electrode for applying a varying electric field to the droplet.   The reaction device according to claim 1, wherein the pedestal is formed using a water-repellent material.   The reaction device according to claim 1, wherein the pedestal is a ring-shaped pedestal having a width of 10 μm or more and a length of 30% or less of the width of the bottom surface.   The reaction device according to claim 1, wherein a volume of the droplet is 0.1 μl or more and less than 2000 μl.   The reaction device according to claim 1, wherein the bottom surface is circular.   The reaction device according to any one of claims 1 to 7, wherein a plurality of the minute volume containers are aligned vertically and horizontally.   The reaction device according to claim 1, further comprising a microchannel connected to the microcapacity container.   The reaction device according to claim 9, wherein the minute capacity container is provided at a portion where two or more micro flow paths intersect.   A droplet is formed in the microcapacity container included in the reaction device according to any one of claims 1 to 10, and the droplet is vibrated by applying a varying electric field to the droplet. Electric field stirring method.   A reaction solution droplet is formed in the microcapacity container included in the reaction device according to claim 1, and a reaction is performed by vibrating the droplet by applying a varying electric field to the droplet. A method for promoting a reaction, which comprises promoting a reaction of a solution. An electric field agitation comprising the reaction device according to any one of claims 1 to 10 and a variable electric field applying device that applies a variable electric field to droplets formed in the microcapacity container of the reaction device. system.