JP4972799B2 - Microreactor and microreactor system - Google Patents

Description

  The present invention has a microreactor that immobilizes a biochemical substance and measures the weight of a specific substance such as an enzyme, an antibody, a protein, a hormone, a sugar chain, or a compound that specifically adsorbs or binds thereto, and the microreactor. It relates to a microreactor system.

  In recent years, the analysis of the human genome (human genetic information) has been completed, and the elucidation of the relationship between abnormal proteins that produce abnormal gene structures and diseases is being promoted. Along with this, the new drug development method has changed from an existing method that relies on the developer's experience and intuition for drugs and compounds to a method that searches for compounds that act directly on abnormal proteins and makes them new drugs. . By adopting this method, it is expected that the period of new drug development that has been necessary for nearly 20 years will be shortened to about 5 years in the future.

  In the search for a new drug candidate compound, the physical binding amount between the abnormal protein and the new drug candidate compound is generally used as an index. As a method for measuring this amount of binding, previously, a compound in which a labeling substance such as an enzyme, a luminescent substance, or a radioisotope was bound was used. After further binding this compound and an abnormal protein, the amount of the labeling substance was determined. The bound compound was quantified by measuring. However, at present, a method of performing measurement without using a labeling substance has attracted attention.

As an example of this measurement method, a measurement method using a reactor will be briefly described. First, a reactor is a device in which an introduction path and a waste liquid path are formed in a chip formed of a semiconductor, glass, resin or the like, and a reaction tank is provided therebetween. In the reaction tank, a sensor having an abnormal protein immobilized thereon is installed in advance.
In the reactor configured as described above, when the sample liquid to be measured containing the compound is poured from the introduction path by a pump or the like, the compound in the sample liquid to be measured reacts with the abnormal protein of the sensor previously installed in the reaction tank, Waste liquid after the reaction is discharged from the waste liquid path. A substance fixed in advance to the sensor is called a ligand, and a substance supplied as a solution is called an analyte.

  That is, in the reaction tank, some of the analytes in the sample liquid to be measured are fixed to the sensor by binding to the ligand. Here, when the reaction between the analyte and the ligand reaches an equilibrium state (that is, the amount of the analyte immobilized on the sensor becomes equal to the amount of the analyte separated from the sensor), the analyte immobilized on the ligand The amount is constant. This amount is the data required for new drug development.

  By the way, the following are known as techniques relating to such a reactor. That is, this is a technique for measuring the viscosity of a sample in contact with the surface of the piezoelectric vibrator and the minute weight attached to the surface of the piezoelectric vibrator by using the vibration of a piezoelectric vibrator (particularly a quartz crystal vibrator) as a sensor. More specifically, when an AC voltage is applied between the electrodes formed on both surfaces of the piezoelectric vibrator, that is, the detection electrode and the counter electrode, resonance occurs at a specific frequency determined from the material and shape of the piezoelectric vibrator. And if a substance adheres to a detection electrode, the resonant frequency of the whole piezoelectric vibrator will change according to the attached weight. This technique is to measure the weight of the substance attached to the detection electrode by measuring this change.

  However, since this method cannot detect a specific substance, a technique for detecting only a specific substance by fixing a means for adsorbing or capturing only the specific substance at a predetermined position is used. As an example, a technique using an antigen-antibody reaction for protein detection is known (see Patent Document 1). By applying such technology to sensors, it becomes possible to measure the minute weight of a specific substance to be measured, and as described above, the amount of the analyte immobilized on the ligand can be measured with high accuracy. Is possible.

In addition, a liquid supply channel, a liquid introduction port, a liquid discharge port, and the like are formed in one chip substrate at the same time as the above-described reaction tank, which is called a microreactor. A system to which a control mechanism is added is called a microreactor system.
JP 2000-338022 A

When measurement is performed using a microreactor, the measurement is started by flowing a liquid into the reaction vessel. However, the reaction tank is normally filled with air (gas) before the measurement. Therefore, at the start of measurement, a liquid is allowed to flow into the interior filled with air.
On the other hand, it is difficult to design a sensor arranged in the reaction tank small in consideration of sensitivity and the like, and a certain size is required. Therefore, the size of the reaction tank is made larger than that of the introduction path for introducing the liquid into the reaction tank. Therefore, when the liquid starts to flow into the reaction tank from the start of the measurement, the flow path suddenly expands and a large non-uniformity in the flow velocity occurs. There was a risk of remaining.

  As a result, the remaining air affects the flow of the solution, making it difficult to perform accurate measurement. In particular, when the remaining air stays on the sensor electrode, the measurement itself becomes difficult.

  The present invention has been made in consideration of such circumstances, and its purpose is to prevent air from remaining in the reaction vessel at the start of measurement, and to perform measurement reliably and with high accuracy. And a microreactor system having the microreactor.

In order to achieve the above object, the present invention provides the following means.
A microreactor according to the present invention is a microreactor for measuring the weight of a specific substance contained in a liquid, and includes a substrate having a liquid inlet for introducing the liquid and a liquid outlet for discharging the liquid; A sensor that is bonded to the surface of the substrate with a packing interposed therebetween and resonates the piezoelectric substrate at a predetermined frequency by a pair of electrodes provided on both surfaces of the piezoelectric substrate, wherein the packing is one of the pair of electrodes. A liquid for storing the liquid surrounding the electrode and allowing the liquid to be introduced into the reaction tank by connecting the liquid introduction port and the reaction tank to the reaction tank for adsorbing or binding the specific substance to the one electrode. A packing that integrally forms an introduction path, a liquid discharge path for discharging the liquid from the reaction tank by communicating the liquid discharge port and the reaction tank, between the substrate and the sensor; The width W of the liquid introduction path and the liquid discharge path is 0.4 mm to 0.6 mm, the center-to-center distance L between the liquid inlet and the liquid outlet is 6.1 mm to 6.4 mm, and the reaction tank is the It is located at the center of the liquid inlet and the liquid outlet and has a radius R of 1.9 mm to 2.1 mm, and the liquid inlet, the liquid outlet, and the reaction tank have the radius R. They are connected by a curved surface formed with a radius of 70% to 95%.

  In the microreactor according to the present invention, the sensor is activated in advance before starting the measurement. That is, a predetermined voltage is applied between the pair of electrodes to resonate the piezoelectric substrate. Next, the liquid is supplied to the liquid introduction path through the liquid introduction port. Then, the supplied liquid flows into the reaction tank from the liquid introduction path, fills the reaction tank, and then is discharged to the outside through the liquid discharge path. In particular, when the reaction vessel is filled with a liquid, one electrode is immersed in the liquid. Therefore, a specific substance (for example, an antigen or the like) contained in the liquid is captured by adsorbing or binding to one electrode.

  Therefore, the weight of one electrode increases by the weight of the specific substance attached to the adsorption film. Then, along with this weight change, the resonance frequency of the sensor changes. Therefore, the weight of the specific substance can be measured by detecting this frequency change. As a result, various biochemical reactions such as an antigen-antibody reaction, a DNA hybridization reaction, a protein binding reaction, and an enzyme reaction can be measured.

  In particular, the center-to-center distance L between the liquid inlet and the liquid outlet is 6.1 mm to 6.4 mm, and the liquid inlet, the liquid outlet, and the reaction tank are 70% of the radius R of the reaction tank. They are connected by a curved surface formed with a radius of ˜95%. Therefore, when the liquid flows into the reaction tank at the start of measurement, it smoothly flows at a uniform flow rate along the curved surface. Therefore, there is no possibility that stagnation or the like occurs in the reaction tank, and the reaction tank can be swept away without leaving the air in the reaction tank. Therefore, air does not remain in the reaction layer as in the prior art. As a result, since measurement can be performed without being affected by residual air, reliable and highly accurate measurement can be performed.

The reaction tank formed between the substrate and the sensor by packing is located at the center of the liquid inlet and the liquid outlet, and has a radius R of 1.9 mm to 2.1 mm. Yes. That is, the reaction tank has a diameter of 3.8 mm to 4.2 mm. Therefore, even if the size of one of the electrodes is about 3 mm in diameter that can stably oscillate with an impedance of 1 KΩ or less, the electrode can be separated from the reaction vessel by about 0.5 mm. Thus, by separating the electrode and the reaction vessel by about 0.5 mm, the inclination of the phase angle at the time of oscillation can be made steep and the oscillation characteristics can be improved.
In addition, since the diameter of the reaction vessel is about 4 mm, the size can be reduced and the volume in the reaction layer can be made as small as possible (1 μl or less). Therefore, efficient measurement can be performed with a small amount of liquid without wastefully consuming the liquid.
In addition, since the width W of the liquid introduction path and the liquid discharge path is 0.4 mm to 0.6 mm, the liquid can be efficiently introduced into the reaction tank without securing a useless volume in these flow paths. Or can continue to be stored in the reaction vessel.

  The microreactor system according to the present invention is connected to the microreactor according to the present invention, a measuring means for measuring a frequency change of the sensor, the liquid inlet and the liquid outlet, and sends the liquid. Liquid feeding means.

  In the microreactor system according to the present invention, various liquids can be fed at an arbitrary timing and at an arbitrary flow rate by the liquid feeding means while measuring the frequency change of the sensor by the measuring means. Measurement can be performed reliably and with high accuracy.

  According to the microreactor and the microreactor system according to the present invention, it is possible to prevent air from remaining in the reaction tank at the start of measurement, and to perform reliable and highly accurate measurement. In addition, measurement can be performed using a sensor that has excellent oscillation characteristics and stably oscillates.

Hereinafter, an embodiment of a microreactor and a microreactor system according to the present invention will be described with reference to FIGS. 1 to 13.
As shown in FIG. 1, the microreactor system 1 of the present embodiment sends a microreactor 2, a measuring means 3 for measuring a frequency change of a sensor 12 described later, and a sample liquid (liquid) F into the microreactor 2. Liquid feeding means 4 for feeding liquid. FIG. 1 is a simplified configuration diagram of the microreactor system 1.

The microreactor 2 measures the weight of a specific substance contained in the sample liquid F. In the present embodiment, a specific substance (analyte) is used as an antigen and an antigen-antibody reaction measurement is performed as an example.
As shown in FIGS. 2 to 5, the microreactor 2 is configured by laminating a hold substrate (substrate) 10, a resin plate 11, and a sensor 12 in three layers. FIG. 2 is a view of the microreactor 2 as viewed from the surface side. FIG. 3 is a view of the microreactor 2 as seen from the back side. FIG. 4 is an exploded perspective view of the microreactor 2. FIG. 5 is a cross-sectional arrow view AA in FIG. However, in FIGS. 4 and 5, the thickness of the packing 23 is exaggerated for easy understanding of the drawings.

  The hold substrate 10 is a transparent substrate formed from an acrylic resin or the like, and has an outer shape formed like an SD memory card. In the hold substrate 10, a liquid introduction port 10 a for flowing the sample liquid F from the front surface side to the back surface side and introducing it into the liquid introduction path 31 described later, and the sample liquid F from the back surface side to the front surface side will be described later. A liquid discharge port 10b for discharging from the liquid discharge path 32 is formed. The liquid inlet 10a and the liquid outlet 10b are each formed to have a diameter of 0.5 mm, and the positions thereof are adjusted so that the distance L between the centers is 6.3 mm.

Further, a SiO ₂ film (not shown) for bonding the sensor 12 is deposited on the entire back surface of the hold substrate 10. On the SiO ₂ film, wiring pattern portions 13 that are electrically connected to a detection electrode 21 and a counter electrode 22 described later are formed. The wiring pattern portion 13 functions as an external connection terminal. The wiring pattern portion 13 is formed by laminating one type of metal or different metals (for example, laminating titanium and gold in two layers).

As shown in FIGS. 6 to 8, the resin plate 11 is formed in a plate shape from silicon resin. FIG. 6 is a view of the resin plate 11 as viewed from the front side. FIG. 7 is a view of the resin plate 11 as seen from the back side. FIG. 8 is a side view of the resin plate 11.
In the resin plate 11, an introduction groove 14 and a discharge groove 15 are respectively formed on the surface facing the hold substrate 10. The introduction groove 14 and the discharge groove 15 are concave portions 14a and 15a having a diameter of about 1.5 mm on one end side, and a concave portion having a diameter of about 0.5 mm that is the same size as the liquid introduction port 10a and the liquid discharge port 10b on the other end side. 14b and 15b. As shown in FIG. 5, the resin plate 11 is bonded to the surface of the hold substrate 10 so that the recesses 14b and 15b communicate with the liquid inlet 10a and the liquid outlet 10b, respectively. Therefore, the microreactor 2 of the present embodiment introduces the sample liquid F from the liquid introduction port 10 a through the introduction groove 14 of the resin plate 11, and samples from the liquid discharge port 10 b through the discharge groove 15 of the resin plate 11. The liquid F is discharged.

As shown in FIGS. 9 to 11, the sensor 12 includes a quartz substrate (piezoelectric substrate) 20 and a pair of electrodes provided on both sides of the quartz substrate 20 to resonate the quartz substrate 20 at a predetermined frequency. The QCM sensor includes a detection electrode 21 and a counter electrode 22. FIG. 9 is a perspective view of the sensor 12. FIG. 10 is a view of the sensor 12 as seen from the back side. 11 is a cross-sectional view taken along the line B-B shown in FIG. 9.
The quartz substrate 20 is an AT cut quartz plate, for example, and is a transparent substrate formed in a square shape from an 8 mm square wafer. The detection electrode 21 and the counter electrode 22 are each formed by vapor deposition, sputtering, or the like so as to be positioned substantially at the center of the quartz crystal substrate 20. That is, the detection electrode 21 and the counter electrode 22 are in a state of facing each other with the quartz crystal substrate 20 interposed therebetween.

Further, lead electrodes 21 a and 22 a that are electrically connected to the detection electrode 21 and the counter electrode 22 are formed on both surfaces of the quartz substrate 20. The detection electrode 21, the counter electrode 22, and the lead electrodes 21a and 22a are formed by laminating one type of metal or different metals (for example, laminating titanium and gold in two layers) similarly to the wiring pattern portion 13. It is a thing.
The detection electrode 21 has an impedance of 1 KΩ or less and a diameter of 3 mm that oscillates stably in the liquid. The counter electrode 22 has the same size.

As shown in FIGS. 4 and 5, the sensor 12 configured as described above is bonded to the back surface side of the hold substrate 10 with the packing 23 interposed therebetween. At this time, the sensor 12 is bonded so that the detection electrode 21 faces the hold substrate 10.
The packing 23 is a packing in which a reaction tank 30, a liquid introduction path 31, and a liquid discharge path 32 are integrally formed between the hold substrate 10 and the sensor 12 as shown in FIG. It is made of a polymer resin such as terephthalate) or PDMS (polydimethylsiloxane). FIG. 12 is a plan view of the packing 23.
The reaction tank 30 is a space in which the sample liquid F is stored around the detection electrode 21 and a specific substance contained in the sample liquid F is adsorbed or combined with the detection electrode 21. The liquid introduction channel 31 is a channel through which the liquid introduction port 10 a of the hold substrate 10 and the reaction vessel 30 are communicated to introduce the sample solution F into the reaction vessel 30. The liquid discharge path 32 is a flow path that allows the liquid discharge port 10 b of the hold substrate 10 and the reaction tank 30 to communicate with each other and discharges the sample liquid F from the reaction tank 30.

Here, the packing 23 of the present embodiment is formed so that the reaction tank 30, the liquid introduction path 31, and the liquid discharge path 32 have the following sizes.
First, the reaction tank 30 is located at the center of the distance L between the centers of the liquid inlet 10a and the liquid outlet 10b described above, and has a radius R of 1.95 mm. That is, the diameter is 3.9 mm. Further, the width W of the liquid introduction path 31 and the liquid discharge path 32 is formed to be 0.5 mm which is the same as the diameter of the liquid introduction port 10a and the liquid discharge port 10b. The liquid introduction path 31 and the liquid discharge path 32 and the reaction tank 30 are connected by a curved surface 33 having a radius R1 of 1.8 mm (approximately 92% of the radius R of the reaction tank 30).
The curved surface 33 will be described in more detail. A virtual circle that is in contact with the intersection P between the liquid introduction path 31 or the liquid discharge path 32 and the liquid introduction port 10a or the liquid discharge port 10b and that is in contact with the outline of the reaction tank 30. A curved surface 33 drawn by S. The thickness of the packing 23 is approximately 80 μm.

As shown in FIG. 5, the packing 23 configured in this manner has the center of the reaction tank 30 and the center of the detection electrode 21, the liquid inlet 10 a and the liquid outlet 10 b, and the liquid inlet 31. And the liquid discharge path 32 are joined to each other while being sandwiched between the hold substrate 10 and the sensor 12 so as to communicate with each other.
This bonding method is not particularly limited to one method. For example, the bonding is performed by siloxane bonds in which silicon and oxygen are alternately bonded. In the case of performing this joining, first, the packing 23 is superimposed on a predetermined position of the sensor 12 and then irradiated with ultraviolet rays. Then, the quartz crystal substrate 20 of the sensor 12 and the packing 23 are joined by a siloxane bond. In particular, since the siloxane bond is a covalent bond, the sensor 12 and the packing 23 can be bonded with high strength, which is a preferable method. Moreover, since only ultraviolet rays are irradiated, neither is heated, and no residual stress is generated in the quartz substrate 20 after bonding. This is also preferable.

  The quartz substrate 20 and the packing 23 are covalently bonded by a siloxane bond, but the lead electrodes 21a and 22a on the quartz substrate 20 and the packing 23 are not bonded but self-adsorbed. However, since the lead electrodes 21a and 22a have a small thickness (several hundreds of nanometers), there is no risk of liquid leakage even if they are not coupled.

Next, after irradiating the back surface side of the hold substrate 10 and the packing 23 to which the sensor 12 is bonded with ultraviolet rays, the hold substrate 10 and the packing 23 are overlapped. Thus, SiO ₂ and the packing 23 that is deposited on the back surface of the hold substrate 10 are bonded by siloxane bonding. As a result, the hold substrate 10 and the packing 23 can be joined. Moreover, the lead electrodes 21a and 22a electrically connected to the detection electrode 21 and the counter electrode 22 are electrically connected to the wiring pattern portion 13 via the conductive adhesive E shown in FIG.

Further, as shown in FIG. 4, an adsorption film 35 that adsorbs the antigen contained in the sample liquid F is formed on the detection electrode 21 of the present embodiment. In this embodiment, the case where the adsorption film 35 is formed will be described as an example. However, the adsorption film 35 is not essential and may not be formed. Further, in order to make the drawings easy to see, the adsorption film 35 is appropriately omitted in each drawing.
The adsorption film 35 is composed of, for example, SAM (self-assembled monolayer) and an antibody (ligand) modified with the SAM, and is formed by the following method.
First, after the surface of the detection electrode 21 is washed with pure water, a SAM is formed on the detection electrode 21 by a SAM reagent (carboxyl terminal disulfide type). Subsequently, washing is performed with a phosphate buffer. Subsequently, SAM is activated with hydroxysuccinimide, and then washed again with a phosphate buffer. Thereafter, the antibody is immobilized on the SAM. In this way, the adsorption film 35 is formed. The adsorption film 35 may be formed before the sensor 12 is bonded or after the sensor 12 is bonded.

  As shown in FIG. 1, the measuring means 3 includes a frequency variable AC power supply 40 and an ammeter 41. The AC power supply 40 and the ammeter 41 are connected in series, and one end is electrically connected to the wiring pattern portion 13 that is electrically connected to the detection electrode 21 and the other end is electrically connected to the counter electrode 22. The pattern part 13 is electrically connected. Then, by applying an AC voltage from the AC power supply 40 to the detection electrode 21 and the counter electrode 22, the quartz crystal substrate 20 can be resonated. In addition, although the electric current which flows into the ammeter 41 changes according to the frequency of an alternating voltage, the frequency of the applied voltage from which an electric current value becomes maximum turns into a resonant frequency. The change in resonance frequency can be measured by monitoring the current value of the ammeter 41.

  The liquid feeding unit 4 includes a supply pump 43 that supplies the sample liquid F to the microreactor 2 and a waste liquid tank 44 that collects the sample liquid F discharged from the microreactor 2. The supply pump 43 is connected to a supply tube 43a whose tip is a needle portion, so that the sample liquid F can be fed through the supply tube 43a. The needle portion of the supply tube 43a is punctured with the resin plate 11, and the tip has reached the recess 14a of the introduction groove 14. Thus, the supply pump 43 is connected to the liquid introduction port 10a of the hold substrate 10 through the introduction groove 14 and the supply tube 43a, and can feed the sample liquid F into the liquid introduction port 10a. It is like that.

  Similarly, the waste liquid tank 44 is connected to a waste liquid tube 44a whose tip is a needle portion, and the sample liquid F can be collected through the waste liquid tube 44a. The needle portion of the waste liquid tube 44a is punctured with the resin plate 11, and the tip has reached the recess 15a of the discharge groove 15. As a result, the waste liquid tank 44 is connected to the liquid discharge port 10b of the hold substrate 10 via the discharge groove 15 and the waste liquid tube 44a, and the sample liquid F can be collected. .

Next, the case where the antigen-antibody reaction is measured by measuring the weight of the antigen attached to the antibody by the microreactor system 1 and the microreactor 2 configured as described above will be described.
Before starting measurement, the sensor 12 is activated in advance. That is, the quartz substrate 20 is resonated by applying an alternating voltage between the detection electrode 21 and the counter electrode 22 by the alternating current power source 40. Then, the resonance frequency in this state is measured from the current value of the ammeter 41.

  Next, the supply pump 43 is operated to supply the sample liquid F into the introduction groove 14 of the resin plate 11 through the supply tube 43a. Then, the introduced sample liquid F flows into the liquid inlet 10 a of the hold substrate 10 after flowing through the introduction groove 14. Subsequently, after passing through the liquid inlet 10 a, the liquid flows into the reaction tank 30 through the liquid inlet path 31 formed by the packing 23. The sample liquid F flowing into the reaction tank 30 is discharged from the liquid discharge port 10b through the liquid discharge path 32 after filling the reaction tank 30. The sample liquid F that has flowed from the liquid discharge port 10b to the discharge groove 15 of the resin plate 11 passes through the discharge groove 15 and is then collected in the waste liquid tank 44 via the waste liquid tube 44a.

  By the way, when the reaction tank 30 is filled with the sample solution F, the detection electrode 21 and the adsorption film 35 formed on the detection electrode 21 are immersed in the sample solution F. Therefore, the antigen contained in the sample solution F adheres to and is captured by the antibody constituting the adsorption film 35. Therefore, the weight of the detection electrode 21 increases by the weight of the antigen captured by the antibody. Then, as the weight increases, the resonance frequency of the sensor 12 changes, so that the current value of the ammeter 41 changes. Therefore, the change in resonance frequency can be measured from the change in current value, and the weight of the antigen attached to the antibody can be measured. As a result, the antigen-antibody reaction can be measured in real time, and the reaction can be quantified.

  In particular, in the microreactor 2 of the present embodiment, the center-to-center distance L between the liquid inlet 10a and the liquid outlet 10b is 6.3 mm apart, and the liquid inlet path 31, the liquid outlet path 32, and the reaction tank 30 are separated from each other. The curved surface 33 is formed with a radius R1 that is approximately 92% of the radius R of the reaction tank 30. Therefore, when the sample liquid F flows into the reaction tank 30 at the start of measurement, it smoothly flows at a uniform flow rate along the curved surface 33 as shown in FIG. FIG. 13 is a view showing the flow of the sample liquid F in the packing 23. Therefore, there is no possibility that stagnation or the like occurs in the reaction tank 30, and it can be pushed away without leaving air in the reaction tank 30. As a result, measurement can be performed without being affected by residual air, and reliable and highly accurate measurement can be performed.

  In addition, since the reaction tank 30 of the present embodiment has a diameter of 3.9 mm, the size of the detection electrode 21 is set to 3 mm so that the impedance is 1 KΩ or less and the oscillation can be stably performed in the liquid. it can. Moreover, even if the detection electrode 21 is of this size, the detection electrode 21 and the reaction tank 30 can be separated by about 0.5 mm. Therefore, the inclination of the phase angle at the time of oscillation can be made steep, and the oscillation characteristics can be improved.

Furthermore, since the diameter of the reaction tank 30 is about 3.9 mm, the size can be reduced, and the volume in the reaction tank 30 determined by the thickness and area of the packing 23 is made as small as possible (1 μl or less). be able to. Therefore, efficient measurement can be performed with a small amount of sample liquid F without wastefully consuming the sample liquid F.
In addition, since the width W of the liquid introduction path 31 and the liquid discharge path 32 is 0.5 mm, which is the same as the diameter of the liquid introduction port 10a and the liquid discharge port 10b, it is possible to secure a useless volume in these channels. The sample liquid F can be efficiently introduced into the reaction tank 30 or kept stored in the reaction tank 30.

  In the above embodiment, after introducing the sample liquid F into the microreactor 2, a buffer solution having a washing function or a buffer function (dissociation function) may be supplied to the microreactor 2 by the supply pump 43. When the buffer solution is supplied in this way, the antigen captured by the antibody is dissociated, so that the resonance frequency changes again. By measuring the resonance frequency at this time, it is possible to rapidly measure the affinity characteristic relating to the reaction rate such as the binding coefficient between the antibody and the antigen and the dissociation constant. In addition, since measurement can be performed using the microreactor 2 that is not affected by residual air, such multi-directional measurement can be performed reliably and with high accuracy.

  The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.

  For example, in the above-described embodiment, the antigen-antibody reaction has been described as an example. However, the present invention is not limited to this, and by appropriately selecting an analyte and a ligand, a DNA hybridization reaction, a protein binding reaction, It can also be applied to various biochemical reactions such as enzyme binding reactions.

Moreover, in the said embodiment, although the radius R of the reaction tank 30 was 1.95 mm, as long as it exists in the range of 1.9 mm-2.1 mm, you may change freely. In addition, although the center distance L between the liquid inlet 10a and the liquid outlet 10b is 6.3 mm, the distance L may be freely changed as long as it is within the range of 6.1 mm to 6.4 mm. Moreover, although the width W of the liquid introduction path 31 and the liquid discharge path 32 is 0.5 mm, it may be within the range of 0.4 mm to 0.6 mm. Further, the radius R1 of the curved surface 33 between the liquid introduction path 31 and the liquid discharge path 32 and the reaction tank 30 is set to approximately 92% of the radius R of the reaction tank 30, but within a range of 70% to 95%. You can change it freely.
If the combination is within the above-mentioned range, when the sample liquid F is poured into the reaction tank 30 at the start of measurement, the air in the reaction tank 30 can be surely excluded, and the air remains. Can be prevented.

It is a simplified lineblock diagram showing one embodiment of a microreactor system of the present invention. It is the figure which looked at the microreactor shown in FIG. 1 from the surface side. It is the figure which looked at the microreactor shown in FIG. 1 from the back surface side. It is a disassembled perspective view of the microreactor shown in FIG. FIG. 3 is a cross-sectional arrow view AA shown in FIG. It is the figure which looked at the resin plate which comprises a microreactor from the surface side. It is the figure which looked at the resin plate shown in FIG. 6 from the back surface side. It is a side view of the resin plate shown in FIG. It is a perspective view of the sensor which comprises a microreactor. It is the figure which looked at the sensor shown in FIG. 9 from the back side. It is a cross-sectional arrow BB figure shown in FIG. It is a top view of packing which comprises a micro reactor. It is the figure which showed the state in which the liquid is flowing along the liquid introduction path, reaction tank, and liquid discharge path which are formed with packing.

Explanation of symbols

F Sample liquid (liquid)
1 Microreactor system 2 Microreactor 3 Measuring means 4 Liquid feeding means 10 Hold substrate (substrate)
10a Liquid inlet 10b Liquid outlet 12 Sensor 20 Crystal substrate (piezoelectric substrate)
21 Detection electrode (one electrode)
22 Counter electrode (the other electrode)
23 Packing 30 Reaction tank 31 Liquid introduction path 32 Liquid discharge path

Claims (2)

A microreactor for measuring the weight of a specific substance contained in a liquid,
A substrate having a liquid inlet for introducing the liquid and a liquid outlet for discharging the liquid;
A sensor that is bonded to the surface of the substrate with packing therebetween and resonates the piezoelectric substrate at a predetermined frequency by a pair of electrodes provided on both sides of the piezoelectric substrate;
The packing surrounds one electrode of the pair of electrodes, stores the liquid, adsorbs or binds the specific substance to the one electrode, and the liquid inlet and the reaction tank. A liquid introduction path for communicating the liquid into the reaction tank by communication and a liquid discharge path for discharging the liquid from the reaction tank by communicating the liquid discharge port and the reaction tank are integrated between the substrate and the sensor. Packing to be formed
The width W of the liquid introduction path and the liquid discharge path is 0.4 mm to 0.6 mm, the center-to-center distance L between the liquid introduction port and the liquid discharge port is 6.1 mm to 6.4 mm, and the reaction tank is the It is located at the center of the liquid inlet and the liquid outlet and has a radius R of 1.9 mm to 2.1 mm, and the liquid inlet, the liquid outlet, and the reaction tank have the radius R. A microreactor which is connected by a curved surface formed with a radius of 70% to 95%. A microreactor according to claim 1;
Measuring means for measuring the frequency change of the sensor;
A microreactor system, comprising: a liquid feeding means connected to the liquid inlet and the liquid outlet for feeding the liquid.

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