JPH041554A - Reaction measuring instrument - Google Patents

Abstract

PURPOSE:To prevent electrical characteristic deteriorating by providing a non-Dc connecting part between a piezoelectric element and an oscillation circuit. CONSTITUTION:Conductor plates 13, 14 connected to the piezoelectric element 1 are fixed on the side plane or the bottom plane of a cell 2 attached on the element 1, and the element 1 is connected to the oscillation circuit 3 by electrostatic capacity with conductor plates 15, 16 connected to the circuit 3 and fixed on the arranged part of the cell 2. The circuit 3 is connected to a microcomputer 5 which monitors data via a frequency counter 4, and furthermore, a recorder 6, a display device 7, and a key switch 8 are connected to the circuit. By employing such configuration, the electrical characteristic can be prevented deteriorating.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention is applicable to chemistry, physical chemistry, biochemistry, polymer chemistry, and medical, pharmaceutical, food, and chemical industries, tracking of chemical reactions, immune reactions, and physical property analysis. , and a device that performs measurements using it.

[Summary of the invention]

The present invention provides a reaction measurement device using a piezoelectric element as a detector, in which an electrical connection portion using capacitance is provided between the piezoelectric element and an oscillation circuit, an impedance measurement device, an impedance-resonance frequency measurement device, or a signal switching circuit. This prevents the connection terminals of both the piezoelectric element with the cell and the main body of the device from being exposed to the outside. Further, even when the connecting terminal is exposed to the outside, the surface of the connecting terminal can be treated to improve wear resistance and corrosion resistance. This prevents the electrical characteristics of the connection part from deteriorating during operations such as cleaning and heat treatment of the piezoelectric element with the cell attached, or due to the physical or chemical effects of samples, water, etc. It has become possible to improve the operability of attaching and detaching the attached piezoelectric element to the main body of the device.

[Conventional technology]

Reactions accompanied by changes in viscosity are considered to be mainly measured by the reaction meter tM device of the present invention. Traditionally, viscosity measurement involves
The capillary method, rotation method, and falling ball method have been used. The AT tube method determines the viscosity from the speed at which the sample solution falls through a thin tube.The falling ball method involves placing a metal ball in the sample solution and determining the viscosity from the falling speed of the sample solution. The viscosity is determined by rotating a cylindrical metal rod in a solution and determining the shear stress. On the other hand, when the target of reaction measurement is a coagulation reaction or gelation reaction, there are methods such as optically measuring the turbidity of the sample, and methods of applying mechanical vibration to the sample and detecting changes in viscosity due to coagulation or gelation. was taken.

[Problem to be solved by the invention]

Conventional viscosity measurement methods have the problem that it takes time to perform a single measurement operation, making it difficult to continuously measure changes caused by a reaction, and also making it impossible to measure small amounts of sample. .

When measuring coagulation reactions or gelation reactions of endotoxins and blood coagulation factors, conventional methods of measuring turbidity
There are problems in that the system is complicated because it includes an optical measurement system, and it is not suitable for measuring colored samples, and depending on the sample, large errors may occur due to salting out. Furthermore, in the method of applying mechanical vibrations, it is difficult to reduce the size and weight of the device due to the presence of mechanical parts, making it inevitable to increase the size of the device.

In addition to these points, both methods require a minimum of 0. 2ml
There was a problem in that it required several samples.

The measurement method using a piezoelectric element devised by the present inventors was able to measure a sample of 0.2 ml or less. Additionally, since there are no mechanically moving parts, it is easy to downsize the system.

However, until now, there was a direct current connection between the piezoelectric element and the oscillation circuit. Due to the physical or chemical effects of oxygen, water, etc. in the air, the electrical characteristics of the connecting portions of both the device body and the piezoelectric element attached to the cell may deteriorate.

Furthermore, there is room for improvement in the operability and safety of attaching and detaching the piezoelectric element with the cell to the device body. In particular, when handling samples that are in the human body or have a risk of infection by viruses, etc., the possibility of damaging protective gloves, etc. with the connection terminals of piezoelectric elements with cells is a major problem. there were.

In addition, in addition to viscosity measurement, an immune reaction measuring device and a gas sensor system using piezoelectric elements have been devised by the present inventors. Samples and cleaning fluids could remain in small gaps in the cell walls, affecting measurement results, and the liquid in the cell could leak through those small gaps.

A gas sensor system measures the adsorption reaction of gas onto a sensitive film on a quartz crystal resonator. The pressure 1i element fixed inside the cell and the external connection part are connected by a conductor penetrating a part of the wall of the sealed cell, but gas sometimes leaks from the small gap between them.

[Means to solve the problem]

This invention is these! In order to solve IN, we constructed a piezoelectric element with cells, the same number of oscillation circuits, and frequency measurement circuits, and the pressure with cells! Elements and impedance measurement equipment! A device consisting of a piezoelectric element with a cell and an impedance-resonance frequency measuring device, a device consisting of a data processing control device added to these devices, a device configured by adding a thermostat to these devices, When using multiple piezoelectric elements, in a reaction measurement device configured by adding a signal switching circuit to the piezoelectric elements, electrostatic It is equipped with an electrical connection part using induction.

[Effect]

A piezoelectric element is a device that utilizes a piezoelectric effect, and can be caused to oscillate by being connected to an oscillation circuit. At this time, the surface of the piezoelectric element causes minute vibrations, so the piezoelectric element is sensitive to the effects of the viscoelasticity and density of the material it is in contact with, as well as changes in weight due to adsorption of materials onto the surface. It is known that the resonant frequency and resonant resistance change due to By measuring this resonance frequency and resonance resistance, it is possible to measure changes in the viscoelasticity of liquids and liquid crystals, adsorption of substances, and accumulation of substances due to sedimentation. When a piezoelectric element with a cell is installed in the device body, the capacitance of the conductor connected to the piezoelectric element and the conductor connected to the oscillation circuit, impedance measuring device, impedance-resonant frequency measuring device, or signal switching circuit, If the structure is such that the piezoelectric element and the oscillation circuit, impedance measuring device, impedance resonance frequency measuring device, or signal switching circuit are electrically connected, the piezoelectric element with the cell and the main body of the device can both have connecting terminals. There is no need to expose it to the outside.

Further, even when the connecting terminal is exposed to the outside, the surface of the connecting terminal can be treated to improve wear resistance and corrosion resistance.

These things prevent deterioration of the electrical characteristics of the connection terminals of both the piezoelectric element with cells and the main body of the device, and improve the operability such as attaching and detaching the piezoelectric element with cells to the main body of the device and cleaning. It also makes it easier to create a sealed part containing the piezoelectric element inside the cell.

(Example) Hereinafter, an example of the present invention will be described based on the drawings. Fig. 1a to Fig. 1n are schematic diagrams of the reaction measuring device of the present invention.

In FIG. 1a, a piezoelectric element 1 has a cell 2 attached thereto. A conductor plate 13.14 connected to the piezoelectric element l is fixed to the side or bottom surface of the cell 2, and a conductor plate 15.16 connected to the oscillation circuit and fixed to the installation part of the cell.
The piezoelectric element 1 and the oscillation circuit 3 are connected by the capacitance between the piezoelectric element 1 and the oscillation circuit 3.The oscillation circuit 3 is connected to a frequency counter 4, and further connected to a microcomputer (including an input/output interface) for monitoring data. A recording device 6, a display device 7, and a key switch 8 are connected to the microcomputer 5.

In FIG. 1, a cell 2 is attached to a piezoelectric element 1. Conductive plates 13 and 14 connected to the piezoelectric element 1 are fixed to the side or bottom of the cell 2, and conductive plates I5 and 6 connected to the impedance measuring device 11 are fixed to the installation part of the cell. Depending on the capacitance, pressure! Element 1
and an impedance measuring device 11 are connected. The impedance measuring device 11 is connected to a microcomputer 5j (including an input/output interface) for monitoring data, and a recording device 6, a display device 7, and a key switch 8 are connected to the microcomputer 5. .

In FIG. 1C, a cell 2 is attached to the piezoelectric element l. Four piezoelectric elements 1 are placed on the side or bottom of the cell 2.
A conductive plate 13.14 connected to the impedance-resonant frequency measurement bag W12 is fixed, and the capacitance between the conductive plate 15.16 connected to the impedance-resonance frequency measurement bag W12 and fixed to the installation part of the cell causes the piezoelectric element 1 and the impedance- A resonance frequency measuring device F12 is connected. The impedance-resonance frequency measuring device 12 is connected to a microcomputer (including an input/output interface) 5 for monitoring data, and the microcomputer 5 includes a recording bag W6,
A display device 7 and a key switch 8 are connected.

In FIG. 1d, a cell 2 is attached to the piezoelectric element 1, and the piezoelectric element 1 is installed so as to be in contact with a thermostatic chamber 9. In FIG.

A conductor plate 13.14 connected to the piezoelectric element 1 is fixed to the side or bottom of the cell 2, and is connected to the oscillation circuit by capacitance with a conductor plate 15.16 fixed to the installation part of the cell. , the oscillation circuit 3 to which the piezoelectric element 1 and the oscillation circuit 3 are connected is connected to a frequency counter 4, further connected to a microcomputer (including an input/output interface) 5 for monitoring data, and a microphone ti: A recording device 6, a display device 7, and a key switch 8 are connected to the digital viewer 5.

In FIG. 1e, a cell 2 is attached to the piezoelectric element 1, and the piezoelectric element 1 is installed so as to be in contact with the thermostatic chamber 9.

A conductor plate 13.14 connected to the piezoelectric element 1 is fixed to the side or bottom of the cell 2, and a conductor F connected to the impedance measuring device 11 and fixed to the installation part of the cell is fixed.
7. Due to capacitance with i15.16. A pressure measuring element 1 and an impedance measuring device 11 are connected. The impedance measuring device 11 includes a microcomputer (including an input/output interface) 5 for monitoring data.
A recording device 6, a display tube f7, and a key switch 8 are connected to the microcomputer 5.

At 111f, piezoelectric element 1 is attached with cell 2 and 1. A conductive plate 13, ]4 connected to a piezoelectric element 1 is fixed to the side or bottom of the cell 2 installed in contact with the thermostat 9, and is connected to an impedance-resonance frequency measuring device 12 to measure the cell. The piezoelectric element 1 and the impedance resonance frequency measuring device 12 are connected by capacitance with the conductor plates 15 and 16 fixed to the installation part. It is connected to a microcomputer (including an input/output interface) 5, and a recording device 6, a display tube f7, and a key switch 8 are connected to the microcomputer-5.

In Fig. 1g, pressure W elements 1+, 1g, ...]
7 contains cells 2+, 2x, ..., 2. is attached. Cell 2. ．． 2. , . . . , 2. On the side or bottom of 1, there is a piezoelectric element, 1. , . . . The conductive plate 13+, 13° . . . , 13. ．． 14. ．．
1.43. ..., 14° is fixed, the conductor plate is+, t5 connected to the oscillation circuit and fixed to the installation part of the cell.
z, ...15,. 16°, 16. , ...,
16. Due to the capacitance of the piezoelectric element 11.1g,
The nine oscillation circuits 3=, 3t, . . . , 3° to which In and the oscillation circuits 3°, 3, 1, . . . , 3R are connected are connected to the frequency counter 4 via the signal switching circuit 10. and further connected to a microcomputer (including a human output interface) 5 for monitoring data, and the microcomputer 5 includes a recording device 61.
2 display device 7 and key switch 8 are connected.

In the first diagram, the pressure is 11.1g, ...1
, l have cells 21.2z, . . . , 2. , is attached. Conductor plates 13+, 13m connected to the piezoelectric elements 1+, 1g, .

..., 13. ．． 141.14! , ..., 14. l
is fixed, connected to the signal switching circuit 10, and fixed to the installation part of the cell. ．． 15a...
15. The pressure cables 11.123, . . . , 1a are connected to the signal switching circuit 1υ by the capacitances of I, 165.16g, . . . , 16. The signal switching circuit 10 is connected to an impedance measuring device 11,
Furthermore, it is connected to a microcomputer (including an input/output interface) 5 for monitoring data and evening data.
The microcomputer 5 includes a recording device 6 and a display bag W.
, 7. When the key switch 8 is connected, in FIG. 1i, the piezoelectric elements 1+, Iz-...
5.2□,..., 211 are attached. Cell 2.
. 2 o..., 2. (7) On the m-plane or the bottom surface, there are piezoelectric elements 11.1g, . . . conductor plates 13.1 connected to Ill. ．． 13. .

. . , 13-114+-14t, . . . , 147 are fixed, and the conductor plate 15 . ．． 152,...,15.
．． 16. , IL, . . . 167, the piezoelectric elements 1t, 1□, . . . , 17 are connected to the signal φ switching circuit 10. The signal switching circuit 10 is connected to an impedance-resonance frequency measuring device 12, and further connected to a microcomputer (including an input/output interface) 5 for monitoring data. device 6,
A display device 7 and a key switch 8 are connected.

In FIG. 1j, piezoelectric elements 15.1g, . . . 1, l
contains cells 2+, 2z, . . . , 2. is attached and installed so as to be in contact with the thermostatic chamber 9.

The piezoelectric elements 1+, 1g, . . . 41. A conductive plate 13 connected to the conductor plate 13. , +3. , ..., 13°, 14
+, 14o,..., 14. conductor plate 151.1 fixed to the cell installation part connected to the oscillation circuit
5g, ..., 1.5. ．． 161.16□,...
, 168, the piezoelectric element 1+, 1g,
..., 1. , and oscillation circuit 3+, 3g, ...
, 3n are connected.

Oscillation circuit 31.3t, ..., 3. , are connected to the frequency counter 4 via the signal switching circuit 10,
Furthermore, it is connected to a microcomputer (including an input/output interface) 5 for monitoring data, and a recording device 61, a display device 7, and a key switch 8 are connected to the microcomputer 5.

In FIG. 1k, piezoelectric elements 11, Ig, . . . 1
, l has cells 21, 2, . . . , 2. is attached,
It is installed so as to be in contact with the thermostat 9.

The piezoelectric elements 11.1z, . . . , 1. The conductor plate 131. IL... 137.14
+, 14g, ..., 14. is fixed, connected to the signal switching circuit lO, and fixed to the installation part of the cell. ,IL,...15. ．． 16□, +6.
, . . . , 167, the piezoelectric element 1. ．． 1. , ...1.1 and the signal switching circuit 1°.0 are connected.

The signal switching circuit 10 includes an impedance measurement device 11
and further connected to a microcomputer (including an input/output interface) 5 for monitoring data, and the microcomputer 5 has a recording device 6.
, a display device 7, and a key switch 8 are connected.

In FIG. 1, piezoelectric elements 11.1□, . . . 1 have cells 2. ．． 2. , ..., 2. l is added,
It is installed so as to be in contact with the thermostat 9.

Cell 2. ．． 2! , ...52. On the side and bottom surfaces of the piezoelectric elements 1r, 1t, . . . , 1. Conductor plates 13+, 13z, ...+, 13-11 connected to l
4+, 14g,..., 14. is fixed, connected to the signal switching circuit 10, and fixed to the installation part of the cell. ．． 15□,...,15,. 161.16t
, . . . , 16, the piezoelectric elements 1+, Ig, . . . , 1i and the signal switching circuit 10
is connected. The signal switching circuit 10 is connected to an impedance-resonance frequency measuring device 12 and further connected to a microcomputer (including an input/output interface) 5 for monitoring data. A device 7 and a key switch 8 are connected.

In Fig. 1m, the piezoelectric element 1 on which the antibody was immobilized was placed in contact with the sample on both sides, and was sealed except for the two inlet/outlet ports for introducing and discharging liquid into the cell. It is installed in cell 2. Cell 2 is thermostat 9
It is installed so that it is in contact with. A conductive plate 13.14 connected to the piezoelectric element 1 is fixed to the inner wall of the cell 2, and piezoelectric The 0 oscillation circuit 3 to which the element 1 and the oscillation circuit 3 are connected is connected to a frequency counter 4, and further connected to a microcomputer (including an input/output interface) for monitoring data.
A recording device 6, a display device 7, and a key switch 8 are connected to the microcomputer 5.

In FIG. 1n, a piezoelectric element 15 covered with a sensitive film is shown. ]
is installed in a closed cell 2 with a rubber section 17 for introducing gas or vaporizable liquid into the cell interior. The cell 2 is placed in contact with a thermostat 9. On the inner wall of the cell 2 are conductive plates 13, . 13t, 14+, 14t are fixed, a conductor plate 15. is connected to the oscillation circuit and fixed to the installation part of the cell. , I5t, 16. ．． The piezoelectric element 1+, Ig and the signal switching circuit 10 are connected by a capacitance of 1.6□. The signal switching circuit 10 is connected to an impedance-resonance frequency measuring device 12, and is equipped with a microcomputer (
5 (including an input/output interface), and a recording device 6, a display device 7, and a key switch 8 are connected to the microcomputer 5.

Further, the crystal resonator and the cell are integrated, and the crystal resonator cell can be easily removed from the main body of the measuring device, and can be used for cleaning or other operations, or can be made disposable.

[Application Example 1 to Measurement] In this example, an application to endotoxin analysis will be described. A crystal resonator cell (piezoelectric element with a cell) using 16 9MHz, AT-cut crystal resonators,
A constant temperature chamber was installed in this reaction measuring device at 37° C., and 0.2 ml of endotoxin sample solution and a specified amount of freeze-dried horseshoe crab blood cell extract were mixed and injected into a quartz crystal cell.

This operation was performed sequentially on 16 crystal units, and at the same time the gelation time (the time until the oscillation frequency stopped changing) was measured.The gelation time was calculated by the data processing section. The endotoxin concentration varied depending on the concentration between 4 To-'EU-m]-1, and the sample amount was 20μ.
Measurement was possible even at m.

During these measurements, there are no externally exposed connection terminals on either the crystal oscillator cell or the main body, and there is no need to physically contact the connection terminals between the device body and the crystal oscillator cell. Operations such as attaching and detaching the child cell and the main body of the device could be performed easily and quickly. Furthermore, the connection terminal did not damage protective gloves or the like during operation.

After the measurement, the crystal resonator cell was washed with water, alcohol, and acid, and was further subjected to dry heat treatment at 180° C. for 4 hours, but the electrical characteristics of the connected portion did not deteriorate.

[Application Example 2 to Measurement] In this example, an application to a blood coagulation test will be described. A crystal resonator cell using 1, 6, or 8 9MHz AT cuft crystal resonators is heated to 37 cm in a thermostat.
℃, incubate for 1 minute, and add 0.05 ml of activated partial thromboplastin solution to 0.05 ml of factor VIII-deficient blood. Sample 0.
After adding 0.05ml of 0.025M calcium chloride solution and incubating for another 2 minutes, add 0.05ml of 0.025M calcium chloride solution.
It was immediately injected into a quartz crystal cell. When measuring multiple samples simultaneously, this operation was performed for six or eight crystal units in sequence, and the coagulation time (time until the oscillation frequency stopped changing) was measured at the same time. The coagulation time varied depending on the concentration of factor VIII between 1-10"UNIT-ml-'. Measurement was also possible with a sample amount of 20 μl.

During these measurements, there are no externally exposed connection terminals on either the crystal resonator cell or the device body, and there is no need to physically contact the connection terminals between the device body and the crystal resonator cell. Operations such as attaching and detaching the cell and the main body of the device could be performed easily and quickly. Furthermore, since the connection terminal does not damage protective gloves or the like during operation, operability and safety do not deteriorate even when measuring samples such as blood products and heated human plasma.

After the measurement, the quartz crystal resonator cell was washed with water, alcohol, and acid, and dried, but the electrical characteristics of the connected parts did not deteriorate.

Furthermore, in this example, measurement of factor 8 was described as a test item, but good results were also obtained for test items of other blood coagulation factors such as factor 9 and fibrinogen.

[Application Example 3 to Measurement] In this example, an application to viscosity measurement will be described. A crystal resonator cell using one 9 MHz, AT-cut crystal resonator was installed in this reaction measuring device, a sample liquid was injected into the crystal resonator cell, and the oscillation frequency was measured. The difference between this oscillation frequency and the oscillation frequency determined when there is no sample liquid is determined by sealing it to the viscosity measured with another viscometer in water-methanol systems, water-ethanol systems, water-glycerin systems, etc. The correspondence relationship is shown.

During these measurements, the connecting terminals of both the crystal resonator cell and the device body are exposed to the outside.1. Since there is no need for physical contact between the connection terminals of the device body and the crystal resonator cell, operations such as attaching and detaching the crystal resonator cell and the device body can be performed easily and quickly, and it is possible to perform operations such as attaching and detaching the crystal resonator cell and the device body. Even when measurements were continued for a long time under these conditions, the electrical characteristics of the connected portion did not deteriorate.

[Application Example 4 to Measurement] In this example, an application to immunoassay will be described. The FIB3 antibody was immobilized on a 9 MHz, AT-cut crystal resonator, and the crystal resonator cell integrated with the cell was installed in this reaction measurement device, and the resonance frequency was measured while flowing pure water through the crystal resonator cell.

Ta. Thereafter, the CEA antigen sample solution was introduced into the quartz crystal resonator cell and reacted, and then the resonance frequency was measured while flowing pure water again. The difference in resonance frequency before and after the reaction is CBA
Antigen concentration 1.5X10'-93X101 ng-ml-
' varied depending on the concentration.

In this example, measurements are taken while flowing pure water into the cell, but the crystal oscillator and oscillation circuit are connected to a conductor installed across a part of the cell wall, as shown in Figure 1. Since the connection is made by the capacitance of the plate, the sample or pure water will not leak from the cell, and the sample will not remain in the small gap between the cell and the connection terminal, which will not affect the measurement results. .

[Application Example 5 to Measurement] In this example, an application to a gas identification sensor system will be described. Two 9 MHz, AT-cut crystal oscillators were used, one crystal oscillator was coated with an azo lectin film, the other crystal oscillator was coated with an azo lectin/cholesterol 3:1 mixed film, and integrated with the cell. A crystal oscillator cell was installed in this reaction measurement device. Thereafter, an odorant gas was introduced into the cell and measurements were taken.

Measurement targets include β-jonone, methano
l, ethanol, citral, acstone,
ethyl ether was used.

Using this reaction measurement device, we determined the ratio of the change in resonance resistance and resonance frequency when a gas was adsorbed to the sensitive film on the crystal oscillator, and found that it varied depending on the type of gas, making it possible to identify the gas.

The crystal oscillator and impedance-resonance frequency measurement device is
As shown in Figure 1n, since the connection is made by the capacitance of the conductor plates installed to sandwich part of the cell wall, there is no possibility that gas leaking during measurement will affect the measurement results. There wasn't.

Furthermore, this reaction measuring device was also able to measure gas concentration from the amount of change in resonance resistance or resonance frequency.

〔Effect of the invention〕

As explained above, the reaction measurement device of the present invention provides an electrical connection portion using capacitance between the piezoelectric element and the oscillation circuit, the impedance measurement device, the impedance-resonance frequency measurement device, or the signal switching circuit. Eliminates the need to expose the connection terminals of both the piezoelectric element with cells and the main body of the device to the outside, and even if the connection terminals are exposed to the outside, the surface of the connection terminals has improved wear resistance and corrosion resistance. It is designed so that it can be processed. For this purpose, piezoelectric elements with cells may be damaged during operations such as attaching and detaching the piezoelectric element with cells to the main body of the device, cleaning, heat treatment, etc., or due to physical or chemical effects such as oxygen or water in the sample or air. It was possible to prevent deterioration of the electrical characteristics of the connection parts of both the device and the main body of the device.

Furthermore, since there is no need to physically contact the connection terminals of the device body and the piezoelectric element with cells, the operability and safety of attaching and detaching the device body and the piezoelectric element with cells are improved. In particular, the possibility of damaging the connecting terminal of the piezoelectric element with a cell, or protective gloves etc. when attaching and detaching the device body and the piezoelectric element with a cell, etc., has been significantly reduced, so there is no need to worry about damage to the human body. ,
The effect is remarkable when handling samples that are at risk of infection, such as viruses.

Furthermore, since the operations for attaching and detaching have become extremely simple, it is now possible to automate cell exchange, creating a system that automates all operations from sample dispensing to cell exchange. is now possible.

Furthermore, when it was necessary to seal the part of the cell into which the sample was introduced, including the piezoelectric element, this could be easily accomplished.

[Brief explanation of drawings]

Figure 1a to 1V! 3A and 4B show schematic diagrams of other embodiments of the reaction measuring device of the present invention. 1 and 10. ..., 1. l...Piezoelectric elements 2 and 21. ..., 2. l...Cells 3 and 3I,
..., 3. ,...Oscillation circuit 4...Frequency counter 5...Computer 6...Recording device f
7...Display device 8...Key switch 9...Thermostat 10...Signal switching circuit 11...Impedance measuring device 12...Impedance-resonant frequency measuring device 13 and 13. ．． 13z, ..., 13. ...Conductor plate 14
and 14+=14g, ..., 14a...conductor plate 1
5 and 15+, 15g, ..., 15. ...conductor plates 16 and 16+, 16g, ..., 16. ...Conductor plate 17...Rubber and above Applicant Seiko Electronic Industries Co., Ltd. Agent Patent Attorney Keisuke Hayashi Figure a Figure A''S Figure Figure Figure

Claims (14)

[Claims] (1) A reaction measurement device comprising a piezoelectric element with a cell, an oscillation circuit, and a frequency measurement circuit, characterized in that it has a non-DC connection between the piezoelectric element and the oscillation circuit. (2) A reaction measuring device comprising a piezoelectric element with a cell and an impedance measuring device, characterized in that it has a non-DC connection between the piezoelectric element and the impedance measuring device. (3) A reaction measuring device comprising a piezoelectric element with a cell and an impedance-resonant frequency measuring device, which is characterized by having a non-DC connection between the piezoelectric element and the impedance-resonant frequency measuring device. Measuring device. (4) Non-DC connection between the piezoelectric element and the oscillation circuit in a reaction measurement device consisting of a piezoelectric element with multiple cells, the same number of oscillation circuits, a signal switching circuit, and a frequency measurement circuit. A reaction measuring device characterized by having: (5) A reaction measuring device comprising a piezoelectric element with a plurality of cells, a signal switching circuit, and an impedance measuring device, characterized by having a non-DC connection between the piezoelectric element and the signal switching circuit. Reaction measurement device. (6) In a reaction measurement device consisting of a piezoelectric element with multiple cells, a signal switching circuit, and an impedance-resonance frequency measuring device, it is necessary to have a non-DC connection between the piezoelectric element and the signal switching circuit. Characteristic reaction measuring device. (7) The reaction measuring device according to any one of items 1 to 6, characterized in that it has a configuration in which a data processing control device is added. (8) A first device characterized by having a configuration in which a constant temperature chamber is added.
7. The reaction measuring device according to any one of paragraphs 7 to 7. (9) The non-DC connection portion is a conductor connected to the piezoelectric element, and a conductor connected to the oscillation circuit, the impedance measurement device, the impedance-resonance frequency measurement device, or the signal switching circuit. 9. The reaction measuring device according to any one of items 1 to 8, characterized in that the reaction measuring device is constituted by a capacitance of . (10) The reaction measuring device according to any one of items 1 to 9, wherein the piezoelectric element with the cell is removable from the device main body. (11) The conductor connected to the piezoelectric element constitutes a part of a cell, and the conductor is connected to the oscillation circuit, the impedance measurement device, the impedance-resonance frequency measurement device, or the signal switching circuit. A first device characterized in that the conductor constitutes a part of the device main body.
10. The reaction measuring device according to any one of items 1 to 10. (12) The reaction measuring device according to any one of items 1 to 11, wherein the piezoelectric element is an AT cut crystal resonator or a BT cut crystal resonator. (13) The reaction measurement according to any one of paragraphs 1 to 12, wherein the data processing control device is comprised of a microcomputer, a key input switch, a display device, a recording device, and an input/output signal interface. Device. (14) The reaction measuring device according to any one of items 1 to 13, wherein the piezoelectric element is attached to a cell so that only one electrode is in contact with the sample.