JP3041361B2 - Reaction measurement device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to the chemistry, physical chemistry, biochemistry, polymer chemistry and medical, pharmacy, food, chemical reaction in the chemical industry, the tracking of immune reaction, physical property analysis and And a device for performing measurement using the same.

[Summary of the Invention]

The present invention provides a reaction measuring device using a piezoelectric element as a detector, a piezoelectric element and an oscillation circuit, an impedance measuring device,
By providing an electrical connection part by capacitance between the impedance-resonance frequency measurement device or the signal switching circuit, so that the connection terminals of both the piezoelectric element with the cell and the device body are not exposed to the outside. It is.
Further, even when the connection terminal is exposed to the outside, the surface of the connection terminal can be subjected to a treatment for improving abrasion resistance and corrosion resistance. As a result, it is possible to prevent the electrical characteristics of the connection portion from deteriorating during operations such as cleaning and heat treatment of the piezoelectric element with the cell, and the physical or chemical action of the sample and water. It has become possible to improve the operability of attaching and detaching the used piezoelectric element to and from the apparatus main body.

[Conventional technology]

As a measurement target of the reaction measuring device of the present invention, a reaction mainly involving a change in viscosity can be considered. Conventionally, for viscosity measurement,
The capillary method, the rotation method, the falling ball method and the like have been used. The capillary method is to determine the viscosity from the speed at which the sample solution falls down the capillary, and the falling ball method is to put a metal ball into the sample solution and determine the viscosity from the falling speed. In the rotation method, a viscosity is determined by rotating a cylindrical metal rod in a sample solution and determining a shear stress. On the other hand, when the reaction measurement target is a coagulation reaction or gelation reaction, a method of optically measuring the turbidity of the sample, a method of applying a mechanical vibration to the sample and detecting a change in viscosity due to coagulation or gelation Was taken.

[Problems to be solved by the invention]

In the conventional viscosity measurement method, since one measurement operation takes time, it is difficult to continuously measure a change accompanying the reaction, and there is a problem that measurement cannot be performed with a small amount of sample. .

In the measurement of coagulation reaction or gelation reaction of endotoxin or blood coagulation factor, the conventional method of measuring turbidity involves the problem that the system becomes complicated due to the inclusion of an optical measurement system, and the measurement of colored samples is difficult. It is not suitable, and there is a problem that a large error is caused by salting out depending on the sample. In addition, in the method of applying mechanical vibration, it is difficult to reduce the size and weight because of the presence of the mechanical part, and it is inevitable that the apparatus becomes large.

In addition to these points, each method has a problem that a sample of at least about 0.2 ml is required. The measurement method using a piezoelectric element devised by the present inventors was able to measure a sample of 0.2 ml or less. Also, since there is no mechanically operating part, the system can be easily miniaturized.

Until now, however, since there was a direct current connection between the piezoelectric element and the oscillation circuit, the attachment and detachment of the piezoelectric element with a cell to the device body, cleaning, heat treatment, etc. Due to physical or chemical action of oxygen or water in the air, or the like, the electrical characteristics of the connection part of both the device body and the piezoelectric element with the cell may be deteriorated.

Further, there is room for improvement in operability and safety such as attachment / detachment of the piezoelectric element having the cell with the device body. In particular, when handling samples that are harmful to the human body or at risk of infection by viruses or the like, the possibility of damaging protective gloves with the connection terminals of the piezoelectric element with cells is a major problem. there were.

In addition to the viscosity measurement, an immunoreaction measurement device and a gas sensor system using a piezoelectric element have been devised by the present inventors.However, in the case of an immunoassay, a connection terminal of a piezoelectric element fixed to a cell and a cell are used. In some cases, a sample or a cleaning liquid may remain in a small gap in the wall of the cell and affect the measurement result, or the liquid in the cell may leak from the small gap.

The gas sensor system measures an adsorption reaction of a gas on a sensitive film on a quartz oscillator. The connecting portion between the piezoelectric element fixed inside the cell and the outside is connected by a conductive wire penetrating a part of the wall of the sealed cell, but gas may leak from a slight gap.

[Means for solving the problem]

In order to solve these problems, the present invention provides a piezoelectric element having a cell and the same number of oscillation circuits and frequency measuring circuits, a piezoelectric element having a cell and an impedance measuring device, or a cell. In the case of using a piezoelectric element with an attached element and an impedance-resonance frequency measuring device, adding them to a data processing control device, adding them to a thermostat, or using a plurality of piezoelectric elements In a reaction measuring device configured by adding a signal switching circuit to these components, an electric connection portion by electrostatic induction is connected between a piezoelectric element and an oscillation circuit, an impedance measuring device, an impedance-resonance frequency measuring device, or a signal switching circuit. Is provided.

[Action]

A piezoelectric element is a device using a piezoelectric effect, and can be oscillated by connecting to an oscillation circuit. At this time, the surface of the piezoelectric element generates minute vibration.
For this reason, the piezoelectric element is known to be affected by the viscoelasticity and density of the substance in contact with the surface or the weight change such as adsorption of the substance on the surface, and the resonance frequency and the resonance resistance are changed. I have. By measuring the resonance frequency and resonance resistance, viscoelastic changes in liquids and liquid crystals, substance adsorption,
It is possible to measure the material deposition by settling.

In a reaction measuring apparatus using this piezoelectric element, when a piezoelectric element with a cell is installed in the apparatus main body, a conductor and an oscillation circuit connected to the piezoelectric element, an impedance measuring apparatus,
A structure in which the piezoelectric element and the oscillation circuit, the impedance measuring device, the impedance-resonant frequency measuring device or the signal switching circuit are electrically connected by the capacitance of the conductor connected to the impedance-resonant frequency measuring device or the signal switching circuit. This eliminates the need to expose the connection terminals of both the piezoelectric element with the cell and the device body to the outside.

Further, even when the connection terminal is exposed to the outside, the surface of the connection terminal can be subjected to a treatment for improving abrasion resistance and corrosion resistance.

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

〔Example〕

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIGS. 1a to 1n are schematic views of the reaction measuring device of the present invention.

In FIG. 1a, a cell 2 is attached to a piezoelectric element 1. A piezoelectric element 1 is provided on the side or bottom of the cell 2.
The piezoelectric elements 1 and the oscillating circuit 3 are connected by the capacitance of the conductive plates 13 and 14 connected to the oscillating circuit and the conductive plates 15 and 16 connected to the oscillating circuit and fixed to the installation portion of the cell. I have. The oscillation circuit 3 is connected to the frequency counter 4,
Further, the microcomputer 5 is connected to a microcomputer (including an input / output interface) 5 for monitoring data. The microcomputer 5 is connected to a recording device 6, a display device 7, and a key switch 8.

In FIG. 1b, the cell 2 is attached to the piezoelectric element 1. A piezoelectric element 1 is provided on the side or bottom of the cell 2.
The piezoelectric elements 1 and the impedance measuring device 11 are fixed by the capacitance of the conductive plates 13 and 14 connected to the conductor plates 15 and 16 connected to the impedance measuring device 11 and fixed to the installation portion of the cell. It is connected. The impedance measuring device 11 is connected to a microcomputer (including an input / output interface) 5 for monitoring data. The microcomputer 5 is connected to a recording device 6, a display device 7, and a key switch 8.

In FIG. 1c, the piezoelectric element 1 has a cell 2 attached thereto. A piezoelectric element 1 is provided on the side or bottom of the cell 2.
The conductor plates 13, 14 connected to the piezoelectric element 1 are fixed to the piezoelectric element 1 by the capacitance of the conductor plates 15, 16 connected to the impedance-resonance frequency measuring device 12 and fixed to the installation portion of the cell. The resonance frequency measuring device 12 is connected. Impedance-resonance frequency measurement device 12,
The microcomputer 5 is connected to a microcomputer (including an input / output interface) 5 for monitoring data. The microcomputer 5 is connected to a recording device 6, a display device 7, and a key switch 8.

In FIG. 1d, the cell 2 is attached to the piezoelectric element 1 and is installed so as to be in contact with the thermostat 9. A conductor plate connected to the piezoelectric element 1 is provided on the side or bottom of the cell 2
The piezoelectric elements 1 and the oscillating circuit 3 are connected by the capacitance of the conductor plates 15 and 16, which are fixed to the oscillating circuit and are fixed to the oscillating circuit. Oscillation circuit 3
Is connected to a frequency counter 4 and further to a microcomputer (including an input / output interface) 5 for monitoring data. The microcomputer 5 includes a recording device 6, a display device 7, and a key switch 8.
Is connected.

In FIG. 1e, the cell 2 is attached to the piezoelectric element 1 and is installed so as to be in contact with the thermostat 9. A conductor plate connected to the piezoelectric element 1 is provided on the side or bottom of the cell 2
The piezoelectric element 1 and the impedance measuring device 11 are fixed by the capacitance of the conductor plates 15 and 16, which are fixed to the impedance measuring device 11 and fixed to the installation portion of the cell.
Is connected. The impedance measuring device 11 is connected to a microcomputer (including an input / output interface) 5 for monitoring data. The microcomputer 5 is connected to a recording device 6, a display device 7, and a key switch 8.

In FIG. 1f, a cell 2 is attached to the piezoelectric element 1, and a conductor plate 1 connected to the piezoelectric element 1 is provided on the side or bottom surface of the cell 2 which is installed in contact with the thermostat 9.
3 and 14 are fixed, and the conductor plate 1 is connected to the impedance-resonance frequency measuring device 12 and fixed to the installation portion of the cell.
The piezoelectric element 1 and the impedance-resonance frequency measuring device 12 are connected by the capacitances 5 and 16. The impedance-resonance frequency measuring device 12 is connected to a microcomputer (including an input / output interface) 5 for monitoring data.
, A recording device 6, a display device 7, and a key switch 8 are connected.

In Figure 1 g, the piezoelectric element 1 _1, 1 _2,..., The 1 _n,
Cells 2 ₁ , 2 ₂ ,..., 2 _n are provided. Cells 2 ₁ , 2 ₂ ,
・ ・, _2n The piezoelectric elements 1 ₁ , 1 ₂ , ・ ・
·, 1 _n and connected to the conductive plate _{13 1, 13 2, ···,} 13 n, 14 1, 1
4 _2, · · ·, 14 _n is fixed, the conductive plate 15 ₁ fixed to the installation portions of the connected cell to the oscillation circuit, 15 _2, · · ·, 15 _n, 16
₁ , 16 ₂ ,..., 16 _n , the piezoelectric elements 1 ₁ , 1
_2, ···, 1 _n and the oscillation circuit _{3 1, 3 2, ···,} 3 n are connected. The oscillation circuits 3 ₁ , 3 ₂ ,..., 3 _n are signal switching circuits 10
And a microcomputer (including an input / output interface) 5 for monitoring data. A recording device 6, a display device 7, and a key switch 8 are connected to the microcomputer 5. Have been.

In Figure 1 h, the piezoelectric element 1 _1, 1 _2,..., The 1 _n,
Cells 2 ₁ , 2 ₂ ,..., 2 _n are provided. Cells 2 ₁ , 2 ₂ ,
・ ・, _2n The piezoelectric elements 1 ₁ , 1 ₂ , ・ ・
·, 1 _n and connected to the conductive plate _{13 1, 13 2, ···,} 13 n, 14 1, 1
4 ₂ ,..., 14 _n are fixed, connected to the signal switching circuit 10 and fixed to the cell installation part 15 ₁ , 15 ₂ ,.
, 15 _n , 16 ₁ , 16 ₂ ,..., 16 _n connect the piezoelectric elements 1 ₁ , 1 ₂ ,..., 1 _n to the signal switching circuit 10. The signal switching circuit 10 is connected to an impedance measuring device 11, and further connected to a microcomputer (including an input / output interface) 5 for monitoring data. The microcomputer 5 includes a recording device 6, a display device 7, and a key. Switch 8 is connected.

In Figure 1 i, the piezoelectric element 1 _1, 1 _2,..., The 1 _n,
Cells 2 ₁ , 2 ₂ ,..., 2 _n are provided. Cells 2 ₁ , 2 ₂ ,
・ ・, _2n The piezoelectric elements 1 ₁ , 1 ₂ , ・ ・
·, 1 _n and connected to the conductive plate _{13 1, 13 2, ···,} 13 n, 14 1, 1
4 ₂ ,..., 14 _n are fixed, connected to the signal switching circuit 10 and fixed to the cell installation part 15 ₁ , 15 ₂ ,.
, 15 _n , 16 ₁ , 16 ₂ ,..., 16 _n connect the piezoelectric elements 1 ₁ , 1 ₂ ,..., 1 _n to the signal 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. The microcomputer 5 includes a recording device 6 and a display device. 7. The key switch 8 is connected.

In Figure 1 j, the piezoelectric element 1 _1, 1 _2,..., The 1 _n,
Cells 2 ₁ , 2 ₂ ,..., 2 _n are attached and installed so as to be in contact with the thermostat 9. Cell 2 _1, 2 _2, ..., on the side surface or the bottom surface of the 2 _n, the piezoelectric element 1 _1, 1 _2, ..., 1 _n and connected to the conductive plate 13 _1, 13 _2, ..., 13 _n , 14 ₁ , 14 ₂ ,..., 14 _n are fixed and connected to the oscillation circuit and fixed to the installation portion of the cell. 15 ₁ , 15 ₂ ,..., 15 _n , 16 ₁ , 16 _2, ..., by the capacitance of the 16 _n, the piezoelectric element 1 _1, 1 _2, ..., 1 _n and the oscillation circuit 3 _1, 3 _2, ..., 3 _n is connected I have. Oscillator circuits 3 ₁ , 3 ₂ ,
.., 3 _n are connected to a frequency counter 4 via a signal switching circuit 10 and further connected to a microcomputer (including an input / output interface) 5 for monitoring data. The device 6, the display device 7, and the key switch 8 are connected.

In Figure 1 k, the piezoelectric element 1 _1, 1 _2,..., The 1 _n,
Cells 2 ₁ , 2 ₂ ,..., 2 _n are attached and installed so as to be in contact with the thermostat 9. Cell 2 _1, 2 _2, ..., on the side surface or the bottom surface of the 2 _n, the piezoelectric element 1 _1, 1 _2, ..., 1 _n and connected to the conductive plate 13 _1, 13 _2, ..., _{13 n, 14 1, 14 2} , ···, 14 n is fixed, the signal switching circuit is connected to 10 by the conductive plate 15 ₁ fixed to the mounting portion of the cell, 15 _2, · · ·, 15 _n, 16 ₁ , 16 ₂ , ...
-, by the capacitance of the 16 _n, the piezoelectric element 1 _1, 1 _2, ..., 1
_n and the signal switching circuit 10 are connected. The signal switching circuit 10 is connected to an impedance measuring device 11, and further connected to a microcomputer (including an input / output interface) 5 for monitoring data. The microcomputer 5 includes a recording device 6, a display device 7,
The key switch 8 is connected.

In Figure 1 l, the piezoelectric element 1 _1, 1 _2,..., The 1 _n,
Cells 2 ₁ , 2 ₂ ,..., 2 _n are attached and installed so as to be in contact with the thermostat 9. Cell 2 _1, 2 _2, ..., the side and bottom of the 2 _n, the piezoelectric element 1 _1, 1 _2, ..., 1 _n and connected to the conductive plate 13 _1, 13 _2, ..., _{13 n, 14 1, 14 2} , ···, 14 n is fixed, the signal switching circuit is connected to 10 by the conductive plate 15 ₁ fixed to the mounting portion of the cell, 15 _2, · · ·, 15 _n, 16 ₁ , 16 ₂ , ...
-, by the capacitance of the 16 _n, the piezoelectric element 1 _1, 1 _2, ..., 1
_n and the signal switching circuit 10 are 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.
The display device 7 and the key switch 8 are connected.

In FIG. 1m, the piezoelectric element 1 with the antibody immobilized thereon is
Both sides are in contact with the sample, and are placed in a sealed cell 2 except for two inlet / outlet ports for introducing and discharging a liquid into the cell. The cell 2 is installed so as to be in contact with the thermostat 9. On the inner wall of cell 2,
The conductor plates 13 and 14 connected to the piezoelectric element 1 are fixed, and the conductor plates 1 and 14 connected to the oscillation circuit and fixed to the installation portion of the cell are fixed.
The piezoelectric element 1 and the oscillation circuit 3 are connected by the capacitances 5 and 16. The oscillation circuit 3 is connected to a frequency counter 4 and further connected to a microcomputer (including an input / output interface) 5 for monitoring data.
The display device 7 and the key switch 8 are connected.

In Figure 1 n, the piezoelectric element 1 coated with the sensitive film _1, 1 ₂
Is installed in a closed cell 2 with a rubber portion 17 for introducing a gas or a liquid that is easily vaporized into the cell. The cell 2 is installed so as to be in contact with the thermostat 9. The inner wall of the cell 2, the piezoelectric element 1 _1, 1 ₂ is connected with the conductor plate 13 _1, 13 _2, 14 _1, 14 ₂ are fixed, is connected to the oscillation circuit is fixed to the mounting portion of the cell conductors Plates 15 ₁ , 15 ₂ , 16 ₁ , 1
The capacitance of the 6 _2, the piezoelectric element 1 _1, 1 ₂ 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. The microcomputer 5 includes a recording device 6 and a display device. 7,
The key switch 8 is connected.

In addition, the quartz oscillator and the cell are integrated, and the quartz oscillator cell can be easily removed from the measuring apparatus main body, and can be subjected to an operation such as cleaning, or can be disposable.

[Application Example 1 to Measurement] In this example, an application to endotoxin analysis will be described. A quartz oscillator cell (piezoelectric element with a cell) using 16 9MHz AT-cut quartz oscillators was installed in this reaction measuring device with a thermostat at 37 ° C. Was mixed with a lyophilized horseshoe crab blood cell extract and injected into a quartz crystal cell. This operation was sequentially performed on 16 quartz resonators, and at the same time, the gelation time (time until the oscillation frequency did not change) was measured.

The gelation time was calculated in the data processing section, and the gelation time varied between endotoxin concentrations of 4-10 ^-3 EU · ml ^-1 depending on the concentration. The measurement was possible even with a sample volume of 20 μl.

At the time of these measurements, neither the crystal unit cell nor the device body had any connection terminals exposed to the outside, and there was no need to physically contact the connection terminals of the device body and the crystal unit cell. Operations such as attachment and detachment of the cell and the apparatus main body could be performed easily and quickly. Further, the protective gloves and the like were not damaged by the connection terminals during the operation. After the measurement, the quartz oscillator cell was washed with water, alcohol, and acid, and further subjected to a dry heat treatment at 180 ° C. for 4 hours. However, the electrical characteristics of the connection portion did not deteriorate.

[Example 2 of Application to Measurement] In this example, an example applied to a blood coagulation test will be described. A crystal oscillator cell using one, six, or eight 9MHz AT-cut quartz oscillators was placed in this reaction measuring device with a thermostat at 37 ° C, and incubated for 1 minute in advance to cause factor VIII deficiency. Add 0.05 ml of the activated partial thromboplastin solution and 0.05 ml of the sample to 0.05 ml of the serum, and add 2 ml.
After incubating for 0 minutes, 0.025M calcium chloride solution is added.
05 ml was added and immediately injected into the crystal oscillator cell.
At the time of simultaneous measurement of a plurality of samples, this operation was sequentially performed on six or eight quartz oscillators, and the coagulation time (time until the oscillation frequency did not change) was measured at the same time. The clotting times varied in a concentration-dependent manner between factor VIII concentrations of 1-10 ^-2 UNIT.ml ^-1 . The measurement was possible even with a sample volume of 20 μl.

At the time of these measurements, neither the crystal unit cell nor the device body had any connection terminals exposed to the outside, and there was no need to physically contact the connection terminals of the device body and the crystal unit cell. Operations such as attachment and detachment of the cell and the apparatus main body could be performed easily and quickly. Further, since the protective gloves and the like are not damaged by the connection terminals during the operation, the operability and safety did not decrease even when measuring a sample such as a blood product or a heated human plasma.

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

In this example, measurement of factor VIII was described as a test item, but good results were obtained for test items of other plasma coagulation factors such as factor ninth and fibrinogen.

[Application Example 3 to Measurement] In this example, an example applied to viscosity measurement will be described. A quartz oscillator cell using one 9 MHz AT-cut quartz oscillator was set in the present reaction measuring apparatus, a sample liquid was injected into the quartz oscillator cell, and the oscillation frequency was measured. The difference between this oscillation frequency and the oscillation frequency obtained when there is no sample liquid is a good response to the viscosity measured with other viscometers in water-methanol, water-ethanol, water-glycerin, etc. The relationship was shown.

At the time of these measurements, neither the crystal unit cell nor the device body had any connection terminals exposed to the outside, and there was no need to physically contact the connection terminals of the device body and the crystal unit cell. Operations such as attachment and detachment of the cell and the main body of the device can be performed easily and quickly, and the electrical characteristics of the connection portion did not deteriorate even if measurement was continued for a long time under high temperature and high humidity conditions. .

[Application Example 4 to Measurement] In this example, an application to an immunoassay will be described. The F1B3 antibody was immobilized on a 9 MHz, AT-cut crystal oscillator, and the crystal oscillator cell integrated with the cell was installed in the present reaction measurement device, and the resonance frequency was measured while flowing pure water through the crystal oscillator cell. Thereafter, the CEA antigen sample solution was introduced into the quartz oscillator cell and reacted, and the resonance frequency was measured while flowing pure water again. The difference between the resonance frequencies before and after the reaction varied between the CEA antigen concentrations of 1.5 × 10 ³ −9.3 × 101 ng · ml ⁻¹ depending on the concentration.

In this embodiment, the measurement is performed while flowing pure water into the cell. However, as shown in FIG. 1m, the crystal oscillator and the oscillation circuit are provided with a conductor set so as to sandwich a part of the cell wall. Since the connection was made by the capacitance of the plate, the sample and pure water leaked from the cell, and the sample remained in the slight gap between the cell and the connection terminal, and did not affect the measurement results. .

[Application Example 5 to Measurement] In this embodiment, an example applied to a gas identification sensor system will be described. 2 9MHz, AT-cut crystal oscillator
One crystal oscillator is an azolectin film, and the other is an azolectin / cholesterol 3:
A quartz oscillator cell coated with the mixed film of No. 1 and integrated with the cell was installed in the present reaction measuring apparatus. Thereafter, an odorant gas was fed into the cell to perform the measurement.

Measurement targets are β-ionone, methnaol, ethanol, ci
tral, acetone, ethyl ether were used. When the ratio of the change in the resonance resistance and the change in the resonance frequency when the gas was adsorbed to the sensitive film on the crystal oscillator was determined by the present reaction measurement device, the ratio changed depending on the type of gas, and the gas could be identified.

Since the crystal unit and the impedance-resonance frequency measuring device are connected by the capacitance of a conductor plate provided so as to sandwich a part of the cell wall as shown in FIG. Leakage did not affect the measurement results.

Further, the present reaction measurement device was able to measure the gas concentration from the change in the resonance resistance or the resonance frequency.

〔The invention's effect〕

As described above, the reaction measuring device of the present invention is provided with an electrical connection part by capacitance between the piezoelectric element and the oscillation circuit, the impedance measuring device, the impedance-resonance frequency measuring device or the signal switching circuit,
Both the piezoelectric element with the cell and the device main body eliminate the need to expose the connection terminals to the outside, and even when the connection terminals are exposed to the outside, the surface of the connection terminals has wear resistance,
It is possible to perform a treatment for improving corrosion resistance. For this reason, the piezoelectric element with a cell is attached or detached from the device main body, during operations such as cleaning and heat treatment, or by a physical or chemical action of oxygen or water in the sample or air. It was possible to prevent the deterioration of the electrical characteristics of the connection portions of both the device and the device main body.

In addition, since there is no need to physically contact the connection terminal of the device body and the piezoelectric element with the cell, the operability and safety of attaching and detaching the device body and the piezoelectric element with the cell are improved. In particular, since the possibility of damaging the connection terminals of the piezoelectric element with the cell and the protective gloves when attaching and detaching the device body and the piezoelectric element with the cell has been greatly reduced, it is harmful to the human body, The effect is remarkable when handling a sample with a risk of infection such as a virus.

In addition, the operation at the time of attachment and detachment has become very easy,
Automation of cell exchange can be easily realized, and a system in which all operations from sample dispensing to cell exchange are automated can be configured.

Further, when it was necessary to seal the portion for introducing the sample inside the cell including the piezoelectric element, it could be easily realized.

[Brief description of the drawings]

FIGS. 1a to 1n are schematic diagrams of another embodiment of the reaction measuring apparatus of the present invention. 1 and 1 _1, · · ·, 1 _n ...... piezoelectric element 2 and 2 _1. · · ·, 2 _n ...... cells 3 and 3 _1, · · ·, 3 _n ...... oscillation circuit 4 ...... frequency counter, 5 Computer 6 Recording device 7 Display device 8 Key switch 9 Thermostat 10 Signal switching circuit 11 Impedance measuring device 12 Impedance-resonance frequency measuring devices 13 and 13 ₁ , 13 ₂ ,..., 13 _n … Conductor plates 14 and 14 ₁ , 14 ₂ ,…, 14 _n … Conductor plates 15 and 15 ₁ , 15 ₂ ,…, 15 _n … Conductor plates 16 and 16 ₁ , 16 ₂ , ..., 16 _n … Conductor plate 17… Rubber

──────────────────────────────────────────────────続 き Continued on the front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) G01N 11/00-11/16 G01N 5/02

Claims (8)

(57) [Claims] 1. A reaction measuring apparatus comprising at least a piezoelectric element, a cell, and a characteristic circuit of the piezoelectric element, wherein the piezoelectric element is mounted on a cell, and two cells connected to the piezoelectric element on a side surface or a bottom surface of the cell. The side conductor plate is fixed without being exposed to the outside, and the cell can be detachably attached to the characteristic measurement circuit of the piezoelectric element. When the cell is attached, the cell-side conductor plate is connected to the characteristic measurement circuit of the piezoelectric element. It is located adjacent to each of the two conductor plates in the cell installation part and makes electrostatic connection, suppressing physical and chemical deterioration of the electrical connection part and improving operational safety A reaction measuring device characterized in that the reaction is performed. 2. The reaction measuring apparatus according to claim 1, wherein the characteristic measuring circuit of the piezoelectric element comprises an oscillation circuit, a frequency counter, and a data processing circuit. 3. The reaction measuring device according to claim 1, wherein the characteristic measuring circuit of the piezoelectric element comprises an oscillation circuit, an impedance measuring device and a data processing circuit. 4. The reaction measuring apparatus according to claim 1, wherein the characteristic measuring circuit of the piezoelectric element comprises an oscillation circuit, an impedance-resonance frequency measuring device, and a data processing circuit. 5. The reaction according to claim 1, wherein the characteristic measuring circuits of the plurality of piezoelectric elements are composed of the same number of oscillation circuits, signal switching circuits, frequency counters and data processing circuits as the number of the piezoelectric elements. Measuring device. 6. The reaction measuring device according to claim 1, wherein the characteristic measuring circuit of the plurality of piezoelectric elements comprises a signal switching circuit, an impedance measuring device, and a data processing circuit. 7. The reaction measuring device according to claim 1, wherein the characteristic measuring circuit for the plurality of piezoelectric elements comprises a signal switching circuit, an impedance-resonance frequency measuring device, and a data processing circuit. 8. The reaction measuring apparatus according to claim 1, wherein the piezoelectric element is an AT-cut quartz oscillator or a BT-cut quartz oscillator.