JPH02220375A - Biochemical measuring instrument - Google Patents

Abstract

PURPOSE:To make a senser compact, increase the life of a connector, and facilitate installation and removal of the senser by providing a means for water- proofing and insulating connection parts of the first and second connectors and at least either a contact part or a contact terminal of the senser. CONSTITUTION:If a first connector case 10 is inserted into an insertion part 7 of a biochemical device, a pin 15 is inserted into a pin insertion part 8a of a second connector 8, and a spring contact 8b is pressure contacted with the pin 15, so the case 10 is electrically connected with the connector 8. A button 13 protrudes from a hole 2c in a case top surface 2a to the case top surface 2a. An O-ring 16 is tightly applied to the inner surface of the insertion part 7 to water-proof a connection part of the case 10 with the connector 8. For installing a senser 60, the button 13 is pushed to push up the forward end of a contact terminal 12, and the senser 60 is inserted until it is applied to an entrance 10a of the senser, when the button 13 is released. The terminal 12 is restored to its original condition by action of a coil spring 14, and its forward end is pressure contacted with contact parts 62b, 63b of the senser 60 to make continuity. The terminal 12 and the contact parts 62b, 63b are insulated and water-proofed by insulation gel 11.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application This invention relates to a small-sized biochemical measuring device using an amperometric sensor or a potentiometric sensor.

(b) Conventional technology Potentiometric sensors and amperometric sensors are used to electrically measure ion concentrations and substance concentrations in sample solutions. A potentiometric sensor is a sensor that uses a change in voltage between electrodes as a signal, and a type that uses a high impedance amplifier to detect changes in potential between electrodes is known. For example, the ion concentration can be measured by measuring the potential difference between the inside and outside of an ion-selective membrane, and ion-selective membranes using glass are currently commercially available.

On the other hand, an amperometric sensor is a sensor that applies a DC or AC potential between electrodes and captures the resulting reaction current as a signal. For example, by applying a constant DC voltage corresponding to oxygen (0,) or hydrogen peroxide (H! O!) between the electrodes, a current proportional to the concentration can be obtained. Alternatively, a method is known in which a reaction current proportional to the concentration of the substance to be measured is obtained indirectly via an electron transfer substance.

Furthermore, enzyme electrodes that combine amperometric sensors and enzyme reactions are also known. For example, by using glucose oxidase (COD) as an enzyme and attaching this COD immobilized membrane to the surface of an amperometric sensor, a decrease in oxygen (02) or an increase in hydrogen peroxide (HzOz) near the electrode due to the enzyme reaction can be achieved. The glucose concentration in the sample can be indirectly determined from the change in the reaction current caused by the change in the reaction current.

Now, in recent years, efforts have been made to make sensors smaller and lower in cost. As for potentiometric sensors, ion and glass sensors using flat glass selective membranes and FETs have become commercially available.

Further, as for amperometric sensors, miniaturized ones shown in FIGS. 7 and 8 have been proposed. FIG. 7 is a diagram illustrating an example of an amperometric sensor that is smaller in size and lower in cost. This amperometric sensor 60 has electrode materials 62 and 63 made of metal films formed on an electrode support base material 61. The electrode support base material 61 is made of a material that has excellent waterproofness and insulation properties, can withstand heat during formation of the electrode materials 62 and 63, and has excellent adhesion to the electrode materials 62 and 63, such as alumina ceramics and polyimide-based materials. film is used.

The electrode materials 62 and 63 are made of platinum, metal, gold, or the like, and are formed by vacuum deposition, sputtering, or other IPi techniques.

An insulating protective film 64 made of photosensitive resin is formed on the electrode support base material 61 and covers the electrode materials 62 and 63. Photolithography is applied to form the insulating protective film 64, and the exposed portions of the electrode materials 62 and 63, that is, the working electrode 62a,
A control electrode 63a and connection portions 62b and 63b are provided, respectively. Lead wires are connected to the connecting portions 62b, 62b by means of soldering or the like.

FIG. 8 shows a miniaturized enzyme electrode.

This enzyme electrode 70 includes both surfaces 71a of an electrode support base material 71,
It includes an amperometric sensor 70° in which electrode materials 72 and 73 are formed on each of the electrodes 71b and an insulating protective film 74 is formed on the surface 71a of the electrode support base 71. In this amperometric sensor 70'', only the electrode material 72 is covered with an insulating protective film 74, and two portions of the electrode material 72 are exposed to form a working electrode 72a and a contact portion 72b, but the entire electrode material 73 is covered with an insulating protective film 74. is exposed and becomes the control electrode 73a and the contact portion 73b as it is.

On this amperometric sensor 70°, a hydrogen peroxide selectively permeable membrane 75 made of acetylcellulose is formed by dip coating, and the working electrode 72a and reference bridge 73a are covered. An immobilized enzyme layer 76 is formed by dropping on the working electrode 72a of the hydrogen peroxide permselective membrane 75.

Furthermore, a surface film 77 made of acedelcellulose is formed by dip coating. In this case, the amperometric link sensor 70' becomes a hydrogen peroxide detection electrode, and the enzyme used is one that produces hydrogen peroxide as a result of the reaction (
For example, C0D). Contact portions 72a, 7
Lead wires (not shown) are connected to each of the terminals 3b by means of soldering or the like, or a connector is directly attached thereto.

(C) Problems to be Solved by the Invention The biochemical analysis apparatus using the conventional potentiometric sensor and amperometric sensor described above is provided with a connector section on both the apparatus main body side and the sensor side. In FIG. 9(a), a lead wire 21 from the sensor S, a lead wire 11 from the device main body M. 1 is provided with a sensor side connector C5 and a device main body side connector CM, respectively, and both connectors Cs and CH are connected at a location away from the sample solution A, thereby showing an example in which the sensor S and the device main body M are electrically connected. . Further, FIG. 9(b) shows an example in which the device main body side connector C″8 is coupled to the connector C″, which is directly attached to the sensor S, and the sensor S and the device main body M are electrically connected. In either case, in order to detect slight changes in current or voltage, it is necessary to prevent leakage current and a drop in impedance, and care must be taken to maintain insulation at the connector part.

However, in the conventional biochemical measuring device described above, the sensor must be equipped with a connector, so even if the sensor itself becomes smaller, its effectiveness does not improve. Also, when replacing the sensor, the connector must also be replaced, and the price of the sensor also includes the price of the connector.
Running costs will increase. Furthermore, since the connector must be attached and detached each time the sensor is replaced, the life of the connector is short, and care must be taken to ensure that the connector is waterproof.

The present invention has been made in view of the above, and aims to provide a biochemical measurement device that effectively reduces the size and cost of a sensor, has a long connector life, and allows easy attachment and detachment of the sensor.

(d) Means and operation for solving the problems In order to solve the above problems, the biochemical measurement device of the present invention is provided with an insertion section into which the first connector is inserted into the case, and the first connector is inserted into the insertion section. a second connector coupled to the connector of the first connector, the first connector having a sensor insertion part into which a sensor is inserted; the sensor insertion part having a contact terminal that contacts a contact part of the sensor; The device includes waterproof insulating means for waterproofly insulating at least one of the connecting portion between the first connector and the second connector and the contact portion between the sensor contact portion and the contact terminal. Therefore, there is no need to provide a connector on the sensor itself, making it possible to effectively reduce the size and cost of the sensor, and also to make the sensor disposable, making it easy to reduce the running cost of the device.

Furthermore, when attaching and detaching the sensor, there is no need to attach and detach the first connector and the second connector, and even if the contact terminal of the first connector is damaged, only the first connector needs to be replaced. Therefore, the life of the connector part can be extended.

(E) Example (Example 1) A first example of the present invention will be described below based on FIGS. 1 to 3.

FIG. 2 is an external plan view of the biochemical measuring device 1 according to the embodiment. The biochemical measuring device 1 of this embodiment uses the amperometric sensor 60 shown in FIG. 7 described above. 2
is a case, and on the top surface 2a of this case, a display 3,
A power switch 4, a calibration switch 5, and a measurement switch 6 are arranged.

On the other hand, an insertion portion 7 is provided on the side surface 2b of the case (see FIGS. 1(a), (b), and (C)). Inside the insertion section 7,
A second connector 8 is provided, and this second connector 8 connects a lead wire 9 to a circuit board (not shown) inside the case 2.
connected by.

A first connector case 10 is inserted into the insertion portion 7 . This first connector case 10 is provided with a sensor insertion port 10a, a front chamber portion 10b, and a rear chamber portion IOC, and the sensor insertion port 10a communicates with the front chamber tob.
The front chamber part 10b and the rear chamber part 10c are also in communication.

The inside of the front chamber part 10b is filled with an insulating gel 11 for waterproofing. Inside the rear chamber part 10c, a pair of contact terminals 12
．． 12 is supported in a see-saw shape, and its tip protrudes into the front chamber portion 10b. The rear end of the contact terminal 12 can be pushed from the outside by a button 13.

Reference numeral 14 denotes a return coil spring, which functions to connect the contact terminal 12 and the pin 15 to each other. This pin 15
protrudes rearward from the first connector case IO. Furthermore, a groove 10 is provided on the outer peripheral surface of the first connector case lO.
d is formed, and the O-ring 16 is attached.

When the first connector case 10 is inserted into the insertion portion 7, the pin 15 is inserted into the pin insertion portion 8a of the second connector 8, the spring contact 8b is pressed against the pin 15, and the first connector case 10 and The second connector 8 is electrically coupled. Further, the button 13 has a hole 2c in the upper surface 2a of the wreath.
It protrudes toward the upper surface 2a of the case. The O-ring 16 is in close contact with the inner surface of the insertion section 7 and connects the first connector case 10 and the second
The joint portion with the connector 8 is made waterproof.

To attach the sensor 60, press the button 13 and lift the tip of the contact terminal 12. In this state, sensor insertion port 1
Insert the sensor 60 into 0a until it hits the button 13
Let go. The contact terminals 12 are returned to their original states by the coil springs 14, and the tips of the contact terminals 12 are connected to the sensors 60, respectively.
The contact portions 62b and 63b are pressed against each other and conductive. At this time, the sensor 60 is positioned by the inner surface of the sensor insertion port 10a, and the contact terminal 12 is surely pressed into contact with the contact portions 62b and 63b. In addition, the contact terminal 12 is made of insulating gel 11.
．． 12 and contact portions 62b and 63b are enclosed and waterproof insulated.

FIG. 3 is a block diagram illustrating the circuit configuration of this biochemical measurement bag ffl. 18 is a sensor drive circuit that applies a predetermined voltage to the sensor 60. The output current of the sensor 60 is converted into a voltage by a current/voltage (1/V) converter 19, then converted into a digital signal by an analog/digital (A/D) converter 20, and then taken into the CPU 21. C
The PU 21 determines the substance concentration according to the calibration curve stored in the memory 22 and displays this on the display 3.

Next, the operation of this embodiment biochemical measuring device 1 will be explained. First, if the sensor 60 is not attached to the biochemical measuring device 1, the sensor 60 is inserted through the sensor insertion port 10a while pressing the button 13. Next, press the power switch 4 to turn on the power, and then press the calibration switch 5.
Press. At this time, a standard solution of a predetermined concentration is applied to the tips of the sensor 60, that is, the working electrode 62a and the reference electrode 63.
Drop onto a. The CPU 21 performs calibration based on the output of the sensor 60 at this time. When the calibration is completed, a message to that effect is displayed on the display 3. After confirming this display,
Rinse or wipe off the standard solution at the tip of the sensor 60.

Next, the measurement switch 6 is pressed, a sample is dropped onto the tip of the sensor 60, and the concentration of the sample is read from the display 3. After confirming the end of the measurement, if you wish to continue measuring another sample, wash or wipe off the sample that has already been measured at the tip of the sensor 60, then press the measurement switch 6 again and perform the same operation. If calibration is required during the process, press the calibration switch 5 and drop a standard solution onto the tip of the sensor 60.

To end the measurement, press the power switch 4 again to turn off the power. When replacing the sensor 60,
All you have to do is turn off the power and then pull out the sensor 60.

If the first connector case 10 is damaged,
Push the button 13 to remove the damaged first connector case 10 from the insertion section 7, and insert a new first connector case 10 into the insertion section 7.

<Example 2> A second example of the present invention will be described with reference to FIGS. 4 and 5.

FIG. 5 is an external plan view of the biochemical measuring device 31 according to this embodiment. This biochemical measuring device 31 is composed of a main body case 32 and a probe case 38, both of which are connected by a lead wire 37.

The main body case 32 includes a display 33 as in the first embodiment.
, a power switch 34, a calibration switch 35, and a measurement switch 36 are provided.

An insertion section 39 is provided at the tip of the probe case, and a second connector 40 is provided within this insertion section 39 (see FIG. 4(a)). The lead wire 37 is connected to this connector 40, and the connector 40 is electrically connected to the circuit board inside the main body case 32. In addition,
The circuit configuration of the biochemical measuring device 31 is the same as that of the first embodiment.

A first connector case 41 is inserted into the insertion portion 39 . The first connector case 41 has a sensor insertion opening 4.
1a, and a terminal chamber 41 communicating with this sensor insertion port 41a.
b is provided. Spring-shaped contact terminals 42, 42 protrude into the terminal chamber 41b and are filled with an insulating gel 43.

The base end portions of the contact terminals 42 and 42 are each supported by the first connector case 41 and electrically connected to the pin 44. These pins 44 protrude rearward from the connector case 41,
They are each inserted into the pin insertion portions 40a of the connector 40, and the spring contacts 40b come into contact with each other. A groove 41c is formed in the outer peripheral surface of the first connector case 41, and an O-ring 45 is attached thereto.

This O-ring 45 is in close contact with the inner surface of the insertion portion 39 and makes the second connector 40 waterproof.

The enzyme electrode 70 (or amperometric sensor 70') is inserted into the first connector case 41 through the sensor insertion port 41a. The contact points between the sensor contact portions 72b and 73b and the connection terminals 42 and 42 are waterproof and insulated by the insulating gel 43. At this time, if the sensor 70 is inserted into the sensor insertion opening 41a until it reaches the end, the sensor 70 will be guided to the inner surface of the sensor insertion opening 41a and will be positioned correctly, and the contact terminals 42, 42 will surely come into contact with the electrode contact parts 72b, 73b. do.

Next, the operation of this biochemical measuring device 31 will be explained. First, the enzyme electrode 70 is attached to the probe case on the third day. Then, press the power switch 34 to turn on the power. Furthermore, the calibration switch 35 is pressed, the tip of the enzyme electrode 70 is placed in the standard solution, and the CPU (not shown) is caused to perform calibration processing.

After confirming that the calibration is complete, wash or wipe off the standard solution adhering to the tip of the enzyme electrode 70, and then turn the measurement switch 35
Press to insert the tip of the enzyme electrode 10 into the sample. The measurement results are displayed on the display 33.

To continue measuring another sample, wash or wipe off the sample attached to the tip of the enzyme electrode 70, press the measurement switch 36 again, and attach the enzyme electrode 7 to the sample to be measured.
Insert the 0 tip. Thereafter, this operation can be repeated to sequentially measure a large number of samples. If calibration is required during the process, press the calibration switch 35 and place the tip of the enzyme electrode 70 into the standard solution. Note that if the amount of sample is sufficient and the same type of sample is to be measured, the enzyme electrode 7
The tips of the enzyme electrodes 70 can be successively inserted into the sample without washing or wiping off the liquid adhering to the tips of the enzyme electrodes 70.

When the measurement is completed, the power button 34 is pressed to turn off the power, and the enzyme electrode 70 is wiped off from the probe case 38. Note that the enzyme electrode 70 can also be left attached to the probe case 38 after the power is turned off.

This embodiment biochemical measuring device 31 can be operated easily and
For example, a sample inside a tank can be analyzed, and there is no need to sample the sample into a container such as a beaker. Furthermore, even if the sample is dangerous, measurements can be made while maintaining a distance.

<Embodiment 3> A third embodiment of the present invention will be described below based on FIG. 6.

The biochemical measurement device 51 of this embodiment has a case 52 shaped like a pencil, making it convenient to carry.
See figure (a)]. The distal end 52a of the case 52 has a second
As in the embodiment, an insertion section 55 is provided, into which the first connector case 41 is inserted. Of course, this part is the first
The configuration may be similar to that of the embodiment.

A display section 53 made of liquid crystal or the like is provided in the center of the case 52. Further, a rotary switch 54 is provided at the rear end portion 52b of the case (see also FIG. 6(b)).
. The circuit configuration of this biochemical measuring device 51 is the same as that of the first embodiment.

To operate this biochemical measurement device 51, first, the enzyme electrode 10 is attached to the case tip 52a. Next, turn the switch 54 one step to the right to set the calibration state (CAL), and the enzyme electrode 70
into the standard solution and perform calibration. After confirming that the calibration has been completed, the standard solution adhering to the tip of the enzyme electrode 70 is washed away or wiped off.

After confirming that the calibration is complete, turn the switch 54 one step further to the right (MEA) to insert the tip of the enzyme electrode 70 into the sample. If you want to continue measuring after confirming that the measurement has finished,
The sample adhering to the tip of the enzyme electrode 70 is washed away or wiped off, and the enzyme electrode 70 is placed in the next sample solution. If calibration is required during the process, the switch 54 may be turned one step to the left to enter the calibration state, and the tip of the enzyme electrode 70 may be placed in the standard solution.

(v) As described in detail, the biochemical measurement device of the present invention includes an insertion portion into which the first connector is inserted into the case, and a second connector coupled to the first connector in the insertion portion. connector·
The first connector has a sensor insertion part into which a sensor is inserted, the sensor insertion part is provided with a contact terminal that contacts a contact part of the sensor, and the first connector and the second connector are connected to each other. and waterproof insulating means for waterproofly insulating at least one of the connecting portion with the sensor contact portion and the contact portion with the contact terminal. Therefore, miniaturization of the sensor,
In addition to making it possible to reduce costs and make biochemical measuring devices more compact, running costs are reduced and sensors can be made disposable.In the field of clinical analysis, for example, rapid blood glucose level measurement at the bedside, In the field of food analysis, its applications are expanding significantly, such as measuring sugar and amino acids in foods, and in the environmental field, on-site water quality testing. In addition, since it has a two-stage configuration of the first connector and the second connector, the life of the connector section of the biochemical measuring device can be extended.

[Brief explanation of the drawing]

FIG. 1(a) is a vertical cross-sectional view of main parts for explaining the connector structure of the biochemical measuring device according to the first embodiment of the present invention, and FIG.
Figure 1 (C
) is a side view for explaining the connector structure, FIG. 2 is an external plan view of the biochemical measuring device, FIG. 3 is a block diagram explaining the circuit configuration of the biochemical measuring device, and FIG. 4 is a side view for explaining the connector structure. FIG. 4(a) is a vertical cross-sectional view of a main part explaining the connector structure of a biochemical measurement device according to a second embodiment of the present invention, and FIG.
) is a vertical cross-sectional view of the main part illustrating the state in which the first connector case of the same connector structure is pulled out, FIG. 5 is an external plan view of the biochemical measurement device, and FIG. FIG. 6 is a side view of the biochemical measuring device according to the third embodiment of
b) is a diagram explaining the rotary switch of the biochemistry measuring device, FIG. 7(a) is an external plan view of the amperometric sensor, and FIGS. 7(b) and 7(C) are Figure 7 (a) middle ■b-■b of the same amperometric sensor, respectively.
8(a) is an external plan view of the enzyme electrode, and FIG. 8(b) and 8(C) are respectively sectional views taken along the line ■C-■C. (a) Middle ■b-■b line,
9(a) and 9(b), which are cross-sectional views taken along the line ①C-②C, are diagrams for explaining the connection between the main body of the conventional biochemical measuring device and the sensor, respectively. 2.52: Case, 7.39.55: Insertion part, 8.40
: Second connector, 10.41: First connector case, 11.43: Insulating gel, 12.42; Contact terminal, 38 nib lobe case, 60: Amperometric sensor, 70; Enzyme electrode, 62b. 63b, 72b, 73b: Contact portion. 72b

Claims (1)

[Claims] (1) The case is provided with an insertion part into which the first connector is inserted, and the second connector is connected to the first connector.
the first connector has a sensor insertion part into which the sensor is inserted, the sensor insertion part is provided with a contact terminal that contacts the contact part of the sensor, and the first connector and the second A biochemical measuring device comprising waterproof insulating means for waterproof insulating at least one of a connecting portion with a connector and a contact portion between a sensor contact portion and a contact terminal.