JP5918554B2 - Biostimulation electrode - Google Patents

Description

  The present invention relates to a biostimulation electrode, for example, an electrode that is attached to the epidermis to stimulate pain sensory nerves.

For clinical trials of diabetes and electroencephalograms, a method has been proposed in which an electrode pair consisting of a cathode and an anode is attached to a subject's fingertip, etc., and an electric current is passed through this to stimulate the subject's pain sensation.
For example, in the case of diabetes, the nerve tissue is degenerated as the disease progresses, so that it can be used as a clue to determine the disease state of the subject by applying electrical stimulation to the pain sensory nerve of the subject and observing the reaction.

As an electrode for stimulating such pain sensation, there is a “pain sensory nerve stimulation electrode” of Patent Document 1.
In this technique, injection needles having different diameters are cut and arranged concentrically. The outer injection needle has a flat end and functions as an anode. The inner injection needle has a sharp tip, and the tip protrudes by about 0.01 to 0.3 mm from the outer injection needle. Functions as a cathode.
When the terminal of the electrode configured as described above is arranged so as to be in contact with the skin of the living body, the anode contacts the skin surface, the cathode pierces the skin, and does not reach the dermis and stays in the epidermis. When an electric current is passed through this, pain sensation can be selectively stimulated.

  However, in the technique described in Patent Document 1, since the electrodes are formed by processing the injection needle, there is a problem that accuracy is likely to vary and the manufacturing cost is high. Therefore, it has been required to provide a large amount of highly accurate electrodes at a low cost.

International Publication No. 2006/059430

  An object of this invention is to provide a cheap biostimulation electrode.

(1) In the first aspect of the present invention, a flat plate shape with a foot portion extending on the opposite side of the cusp and the cusp tip to stimulate the skin is formed at an acute angle of BIOLOGICAL a first electrode, a second electrode having a said contact portion and the foot portion extending on the opposite side of the contact portion from the cylindrical portion and the cylindrical portion having a distal end in contact with a line or surface in the epidermis of the raw body An insulating member that fixes the first electrode and the second electrode such that the pointed head and the contact portion with respect to the epidermis of the living body are in a predetermined positional relationship, and the first electrode is , the plane of the previous sharp shape due to the flat shape, by a one or more flat or curved surfaces formed toward the tip of the pointed shape, and the peak portion is formed, together with the insulating member, A first through hole in which a conductor is disposed on an inner peripheral surface and a foot portion of the first electrode is press-fitted; and an inner peripheral surface Conductor is disposed, the foot portion of the second electrode is provided with a second through hole to be press-fitted, to provide a biological stimulation electrode, characterized in that.
(2) In the invention according to claim 2, the pointed head has a blunt portion having a width of 50 μm or less, and provides the biostimulation electrode according to claim 1.
(3) In the invention according to claim 3, the biostimulation electrode according to claim 1 or 2, wherein the surface roughness of the pointed head is Ra 10 μm or less.
(4) In the invention described in claim 4 , the first electrode is formed with a protruding portion that defines a press-fitting amount when the foot is press-fitted. The biostimulation electrode according to claim 1, claim 2, or claim 3 is provided.
(5) In the invention described in claim 5, wherein the first electrode, and the second electrode is gold Shokumata among the preceding claims, characterized according to claim 4 that is electrically conductive resins A biostimulation electrode according to any one of the claims is provided.
(6) In the invention described in claim 6, any one of claims 1 to 5, characterized in that it comprises a plurality of electrode pairs set consisting of the first electrode and the second electrode 1 The biostimulation electrode according to the claim is provided.
( 7 ) In the invention according to claim 7 , at least one of the plurality of first electrodes or second electrodes of the electrode pairs is insulated from each other. A biostimulation electrode according to 6 , is provided.
( 8 ) In the invention according to claim 8 , the insulating portion is a storage portion that stores the first electrode and the second electrode so that the pointed portion and the contact portion are in a predetermined positional relationship. is composed of resin having, either before Symbol the first electrode and the second electrode is fixed by being caulked by the resin, the preceding claims, characterized in that one of claims 7 1 The biostimulation electrode according to the claim is provided.

  According to the present invention, since the first and second electrodes are formed from one flat plate, an inexpensive biostimulation electrode can be provided.

It is a figure for demonstrating the electrode which concerns on 1st Embodiment. It is a figure for demonstrating the biostimulation electrode part which concerns on 1st Embodiment. It is a figure for demonstrating the further modification of 1st Embodiment. It is a figure for demonstrating the shape of a stimulation electrode part. It is a figure for demonstrating 2nd Embodiment. It is a figure for demonstrating 3rd Embodiment. It is the figure which showed the biostimulation electrode part which concerns on 3rd Embodiment. It is the figure which showed the modification of the electrode which concerns on 3rd Embodiment. It is a figure for demonstrating the biostimulation electrode part which concerns on 4th Embodiment. It is a figure showing the state which press-fitted a pair of stimulation electrode and the contact electrode to the through-hole of the resin part which concerns on 4th Embodiment. It is a figure showing the manufacturing method of the stimulation electrode and contact electrode which concern on 4th Embodiment. It is a figure showing the shape of the stimulation electrode used in 4th Embodiment and a modification. It is a figure showing the modification regarding the shape of the stimulation electrode which concerns on 4th Embodiment. It is a figure showing the modification of the arrangement | positioning direction of the stimulation electrode which concerns on 4th Embodiment. It is explanatory drawing about the attachment member and protective cover of a biostimulation electrode part.

(1) Outline of Embodiment The stimulation electrode 10 for stimulating the pain sensory nerve and the contact electrode 20 (FIG. 1) paired with the stimulation electrode 10 are integrally formed from the skin contact site to the lead wire connector site, Fix to the resin body by heat caulking.
The stimulation electrode 10 and the contact electrode 20 can be mass-produced at low cost by being integrally processed from a metal plate by sheet metal processing (such as punching, bending, drawing).
In addition, by fixing the stimulation electrode 10 and the contact electrode 20 with a resin so as to have a predetermined positional relationship, high dimensional accuracy can be realized by the electrode pair 30 including the stimulation electrode unit 12 and the contact electrode unit 22. it can.
Further, since the stimulation electrode 10 is made of a metal plate, the stimulation electrode portion 12 has a ridgeline, which increases the contact area in contact with the epidermis compared to the case where the tip is a point, and the certainty when stimulating the pain sensory nerve. Will increase.
In addition, since the stimulation electrode 10 and the contact electrode 20 are formed as an integral structure, the number of joined parts of the conductive parts is reduced and the reliability is improved.

(2) Details of the embodiment (first embodiment)
First, the electrode according to the first embodiment will be described with reference to FIGS.
FIG. 1A is a diagram showing the outer shape of the electrode.
The stimulation electrode 10 is an electrode for pain sensory nerve stimulation, and is formed, for example, by extracting the electrode member 11 from a metal plate and bending it. Thus, the stimulation electrode 10 is formed by integrally processing the electrode member 11 extracted from the metal plate.
The electrode member 11 has a thickness of about 0.1 to 0.2 mm, and SUS304, SUS316, or the like that is harmless to the human body is used.
Further, another metal that is harmless to the human body may be used, or the surface may be plated with a metal that is harmless to the human body such as gold.

The stimulation electrode 10 has a substantially rectangular shape having a total length of about 10 mm and a width of about 1 mm. The distal end region is bent in an L shape in the width direction of the electrode member 11 at the bent portion 14, and the distal end thereof is the bent portion 13. The electrode member 11 is bent in the thickness direction.
A stimulation electrode portion 12 configured to have an acute angle so as to be pressed and stabbed into a living body's epidermis (skin) is formed at the bent tip of the electrode member 11. The shape of the stimulation electrode portion 12 is formed by a mold during punching.
The length from the bent portion 13 to the stimulation electrode portion 12 is about 3 mm, and the angle of the stimulation electrode portion 12 is about 50 °. This angle is an example and may be an acute angle or an obtuse angle.

The contact electrode 20 is formed by punching an electrode member 21 from the same metal plate as the stimulation electrode 10 and bending it. Thus, the contact electrode 20 is formed by integrally processing the electrode member 21 extracted from the metal plate.
The contact electrode 20 has a substantially rectangular shape with a total length of about 10 mm and a width of about 1 mm. The tip region is bent in the thickness direction of the electrode member 21 at the bent portion 25, and the tip is bent at the bent portion 24. Bent in the opposite direction to 25. Therefore, the annular portion 26 (flange) formed at the tip is parallel to the plate surface on the other end side of the electrode member 21.

The annular portion 26 has an outer diameter of about 3 mm and an inner diameter of about 1.5 to 2 mm. On the inner diameter side, a cylindrical portion 23 (cylinder) having a height of about 5 mm is formed in the bending direction of the bent portion 25. Yes. The cylindrical portion 23 is formed by drawing or the like.
The end portion of the cylindrical portion 23 is formed with a contact electrode portion 22 configured to be flat so as to be pressed and come into contact with the skin of the living body. The contact electrode portion 22 only needs to be configured by a line or a surface in order to have a function of regulating the insertion amount of the stimulation electrode portion 12.

The bent portion 25 is formed at a predetermined angle so that the center line on the other end side of the electrode member 21 and the center line of the cylindrical portion 23 are separated by a predetermined distance or more.
This is to prevent the electrode member 11 and the electrode member 21 from interfering with each other when the stimulation electrode 10 is combined with the contact electrode 20 in the direction of the arrow.
As described above, the stimulating electrode 10 and the contact electrode 20 can be formed from a metal plate by sheet metal processing (press processing such as punching, bending, drawing), so that they can be easily mass-produced with high dimensional accuracy. Can do.

FIG. 1B is a diagram showing a combination of the stimulation electrode 10 and the contact electrode 20.
Although not shown, the stimulation electrode 10 and the contact electrode 20 are placed and positioned in a mold for insert molding.
Further, the stimulation electrode 10 and the contact electrode 20 may be positioned using a jig and installed in a mold for insert molding.
In this way, when the stimulation electrode 10 and the contact electrode 20 are positioned, insert molding, that is, when the resin is injected into the mold and solidified, the stimulation electrode 10 and the contact electrode 20 are fixed in a predetermined positional relationship. An electrode pair 30 in contact with the epidermis is formed by the portion 12 and the contact electrode portion 22.

The other end side of electrode member 11 and electrode member 21 (side facing stimulation electrode portion 12 and contact electrode portion 22) functions as a lead portion connected to the power cord.
Since the center line of the electrode member 21 and the center line of the cylindrical portion 23 are separated by a predetermined distance, the electrode member 11 and the other end side of the electrode member 21 do not interfere with each other and can be formed on the same plane. .
When the other end sides of the electrode member 11 and the electrode member 21 are formed on the same plane, the electrode member 11 and the electrode member 21 can be easily connected to a connector, or a terminal can be crimped.

FIG. 1C is a diagram for explaining the positional relationship between the stimulation electrode unit 12 and the contact electrode unit 22.
The center line of the stimulation electrode portion 12 coincides with the center line of the cylindrical portion 23, and the stimulation electrode portion 12 protrudes from the contact electrode portion 22 by about 0 to 0.5 mm.
When the electrode pair 30 is formed by the stimulation electrode unit 12 and the contact electrode unit 22 arranged as described above and the electrode pair 30 is pressed against the epidermis, the stimulation electrode unit 12 is stuck in the epidermis and the contact electrode unit 22 is applied to the epidermis. It contacts to make electrical contact with the epidermis and regulates the insertion amount of the stimulation electrode portion 12 into the epidermis.

In this embodiment, as an example, a pulse voltage is applied using the stimulation electrode unit 12 as a cathode and the contact electrode unit 22 as an anode. However, the stimulation electrode unit 12 may be used as an anode and the contact electrode unit 22 may be used as a cathode. You may comprise so that the alternating voltage may be applied to the part 12 and the contact electrode part 22, or a direct current voltage may be applied.
In the present embodiment, the stimulation electrode unit 12 is pierced into the epidermis. However, depending on the purpose of use of the electrode pair 30, it may be merely sunk into the epidermis, and is not necessarily pierced.

Next, the biostimulation electrode unit 1 will be described with reference to FIGS.
FIG. 2A is a plan view of the biostimulation electrode unit 1 viewed from the back side.
When the stimulation electrode 10 and the contact electrode 20 are insert-molded in the predetermined positional relationship shown in FIG. 1C, the biological stimulation electrode portion 1 in which the stimulation electrode 10 and the contact electrode 20 are fixed by the resin portion 35 is obtained.
Hereinafter, the surface on which the electrode pair 30 is formed is referred to as a front surface, and the surface facing the surface is referred to as a back surface.

The resin part 35 is made of a resin having a cylindrical shape, and has a diameter of about 10 mm and a thickness of about 4 mm, for example. In addition, resin should just be harmless to a biological body, and should just have insulation, for example, a polycarbonate is used.
The biostimulation electrode unit 1 is formed by insert molding by injecting resin while the stimulation electrode 10 and the contact electrode 20 are fixed to a mold, so that the stimulation electrode 10 and the contact electrode 20 are embedded in the resin unit 35. It has become a shape.
The resin part 35 in this embodiment functions as an insulating member (fixed part). However, a ceramic substrate or the like may be used instead of the resin portion 35. In this case, a through-hole is provided in the ceramic substrate in the same manner as in the fourth embodiment described later, and the feet provided in the stimulation electrode 10 and the contact electrode 20 are press-fitted into the through-hole.

FIG. 2B is a perspective view of the biostimulation electrode unit 1 viewed from the surface direction.
The surface of the resin part 35 is formed flat, and the electrode pair 30 protrudes at the center. The protruding amount of the cylindrical portion 23 is, for example, about 1 mm.
Although resin is not injected into the cylindrical portion 23, the cylindrical portion 23 may be filled with resin.

Although not shown, a connector is connected to the electrode members 11 and 21, whereby the biostimulation electrode unit 1 is connected to the power cord.
A second connector is formed at the other end of the power cord. By attaching / detaching the second connector, the biostimulation electrode unit 1 is attached / detached from the power supply device.
Thus, since the biostimulation electrode part 1 can be attached or detached, it can be made disposable every use, and an infectious disease can be prevented.

When the surface of the biostimulation electrode unit 1 configured as described above is pressed against the epidermis of the human body, the contact electrode unit 22 contacts the epidermis, and the stimulation electrode unit 12 is inserted inside the epidermis to reach the pain sensory nerve.
When a voltage is applied to the electrode member 11 and the stimulation electrode unit 12, the stimulation electrode unit 12 can stimulate the pain sensation satisfactorily.
Further, the stimulation electrode 10 and the contact electrode 20 are plate-like members and are bent, and the bent portion is molded in the resin portion 35, so that the rigidity of the electrode pair 30 is high, and the electrode pair 30 The arrangement of the electrode pair 30 can be maintained even when stress is applied.

FIG. 2C is a diagram for explaining a modification of the present embodiment.
In this example, the electrode member 11 and the electrode member 21 are formed shorter than the previous embodiment, and the lead terminals 41 and 43 are connected by the connection portions 42 and 44 in the end region, respectively.
The connection parts 42 and 44 electrically and physically connect the electrode member 11 and the electrode member 21 and the lead terminals 41 and 43 by, for example, crimping, soldering, or a conductive adhesive.
When the stimulation electrode 10 and the contact electrode 20 are set in a mold with the lead terminals 41 and 43 connected, and the resin is injected and solidified, the biological stimulation electrode portion 1 is formed.

FIG.2 (d) is the figure which showed the biostimulation electrode part 1 after the insert molding which concerns on this modification.
A notch portion is formed at the end of the resin portion 35, and lead terminals 41 and 43 project outside from the resin portion 35. This notch is formed by the shape of a mold.
A connector 49 can be connected to the lead terminals 41 and 43.

Next, a further modification of the first embodiment will be described with reference to FIG.
In the previous embodiment, a single electrode pair 30 was formed on the biostimulation electrode unit 1, but in this modification, three electrode pairs 30 are formed.

FIG. 3A shows the arrangement of the electrodes.
The stimulation electrode 10 is configured in a substantially T shape, and stimulation electrode portions (not shown because it is located on the back of the paper) for forming electrode pairs 30a and 30c are formed at both ends of the T shape. A stimulating electrode portion for forming the electrode pair 30b is also formed in the middle of the process. The stimulation electrode 10 is integrally processed from a single metal plate.
In addition, individual contact electrodes 20a, 20b, and 20c are arranged corresponding to the respective stimulation electrode portions to form electrode pairs 30a, 30b, and 30c.

FIG.3 (b) is the top view which looked at the biostimulation electrode part 1 which concerns on this modification from the back surface.
The biostimulation electrode unit 1 is formed by placing the stimulation electrode 10 and the contact electrodes 20a to 20c in a mold and performing insert molding.
The electrode pairs 30a, 30b, and 30c are formed on a circumference that is concentric with the bottom surface of the resin portion 35 as indicated by a broken line 36.
For this reason, when the biostimulation electrode unit 1 is pressed against the epidermis, the force is distributed in a balanced manner to the electrode pairs 30a, 30b, 30c.

FIG.3 (c) is the perspective view which looked at the biostimulation electrode part 1 which concerns on this modification from the surface direction.
Electrode pairs 30a, 30b, and 30c protrude from the surface of the biostimulation electrode unit 1. The configuration of the electrode pairs 30a to 30c is the same as that of the electrode pair 30 of the first embodiment.
In this way, since there are a plurality of electrode pairs 30, even if one of the stimulation electrode portions 12 is stuck in a place where the density of nerve fibers is low, the other electrode pairs 30 are located where the density of nerve fibers is high. You can expect to be stabbed. Therefore, pain sensation can be stimulated more reliably and reliability can be improved.

Further, since the contact electrodes 20a, 20b, and 20c are insulated from each other independently, it is possible to individually apply voltages having different waveforms to the electrode pairs 30a, 30b, and 30c.
Alternatively, as a further modification, when the contact electrodes 20a, 20b, and 20c are three-dimensionally crossed inside the resin portion 35 so as not to interfere with the stimulation electrode 10a, the contact electrodes 20a, 20b, and 20c are formed from a single metal plate. In addition, the number of terminals connected by the connector can be two.
In the present modification, the number of electrode pairs 30 is three, but other numbers such as two or four may be used.

  FIG. 3D shows a further modification in which a lead terminal 43a is connected to the contact electrode 20a through a connecting portion 44a. Similarly, the lead terminals are attached to the other electrodes, and the connector 49 is attached.

Each drawing in FIG. 4 is a diagram for explaining the shape of the stimulation electrode unit 12.
FIG. 4A shows an example in which the inclined surface portions 15 are formed symmetrically from both end surfaces at the end portions in the width direction of the electrode member 11 toward the center line of the electrode member 11. This shape can be formed by punching. The stimulation electrode portion 12 is configured by a ridge line formed at the apex of the slope portion 15.

Thus, since the stimulation electrode part 12 is comprised by a ridgeline, when the stimulation electrode part 12 penetrate | invades into the epidermis, the contact area of the stimulation electrode part 12 is larger than the case where the stimulation electrode part 12 is comprised with a point. This increases the possibility that the nerve fiber will be pierced at a high density.
In addition, since the slope portion 15 and the stimulation electrode portion 12 constitute an equipotential surface, the distribution of the electric field in the epidermis is different from the case where the stimulation electrode portion 12 is constituted by points, and the density of nerve fibers is high. The possibility of overlapping places with strong electric fields also increases.

FIG. 4B shows an example in which two stimulation electrode portions 12 similar to those in FIG. 4A are formed in the biological stimulation electrode portion 1 in the width direction of the electrode member 11. This shape can be formed by punching.
Thus, by forming the plurality of stimulation electrode portions 12, it is possible to increase the possibility that the stimulation electrode portion 12 is stuck in a place where the nerve density is high.

FIG. 4C shows an example in which the slope 15 is formed from the center of the electrode member 11 toward the corner of the end face in the width direction of the electrode member 11. This shape can also be formed by punching.
In this case, two more acute electrode (sharp) stimulation electrode portions 12 can be obtained.
When the stimulation electrode portion 12 has a more acute angle, it becomes easier to pierce the epidermis, and the presence of the two stimulation electrode portions 12 increases the possibility that the stimulation electrode portion 12 pierces a portion having a high nerve density.

FIG. 4D shows an example in which three stimulation electrode portions 12 are formed at the tip of the electrode member 11. This shape can also be formed by punching.
Since there are three stimulation electrode portions 12, it is possible to further increase the possibility that the stimulation electrode portion 12 is stuck in a place where the nerve density is high.

FIG. 4E shows an example in which the electrode member 11 is widened, and stimulation electrode portions 12 similar to those in FIG. 4C are provided at both ends in the width direction.
In this case, since the space | interval of the stimulation electrode part 12 becomes wide and the stimulation electrode part 12 becomes sharper, it is easy to stab the stimulation electrode part 12 in the epidermis, and the possibility of being pierced in a place with high nerve density is increased. it can.

FIG. 4F shows an example in which a slope 16 in the thickness direction (surface viewed from the thickness direction) is formed in addition to the slope 15 in the width direction of the electrode member 11 (surface viewed from the width direction). .
The slope portion 15 is formed by punching, and then the slope portion 16 is formed by grinding or hitting the tip.
In this case, since the stimulating electrode part 12 becomes a point, the stimulating electrode part 12 becomes sharper and is easily pierced into the epidermis.

FIG. 4G shows an example in which the slope portion 16 is not provided in the width direction of the electrode member 11 but the slope portion 16 in the thickness direction is provided on one surface. This shape is formed by grinding or hitting the tip.
In this case, the length of the ridge line of the stimulation electrode part 12 can be made longer than the case where the slope in the width direction of the electrode member 11 is provided. However, the width of the electrode member 11 is assumed to be larger than the thickness. The slope 16 is formed by, for example, grinding or hitting.

FIG. 4H is an example in which slopes 16 are provided in the thickness direction from both surfaces of the electrode member 11.
In this case, the inclined surface portion 16 is formed symmetrically on both end faces of the electrode member 11, and when the stimulation electrode portion 12 is stabbed into the epidermis, a force acts on the electrode member 11 with a good balance.

FIG. 4I shows an example in which the slope portion 15 of the electrode member 11 is formed by a curved surface. This shape can be formed by punching.
The slope portion 15 is formed in a concave shape so as to go around the side surface of the electrode member 11, and the stimulation electrode portion 12 has a sharper ridgeline than in the case of FIG. For this reason, it becomes easier to pierce the epidermis.

While various forms of the stimulation electrode unit 12 have been described above, various forms are possible.
In the present embodiment, since the shape of the stimulation electrode portion 12 is formed from a metal plate by punching or the like, various shapes can be easily formed by a mold, and the shape can be set according to the purpose and application. it can.

In the first embodiment described above, the following effects can be obtained.
(1) Since the stimulation electrode 10 and the contact electrode 20 are integrally formed from a metal plate, they can be mass-produced at low cost.
(2) Since the stimulation electrode 10 and the contact electrode 20 have an integral structure, there is no joining of the conductive portions, and reliability is improved.
(3) Since the stimulation electrode 10 and the contact electrode 20 are positioned and insert-molded, the dimensional accuracy of the electrode pair 30 can be easily ensured.
(4) When the stimulating electrode 10 and the contact electrode 20 are insert-molded and fixed, the electrode is riveted, the lead wire is soldered, and the components are stacked by various bonds to the electrical circuit of the board. The manufacturing cost can be reduced with fewer steps.
(5) Since the stimulation electrode 10 and the contact electrode 20 are bent and fixed to the resin portion 35, the rigidity when an external force is applied to the electrode pair 30 can be increased.
(6) Since the electrode member 11 is plate-shaped and the stimulation electrode portion 12 is a ridgeline, the portion that contacts the epidermis is formed at the tip of the cone, so that the contact can be made more reliably than in the case of point contact with the epidermis. it can. However, it is preferable to increase the current density by shortening the length of the ridge line and making it close to point contact. Thereby, it becomes possible to maintain a high current density while reliably contacting the skin, and reliability is improved.
(7) Since the biostimulation electrode unit 1 can be mass-produced at a low cost, it can be disposable and prevent infection due to reuse.
(8) When reusing the biostimulation electrode unit 1, steam sterilization is possible because there is no space between parts. In the case of gas sterilization, the time required for gas replacement is shortened and the replacement efficiency is improved. , Drying time can be shortened.
(9) Since the structure is simple, quality control is easy and productivity is improved.

(Second Embodiment)
Next, a second embodiment will be described with reference to FIG.
In the present embodiment, the other end sides of the stimulation electrode 10 and the contact electrode 20 are exposed on the surface of the resin portion 35, and the substrate 47 is connected thereto.

Fig.5 (a) is the top view which looked at the resin part 35 in which the electrode was installed from the back surface.
On the back surface of the resin portion 35, the electrode member 11a and the electrode member 21a having a rectangular shape, the electrode member 11b and the electrode member 21b, and the circle in which the electrode member 11c and the electrode member 21c are concentric with the resin portion 35 are equally divided into three. Exposed to position.
The back surface and side surfaces of the exposed surfaces of these electrode members are embedded in the resin portion 35.

FIG.5 (b) is sectional drawing which looked at the cross section of the resin part 35 in the arrow AA direction of Fig.5 (a).
The electrode member 11c penetrates the resin portion 35, the stimulation electrode portion 12 protrudes from the surface of the resin portion 35, and the other end portion is bent in a direction away from the electrode member 21c on the surface of the resin portion 35. Are exposed on the back surface of the resin portion 35.
The electrode member 21c also penetrates the resin portion 35, the cylindrical portion 23 protrudes from the surface of the resin portion 35, and the other end portion is bent in the direction away from the electrode member 11c on the surface of the resin portion 35. The side surface is exposed on the back surface of the resin portion 35.

The stimulation electrode part 12 is located on the center line of the cylindrical part 23, and an electrode pair 30 c is formed by the stimulation electrode part 12 and the contact electrode part 22. The configuration of the electrode pair 30c is the same as that of the electrode pair 30 of the first embodiment.
Although not shown, the electrode member 11a and the electrode member 21a, and the electrode member 11b and the electrode member 21b have the same configuration, and an electrode pair 30a and an electrode pair 30b are formed on the surface of the resin portion 35.
The above configuration is obtained by insert molding by fixing the electrode member 11a and the electrode member 21a, the electrode member 11b and the electrode member 21b, and the electrode member 11c and the electrode member 21c to a mold.

FIG.5 (c) is the top view which looked at the biostimulation electrode part 1 from the back surface.
The biostimulation electrode portion 1 is formed by attaching a flexible substrate 47 to the back surface of the resin portion 35 shown in FIG.
The substrate 47 has a connection terminal 45a corresponding to the electrode member 11a, a connection terminal 46a corresponding to the electrode member 21a, a connection terminal 45b corresponding to the electrode member 11b, a connection terminal 46b corresponding to the electrode member 21b, and an electrode member 11c. The connection terminal 45c and the connection terminal 46c corresponding to the electrode member 21c are formed, and these connection terminals are connected to the corresponding electrode member by, for example, a conductive adhesive or solder.
The substrate 47 has wirings 48 that lead from the connection terminals to the connectors, and a voltage is applied to the electrode pairs 30 a to 30 c via the wirings 48.

FIG. 5D is a perspective view showing a place where the substrate 47 is arranged on the resin portion 35.
Electrode pairs 30 a to 30 c are formed concentrically with the resin portion 35 on the surface of the resin portion 35, and the substrate 47 is attached in the direction indicated by the arrow from the back surface of the resin portion 35.
For example, an adhesive surface is formed on the surface of the substrate 47 in contact with the resin portion 35, and the substrate 47 is bonded to the resin portion 35.
FIG. 5E is a perspective view showing a completed product of the biostimulation electrode unit 1.

Thus, in 2nd Embodiment, by arrange | positioning the board | substrate 47 to the electrode member 11a exposed to the surface of the resin part 35, the electrode member 21a, the electrode member 11b, the electrode member 21b, the electrode member 11c, and the electrode member 21c. The biostimulation electrode unit 1 is configured.
Since the size of the electrode member 11a, the electrode member 21a, the electrode member 11b, the electrode member 21b, the electrode member 11c, and the electrode member 21c is smaller than that in the first embodiment, a larger number of electrode members can be formed from one metal plate. Can be formed. Therefore, manufacturing cost can be reduced.
Further, since the metal member of the lead portion does not protrude from the resin portion 35, it is possible to save a supplementary space when the resin portion 35 before the substrate 47 is attached is supplemented as an intermediate product.
In the present embodiment, the electrode pairs 30a to 30c are provided in the resin portion 35, but a single electrode pair 30 or an arbitrary number of electrode pairs 30 may be provided.

(Third embodiment)
Next, a third embodiment will be described with reference to FIG.
FIG. 6A is a diagram showing the appearance of the contact electrode 20.
The electrode member 21 has a distal end portion bent in a U shape at bent portions 58 and 59, and a contact electrode portion 55 parallel to the plate surface is formed at a predetermined distance from the plate surface of the electrode member 21. .
The contact electrode portion 55 has a substantially square shape, and has four rounded corners and an R shape so as not to damage the skin when contacting the skin.
Since the four corners of the contact electrode portion 55 have an R shape, one side of the contact electrode portion 55 is wider than the width of the electrode member 21.

In the center of the contact electrode portion 55, a circular stimulation electrode portion hole 56 in which the stimulation electrode portion 12 of the electrode member 11 is disposed is formed.
Reference holes 51 and 52 for positioning and fixing the electrode member 21 are provided on both sides of the contact electrode portion 55 of the electrode member 21.
Further, an elongated hole 53 for fixing the electrode member 21 is provided at the other end portion of the electrode member 21. The long hole 53 has a long diameter in the length direction of the contact electrode 20.
The electrode member 21 is formed by punching or bending from a metal plate.
The stimulation electrode hole 56, the reference holes 51 and 52, and the elongated hole 53 may be formed by punching, or may be formed by cutting with a drill or the like.

As described above, the contact electrode 20 of this embodiment can be formed by punching and bending, and is easier to process than the case of forming the cylindrical portion 23 of the first embodiment.
Further, since the contact electrode portion 55 has a larger area in contact with the epidermis than the contact electrode portion 22 of the first embodiment, the current density in the epidermis is reduced, and thereby the electrical stimulation that the contact electrode 20 gives to the epidermis. Therefore, electrical stimulation by the stimulation electrode unit 12 can be made more prominent with respect to the subject.

FIG. 6B is a diagram showing the appearance of the stimulation electrode 10.
The electrode member 11 has the same shape as that of the first embodiment, and reference holes 61 and 62 for positioning and fixing the electrode member 11 are provided in the vicinity of the bent portion 13.
Further, an elongated hole 63 for fixing the electrode member 21 is provided at the other end portion of the electrode member 21. The long hole 63 has a long diameter in the length direction of the stimulation electrode 10 in order to have play.
The electrode member 21 is formed by punching or bending from a metal plate.
The reference holes 61 and 62 and the long hole 63 may be formed by punching, or may be formed by cutting with a drill or the like.

FIG. 6C is a diagram showing a state where the stimulation electrode 10 and the contact electrode 20 are arranged on the back surface side resin portion 36.
The back surface side resin portion 36 is made of a resin having a substantially disk shape, and is formed, for example, by injection molding into a mold.
The end surface of the back surface side resin portion 36 is a flat surface, and a stimulation electrode groove portion 71 for storing the stimulation electrode 10 and a contact electrode groove portion 72 for storing the contact electrode 20 are formed on the surface.
The depths of the stimulation electrode groove 71 and the contact electrode groove 72 are set to be larger than the thicknesses of the electrode member 11 and the electrode member 21.

In the stimulation electrode groove 71, cylindrical projections 37a and 37b that fit into the reference holes 61 and 62 and the elongated hole 63 (not shown in the drawing in order to avoid complication of the drawing) of the stimulation electrode 10, 37c is formed.
The contact electrode groove 72 is formed with protrusions 38a, 38b, and 38c that fit into the reference holes 51 and 52 and the elongated hole 53 of the contact electrode 20 (reference numerals are not shown in the figure to avoid complication of the drawing). Has been.
The heights of the projections 37a to 37c and 38a to 38c are set to be larger than the thicknesses of the electrode member 11 and the electrode member 21, and the stimulation electrode 10 and the contact electrode 20 are caulked later by heat. The height necessary for fixing is secured.

A circular recess 73 is formed at a location where the bent portion 13 is located between the protrusions 38a and 38b. The center of the recess 73 coincides with the center of the bent portion 13, and the diameter of the recess 73 is set larger than the width of the bent portion 13.
By forming the concave portion 73 in the back surface side resin portion 36, the bent portion 13 floats from the back surface side resin portion 36 and is cantilevered, and when the stimulation electrode portion 12 is in contact with the epidermis, a portion in the vicinity of the bent portion 13 Can exhibit springiness (elasticity).
Further, since the bent portion 13 is not in contact with the back surface side resin portion 36, no foreign matter is caught between the back surfaces of the bent portion 13, and the accuracy of the protruding amount of the stimulation electrode portion 12 from the contact electrode portion 55 can be maintained. .

FIG. 6D is a view showing a state where the stimulation electrode 10 and the contact electrode 20 are arranged on the back surface side resin portion 36.
As shown in the figure, the stimulation electrode 10 is positioned by the protrusions 37a and 37b with respect to the back surface side resin portion 36, and the contact electrode 20 is positioned by the protrusions 38a and 38b with respect to the back surface side resin portion 36. The

Thereby, the stimulation electrode 10 and the contact electrode 20 are disposed at a position where the stimulation electrode portion 12 protrudes from the center of the contact electrode portion 55 by a predetermined amount, and the electrode pair 30 is formed.
Although not shown, after positioning the stimulation electrode 10 and the contact electrode 20 in this manner, the protrusions 37a to 37c and 38a to 38c are caulked with heat to fix the stimulation electrode 10 and the contact electrode 20 to the back surface side resin portion 36. .

  When the electrode pair 30 is fixed contact, high dimensional accuracy is required. However, since the stimulation electrode portion 12 of this embodiment has a spring property, it is a low pressure contact, and it is not always necessary to perform dimensional control strictly, and thus manufacturing. Cost can be suppressed.

Next, the biostimulation electrode unit 1 of the present embodiment will be described with reference to FIG.
FIG. 7A is a diagram showing a side view of the biostimulation electrode unit 1, and FIG. 7B is a diagram showing a front view of the biostimulation electrode unit 1.
As illustrated in FIG. 6D, after the stimulation electrode 10 and the contact electrode 20 are fixed to the back surface side resin portion 36, when the surface side resin portion 39 is attached to the surface of the back surface side resin portion 36, the biological stimulation electrode portion 1 is Complete.

The front surface side resin portion 39 is made of a resin having a substantially disk shape having the same outer diameter as that of the back surface side resin portion 36, and a hole portion through which the electrode pair 30 is passed to the front surface side is formed at the center.
The front surface side resin portion 39 is fixed to the surface of the back surface side resin portion 36 using, for example, an adhesive, ultrasonic waves, heat, or the like, and the electrode pair 30 protrudes from the central hole by a predetermined amount to the front surface side. .
Further, the front side resin part 39 and the back side resin part 36 are integrally formed with a connector part 86 extending to the other end side of the stimulation electrode 10 and the electrode member 11.

  In the third embodiment, the stimulation electrode 10 and the contact electrode 20 are attached to the biostimulation electrode unit 1 by assembly instead of insert molding. However, these electrodes may be fixed to a mold and formed by insert molding. .

Next, a modification of the contact electrode 20 and the stimulation electrode 10 in the third embodiment will be described with reference to FIG.
FIG. 8A shows a case where convex bent portions 81 facing outward are provided on the electrode members 21 at both ends of the contact electrode portion 55. The bent portion 81 exhibits springiness when the contact electrode portion 55 is pressed against the skin.
FIG. 8B shows a case where a bent portion 82 having a step shape is provided on the electrode member 21 at both ends of the contact electrode portion 55. The bent portion 82 also exhibits springiness when the contact electrode portion 55 is pressed against the skin.

FIG. 8C is a front view and a side view in the case where the bent portion 83 is formed in the vicinity of the stimulation electrode portion 12 of the electrode member 11, and the spring property is obtained when the stimulation electrode portion 12 is pressed against the epidermis. Demonstrate.
FIG. 8D is a front view and a side view when the spring constant is increased by increasing the width of the electrode member 11 at the portion where the bent portion 84 is formed. In this way, the elastic spring constant can be adjusted by changing the width or thickness of the electrode member 11 at the location where the bent portion 84 is formed.

FIG. 8E shows a case where the two rectangular portions 56a and 56b formed on the electrode member 21 are bent in a U-shape toward the stimulation electrode portion 12, and the tip side is used as a contact electrode portion. The contact electrode portion comes into contact with the skin by two lines.
In this case, the back surface side resin portion 36 is three-dimensionally crossed so that the electrode member 11 and the electrode member 21 do not interfere with each other.
FIG. 8F shows a case where one rectangular portion 57 formed on the electrode member 21 is bent toward the stimulation electrode portion 12 and the tip side is used as a contact electrode portion.
Thus, the contact electrode part can be formed on one side of the stimulation electrode part 12.

(Fourth embodiment)
Next, a fourth embodiment will be described with reference to FIGS.
(1) Outline of the fourth embodiment In the first embodiment, the stimulation electrode 10 and the contact electrode 20 are both integrated from the skin contact portion to the connector portion of the lead wire, and the resin body is formed by insert molding or heat caulking. The case of fixing was explained.
In the fourth embodiment, the stimulation electrode 10 and the contact electrode 20 are common to the first embodiment in that they are mass-produced at low cost by integrally processing from a metal plate by sheet metal processing. The contact electrode 20 is formed at the skin contact site alone.
Further, each of the stimulation electrode 10 and the contact electrode 20 is provided with a foot portion, and the foot portion is fixed by being press-fitted into a through hole formed in the resin portion 35, and the inner peripheral surface of the through hole and the resin portion 35 are fixed. It is electrically connected to the wiring formed on the back surface.

  According to the fourth embodiment, since the feet 17 and 28 are provided on the stimulation electrode 10 and the contact electrode 20, and the living body stimulation electrode portion 1 is formed by press-fitting into the through holes 91 and 93 formed in the resin portion 35. Can be assembled with high accuracy and ease.

(2) Details of Fourth Embodiment FIG. 9 is a view showing the resin portion 35 of the stimulation electrode 10 and the contact electrode 20 in the biostimulation electrode portion 1 of the present embodiment. (B) is the figure showing the after arrangement.
In addition, each size, such as thickness in the stimulation electrode 10, the contact electrode 20, and the resin part 35, a diameter, is the same as that of Embodiment 1-3.

As shown in FIG. 9, the contact electrode 20 of this embodiment includes a cylindrical portion 27, a foot portion 28, and a tapered portion 29.
The cylindrical portion 27 of the contact electrode 20 is formed by rounding a rectangular metal plate into a cylindrical shape by bending. Both ends of the rectangle are brought into contact with each other by rounding into a cylindrical shape, and may be connected by welding, but in this embodiment, welding is not performed. Moreover, both ends should just be the state which adjoined and opposes, and do not need to contact.
In the present embodiment and the above-described embodiment, the shape of the portion where the contact electrode 20 is in contact with the skin is a cylinder. However, the shape is not necessarily a cylinder, and may be various shapes such as a square cross section, a triangle shape, and a U shape. There may be.

Two end portions 28 extending from the cylindrical portion 27 are formed at one end of the cylindrical portion 27. The feet 28 and 28 have a function of fixing the cylindrical portion 27 to the resin portion 35 and electrically connecting to the wiring formed on the resin portion 35.
The two feet 28 and 28 in the present embodiment are arranged on an imaginary line passing through the center line of the cylindrical portion 27. Note that the number of legs may be one, or three or more.

  At the tips of both feet 28, tapered portions 29 are formed with the tips tapered by cutting off the corners. The tapered portion 29 has a function of easily inserting the foot portion 28 into two through holes 93 (second through holes) formed in the resin portion 35.

On the other hand, the stimulation electrode 10 includes a stimulation electrode portion 12 formed at one end of a metal plate, a foot portion 17, a tapered portion 18, and a locking portion 19.
The stimulation electrode part 12 is provided with a pointed head having a minimum area, and the width of the blunt part in the pointed head is formed to be 50 μm or less. The pointed head of this embodiment is composed of a combination of two or more ridge lines and surfaces.
And the width | variety of 50 micrometers or less of the said blunt part is implement | achieved by forming the surface roughness of the pointed head in the stimulation electrode part 12 to Ra10 micrometers or less.

The stimulation electrode portion 12 includes two slope portions 15 (surface viewed from the width direction) in the width direction of the electrode member 11, a slope portion 16 (surface viewed from the thickness direction) in the thickness direction, and the slope portion 16. And a flat portion on the opposite side.
In this embodiment, the stimulating electrode portion 12 is formed with an acute angle portion corresponding to the slope portion 15 by punching (punching) a metal plate, and after this punching, the tip portion is forged, polished, etched, cut, or the like. A pointed head is formed by the slope portions 15 and 16. In addition, when the pointed head is formed by forging, forging may be performed simultaneously with the punching process.

A single foot 17 is provided on the opposite side of the stimulation electrode 10 to the longitudinal direction of the stimulation electrode 12. Similar to the foot portion 28 of the contact electrode 20, the foot portion 17 has a function of fixing the stimulation electrode 10 to the resin portion 35 and electrically connecting to the wiring formed on the resin portion 35.
At the tip of the foot 17, a taper 18 is formed with the tip tapered by cutting the corner. The tapered portion 18 has a function of easily inserting the foot portion 17 into the through hole 91 (first through hole) formed in the resin portion 35.

A locking portion 19 that protrudes in the width direction is formed at substantially the center in the longitudinal direction of the stimulation electrode 10.
The locking portion 19 has a function as a stopper that defines the amount of insertion when the foot portion 17 of the stimulation electrode 10 is press-fitted into the through hole 91 of the resin portion 35. For this reason, it forms so that the distance from the end surface by the side of the taper 18 of the latching | locking part 19 to the stimulation electrode part 12 may become a predetermined value.
In addition, in this embodiment, although the latching | locking part 19 is formed in the both sides of the width direction, you may make it form only any one.
When the locking portions 19 are formed on both sides as in the present embodiment, the position of the end face on the tapered portion 18 side of the locking portion 19 is the same (the distance from the stimulation electrode portion 12 is a specified value). To form.

The resin part 35 is provided with a through-hole set 90 for fixing an electrode pair composed of the stimulation electrode 10 and the contact electrode 20.
The resin portion 35 of the present embodiment is provided with a total of four through-hole sets 90, one at the center and three at each vertex position of an equilateral triangle with the center as the center of gravity.
In the resin part 35 of the present embodiment, a one-pole biostimulation electrode part 1 is formed by arranging an electrode pair in the center, and a three-pole living body is arranged by arranging electrode pairs at three positions of each vertex of an equilateral triangle. The stimulation electrode unit 1 is formed, and further, the four-electrode biostimulation electrode unit 1 is formed by arranging electrode pairs at all four locations. Thus, the resin portion 35 is also used as a resin portion for one pole, three poles, and four poles.

Each through hole set 90 has three through holes 93, 91, 93 formed in a line, the foot 17 of the stimulation electrode 10 passes through the central through hole 91, and the feet 28, 28 of the contact electrode 20 pass through on both sides. The holes 93 and 93 are press-fitted.
Ink containing a metal material is screen-printed (conductor printed) on the inner peripheral surfaces of the through holes 91 and 93. On the back surface of the resin portion 35 (opposite to the side where the electrode pair is disposed), the wiring from each through hole 91 to the lead wire 98 is screen-printed, as will be described in detail later. To the lead wire 97 are screen-printed.

  By pressing the foot portions 17 of the three stimulation electrodes 10 into the respective through holes 91 and then pressing the foot portions 28 and 28 of the three contact electrodes 20 into the respective through holes 93 and 93, FIG. ) Is formed.

FIG. 10 shows a state in which the pair of stimulation electrodes 10 and the contact electrodes 20 are press-fitted into the through holes 91 and 93 of the resin portion 35.
FIG. 10A is a diagram showing the stimulation electrode unit 12 side (upper side). As shown in FIG. 10A, wirings 94, 92, 94 are screen-printed on the inner peripheral surface and the end surface of the through holes 93, 91, 93 arranged in a line, respectively.
FIG. 10 (d) shows the state of this wiring from the back surface of the resin portion 35, and the wirings 94 and 94 of the through hole 93 are connected to the lead wire 97 by the wiring 96.
Further, the wiring 92 printed on the inner peripheral surface of the through hole 91 is connected to the lead wire 98 by the wiring 95.
In the stimulation electrode 10, the foot portion 17 is press-fitted in a direction in which the arrangement direction of the through holes 93, 91, 93 and the width direction of the stimulation electrode 10 are orthogonal.

FIGS. 10B and 10C are an AA sectional view and a BB sectional view in FIG. 10A, respectively.
In FIGS. 10B and 10C, the wirings 92, 94, and 96 are displayed thicker than actual to clarify their existence, but are actually screen printed thinner.
Similarly, the stimulating electrode 10 and the contact electrode 20 in FIG. 10C are also separated from the resin portion 35 by the thickness of the wirings 92 and 94 (the wiring 94 is not shown because it exists at the front and back). Actually, it is in contact with the resin portion 35 by the force when the feet 17 and 28 are press-fitted.

  The biostimulation electrode portion 1 shown in FIGS. 9 and 10 is in a state in which the feet 17, 28, and 28 of the stimulation electrode 10 and the contact electrode 20 protrude from the back side of the resin portion 35. Etc., a cover is provided.

FIG. 11 shows a method for manufacturing a stimulation electrode and a contact electrode according to the fourth embodiment.
About the stimulation electrode 10, as shown to Fig.11 (a), the stimulation electrode group 100 with which the several stimulation electrode 10 was connected to the continuous base 110 by the punching process from a metal plate is formed.
As the metal plate forming the stimulation electrode group 100, SUS304, SUS316, or the like having a thickness of about 0.1 to 0.2 mm is used, as described in the first embodiment. Further, another metal that is harmless to the human body may be used, or the surface may be plated with a metal that is harmless to the human body such as gold.

Each stimulation electrode 10 is connected to the continuous base 110 at the tip of its tapered end 18.
Then, in the stimulation electrode group 100 formed by punching, the tip of each stimulation electrode is formed by forging, polishing, etching, cutting, and the like to form the stimulation electrode portion 12 and its pointed head by the slope portions 15 and 16.
By forming the stimulation electrode group 100 in which the plurality of stimulation electrodes 10 are connected to the continuous base 110 in this way, the stimulation electrode portion 12 and its cusp are processed efficiently for the plurality of stimulation electrodes 10. Can do.
In addition, although the stimulation electrode group 100 illustrated in FIG. 11A illustrates the case where the plurality of stimulation electrodes 10 are formed only on one side of the continuous base 110, the plurality of stimulation electrodes 10 are provided on both sides of the continuous base 110. May be formed.

The plurality of stimulation electrodes 10 are processed from the stimulation electrode portion 12 and its pointed head, and then separated from the continuous base portion 110 to become individual stimulation electrodes 10.
The stimulation electrode 10 has a portion (main body portion) other than the stimulation electrode portion 12 in a flat plate state in addition to the columnar shape, and a locking portion 19 that protrudes from the main body portion on both sides in the width direction. Therefore, rolling during transportation is prevented.

On the other hand, with respect to the contact electrode 20, a metal plate made of the same material as that of the stimulation electrode 10 is punched to form a rectangular portion 200 that becomes a cylindrical portion 27 and two foot portions 28 as shown in FIG. To do. A tapered portion 29 is also formed at the tip of the foot portion 28 during the punching.
By rounding the rectangular portion 200 so that the width direction is the axial direction, the cylindrical portion 27 is formed as shown in FIG.
In FIG. 11 (c), both ends in the longitudinal direction of the rectangular portion 200 are separated in the cylindrical shape 27, but are shown separated to facilitate understanding of the state. Both ends are formed in contact with each other. However, both end portions may be slightly separated in a state of facing each other as shown in FIG. Further, both ends may be completely connected by welding or the like.

  11 (b) and 11 (c), the contact electrodes 20 are individually punched. However, like the stimulation electrode group 100 described with reference to FIG. 11 (a), the contact electrodes 20 are formed on one side or both sides of the continuous base. A plurality of contact electrodes 20 may be formed. In this case, both or one of the tapered portions 29, 29 is formed in a state of being connected to the continuous base. When one of the tapered portions 29 is connected, the lengths of both feet 28 are different, but there is no particular problem in assembling.

FIG. 12 shows the shape of the stimulation electrode 10 used in the fourth embodiment and the shape of the modified example. Each of FIGS. 12A to 12H is a plan view and a front view in order from the top. The figure and the perspective view are represented.
In FIG. 12, only a part on the stimulation electrode portion 12 side is shown, and the locking portion 19 and the like are omitted.
In addition, about the shape by the side of the stimulation electrode part 12 shown to Fig.12 (a)-(h), it is possible to employ | adopt also in 1st Embodiment-3rd Embodiment.

FIGS. 12A and 12F show the first basic shape and the second basic shape obtained by punching a metal plate, and the forging, polishing, etching, cutting, and the like described above with respect to this basic shape. 12 (b) to (e), (g), and the stimulation electrode portion 12 and the cusp shown in (h) are formed.
In addition, in each figure except the 1st, 2nd basic shape in FIG. 12, in order to clarify the position of a cusp, the black circle is attached | subjected to the applicable location. Moreover, in order to clarify the corresponding slope part between a top view, a front view, and a perspective view, it has attached the oblique line.

FIG. 12A shows the first basic shape.
This first basic shape is formed by punching left and right from the center line in the longitudinal direction to form the slope portions 15 and 15 so that the tip portion is triangular. A ridgeline 12a is formed at the center tip of the triangle. This basic shape is the shape described in the first embodiment.

FIG. 12B shows the slope 16 formed by cutting the upper surface of the triangular portion formed at the tip from the first basic shape obliquely toward the pointed head.
FIG. 12C is a bisector (ridge line) such that the bisector passing through the cusp is a ridge line in the triangle forming the slope 16 from the shape of FIG. 12B. Line) and rearward (opposite side of the pointed head) and is cut diagonally downward in the left-right direction. Thereby, the slope 15 is scraped away and rhombus-like slopes 16c1 and 16c2 are formed.

12 (d) and 12 (e) show conical surfaces 16d and 16e formed in the first basic shape by cutting the tip portion into a conical shape so that one end of the ridge line 12a becomes a pointed head. is there.
In the modified example of FIG. 12D, the cross-sectional shape remains rectangular except for the tip portion cut into a conical shape.
On the other hand, in the modified example of FIG. 12 (e), except for the tip portion cut into a conical shape, the cross section is cut so as to be semicircular or curved.
In the modification shown in FIGS. 12D and 12E, the case of one curved surface (conical surfaces 16d and 16e) has been described. However, as shown in FIG. However, two curved surfaces may be formed on both sides thereof.

FIG. 12F shows the second basic shape.
The second basic shape is formed by obliquely punching from one side in the width direction to the other side to form a tip portion in a right triangle shape. In this example, only one slope portion 15f is formed on the oblique side portion of the right triangle.

FIG. 12G shows a slope 16g formed by cutting the upper surface of the right triangle formed at the tip obliquely toward the pointed head from the second basic shape. As a result, the slanted portion 15f is shaved and becomes 15 g.
FIG. 12H shows the shape of FIG. 12G, in which the slope portion 16g is cut by cutting the slope portion 16g obliquely downward in the right triangle forming the slope portion 16g.
12 (f), 12 (g), and 12 (h) are shapes obtained by dividing the width in FIG. 12 (a), 12 (b), and 12 (c) into two equal parts from the center. It is.

  In the above-described modification, for the sake of explanation, the case where the first and second basic shapes are cut into other shapes has been described, but other methods such as forging are naturally possible.

FIG. 13 illustrates a modification regarding the shape of the stimulation electrode 10 in the fourth embodiment.
In this modification, as shown in FIG. 13 (b), the two locking portions 19 and 19 in the stimulation electrode 10 (see FIG. 13 (a)) described in the fourth embodiment are respectively counterclockwise. Are bent at a predetermined angle. In the modification shown in FIG. 13B, the predetermined angle is bent by 90 degrees, but other angles may be used.
Further, both of the locking portions 19 are bent in the counterclockwise direction, but one may be bent in the clockwise direction, the other may be bent in the counterclockwise direction, and only one of them may be bent. Good.

According to this modification, when the stimulation electrode 10 is placed on a flat surface, the bent locking portion 19 can lift the main body portion (a portion other than the locking portion 19) from the flat surface.
Thereby, when press-fitting into the resin part 35, the work of gripping the stimulation electrode 10 is facilitated, and in particular, the stimulation electrode 10 can be easily grasped by the robot on the production line.

FIG. 14 illustrates a modification example regarding the arrangement direction of the stimulation electrode 10 in the fourth embodiment.
In this modification, the three stimulation electrodes 10 are arranged so that the surfaces in the width direction face the center direction of the resin portion 35.
According to this modification, since the surface in the width direction of the three stimulation electrodes 10 and the locking portion 19 are in the radial direction, the biostimulation electrode portion 1 is moved in a contact state when used in the examination. Even in this case, wobbling of each stimulation electrode 10 can be prevented.
In FIG. 14, along the direction change of the stimulation electrode 10, the direction of the three outer through-hole sets 90 used in the case of three poles is also such that the line connecting the centers of the through-holes 93, 91, 93 is orthogonal to the radius. Although the direction is changed, the direction of the fourth embodiment shown in FIG. 9 may be maintained. In this case, only the stimulation electrode 10 is press-fitted so as to face the center direction.

Next, an attachment member and a protective cover for attaching the biostimulation electrode unit 1 to the skin will be described with reference to FIG.
In FIG. 15, the side surface of the biostimulation electrode 1 is shown, and the cross section of the attachment portions 301 and 302 and the protective cover 303 is shown.

The biostimulation electrode 1 may be any of the first to fourth embodiments described above and modifications thereof (including modifications described later).
In FIG. 15, the biostimulation electrode unit 1 described in FIG. 9 is used.
However, the lead wires 97 and 98 are connected via a flexible wiring board 47 as in FIG.
That is, the wiring board 47 is attached to one surface of the resin portion 35. In the wiring board 47, three (or n) through-holes and wirings 95 and 96 (the arrangement relationship is arranged in the same manner as in FIG. 10) so as to communicate with the respective through-holes 91 and 93 of the resin portion 35. Is formed).
Wirings 92 and 94 (arranged in the same manner as in FIG. 10) are formed inside the through holes of the resin part 35 and the wiring board 47 that communicate with each other. The wirings 92 and 94 are formed by inserting cylindrical metal into a through hole communicating with each other and caulking both ends. Both ends of the wirings 92 and 94 are caulked, whereby caulking portions are formed in parallel with both planes of the resin portion 35 and the wiring board 47. In the caulking portion, on the resin portion 35 side, the locking portion 96 of the stimulation electrode 10 and the end surface on the foot portion 28 side of the cylindrical portion 27 in the contact electrode 20 abut. On the other hand, on the wiring board 47 side of the caulking portion, the wirings 92 and 94 and the wirings 95 and 96 are connected by caulking.

The foot portion 17 of the stimulation electrode 10 and the foot portion 28 of the contact electrode 20 are press-fitted into the wirings 92 and 94 formed in both the through holes of the resin portion 35 and the wiring board 47 as described in FIG. The both ends protrude from the wiring board 47.
However, in FIG. 15, the protruding portion is omitted.

The attachment portions 301 and 302 are made of an elastic member such as polyurethane, and are formed in a circular shape having an outer diameter larger than the outer diameter of the biostimulation electrode portion 1.
In the mounting portion 301, through holes having the same number as the contact electrodes 20 and having an inner diameter larger than the outer diameter of the contact electrodes 20 are formed at positions corresponding to the arrangement of the contact electrodes 20. An adhesive layer made of an adhesive material is formed on both surfaces of the attachment portion 301.
The thickness of the attachment portion 301 is formed to be shorter than the length of the cylindrical portion 27.
Then, the contact electrode 20 of the biostimulation electrode portion 1 is inserted through the through hole of the attachment portion 301, and the resin portion 35 is attached to the attachment portion 301.

On the other hand, the attachment portion 302 has an adhesive layer made of an adhesive on one surface, and the side on which the adhesive layer is formed is attached to the peripheral surfaces of the wiring board 47 and the attachment portion 301.
Thus, by attaching both the attachment part 301 and the attachment part 302 so as to sandwich the biostimulation electrode part 1 from both sides, the biostimulation electrode part 1 is accommodated inside and the lead wires 97 and 98 are attached. It is fixed.
In addition, the biostimulation electrode unit 1 can be attached to the skin or the like by the adhesive layer formed on the open surface of the attachment portion 301 (the surface on the side not attached to the attachment portion 302).

The protective cover 303 is a cover for protecting the adhesive layer (attachment side to the skin) of the biostimulation electrode part 1 and the attachment part 301.
The protective cover 303 is formed in a circular shape having an outer diameter larger than the outer diameter of the mounting portion 301 with a transparent thin resin.
The protective cover 303 is formed with a circular first recess 304 and a circular second recess 305 concentrically formed in the same direction in the first recess.
The first recess has an inner diameter larger than that of the attachment portion 301 and is formed at a depth substantially the same as the thickness of the attachment portion 301.
On the other hand, the second recess 305 has an inner diameter that can accommodate all the contact electrodes 20 and is formed at a depth that ensures a predetermined distance from the tip of the stimulation electrode 10.

  By sticking the bottom surface of the first concave portion of the protective cover 30 to the adhesive layer of the attachment portion 301, the adhesive layer is protected and the stimulation electrode portion 10 and the contact electrode portion 20 are protected by the second concave portion.

The biostimulation electrode unit 1 of the embodiment described above and the modified example is supposed to electrically stimulate the epidermis of the human body, but this does not limit the target to the human body. Electrical stimulation may be given to other animals or plants.
Further, in this case, the size and arrangement of the electrode pair 30 such as the protruding amount of the stimulation electrode unit 12 can be appropriately changed according to the purpose.

Further, in each of the embodiments and modifications described above, the case where the metal plate is punched (punched) to form the stimulation electrode 10 and the contact electrode 20 has been described. It may be formed by cutting.
Furthermore, in each of the embodiments and modifications described above, the case where the stimulation electrode 10 and the contact electrode 20 are formed from a metal plate has been described, but they may be formed from a conductive resin.

Further, the following configurations are obtained by the embodiments and modifications described above.
In the stimulation electrode 10, the stimulation electrode portion 12 functions as a stimulation portion formed at an acute angle, and since the bent portions 13 and 14 are formed, the stimulation with the tip that stimulates the epidermis of the living body formed at an acute angle. And functions as a first electrode in which a bent portion is formed between the stimulation portion at the tip and the other end.
Further, the contact electrode 20 has the contact electrode portion 22 in contact with the epidermis and the bent portions 24 and 25, and therefore has a contact portion that contacts the living body's epidermis with a line or a surface at the tip, It functions as a second electrode in which a bent portion is formed between the contact portion and the other end.
Furthermore, since the resin part 35 is fixed so that the stimulation electrode part 12 and the contact electrode part 22 have a predetermined positional relationship and constitute the electrode pair 30, the stimulation part and the contact part with respect to the epidermis of the living body have a predetermined positional relation. So as to function as a resin portion for fixing the first electrode and the second electrode.
Further, the bent portions of the first electrode and the second electrode may be bent portions for exerting elasticity.

In the first embodiment, the portions on the other end side of the bending portions 13 and 14 of the stimulation electrode 10 and the portions on the other end side of the bending portions 24 and 25 of the contact electrode 20 are fixed by the resin portion 35. Therefore, the first electrode and the second electrode are fixed to the resin portion at least on the other end side from the bent portion.
In the second and third embodiments, at least the other end side is fixed to the bent portion.
Since the other end side is fixed with the resin part 35 rather than the bent part, when a stress acts on the stimulation electrode part 12 and the contact electrode part 22, high rigidity can be exhibited.

  Since the stimulation electrode 10 and the stimulation electrode portion 12 are integrally formed from a metal plate by sheet metal processing, at least one of the first electrode and the second electrode is integrally processed from a metal plate.

  In the first embodiment and the second embodiment, since the stimulation electrode 10 and the contact electrode 20 are fixed by insert molding, the first electrode and the second electrode are formed by insert molding. It is fixed to.

  In the third embodiment, reference holes 61 and 62 are provided in the stimulation electrode 10, and reference holes 51 are provided in the contact electrode 20, and these are protrusions 37 a, 37 b and 36 a provided in the back surface side resin part 36, respectively. , 36b, and the protrusions 37a, 37b, 36a, 36b are caulked with heat to fix the stimulation electrode 10 and the contact electrode 20 to the back surface side resin part 36, so that the first electrode and the second electrode A reference hole is formed in the electrode, the resin portion is provided with a protrusion that fits into the reference hole, and the reference hole of the first electrode and the second electrode is the protrusion. It is being fixed to the said resin part by being fixed to.

  In the third embodiment, since the bent portion 13 of the stimulation electrode 10 is located in the recess 73 and has a shape floating in the space, the other end side of the bent portion 13 is the outer periphery of the back surface side resin portion 36. Since the first electrode is cantilevered to the part side, the first electrode is bent to the outer peripheral part side of the resin part and is cantilevered by the resin part, and around the bent part in the resin part, A space is provided.

  In the first embodiment, since the other end side of the stimulation electrode 10 and the contact electrode 20 extends to the outer peripheral portion of the resin portion 35 and is connected to the connector, other than the first electrode and the second electrode, The end side is extended to the outer peripheral part of the resin part.

  In the second embodiment, the electrode members 11a to 11c and 21a to 21c are exposed on the back side of the resin portion 35, and the wiring 48 reaching the outer peripheral portion of the resin portion 35 is formed. The other end side of the first electrode and the second electrode is exposed on the side of the resin portion facing the side where the first electrode and the second electrode are formed, and the exposed other end And a wiring member that reaches the outer peripheral portion of the resin portion.

  In the first embodiment, the biostimulation electrode unit 1 has three electrode pairs 30, and thus has a plurality of electrode pairs each composed of a set of the first electrode and the second electrode. Yes.

Further, since the contact electrodes 20a to 20c are insulated from each other, at least one of the first electrodes or the second electrodes of the plurality of the electrode pairs is insulated from each other.
Thereby, the voltage of a different pattern can be applied to the electrode pairs 30a-30c.

  In addition, since the biostimulation electrode unit 1 is connected to a power supply device via a connector, and the electrode pair 30 is driven by an electrical signal transmitted from a circuit of the power supply device, the biostimulation electrode and the biostimulation electrode It is possible to provide a biostimulation apparatus including a biostimulation electrode drive circuit that transmits and drives an electrical signal.

Moreover, since the stimulation electrode 10 is formed by processing a metal plate into a sheet metal and the tip of the stimulation electrode portion 12 has a ridgeline, the tip that stimulates the epidermis of a living body is formed at an acute angle having a ridgeline. And functions as a first electrode processed from one metal plate.
On the other hand, the contact electrode 20 functions as a second electrode that has a contact portion at the tip that makes contact with the epidermis of a living body with a line or a surface, and a bent portion is formed between the contact portion and the other end of the tip. Yes.
And the back surface side resin part 36 functions as a fixing part that fixes the first electrode and the second electrode so that the stimulation part and the contact part with respect to the epidermis of the living body have a predetermined positional relationship. .

  Since the example of FIG. 4B has a plurality of stimulation electrode portions 12, a plurality of ridge lines of the stimulation portion are formed.

In addition, the stimulation electrode 10 functions as a first electrode having a stimulation part in which a tip that stimulates the epidermis of a living body is formed at an acute angle.
Since the contact electrode 20 is integrally processed from a metal plate, the contact electrode 20 is integrally processed from a single metal plate and functions as a second electrode having a contact portion at the tip that contacts the living body's epidermis with a line or surface. Yes.
Furthermore, the back surface side resin portion 36 functions as a fixing portion that fixes the first electrode and the second electrode so that the stimulation portion and the contact portion with respect to the epidermis of a living body have a predetermined positional relationship. .

  In the third embodiment, the contact electrode portion 55 is provided with a stimulation electrode portion hole 56, and the stimulation electrode portion 12 contacts the epidermis via the stimulation electrode portion hole 56. A hole is formed in the electrode, and the stimulating part contacts the epidermis of the living body through the hole.

  Further, the portions of the electrode member 21 positioned at both ends of the contact electrode portion 55 are formed narrower than the width of the contact electrode portion 55, and the four corners of the contact electrode portion 55 are rounded and formed in an R shape. Is a surface, the width of the support portion supporting the contact portion is formed narrower than the width of the contact portion, and the corner portion of the contact portion is formed in a round shape.

  Further, the flexible wiring board 47 described in FIGS. 5 and 15 has been described with respect to the case where the flexible electrode 47 is disposed on the side opposite to the side where the stimulation electrode 10 and the contact electrode 20 are disposed. The wiring board 47 may be disposed on the side where 10 and the like are disposed.

DESCRIPTION OF SYMBOLS 1 Biological stimulation electrode part 10 Stimulation electrode 11 Electrode member 12 Stimulation electrode part 13, 14 Bending part 15, 16 Slope part 17 Foot part 18 Tip 19 Locking part 20 Contact electrode 21 Electrode member 22 Contact electrode part 23 Cylindrical part 24, 25 Bent part 26 Ring part 27 Cylindrical part 28 Foot part 29 Tip 30 Electrode pair 35 Resin part 36 Back side resin part 37 Projection part 38 Projection part 39 Front side resin part 41, 43 Lead terminal 42, 44 Connection part 45, 46 Connection terminal 47 Substrate 48 Wiring 49 Connector 51, 52 Reference hole 53 Long hole 55 Contact electrode part 56 Stimulation electrode part hole 58, 59 Bent part 61, 62 Reference hole 63 Long hole 71 Stimulation electrode groove part 72 Contact electrode groove part 73 Concave part 81, 82, 83, 84 Bent part 86 Connector part 90 Through-hole set 91, 93 Through-hole 92, 94-96 Wiring 100 Stimulation electrode group 110 Continuous base 200 Rectangular portion 301, 302 Mounting portion 303 Protective cover 304 First recess 305 Second recess

Claims (8)

A first electrode of the plate-shaped tip to stimulate the epidermis of the raw body and a leg portion extending on the opposite side of the cusp and cusp portion formed at an acute angle,
A second electrode having a said contact portion and the foot portion extending on the opposite side of the contact portion from the cylindrical portion and the cylindrical portion having a distal end in contact with a line or surface in the epidermis of the raw body,
An insulating member that fixes the first electrode and the second electrode so that the cusp and the contact portion with respect to the epidermis of a living body have a predetermined positional relationship;
The first electrode includes a planar Former sharp shape due to the flat shape, by a one or more flat or curved surfaces formed toward the tip of the pointed shape, and the peak portion is formed, together with ,
The insulating member has a conductor disposed on an inner peripheral surface thereof, a first through hole into which a foot portion of the first electrode is press-fitted, and a conductor disposed on an inner peripheral surface of the insulating member. A second through-hole into which the foot is press-fitted,
A biostimulation electrode characterized by that.   The biostimulation electrode according to claim 1, wherein the pointed head has a blunt portion having a width of 50 μm or less.   The biostimulation electrode according to claim 1 or 2, wherein the surface roughness of the pointed head is Ra 10 µm or less. The said 1st electrode is protrudingly formed by the latching | locking part which prescribes | regulates the amount of press-fit in the case of the press-fit of the said foot part , The Claim 2, Claim 2, or Claim 3 characterized by the above-mentioned. Biostimulation electrode. Said first electrode and said second electrode are gold Shokumata the biostimulation according to claims 1, characterized in that the electrically conductive resins to any one of claims of claims 4 electrode. The biostimulation electrode according to any one of claims 1 to 5 , comprising a plurality of electrode pairs each including a set of the first electrode and the second electrode. The biostimulation electrode according to claim 6 , wherein at least one of the plurality of first electrodes or second electrodes of the electrode pairs is insulated from each other. Said insulating section, said contact portion and the peak portion is formed of a resin having a storage portion for accommodating the first electrode and the second electrode so as to have a predetermined positional relationship, before Symbol first The electrode and the second electrode are fixed by caulking with the resin ,
Biostimulation electrode according to any one of claims of claims 1 to 7, wherein, characterized in that.

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