KR200278492Y1 - A bioelectrode - Google Patents

Abstract

Disclosed is an electrocardiogram bioelectrode capable of maintaining a stable degree of sensing even against external disturbances of the bioelectrode and having a long-term use without sweat or allergy due to a design having excellent breathability. The bioelectrode 200 is formed of a woven fabric and a nonwoven fabric including synthetic polymer such as polyethylene and natural polymer such as cellulose, and biocompatible adhesives 3a and 3d are coated on both surfaces thereof, and holes 3c are provided in the central portion thereof. A polymer film electrode element such as polyethylene terephthalate, which is attached to the base 3 and the adhesive 3a on one side of the base 3, is coated with carbon 4b and silver / silver chloride 4, and has air permeable holes 4c. (4), a reinforcing member (2) having a breathable hole (2a) of a material such as cellulose attached to one surface of the film electrode element (4) and printed a logo, and provided at the tip of the reinforcing member (2) And a female snap (1) to which a lead wire (8) connecting the electrocardiograph (not shown) and the bioelectrode 200 is made of a stainless material or a nickel plated brass material, and a tip of the electrode element 4. And the carbon coating layer 4b of the electrode element and reinforcement (2) a male snap 1 provided at the tip and a male snap 9 of a stainless material or nickel plated brass material which is press-fixed, a lower end of the male snap 9 and a carbon coating layer of the electrode element 4; (4b) is provided to protect the reinforcing material (10) is fixed with the adhesive (10a), and provided in the hole (3c) of the central portion of the base (3) exposed silver / silver salt of the polymer film electrode element (4) Conductive hydrogel adhesive (5) provided to cover the cargo coating layer (4a), and polyethylene terephthalate, such as polyethylene terephthalate provided to protect the other surface adhesive (3d) and the conductive hydrogel adhesive (5) of the base (3) Half moon-shaped residual release paper remaining from the base release paper to prevent adhesion of the base 3 adhesive 3d when the release film 6 of the polymer material and the bioelectrode 200 are taken out from the skin 7 by hand. (3b) is provided. The electrocardiogram bioelectrode 200 is composed of a stable configuration against external stimuli, and thus has excellent sensing accuracy and excellent breathability, and thus can be used for a long time without allergic reaction.

Description

Bioelectrode for electrocardiogram {A bioelectrode}

The present invention relates to a electrocardiogram bioelectrode capable of maintaining a stable degree of sensing even in the disturbances of external electrodes of the bioelectrode and having excellent breathability and enabling long-term use without sweat or allergy problems.

In the medical field, in order to measure the biopotential such as electrocardiogram, electromyography, and electroencephalogram for proper treatment, the body signal is transmitted to an external device to diagnose for proper treatment. Representative bioelectric signals such as ElectrocardioGram, ElectroMyoGram, ElectroEncephaloGram, and Bio-Impedance signals are the most basic methods for diagnosing a subject's health in a non-invasive manner. In general, in the case of ECG and respiratory signals, the vital signal is the vital signal, which is widely used in clinical practice.

For example, when measuring the biopotential of the heart, the bioelectrode needs to be directly connected to a part of the living body in order to induce a weak electric signal efficiently and guide it to an electrocardiogram or the like. Just contacting the bioelectrode with each other does not electrically connect the bioelectrode and the living body, and complex electric potential or impedance is generated due to unstable contact between the bioelectrode and the skin, and thus an electrical signal cannot be accurately measured. Therefore, the above-mentioned bioelectrode has no irritation to the skin and at the same time adheres the bioelectrode to the skin to attach a stable electric signal to the living body through a conductive polymer medium which can be induced from the living body to an external device.

In the bioelectrode, factors such as the structure, shape, and material of the electrode, which are sensors, have a great influence on the performance and usefulness of the entire measuring system. Particularly, a material capable of satisfying conditions such as biostimulation, impedance, and adhesion Conductive hydrogel adhesive.

Hydrogels are generally prepared by adding thickeners such as glycerol and polyethylene oxide to synthetic polymers such as polypyrrolidone, polyhydroxyacrylate, polyvinyl alcohol, polyamide, acrylic acid, and natural polymers such as gelatin and agar.

Hydrogel contains a large amount of water and consists of a three-dimensional network structure and contains water by hydrophilic functional groups and capillary or osmotic pressure. The reason why the hydrogel does not dissolve in water is that it has some electrostatic and lipophilic interactions, but due to the high polymer-coupling characteristics of the covalent bonds, it is the basic element of the hydrogel to maintain the mechanical properties and shape while absorbing water. to be. Medical hydrogels have affinity with blood, body fluids and biological tissues, and thus are used in general biomaterials such as adhesives, biological tissue adhesives, contact lenses, image dressing agents and artificial cartilage. Accordingly, the conductive hydrogel adhesive should have electrical properties and properties capable of adhering to the biological surface while maintaining the above properties.

Electrocardiographic bioelectrode 100 employing the conductive hydrogel is shown in FIGS. 1 to 4. It is formed in the form of a foam pad, a woven fabric, a nonwoven fabric, a tape including synthetic polymers such as polyethylene and natural polymers such as cellulose, for example, and a base (3) coated with acrylic biocompatible adhesive (3a) on one surface thereof. Is attached to the other side of the base (3) to prevent moisture evaporation, and the like is provided in the center of the reinforcing material (2) of the polymeric material, the logo is printed, and the mutually attached base (3) and the reinforcing material (2) Lead wire connecting the electrode (4), the electrocardiogram (not shown), and the electrode element (4) coated with silver / silver chloride to the glass (1) of the stainless steel material or nickel coated brass material and the glass fiber reinforced plastic. To protect the conductive hydrogel adhesive 5 and the hydrogel adhesive 5 and the remaining adhesive portions of the base 3 provided to cover the exposed surface of the electrode element 4 to which 8 is connected. part Which consists of a release film (6) of polymer material.

The current path of the electrocardiogram signal in the case of measuring the electrocardiogram using the electrocardiogram bioelectrode 100 is the electromotive force in the heart → the tissue in the body → skin → the conductive hydrogel adhesive → the electrode element → the lead wire → the electrocardiogram → the skin My organization → The heart is electromotive force.

In the electrocardiogram bioelectrode 100, elements such as the structure and shape of the electrode as a sensor, the material and shape of the base, and the conductive hydrogel adhesive have a great influence on the performance and usefulness of the entire measuring system. Problems such as measurement error or misdiagnosis due to poor contact of the bioelectrode due to the movement of the bioelectrode, and biostimulation due to the lowering of the breathability of the bioelectrode due to the continuous use of the bioelectrode, are still problems to be solved.

In detail, in order to diagnose the state of the heart, the electrocardiogram bioelectrode is contacted by contacting the heart with the skin around the heart, and then the lead wire connected to the electrocardiogram is connected to the snap of the electrocardiograph bioelectrode. The state of electromotive force in the heart is continuously checked through the shape of the heart wave. As a factor for contacting and maintaining the bioelectrode 100 on the skin 7, the hydrogel adhesive 5 covering the adhesive 3a of the bioelectrode base 3 and the surface of the electrode element provided in the center of the bioelectrode is provided. to be. Meanwhile, as shown in FIG. 4, the snap 1 connected to the electrode element 4 in the center of the bioelectrode and the lead wire 8 connected to an electrocardiogram (not shown) eliminate such adhesive force. In the operating room, where complex strands of wires are used in a complex way, and in the case of a stress test with a lot of movement, the adhesion of the bioelectrode to the skin cannot be perfectly maintained, resulting in movement artefact or noise. ).

The present invention was created in order to solve the above problems, it is possible to maintain a stable sensing degree to the external disturbance factors of the biological electrode, the breathable design of electrocardiogram bioelectrode that can be used for a long time without problems of sweat or allergy The purpose is to provide.

1 is a perspective view showing a bioelectrode for an electrocardiogram,

2 is a cross-sectional view of FIG.

3 is an exploded perspective view of FIG. 1;

4 is a cross-sectional view of the tensile force of the ECG lead wire applied to the bioelectrode of FIG. 1;

5 is a perspective view showing a bioelectrode for an electrocardiogram applied to the present invention;

6 is a cross-sectional view of FIG.

7A is an exploded perspective view of FIG. 5;

FIG. 7B is a rear view of the electrode element shown in FIG. 7A;

8 is a cross-sectional view of a state in which a tensile force of an electrocardiograph lead is applied to the bioelectrode of FIG. 5.

* Explanation of symbols for main parts of the drawings

1.Snap (female) 2 ... Reinforcement (sticker)

2a ... breathable hole 3 ... base

3a ... base adhesive 3b ... residual release paper

3c ... hole in the center of the base 3d ... base adhesive

4 ... electrode element 4a ... silver / silver chloride coating layer

4b ... Carbide coating layer 4c ... Breathable hole

5 ... conductive hydrogel adhesive 6 ... release film

7 skin 8 lead wire

9 ... Snap 10 ... Reinforcements

10a ... Reinforcement adhesive 100 ... Bielectrode for electrocardiogram

200 ... Electrocardiogram Electrode Electrode According to the Invention

Electrocardiogram bioelectrode of the present invention to achieve the above object, the base is a pressure-sensitive adhesive is applied on both sides and the hole formed in the central portion; And

A polymer film electrode element attached to an upper surface of the base and having a plurality of breathable holes and an extension portion extending from the body and having a conductive layer formed on a lower surface thereof; and

A first reinforcing material attached to an upper surface of the electrode element and having a plurality of breathing holes corresponding to the breathing holes of the electrode element; and

A female and male snap terminal through which the lead portion of the electrocardiograph is connected and fixed to each other by penetrating through the extension of the film electrode element and the first reinforcing material corresponding thereto; and

A second reinforcing material provided to protect the conductive layer on the bottom surface of the male snap terminal and the film electrode element extension; and

A conductive hydrogel adhesive provided in a hole in the central portion of the base and provided to cover the conductive layer of the polymer film electrode element; and

And a release film provided to protect the bottom surface of the base and the conductive hydrogel adhesive.

The base is formed of natural and synthetic polymers including polyethylene, polypropylene, nylon, polyester, cellulose, and the like, and the first reinforcing material is formed of a film of cellulose, polyethylene, polypropylene, or the like.

The conductive layer of the film electrode element is formed on the electrode element body and is formed on the first conductive layer of silver / silver chloride connected to the hydrogel adhesive and the extension of the electrode element and connected to the female / male snap terminal. And a second conductive layer formed of carbon.

According to the above features of the present invention, since the base is coated with the adhesive on the bottom is attached to the skin and the extension portion of the film electrode element where the male / male snap terminal is located is not attached to the skin by the second reinforcing material, it is connected to the snap terminal When the external force acts on the snap terminal by tension or flow of the lead wire, the extension portion of the film electrode element to which the snap terminal is fixed and the corresponding first reinforcing material are separated from the skin together to buffer the external force, thereby stably bonding the base. Adheres to the skin.

Hereinafter, a preferred embodiment of an electrocardiogram bioelectrode according to the present invention will be described in detail with reference to the accompanying drawings.

5 to 8, the electrocardiogram bioelectrode 200 according to the present invention is formed of a woven fabric and a nonwoven fabric including, for example, a synthetic polymer such as polyethylene and a natural polymer such as cellulose, and a biocompatible adhesive on both sides. A base 3 to which 3a and 3d are applied and a hole 3c is formed in the central portion thereof; The first conductive layer 4b made of carbon and the second conductive layer 4a made of silver / silver chloride are formed on the bottom of the base 3, which is attached to the upper adhesive 3a, and a plurality of breathable holes 4c are formed. A polymer film electrode element 4 such as formed polyethylene terephthalate; The first reinforcing material 2 is formed of a material such as cellulose attached to the upper surface of the film electrode element 4 and printed with a logo, and has a plurality of breathable holes 2a formed therein.

The film electrode element 4 is attached to an upper surface of the base 3 and includes a body 4e having the plurality of breathing holes 4c formed therein, and an extension 4f extending from the body 4e. At this time, the connecting portion of the body 4e and the extension portion 4f is formed with a narrow portion as shown.

As shown in FIG. 7B, the film electrode element 4 is formed on the first conductive layer 4a of silver / silver chloride formed on the body 4e and the extension part 4f and formed of carbon. The two conductive layers 4b are provided.

The first reinforcing material 2 is formed in a shape corresponding to that of the film electrode element 4, and the base 3 is attached to the body 4e of the film electrode element 4.

In addition, a female snap terminal (1) to which a lead wire (8) connecting the electrocardiogram (not shown) and the bioelectrode 200 is connected to a tip of the first reinforcing material 2 using a stainless material or a nickel plated brass material. Is provided, and a male snap terminal 9 of stainless material or nickel plated brass material which is compression-fixed with the female snap terminal 1 is provided at the extension portion 4f of the electrode element 4.

The second reinforcing material is fixed to the bottom of the extension part 4f of the electrode element 4 by the adhesive 10a to protect the lower end of the male snap terminal 9 and the second conductive layer 4b of the electrode element 4 ( 10) is provided.

In addition, a conductive hydrogel adhesive 5 is attached to the hole 3c of the central portion of the base 3 so as to be connected to the second conductive layer 4a made of silver / silver chloride of the polymer film electrode element 4. A release film 6 made of a polymer material such as polyethylene terephthalate is provided to protect the bottom adhesive 3d of the base 3 and the conductive hydrogel adhesive 5. In order to prevent the base 3 adhesive 3d from sticking when the bioelectrode 200 is taken out of the skin 7 by hand, the base 3 is provided with a residual moon-shaped residual release paper 3b. .

As described above, the bioelectrode of the present invention has a film electrode element 4 having a base 3 coated with a pressure-sensitive adhesive 3d attached to the skin 7 and a male / male snap terminal 1, 9 positioned thereon. Since the extension portion 4f of is not attached to the skin 7 by the second reinforcing material 10, the tension or flow of the lead wire 8 or the like connected to the snap terminal 1 as shown in FIG. When an external force acts on the snap terminals 1 and 9, the extension part 4f of the film electrode element 4 to which the snap terminal is fixed and the first reinforcing material 2 corresponding thereto are separated from the skin 7 together. Since the external force is buffered, the adhesive portion of the base 3 is stably adhered to the skin. Accordingly, the sensing accuracy is improved during ECG measurement, thereby enabling stable measurement.

In addition, the plurality of air vents (2a) (4c) to facilitate the discharge of sweat or the like to maintain the adhesion to the skin for a long time.

On the other hand, the polymer material to be used when manufacturing the electrocardiogram bioelectrode 200 from the above is not limited to the above, and has various shapes such as round, square, rectangular, oval, etc. Needless to say, the bioelectrode can be manufactured.

The present invention as described above, when the external force acts on the snap terminal (1) (9) by the tension or flow of the lead wire (8) connected to the snap terminal 1, the film electrode element (4) to which the snap terminal is fixed Since the extension portion 4f and the first reinforcing material 2 corresponding thereto are separated from the skin 7 together to buffer the external force, the adhesive portion of the base 3 is stably adhered to the skin. Accordingly, the sensing accuracy is improved during ECG measurement, thereby enabling stable measurement.

In addition, the plurality of air vents (2a) (4c) to facilitate the discharge of sweat or the like to maintain the adhesion to the skin for a long time.

Therefore, the electrocardiogram bioelectrode 200 according to the present invention is composed of a stable configuration to an external stimulus, and thus has excellent sensing accuracy and excellent breathability, and thus can be used for a long time without an allergic reaction.

Claims (4)

A base coated with adhesive on both sides and having a hole formed in the central portion thereof; and A polymer film electrode element attached to an upper surface of the base and having a plurality of breathable holes and an extension portion extending from the body and having a conductive layer formed on a lower surface thereof; and A first reinforcing material attached to an upper surface of the electrode element and having a plurality of breathing holes corresponding to the breathing holes of the electrode element; and A female and male snap terminal through which the lead portion of the electrocardiograph is connected and fixed to each other by penetrating through the extension of the film electrode element and the first reinforcing material corresponding thereto; and A second reinforcing material provided to protect the conductive layer on the bottom surface of the male snap terminal and the film electrode element extension; and A conductive hydrogel adhesive provided in a hole in the central portion of the base and provided to cover the conductive layer of the polymer film electrode element; and And a release film provided to protect the bottom surface of the base and the conductive hydrogel adhesive. The electrocardiogram bioelectrode of claim 1, wherein the base is formed of natural and synthetic polymers including polyethylene, polypropylene, nylon, polyester, cellulose, and the like. The ECG bioelectrode of claim 1, wherein the first reinforcing material is formed of a film such as cellulose, polyethylene, or polypropylene. The conductive layer of claim 1, wherein the conductive layer of the film electrode element is formed on the electrode element body and is formed on a first conductive layer of silver / silver chloride connected to the hydrogel adhesive and an extension of the electrode element. Electrocardiogram bioelectrode, characterized in that it is formed of a second conductive layer formed of carbon connected to the male snap terminal.