The present invention relates to a biological electrode, and more particularly, to a biological electrode capable of realizing good contacting with a scalp of a subject for detection.
In order to diagnose a health condition of a subject for detection in a medical facility or the like, a biological electrode is disposed on a body of the subject to detect various electric signals. For example, electroencephalogram is measured by disposing an electrode on a scalp of the subject.
Conventionally, as an electrode for electroencephalography, for example, a biological electrode including an electrode portion made of a conductive silicone rubber or the like has been proposed (for example, see JP-A-2017-74369). Examples of the electrode portion of the biological electrode include those in which a plurality of protrusions with sharp tips are provided on the side that comes into contact with a subject, and the plurality of protrusions are formed in a brush-like shape. The biological electrode for electroencephalography further includes, for example, a pedestal for disposing an electrode portion, and the pedestal is provided with a terminal for assembling with a counterpart component, an insulating rubber for supporting the terminal, and the like.
Conventionally, in a biological electrode for electroencephalography, the number of protrusions at the tips of the electrode portion is set to be larger in order to increase the area in contact with a scalp of a subject. Hereinafter, the number of protrusions provided in the electrode portion may be referred to as the “number of protrusions” of the electrode portion.
However, when the number of protrusions of the electrode portion in the biological electrode for electroencephalography is increased, the protrusions are densely arranged with respect to one electrode portion, and therefore, when the electroencephalogram of a subject having a large amount of hair is measured, a space for housing the hair is reduced between the scalp and the electrode portion. For this reason, such a biological electrode is problematic in that the electrode portion easily floats from the scalp, and conversely, it is difficult to contact with the scalp.
In addition, when detecting an electroencephalogram of a subject having a large amount of hair, a strong pressing force must be applied to a biological electrode in order to prevent the biological electrode from floating due to the hair and to bring the electrode portions into close contact with a scalp of the subject. However, if the use of biological electrode with a strong pressing force is continued for a long time as described above, the scalp of the subject may be painful.
In view of the above problems, the present invention provides a biological electrode capable of realizing good contacting with the scalp of a subject. In particular, there is provided a biological electrode suitable for electroencephalography and capable of realizing good contacting with the scalp even in a subject having a large amount of hair.
In order to solve the above problem, the present invention provides the following biological electrode.
[1] A biological electrode comprising an electrode member in contact with a body of a subject, wherein
[2] The biological electrode according to [1], wherein each of the plurality of electrode protrusions is arranged so as to be located on the circumference of one virtual circle or a plurality of virtual concentric circles on the outer peripheral part of the electrode protrusion forming surface.
[3] The biological electrode according to [1] or [2], wherein the plurality of electrode protrusions are arranged at equal intervals on the outer peripheral part of the electrode protrusion forming surface.
[4] The biological electrode according to any one of [1] to [3], wherein each of the plurality of electrode protrusions has an oblique conical shape with a rounded apex.
[5] The biological electrode according to any one of [1] to [4], which is used for electroencephalography of a subject.
The biological electrode of the present invention is effective in realizing good contacting with a scalp of a subject. In addition, the biological electrode of the present invention does not require excessive pressing of the electrodes. Therefore, it is possible to reduce pain in the scalp at the time of measuring. In particular, even in a subject having a large amount of hair, a subject having long hair, a subject having a large volume of hair (in other words, having thick hair), or the like, stable contacts with the scalp can be realized.
Hereinafter, embodiments of the present invention will be described with reference to the drawings. It should be understood that the present invention is not limited to the following embodiments, and changes, improvements, and the like of the design can be appropriately made based on ordinary knowledge of a person skilled in the art without departing from the spirit of the present invention.
As shown in
The biological electrode 1 can be suitably used for sensing electrical signals from a body of a subject, transmitting electrical stimulations to a subject, or both the sensing and transmiting described above, by contacting a plurality of electrode protrusions 22 of the electrode member 20 with a body of a subject. Specifically, for example, it can be used as a biological electrode 1 for a medical measuring instrument, a wearable measuring instrument, a health monitoring instrument, or the like. In particular, the biological electrode 1 can be suitably used when measuring electroencephalograms as electric signals.
The biological electrode 1 of the present embodiment further includes a support member 10 for supporting the electrode member 20. The support member 10 is made of an electrically insulating material. For example, the support member 10 may be formed of a silicone rubber or the like. In the biological electrode 1 of the present embodiment, the support member 10 is formed in a disk shape. The support member 10 has a support surface 10a for supporting the electrode member 20 and a rear surface 10b opposed to the support surface 10a. In addition, a through hole 10c that penetrates the support member 10 in the thickness direction (that is, penetrates from the support surface 10a to the rear surface 10b) is formed in the center part of the support member 10 (see, for example,
Note that the support member 10 only needs to have a configuration corresponding to the support surface 10a, the rear surface 10b, and the through hole 10c, and is not necessarily formed in a disk shape.
In the biological electrode 1, the electrode member 20 is made of, for example, a conductive rubber, and has, as described above, an electrode body 21 supported by the support member 10, and a plurality of electrode protrusions 22 protruding from the electrode body 21 on the side opposite to the support member 10. Examples of the conductive rubber include so-called conductive silicone rubbers containing silicone rubber and metal particles. Examples of the silicone rubber include a room temperature curable type liquid silicone rubber. Further, examples of the metal particles include silver particles. The room temperature curable type liquid silicone rubber is a silicone rubber that is in a liquid state or a paste state before curing, and that undergoes a curing reaction at 20° C. to 100° C. to become a rubber elastic body. The silver particles may include aggregated particles (aggregates) in which a plurality of silver particles (primary particles) are gathered and aggregated, and silver particles in a flake state.
The conductive rubber forming the electrode member 20 may include other conductive metal particles, carbon-based material particles (such as a carbon black and a carbon nanotube), or the like, instead of the silver particles, and may appropriately include a reinforcing material, a filler, various additives, and the like.
The electrode body 21 of the electrode member 20 preferably has a shape similar to that of the support member 10. That is, in the biological electrode 1 of the present embodiment, the electrode body 21 is formed in a disk shape. The electrode body 21 has a supported surface 21a supported by the support surface 10a of the support member 10 and an electrode protrusion forming surface 21b opposed to the supported surface 21a.
The plurality of electrode protrusions 22 are protruded on the electrode protrusion forming surface 21b of the electrode body 21. The plurality of electrode protrusions 22 are arranged on the outer peripheral part 29 of the electrode protrusion forming surface 21b so as to avoid the central part 28 of the electrode protrusion forming surface 21b of the electrode body 21.
In the biological electrode 1 of the present embodiment, the protrusion height h of each electrode protrusion 22 arranged on the outer peripheral part 29 of the electrode protrusion forming surface 21b as described above has a particularly main configuration. That is, in the biological electrode 1 of the present embodiment, the protrusion height h of each electrode protrusion 22 from a proximal end thereof to a distal end thereof in the direction perpendicular to the electrode protrusion forming surface 21b is 6 to 15 mm. Hereinafter, the protrusion height h of each electrode protrusion 22 from a proximal end thereof to a distal end thereof in a direction perpendicular to the electrode protrusion forming surface 21b may be simply referred to as a “protrusion height h of the electrode protrusion 22”.
In the biological electrode 1, since the electrode protrusions 22 having a protrusion height h of 6 to 15 mm are arranged only on the outer peripheral part 29 of the electrode protrusion forming surface 21b, the central part 28 of the electrode protrusion forming surface 21b surrounded by the electrode protrusions 22 is a space for housing the hair of the subject. The space in the central part 28 has a space height corresponding to the protrusion height h of the electrode protrusion 22, and the hair of the subject can be satisfactorily housed in the space. Therefore, the biological electrode 1 can realize good contact with the scalp of a subject, and the excessive pressing of the biological electrode 1 against the subject is not required, and the pain of the scalp at the time of measuring can be reduced. In particular, even in a subject having a large amount of hair, a subject having long hair (for example, a woman growing her hair), a subject having a large volume of hair (in other words, having thick hair), or the like, stable contacts with the scalp can be realized.
If the protrusion height h of the electrode protrusion 22 is less than 6 mm, the space height of the central part 28 of the electrode protrusion forming surface 21b is too low, and the hair of the subject may not be sufficiently housed in the space of the central part 28. For example, generally, the average hair thickness is 0.085 mm, and the number of hairs growing per unit area of the scalp of the subject is on the order of 208 hairs/cm2. Hereinafter, the number of hairs growing per unit area may be referred to as “density of hair (hairs/cm2)”.
As shown in
In a subject having thick hair and high hair density, the average hair thickness is about 0.150 mm, and the hair density is about 300 hairs/cm2. Then, according to the average hair thickness (mm) and the hair density (hairs/cm2) for such a subject, the number of hairs per unit length is 17 hairs/cm, the number of hairs in the linear line of the above range (5 mm) is 87, and when all the hair in the linear line up to the above range (5 mm) is overlapped, the hair bulk is 13 mm. Therefore, if the protrusion height h of the electrode protrusion 22 is secured to 15 mm, even in a subject having thick hair and high hair density, the hair can be satisfactorily housed in the space of the central part 28 surrounded by the electrode protrusions 22. Then, if the protrusion height h of the electrode protrusion 22 exceeds 15 mm, the protrusion height h of the electrode protrusion 22 becomes excessive, and the demoldability from the mold when the electrode protrusion 22 is molded and formed may deteriorate. In addition, from the viewpoint of reducing the size of the biological electrode 1, it is not preferable that the protrusion height h of the electrode protrusion 22 becomes excessive.
The arrangement of the plurality of electrode protrusions 22 in the outer peripheral part 29 of the electrode protrusion forming surface 21b is preferably circular with respect to the outer peripheral part 29 of the electrode protrusion forming surface 21b from the viewpoint of balancing. For example, each of the plurality of electrode protrusions 22 is preferably arranged so as to be located on the circumference of the virtual circle 25 on the outer peripheral part 29 of the electrode protrusion forming surface 21b. The virtual circle may be one virtual circle or a plurality of virtual concentric circles. However, the arrangement of the electrode protrusions 22 is not limited to the above-described arrangement, and for example, a shape drawn by connecting the points where a plurality of electrode protrusions 22 are arranged may be a triangle, a quadrangle, or the like.
The plurality of electrode protrusions 22 are preferably arranged at equal intervals on the outer peripheral part 29 of the electrode protrusion forming surface 21b. It should be noted that the distance between two adjacent electrode protrusions 22 is not necessary to be strictly equal, and may be substantially equal. Further, the arrangement of the electrode protrusion 22 is not limited to the above-described aspect, and may be, for example, such that, in the outer peripheral part 29 of the electrode protrusion forming surface 21b, all of the distances between two adjacent electrode protrusions 22 are not the same, and for example, they may have a constant arrangement pattern having two or more types of distances. Further, for example, a plurality of electrode protrusions 22 may be randomly arranged on the outer peripheral part 29 of the electrode protrusion forming surface 21b.
The number of the electrode protrusions 22 arranged on the outer peripheral part 29 of the electrode protrusion forming surface 21b is not particularly limited, and can be appropriately determined in accordance with the size of the electrode protrusion forming surface 21b and the like.
Further, the shapes of the electrode protrusion forming surface 21b are not particularly limited. The protrusions may be formed so as to protrude from the electrode protrusion forming surface 21b of the electrode body 21 so that the protrusion height h is 6 to 15 mm. Here, an example of the shape of the electrode protrusion forming surface 21b will be described with reference to an example of the electrode protrusion forming surface 21b in the biological electrode 1 shown in
As shown in the biological electrode 1 of
Each distal end of the plurality of electrode protrusions 22 is preferably formed in a hemispherical shape. In addition, each of the plurality of electrode protrusions 22 is preferably formed such that, when viewed from the arrangement center O of the plurality of electrode protrusions 22, the center of the distal end (also referred to as the center of the cross section of the distal end) C2 is located radially outward of the center C1 of the cross section of the proximal end. For example, such an electrode protrusion 22 has an obliquely conical shape with a rounded apex of the distal end. With this configuration, it is possible to secure a wider space of the central part 28 of the electrode protrusion forming surface 21b surrounded by the electrode protrusions 22.
In the biological electrode 1, the connector 30 is formed as a snap button type connector. More specifically, the connector 30 is formed as a male side connector in a snap button type connector. For example, as shown in
The first conductive member 40 and the second conductive member 50 are formed of stainless steel, for example. In the first conductive member 40, one end side is embedded in the electrode body 21 of the electrode member 20 and extends through the support member 10, and the other end side protrudes from the rear surface 10b of the support member 10. The second conductive member 50 is disposed on the rear surface 10b of the support member 10, in a state of being fitted to the other end side of the first conductive member 40. Then, the electrode member 20 of the biological electrode 1 is electrically connected to the outside by mounting (fitting) the female side connector (not shown) of the snap button type connector to the second conductive member 50. That is, the connector 30 is configured such that a part thereof is embedded in the electrode body 21 of the electrode member 20 and extends through the support member 10 to have a connecting part with the outside which is positioned on the rear surface 10b of the support member 10.
For example, the electrode member 20 of the biological electrode 1 is electrically connected to the measuring device by mouting (fitting) a female side connector attached to the distal end of a lead wire of the measuring device to the second conductive member 50. The measuring device is a device for inputting a biological signal detected by the plurality of electrode protrusions 22 of the electrode member 20 of the biological electrode 1, and processing, displaying, and analyzing the input biological signal. and is not particularly limited, but may be, for example, an electroencephalogram measuring device, a wearable information device, and a health monitoring device.
The first conductive member 40 and the second conductive member 50 will be specifically described with reference to
The first conductive member 40 includes a first bottomed cylindrical part 41 having an open end 41a at one end and a closed end 41b at the other end, and a first flange part 42 extending radially outward from the open end 41a of the first bottomed cylindrical part 41. The outer diameter of the first bottomed cylindrical part 41 is set to be substantially the same as the diameter of the through hole 10c of the support member 10. A fitting portion 43 recessed in the radial direction is formed in an area near the closed end 41b on the outer peripheral surface of the first bottomed cylindrical part 41. The first flange part 42 is slightly inclined so that the outer side in the radial direction is positioned closer to the closed end 41b of the first bottomed cylindrical part 41 than the inner side.
In the first conductive member 40, mainly a surface of the first flange part 42 opposite to the first bottomed cylindrical part 41 side is embedded in the electrode body 21 of the electrode member 20, the first bottomed cylindrical part 41 is inserted into the through hole 10c of the support member 10 (i.e., extends through the support member 10), and an area (including the fitting portion 43) of the first bottomed cylindrical part 41 on the closed end 41b side protrudes from the rear surface 10b of the support member 10. In the following, a surface of the first flange part 42 opposite to the first bottomed cylindrical part 41 is referred to as a “embedded surface”.
The second conductive member 50 includes a second bottomed cylindrical part 51 having an open end 51a at one end and a closed end 51b at the other end, and a second flange part 52 extending radially outward from the open end 51a of the second bottomed cylindrical part 51. The second bottomed cylindrical part 51 is formed so as to increase the inner diameter toward the closed end 51b from the open end 51a. The inner diameter of the open end 51a of the second bottomed cylindrical part 51 is set to be substantially the same as the outer diameter of the fitting portion 43 formed on the outer peripheral surface of the first bottomed cylindrical part 41 of the first conductive member 40. The side surface and the bottom surface of the second bottomed cylindrical part 51 are connected by a smooth curved surface. The second flange part 52 has an inclined part that is inclined so that the outer side in the radial direction is away from the closed end 51b of the second bottomed cylindrical part 51 than the inner side.
In the second conductive member 50, the open end 51a of the second bottomed cylindrical part 51 is fitted and fixed to the fitting portion 43 of the first bottomed cylindrical part 41 of the first conductive member 40, by caulking or the like, thereby, the connector 30 of the biological electrode 1 is formed.
Next, an example of the manufacturing method of the biological electrode 1 will be described. However, the manufacturing method of the biological electrode 1 is not limited to the following method. In the following description, it is assumed that the connector 30 is attached to the support member 10 in advance. Specifically, it is assumed that the first bottomed cylindrical part 41 of the first conductive member 40 is inserted into the through hole 10c of the support member 10 from the closed end 41b side, and the open end 51a of the second bottomed cylindrical part 51 of the second conductive member 50 is fitted to the fitting portion 43 of the first bottomed cylindrical part 41 of the first conductive member 40 protruding from the rear surface 10b of the support member 10, thereby, the assembly of the support member 10 and the connector 30 is formed in advance. Therefore, in the following manufacturing method, the connector 30 is treated as a member provided on the support member 10 side.
In manufacturing the biological electrode 1, first, a conductive rubber which is in a liquid state or a paste state and contains silicone rubber and metal particles is stirred, and the stirred conductive rubber is injected into a mold (cavity) having a shape of the electrode member 20. In this way, the conductive rubber is formed in the shape of the electrode member 20 in the mold.
Next, the support member 10 to which the connector 30 is attached, that is, the assembly of the support member 10 and the connector 30 is placed on the conductive rubber in the mold with the support surface 10a of the support member 10 facing downward. Thereby, the support surface 10a of the support member 10 is placed on an area corresponding to the supported surface 21a of the electrode body 21 of the conductive rubber formed in the shape of the electrode member 20. In addition, the embedded surface of the first flange part 42 of the first conductive member 40 is embedded in an area corresponding to the electrode body 21 of the conductive rubber formed in the shape of the electrode member 20.
Next, the conductive rubber formed in the shape of the electrode member 20 is crosslinked, with the assembly of the support member 10 and the connector 30 placed thereon. Thus, the conductive rubber formed in the shape of the electrode member 20 is cured, and the first conductive member 40 and the electrode member 20 are integrated. That is, the connector 30 and the electrode member 20 having the electrode body 21 are integrally molded. In this way, the support member 10, the electrode member 20, and the connector 30 are integrated. Thereafter, the integrated support member 10, the electrode member 20, and the connector 30 are removed from the mold and post-processing as needed to manufacture the biological electrode 1.
The biological electrode of the present invention can be used as a biological electrode for sensing electrical signals from a body of a subject, transmitting electrical stimulations to the subject, or both sensing and transmitting as described above, by contacting the body of the subject.
Number | Date | Country | Kind |
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2021-024067 | Feb 2021 | JP | national |
This application is a U.S. National Phase application under 35 U.S.C. 371 of International Application No. PCT/JP2022/003137, filed on Jan. 27, 2022, which claims priority to Japanese Patent Application No. 2021-024067, filed on Feb. 18, 2021. The entire disclosures of the above applications are expressly incorporated by reference herein.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2022/003137 | 1/27/2022 | WO |