KR20200108765A - Device using reversed electrodialysis and redox activity, and method for delivering drug using the same - Google Patents

Abstract

The present invention relates to a device using reverse electrodialysis and an oxidation-reduction reaction, and a method of delivering a drug using the same. The present invention relates to a base sheet, a first electrode pattern disposed in one area of the base sheet, a second electrode pattern disposed in another area of the base sheet and continuously connected to each other, the first electrode pattern, and the And a third electrode pattern disposed inside at least one of the second electrode patterns, and a battery unit having one end electrically connected to the first electrode pattern and the other end electrically connected to the second electrode pattern.

Description

Device using reversed electrodialysis and redox activity, and method for delivering drug using the same}

The present invention relates to an apparatus and a method, and more particularly, to an apparatus using reverse electrodialysis and an oxidation-reduction reaction, and a method of delivering a drug using the same.

In general, in the cosmetic field, a sheet mask pack is a product that can obtain moisturizing and cleansing effects by attaching a sheet type manufactured in the form of a face without the need to apply it by hand. It is available on the market in a variety of forms, such as a sheet divided into two sheets, and a sheet tailored to specific areas such as under the eyes, around the eyes and around the mouth.

In general, since a physiologically active substance is delivered topically transdermally, there is a limit to the delivery of useful substances to the skin. In order to deliver useful substances to the skin by using a mask pack, it is important to ensure that the mask pack adheres well to the skin. In addition, various attempts have been made to further enhance the cosmetic effect, and one of them is to use an iontophoresis device.

Iontophoresis is a drug delivery method that allows charged molecules to pass through tissues easily. Iontophoresis device is a technology that penetrates ionic substances into the skin using a direct current. In order to use the repulsive force acting between ions of the same polarity, ionic substances with positive characteristics are applied to the'+' electrode. The ionic material having negative characteristics is applied to the'-' electrode so that the ionic material can easily penetrate the skin. Unlike traditional transdermal administration methods in which drugs are passively absorbed, iontophoresis devices carry out active transport within an electric field.

An object of the present invention is to provide a device using reverse electrodialysis and an oxidation-reduction reaction that improves electrical stimulation or drug absorption and improves stability, and a method of delivering a drug using the same. However, these problems are exemplary, and the scope of the present invention is not limited thereby.

One aspect of the present invention includes a base sheet, a first electrode pattern disposed in one region of the base sheet and continuously connected to each other, and a second electrode pattern disposed in another region of the base sheet and continuously connected to each other. And, a third electrode pattern disposed inside at least one of the first electrode pattern and the second electrode pattern, and one end is electrically connected to the first electrode pattern, and the other end is electrically connected to the second electrode pattern. It provides an apparatus using reverse electrodialysis and an oxidation-reduction reaction including a battery unit connected to each other.

In addition, the battery unit is activated to transfer current to the first electrode pattern and the second electrode pattern, and an oxidation-reduction reaction is activated in the first electrode pattern and the third electrode pattern, or the second electrode pattern and An oxidation-reduction reaction may be activated in the third electrode pattern.

In addition, when the base sheet is dry, the oxidation-reduction reaction is not activated, and when the first activating solution is injected into the base sheet, the oxidation-reduction reaction may be activated.

In addition, the first activation solution contains a drug, and when the oxidation-reduction reaction is activated, the drug may be delivered to the subject.

In addition, the battery unit is a reversed electrodialysis (RED) battery, and when a second activating solution is injected into the battery unit, the battery unit may be activated.

In addition, a plurality of the first electrode patterns are arranged to be connected to each other in the one region of the base sheet, and a plurality of the second electrode patterns have a closed loop shape. A plurality of third electrode patterns may be disposed to be connected to each other in the other regions of the sheet, and may be spaced apart from the inside of the closed loop of the first electrode pattern or the second electrode pattern.

In addition, the first electrode pattern may be disposed on one surface of the base sheet, and the second electrode pattern may be disposed on one surface or the other surface of the base sheet.

In addition, the third electrode pattern may be disposed on the same surface as the first electrode pattern or the second electrode pattern, or may be disposed on a different surface of the base sheet.

In addition, at least one of the first electrode pattern, the second electrode pattern, and the third electrode pattern may be disposed inside the base sheet.

In addition, the first electrode pattern and the second electrode pattern may have the same shape.

In addition, the third electrode pattern includes a 3a electrode pattern disposed inside the first electrode pattern, and a thirdb electrode pattern having a polarity different from that of the 3a electrode pattern, and disposed inside the second electrode pattern. Can be equipped.

In addition, the first electrode pattern and the second electrode pattern may have a polygonal shape or a circular shape.

In addition, in the third electrode pattern, a plurality of electrode ends may be radially disposed.

In addition, it may further include a drug sheet that includes a drug therein and is attached to one surface of the base sheet to activate the first electrode pattern and the second electrode pattern.

In addition, a pouch having a first storage space for storing the base sheet, a second storage space for storing drugs injected into the base sheet, and a valve for selectively connecting the first storage space and the second storage space. It may further include.

Another aspect of the present invention includes the steps of attaching a drug sheet to an object, injecting a second activating solution into a device using reverse electrodialysis and oxidation-reduction reaction to activate the battery unit, and the base sheet to which the battery unit is attached. Attaching to the drug sheet; Including, the device using the reverse electrodialysis and oxidation-reduction reaction is arranged in one region of the base sheet, the first electrode pattern connected to each other continuously, and the base sheet A second electrode pattern disposed in another area and continuously connected to each other, and a third electrode pattern disposed inside at least one of the first electrode pattern and the second electrode pattern, and the reverse electrodialysis battery A portion is disposed on the base sheet, one end is electrically connected to the first electrode pattern, and the other end is electrically connected to the second electrode pattern. It provides a drug delivery method using reverse electrodialysis and an oxidation-reduction reaction.

In addition, when the base sheet is attached to the drug sheet, an oxidation-reduction reaction is activated in the first electrode pattern and the third electrode pattern, or an oxidation-reduction reaction is activated in the second electrode pattern and the third electrode pattern. When the second activating solution is injected into the battery unit, the reverse electrodialysis battery unit is activated so that current may be transferred to the first electrode pattern and the second electrode pattern.

In addition, the drug sheet includes a first activating solution, and when the first activating solution is absorbed by the base sheet and the oxidation-reduction reaction is activated, the drug may be delivered to the subject.

In addition, a plurality of the first electrode patterns are arranged to be connected to each other in the one region of the base sheet, and a plurality of the second electrode patterns have a closed loop shape. A plurality of third electrode patterns may be disposed to be connected to each other in the other regions of the sheet, and may be spaced apart from the inside of the closed loop of the first electrode pattern or the second electrode pattern.

An apparatus using reverse electrodialysis and an oxidation-reduction reaction according to an embodiment of the present invention and a method of delivering a drug using the same are provided by the electric current supplied from the battery unit and the potential difference generated by the oxidation-reduction reaction. Electrical stimulation may be generated in the skin EP, and the drug may be delivered to the skin EP of the subject.

An apparatus using reverse electrodialysis and an oxidation-reduction reaction according to an embodiment of the present invention and a method of delivering a drug using the same, are supplied with a relatively high level of current from the battery part, and the oxidation-reduction reaction of the electrode pattern Thus, a relatively low level of current can be supplied. Since various levels of electric current are supplied, electric stimulation of various strengths can be provided to the object and various kinds of drugs can be delivered to the skin of the object.

In the device using reverse electrodialysis and oxidation-reduction reaction according to an embodiment of the present invention and a method of delivering a drug using the same, a potential difference is continuously generated by the arrangement of the electrode pattern, so that the drug is delivered to the subject for a long time. Or electrical stimulation. Since the first electrode pattern and the second electrode pattern are each continuously disposed, and the third electrode pattern is disposed inside the first electrode pattern or the second electrode pattern, it is between the first electrode pattern and the third electrode pattern or the second electrode. Even if an oxidation-reduction reaction is generated between the pattern and the third electrode pattern, a potential difference may be generated again.

The device using reverse electrodialysis and oxidation-reduction reaction according to an embodiment of the present invention and a method of delivering a drug using the same can be safely activated. When the base sheet is in a dry state, the oxidation-reduction reaction is not activated in the electrode pattern, but when the first activating solution is injected into the base sheet, the oxidation-reduction reaction is activated to generate a potential difference. In addition, the reverse electrodialysis battery unit is not activated in a dry state, but when the second activation solution is injected into the chamber, a current is generated. Therefore, the user can use the activation solution safely and quickly.

1 is a diagram showing an apparatus using reverse electrodialysis and an oxidation-reduction reaction according to an embodiment of the present invention.
FIG. 2 is an enlarged view showing an enlarged partial area of FIG. 1.
3 is a diagram showing a cross section in which the device using reverse electrodialysis and oxidation-reduction reaction of FIG. 1 is activated.
4 is a cross-sectional view showing the reverse electrodialysis battery unit of FIG. 1.
5A to 5E are views showing a modified example of the apparatus using reverse electrodialysis and oxidation-reduction reaction of FIG. 1.
6A to 6C are diagrams showing a modified example of the apparatus using the reverse electrodialysis and oxidation-reduction reaction of FIG. 1.
7 is a cross-sectional view showing an apparatus using reverse electrodialysis and oxidation-reduction reaction according to another embodiment of the present invention.
8 is a cross-sectional view showing an apparatus using reverse electrodialysis and an oxidation-reduction reaction according to another embodiment of the present invention.
9 is an enlarged view showing a partial area of FIG. 8 on an enlarged scale.
10 is a cross-sectional view showing an apparatus using reverse electrodialysis and an oxidation-reduction reaction according to another embodiment of the present invention.
11 is an enlarged view showing a partial area of FIG. 10 on an enlarged scale.
12 is a cross-sectional view showing an apparatus using reverse electrodialysis and an oxidation-reduction reaction according to another embodiment of the present invention.
FIG. 13 is a graph showing a potential difference generated when the first electrode pattern and the second electrode pattern of FIG. 9 are activated.
14 is a flow chart illustrating a drug delivery method using reverse electrodialysis and oxidation-reduction reaction according to another embodiment of the present invention.

Since the present invention can apply various transformations and have various embodiments, specific embodiments are illustrated in the drawings and will be described in detail in the detailed description. Effects and features of the present invention, and a method of achieving them will be apparent with reference to the embodiments described later in detail together with the drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various forms.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, and when describing with reference to the drawings, the same or corresponding constituent elements are assigned the same reference numerals, and redundant descriptions thereof will be omitted. .

In the following embodiments, terms such as first and second are not used in a limiting meaning, but are used for the purpose of distinguishing one component from another component.

In the following examples, the singular expression includes the plural expression unless the context clearly indicates otherwise.

In the following embodiments, terms such as include or have means that the features or elements described in the specification are present, and do not preclude the possibility of adding one or more other features or elements in advance.

In the following embodiments, when a part such as a film, a region, or a component is on or on another part, not only the case directly above the other part, but also another film, region, component, etc. are interposed therebetween. This includes cases where there is.

In the drawings, components may be exaggerated or reduced in size for convenience of description. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of description, and the present invention is not necessarily limited to what is shown.

1 is a view showing an apparatus 100 using reverse electrodialysis and an oxidation-reduction reaction according to an embodiment of the present invention, and FIG. 2 is an enlarged view showing a partial area of FIG. 1, and FIG. 3 Is a diagram showing a cross section in which the device 100 using reverse electrodialysis and oxidation-reduction reaction of FIG. 1 is activated.

1 to 3, an apparatus 100 using reverse electrodialysis and an oxidation-reduction reaction is an apparatus using a current supplied from a battery unit and a current generated in an oxidation-reduction reaction. In the apparatus 100 using reverse electrodialysis and oxidation-reduction reaction, when the battery unit is activated, a relatively high level electric field (HLEF) is formed or a relatively high level micro-current is generated. ; HLMC) is a device that is formed. The device 100 using reverse electrodialysis and an oxidation-reduction reaction may deliver a drug to an object by using electric energy generated from a reverse electrodialysis battery.

In addition, the device 100 using reverse electrodialysis and oxidation-reduction reaction forms a relatively low level electric field (LLEF) when the oxidation-reduction reaction is activated, or a relatively low level of microcurrent ( It is a device that forms a low level micro-current (LLMC). The device 100 using reverse electrodialysis and an oxidation-reduction reaction may deliver a drug to a subject using electrical energy generated by an oxidation reaction and a reduction reaction of a galvanic cell.

Hereinafter, "activation" is defined as the current is supplied to the device 100 using reverse electrodialysis and oxidation-reduction reaction. Specifically, "activation of the battery part" is defined as the current supplied from the battery part of the apparatus 100 using reverse electrodialysis and oxidation-reduction reaction. In addition, "activation of an oxidation-reduction reaction" is defined as generating an oxidation-reduction reaction in the electrode pattern.

Hereinafter, the "first activation solution" is defined as a solution capable of activating an oxidation-reduction reaction in the apparatus 100 using reverse electrodialysis and an oxidation-reduction reaction. In one embodiment, the first activation solution may be a drug, and in another embodiment, a drug and an added solution may be used.

Hereinafter, the "second activation solution" is defined as a solution that drives the battery part in order to receive current from the battery part in the apparatus 100 using reverse electrodialysis and oxidation-reduction reaction.

Hereinafter, a device 100 using reverse electrodialysis and an oxidation-reduction reaction is attached to the object, and a drug is delivered using an electrical reaction or an electrical stimulation is applied to the skin. For example, the skin of an animal or human I can.

The device 100 using reverse electrodialysis and an oxidation-reduction reaction is attached to an object and can deliver a drug to the object upon activation. In addition, the device 100 using reverse electrodialysis and an oxidation-reduction reaction may increase the absorption rate of drugs by electrically stimulating the skin of an object, improve blood circulation, and amplify protein synthesis. In addition, the device 100 using reverse electrodialysis and oxidation-reduction reactions is attached to a wound of an object, so that the regeneration speed of the affected area may be improved by electrical stimulation.

In the following drawings, ions move to the base sheet and electrons move to the skin EP of an object, but embodiments of the present invention are not limited thereto. Since both the active base sheet and the skin EP have electrical conductivity, ions may move to the base sheet and/or the skin EP, and electrons may move to the base sheet and/or the skin EP. In addition, ions and electrons may move in opposite directions in either of the base sheet and the skin EP. However, hereinafter, for convenience of explanation, an embodiment in which ions move to the base sheet and the former move to the skin EP of an object will be described.

The apparatus 100 using reverse electrodialysis and oxidation-reduction reaction may include a base sheet 110, a first electrode pattern 120, a second electrode pattern 130, and a third electrode pattern 140.

The base sheet 110 may be formed of a sheet having a predetermined thickness formed to be attached to the skin of an object. One side of the base sheet 110 is in close contact with the user's skin, and the other side is exposed to the outside.

The base sheet 110 may have various sizes and shapes depending on the location of the object to which the device 100 using reverse electrodialysis and oxidation-reduction reaction is attached. For example, if the device 100 using reverse electrodialysis and oxidation-reduction reaction is used as a mask pack, the base sheet 110 may have openings corresponding to eyes and mouths, and may have incision lines. In another embodiment, if the device 100 using reverse electrodialysis and oxidation-reduction reaction is used as a medical patch, the base sheet may be a polygonal or circular shape depending on the shape of a portion requiring electrical stimulation or drug delivery. It can be formed as However, in the following description, for convenience of description, the case where the base sheet 110 has a shape of a mask pack will be mainly described.

The base sheet 110 may be formed of a material having biocompatibility. Since the base sheet 110 maintains contact with the skin of the object, it may be formed of a safe material having biocompatibility.

The base sheet 110 is stored in a dry state when the device 100 using reverse electrodialysis and oxidation-reduction reaction is not used, and is kept in a wet state when the device 100 using reverse electrodialysis and oxidation-reduction reaction is used. It is activated. The base sheet 110 is wetted by the first activation solution, and may be formed of a material that can be kept wet for a certain period of time. For example, the base sheet 110 may be formed of a woven material or a non-woven material. The base sheet 110 may mean a general sheet for use as a conventional mask pack or medical band.

The base sheet 110 may be formed of a flexible material, and may be deformed in shape while being attached to the skin of an object. The base sheet 110 may be formed of a material that can be deformed in shape by an external force applied by a user.

The base sheet 110 is preferably made of a material that is deformed by an external force and has a resilience, and, for example, a polymer such as natural rubber, polyisoprene, polysilmoxine, polybutadiene, and polyacrylamide. Polyvinyl alcohol, polyacrylic acid, polyethylene, polypropylene and copolymers thereof, polyester, fluororesin, polyvinylpyrrolidone and carboxyvinyl polymer, polyacrylic acid and copolymers thereof, polyhydroxymethyl cellulose (poly (hydroxyl methyl cellulose)), poly(hydroxyl alkylmethacrylate) and copolymers thereof, polyethylene glycol (poly(ethylene glycoloxide)) and copolymers thereof, polyethylene glycol-polycaprolactone multiple Block copolymers, polycaprolactone and copolymers thereof, polylactide and copolymers thereof, polyglycolide and copolymers thereof, poly(methyl methacrylate) and It may be made of a copolymer thereof, polystyrene, polydimethylsiloxane (PDMS), a copolymer thereof, and a combination thereof.

The base sheet 110 may be divided into a first region S1 that is one region and a second region S2 that is another region according to the arrangement of the electrode patterns. The first area S1 is an area where the first electrode pattern 120 is disposed, and the second area S2 is an area where the second electrode pattern 130 is disposed. The first region S1 and the second region S2 may be variously disposed according to the arrangement of the electrode pattern. The separation area 111 may be disposed between the first area S1 and the second area S2 to separate the first area S1 and the second area S2.

The first electrode pattern 120 is disposed in the first region S1 of the base sheet 110 and may be connected to each other continuously. The first electrode pattern 120 may have a closed loop shape. In FIG. 2, each of the first electrode patterns 120 has a hexagonal closed loop shape that is continuously connected, and is connected to other first electrode patterns 120 adjacent to each other.

In an embodiment, as shown in FIG. 1, a plurality of first electrode patterns 120 may be disposed over the entire first region S1 of the base sheet 110. When the oxidation-reduction reaction is generated in the first electrode pattern 120 and the third electrode pattern 141, the device 100 using reverse electrodialysis and the oxidation-reduction reaction is performed in the first region of the base sheet 110 ( Throughout S1), electrical stimulation and drug delivery can be performed to the skin of the subject.

In another embodiment, a plurality of first electrode patterns 120 may be disposed only in a partial area of the first area S1. An oxidation-reduction reaction is generated in the first electrode pattern 120 and the 3a electrode pattern 141, and the device 100 using reverse electrodialysis and oxidation-reduction reaction is applied only to a local portion of the base sheet 110. Electrical stimulation and drug delivery can be performed on the skin.

In another embodiment, one of the first electrode patterns 120 may be disposed in the first region S1 of the base sheet 110. A number of first electrode patterns 120 may be disposed in the first region S1 of the base sheet 110, and the 3a electrode patterns 141 may be disposed therein. An oxidation-reduction reaction is generated in the first electrode pattern 120 and the 3a electrode pattern 141, and the device 100 using reverse electrodialysis and oxidation-reduction reaction is performed in a partial area of the base sheet 110. Electrical stimulation and drug delivery can be performed on the skin.

The second electrode patterns 130 are disposed in the second region S2 of the base sheet 110 and may be connected to each other continuously. The second electrode pattern 130 may have a closed loop shape. In one embodiment, as shown in FIG. 2, the second electrode pattern 130 may have the same shape as the first electrode pattern 120. Each of the second electrode patterns 130 has a hexagonal closed loop shape that is continuously connected, and is connected to other second electrode patterns 130 adjacent to each other.

In one embodiment, as shown in FIG. 1, a plurality of second electrode patterns 130 may be disposed over the entire second region S2 of the base sheet 110. When the oxidation-reduction reaction is generated in the second electrode pattern 130 and the third electrode pattern 140, the apparatus 100 using reverse electrodialysis and the oxidation-reduction reaction is performed in the second region (S2) of the base sheet 110. ), it is possible to perform electrical stimulation and drug delivery to the skin of the subject.

In another embodiment, a plurality of second electrode patterns 130 may be disposed only in a partial area of the second area S2. An oxidation-reduction reaction is generated in the second electrode pattern 130 and the 3b electrode pattern 142, and the device 100 using reverse electrodialysis and oxidation-reduction reaction is applied to only a local portion of the base sheet 110. Electrical stimulation and drug delivery can be performed on the skin.

In another embodiment, one of the second electrode patterns 130 may be disposed in the second region S2 of the base sheet 110. A number of second electrode patterns 130 may be disposed in the second region S2 of the base sheet 110, and the 3b electrode patterns 142 may be disposed therein. An oxidation-reduction reaction is generated in the second electrode pattern 130 and the 3b electrode pattern 142, and the device 100 using reverse electrodialysis and oxidation-reduction reaction is performed in a partial area of the base sheet 110. Electrical stimulation and drug delivery can be performed on the skin.

The third electrode pattern 140 may be disposed inside at least one of the first electrode pattern 120 and the second electrode pattern 130. A plurality of third electrode patterns 140 may be spaced apart from the inside of the closed loop of the first electrode pattern 120 or the second electrode pattern 130.

The third electrode pattern 140 may have a shape corresponding to the first electrode pattern 120 or the second electrode pattern 130 in FIG. 2. For example, the third electrode pattern 140 may also have a hexagonal closed loop shape like the first electrode pattern 120 and the second electrode pattern 130.

The third electrode pattern 140 has a 3a electrode pattern 141 disposed inside the first electrode pattern 120 and a 3b electrode pattern 142 disposed inside the second electrode pattern 130. I can. The 3a electrode pattern 141 is disposed in the first region S1 and the thirdb electrode pattern 142 is disposed in the second region S2, so that the 3a electrode pattern 141 and the 3b electrode pattern 142 ) Can be arranged spaced apart from each other.

The 3a electrode pattern 141 and the 3b electrode pattern 142 may have different polarities. The 3a electrode pattern 141 has a polarity different from that of the first electrode pattern 120, and the 3b electrode pattern 142 has a polarity different from that of the second electrode pattern 130. Since the first electrode pattern 120 and the second electrode pattern 130 have different polarities, the 3a electrode pattern 141 and the 3b electrode pattern 142 also have different polarities.

The third electrode pattern 140 is disposed to be spaced apart from each other differently from the first electrode pattern 120 and the second electrode pattern 130. The 3a electrode pattern 141 is not connected to the first electrode pattern 120 and is disposed within the first electrode pattern 120 while being spaced apart at a predetermined interval. The 3b electrode pattern 142 is not connected to the second electrode pattern 130 and is disposed inside the second electrode pattern 130 while being spaced apart at a predetermined interval.

The oxidation-reduction reaction may be activated in the first electrode pattern 120 and the third electrode pattern 140, or the oxidation-reduction reaction may be activated in the second electrode pattern 130 and the third electrode pattern 140.

The oxidation-reduction reaction is activated in the first electrode pattern 120 and the 3a electrode pattern 141, and at this time, the first electrode pattern 120 and the 3a electrode pattern 141 are activated with different polarities. In addition, as shown in FIG. 3, the first electrode pattern 120 and the 3a electrode pattern 141 are disposed on one surface of the base sheet 110 to contact the skin EP of the object. Since the first electrode pattern 120 and the third electrode pattern 141 are in contact with the skin EP, electrical stimulation may be effectively generated on the skin EP.

The 3a electrode patterns 141 are arranged in a number corresponding to the first electrode pattern 120. Since the 3a electrode pattern 141 is disposed inside the first electrode pattern 120, it may be preferably disposed equal to the number of the first electrode patterns 120.

The oxidation-reduction reaction is activated in the second electrode pattern 130 and the 3b electrode pattern 142, and at this time, the second electrode pattern 130 and the 3b electrode pattern 142 are activated with different polarities. In addition, as shown in FIG. 3, the second electrode pattern 130 and the 3b electrode pattern 142 may be disposed on one surface of the base sheet 110 to contact the skin EP of the object. Since the second electrode pattern 130 and the 3b electrode pattern 142 are in contact with the skin EP, electrical stimulation can be effectively generated on the skin EP.

The 3b electrode patterns 142 are arranged in a number corresponding to the second electrode pattern 130. Since the 3b electrode pattern 142 is disposed inside the second electrode pattern 130, it may be preferably disposed equal to the number of the second electrode patterns 130.

The first electrode pattern 120 and the second electrode pattern 130 are printed on at least one surface of the base sheet 110. The first electrode pattern 120 is printed to be continuous with each other in the first region S1 of the base sheet 110, and the second electrode pattern 130 is continuous with each other in the second region S2 of the base sheet 110. Is printed to do.

The first electrode pattern 120 and the third electrode pattern 140 may generate electromotive force with a galvanic battery, and the second electrode pattern 130 and the third electrode pattern 140 may also generate electromotive force with a galvanic battery. have. The first electrode pattern 120, the second electrode pattern 130, and the third electrode pattern 140 are not limited to a specific material, and may be formed of various materials capable of generating a potential difference. For example, the first electrode pattern 120, the second electrode pattern 130 and the third electrode pattern 140 are zinc-silver, zinc-silver oxide, zinc-silver halide, zinc-silver chloride, zinc-silver bromide, zinc-silver iodide, and Zinc-silver fluoride includes, but is not limited to.

One end of the battery unit 150 may be electrically connected to the first electrode pattern 120 and the other end may be electrically connected to the second electrode pattern 130. The battery unit 150 is activated so that current can be transferred to the first electrode pattern 120 and the second electrode pattern 130. The battery unit 150 is installed in the separation area 111 of the base sheet 110, is electrically connected to the first electrode pattern 120 and the second electrode pattern 130, and when activated, the first electrode pattern 120 ) And the second electrode pattern 130 have different polarities.

In one embodiment, the battery unit 150 is not limited to a specific battery, and various batteries capable of generating current may be used. For example, the battery unit may include a reverse electrodialysis battery, a primary battery, or a secondary battery, and in detail, a flexible battery, an alkaline battery, a dry cell, a mercury battery, a lithium battery, a nickel-cadmium battery , A nickel-hydrogen battery, a lithium ion secondary battery, and a lithium ion polymer secondary battery. In another embodiment, the battery unit 150 may preferably be a reverse cell dialysis cell. However, in the following description, for convenience of explanation, the case where the battery unit 150 is a reverse electrodialysis battery will be mainly described.

4 is a cross-sectional view illustrating the reverse electrodialysis battery unit 150 of FIG. 1.

4, the reverse electrodialysis battery unit 150 includes a cation exchange membrane 151, an anion exchange membrane 152, a cathode 153, an anode 154, a first chamber C1 and a second chamber C2. Includes. In addition, the reverse electrodialysis battery unit 150 is connected to the negative electrode 153 and the positive electrode 154 by the connection part 156 of the intermediate sheet 155, respectively.

The cathode 153 and the anode 154 may include conductive materials, for example, silver, silver epoxy, palladium, copper, aluminum, gold, titanium, palladium, chromium, nickel, platinum, silver/silver chloride, It may be silver/silver ions, or mercury/mercury oxide.

The cation exchange membrane 151 and the anion exchange membrane 152 are disposed to be spaced apart, and the spaces generated by the separation become a first chamber C1 and a second chamber C2. That is, the first chamber C1 and the second chamber C2 are defined by the cation exchange membrane 151 and the anion exchange membrane 152.

Cations (Na+) in the first chamber C1 containing the electrolyte at a high concentration pass through the cation exchange membrane 151 and move to the second chamber C2 containing the electrolyte at a low concentration. According to a similar principle, the anions Cl- in the first chamber C1 containing the electrolyte at a high concentration pass through the anion exchange membrane 112 and move to the second chamber C2 containing the electrolyte at a low concentration. The movement of ions occurs in the cation exchange membrane 151, the anion exchange membrane 112, the first chamber C1 and the second chamber C2. By using the movement of these ions as electromotive force, in the cathode 153 in order to compensate for the relatively insufficient cations, an oxidation reaction occurs to produce electrons, and in the anode 154 to compensate for the relatively insufficient anions, a reduction reaction is performed. It wakes up and consumes electrons. Accordingly, the reverse electrodialysis battery unit 150 generates an ionic current and outputs the current.

In the present specification, "Reversed ElectroDialysis (RED)" may refer to a salinity gradient energy resulting from a difference in salt concentration between two solutions. In one embodiment, reverse electrodialysis may mean a phenomenon in which a current flows through the first electrode pattern 120 and the second electrode pattern 130. Therefore, the reverse electrodialysis battery unit 150 may mean a device that generates current using reverse electrodialysis. The reverse electrodialysis battery unit 150 may generate a current by a difference in ion concentration of an electrolyte in a solution between a high concentration electrolyte solution and a low concentration electrolyte solution.

In the present specification, "electrolyte" may mean a material dissolved in a solvent such as water and dissociated into ions to allow current to flow, and the electrolyte solution may mean a solution such as water in which an electrolyte is dissolved. The electrolyte may be included in an electrolyte solution. The reverse electrodialysis battery unit 150 generates a current through a difference between a high concentration electrolyte solution and a low concentration electrolyte solution, and the amount of the electrolyte in the first chamber C1 in which the electrolyte is contained in a high concentration is the amount of the electrolyte contained in the low concentration. It may be higher than the amount of the electrolyte in the second chamber (C2). The second chamber C2 in which the electrolyte is contained in a low concentration may include one that does not contain an electrolyte. For example, the electrolyte is contained in an electrolyte solution, and the first chamber (C1) in which the electrolyte is contained at a high concentration is about 0.1 to about 20 mol/L, about 0.5 to about 15 mol/L, about 0.7 to about 10 mol/L, about 1.0 to about 8.0 mol/L, about 1.0 to about 2.0 mol/L, or about 1.2 to about 1.8 mol/L of an ionic concentration of an electrolyte solution, wherein the electrolyte is contained in a low concentration. The two-chamber C2 does not contain an electrolyte, or about 0.005 to about 10 mol/L, about 0.005 to about 8 mol/L, about 0.01 to about 6 mol/L, about 0.05 to about 6.0 mol/L, about 0.1 To about 4.0 mol/L, or about 0.1 to about 2.0 mol/L, and the ion concentration of the electrolyte solution in the first chamber C1 in which the electrolyte is contained in a high concentration is a low concentration of the electrolyte. It may be higher than the ion concentration of the electrolyte solution in the second chamber 4 included as.

In another embodiment, the first chamber C1 and the second chamber C2 may include an electrolyte paste. The electrolyte paste may include a water-soluble polymer binder and an electrolyte. The water-soluble polymer binder is, for example, selected from the group consisting of cellulose-based resin, xanthan gum, polyvinylpyrrolidone, polyvinyl alcohol, water-soluble (meth)acrylic resin, polyether-polyol, and polyetherurea-polyurethane. There can be more than one. By mixing the water-soluble polymer binder and the electrolyte to prepare an electrolyte paste, a chamber containing the electrolyte paste may be manufactured. When the electrolyte paste is applied, the internal resistance of the reverse electrodialysis battery unit 150 can be lowered and the fluidity of the electrolyte in the chamber can be improved.

In yet another embodiment, the first chamber C1 and the second chamber C2 may contain hydrogels containing an electrolyte. For example, the first chamber C1 containing the electrolyte at a high concentration contains a solid material containing a high concentration electrolyte or a hydrogel containing the high concentration electrolyte, or a second chamber containing the electrolyte at a low concentration (C2) may be empty or containing a solid material containing a low-concentration electrolyte or a hydrogel containing a low-concentration electrolyte. When the solid material or hydrogel is included, for example, when salt (NaCl) in a solid state is included, when water flows into the chamber, the solid material or hydrogel is dissolved in water to form an aqueous electrolyte solution. By forming a flow of ions can occur. The solid substance or hydrogel may be used without limitation as long as it has water-soluble or ionic permeability, and has appropriate mechanical properties. Examples of the solid material or hydrogel include agar, polyethylene glycol diacrylate (PEGDA), poly(2-hydroxyethyl methacrylate) (PHEMA), alginic acid, such as sodium alginate, calcium alginate, or potassium alginate. can do. In addition, the solid material or hydrogel may include a solid powder formulation of an ionic binding material.

The first chamber C1 and the second chamber C2 may be made of a woven or non-woven fabric capable of absorbing an aqueous solution. For example, the non-woven fabric can be a non-woven fabric. When the first chamber C1 and the second chamber C2 are made of a fabric capable of absorbing an aqueous solution, the electrolyte may be included in the chamber in the form of a powder. In the case where the electrolyte is present in the form of a powder on the fabric, when the second activating solution, for example, water is introduced into the chamber, the electrolyte is dissolved in water to form an aqueous electrolyte solution, whereby ions may flow. Further, the first chamber C1 and the second chamber C2 may be fabric or non-woven fabric impregnated with an electrolyte. The electrolyte-impregnated fabric or non-woven fabric may be prepared, for example, through a hot air rolling process after putting the nonwoven fabric in a NaCl solution. For example, the first chamber C1 containing an electrolyte at a high concentration may be prepared through a hot air rolling process after putting a fabric or non-woven fabric capable of absorbing an aqueous solution in a high concentration NaCl solution, and containing an electrolyte at a low concentration. The second chamber C2 may be manufactured through a hot air rolling process after putting a woven or non-woven fabric capable of absorbing an aqueous solution in a low NaCl concentration solution. In addition, the second chamber C2 containing the electrolyte at a low concentration may be composed of a woven or non-woven fabric capable of absorbing an aqueous solution without impregnating NaCl.

In the present specification, the "ion-exchange membrane" may mean a membrane having a strong tendency to pass through either cations or anions. The ion exchange membrane may be a synthetic resin, for example, the synthetic resin may be crosslinked. Since the cation exchange membrane 151 has a negative charge, ions having a negative charge can pass through the ions having a positive charge without repelling and passing through the ions, and may be, for example, the cation exchange membrane 151 having a sulfone group. Conversely, since the anion exchange membrane 152 has a positive charge, ions having a positive charge can be repelled and pass through the ions having a negative charge without passing through, and for example, the anion exchange membrane 152 having a tetravalent ammonium may be used. The kind of monomer forming the cation exchange membrane 151 is a sulfonic acid-type monomer, for example, 2-(meth)acrylamide-2-methylpropanesulfonic acid (2-(meth)acrylamide-2-methylpropanesulfonic acid) , 3-sulfopropane (meth)acrylate, 10-sulfodecaine (meth)acrylate) and salts thereof; Carboxylic acid-type monomers such as 2-(meth)acryloylethylphthalic acid (2-(meth)acryloylethylphthalic acid), 2-(meth)acryloylethylsuccinic acid (2-(meth)acryloylethylsuccinic acid) , 2-(meth)acryloylethylmaleic acid, 2-(meth)acryloylethyl-2-hydroxyethylphthalic acid (2-(meth)acryloylethyl-2-hydroxyethylphthalic acid ), 11-(meth)acryloyloxydecyl-1,1-dicarboxylic acid (11-(meth)acryloyloxydecyl-1,1-dicarboxylic acid), and salts thereof; And sulfuric acid-type monomers such as 2-(meth)acryloyloxyethyl dihydrogenphosphate (2-(meth)acryloyloxyethyl dihydrogenphosphate), 2-(meth)acryloyloxyethyl phenyl hydrogenphosphate (2 -(meth)acryloyloxyethyl phenyl hydrogenphosphate), 10-(meth)acryloyloxydecyl dihydrogenphosphate (10-(meth)acryloyloxydecyl dihydrogenphosphate), 6-(meth)acryloyloxydecyl dihydrogenphosphate (6 -(meth)acryloyloxyhexyl dihydrogenphosphate), and salts thereof. The types of monomers forming the anion exchange membrane 152 are N,N-dimethylaminoethyl(meth)acrylate, N,N-diethylaminoethyl(meth)acrylate (N,N-diethylaminoethyl(meth)acrylate), N,N-dimethylaminoethyl (meth)acrylate/methyl chloride (N,N-dimethylaminoethyl(meth)acrylate/methyl chloride), and N,N-diethylamino It may include ethyl (meth) acrylate / methyl chloride (N,N-diethylaminoethyl (meth) acrylate / methyl chloride). The ion exchange capacity (IEC) of the cation exchange membrane 151 or the anion exchange membrane 152 is about 0.5 meg/g or more, or about 1.0 meg/g or more, for example, about 0.5 to about 20.0 meg/g. , About 1.0 to about 10.0 meg/g, about 2.0 to about 10.0 meg/g, and about 5.0 to about 10.0 meg/g. In addition, the permeation selectivity of the cation exchange membrane 151 or the anion exchange membrane 152 is about 70% or about 80% or more, for example, about 80 to about 100%, about 90 to about 100%, or about 95 to about 100 It can be %.

In another embodiment, the reverse electrodialysis battery unit 150 may further include a spacer (not shown) for separating the cation exchange membrane 151 and the anion exchange membrane 152. The spacer may be substantially the same as the first chamber C1 and the second chamber C2 accommodating the electrolyte. The spacer may serve to prevent the ion exchange membranes from sticking, and may include, for example, a mesh made of polypropylene or polyethylone, a sponge, an adhesive tape, or a fabric, for example, a cloth, a nonwoven fabric, and the like. I can. In addition, the spacer may serve as a support for supporting the cation and anion exchange membrane 152 and the first chamber C1 and the second chamber C2.

In another embodiment, the reverse electrodialysis battery unit 150 may further include a container for accommodating the first chamber C1 and the second chamber C2. The container may be configured to include a hole in order to administer a second activation solution for activating the reverse electrodialysis battery unit 150 or to expose a part of the reverse electrodialysis battery unit 150.

The intermediate sheet 155 may be configured to allow the current generated from the battery unit 150 to flow to the base sheet 110. The intermediate intermediate sheet 155 partially includes an insulating portion, and the current generated from the negative electrode 153 and the positive electrode 154 of the reverse electrodialysis battery unit 150 by the insulating portion of the intermediate intermediate sheet 155 It may not be electrically connected. For example, the intermediate sheet 155 may be partially coated or printed with a mesh structure including a conductive material to form a circuit. The circuit may form two separate circuits, one circuit connected to the positive electrode and the other connected to the negative electrode.

The intermediate media sheet 155 may at least partially contain a conductive material, be coated with a conductive material, or be composed of a conductive fabric (woven) or a conductive non-woven fabric (e.g., non-woven fabric). have. In addition, for example, the intermediate media sheet 155 may be in a dry form.

Materials of the intermediate media sheet 155 are synthetic resins, such as acrylic resin, urethane resin, silicone resin, styrene resin, aniline resin, amino resin, aminoalkyd resin, vinyl acetate resin, alkyd resin, epoxy resin, toluene. Resin, or a combination thereof. The conductive material may be selected from the group consisting of carbon, gold, silver, aluminum, copper, SUS (Steel Use Stainless), and combinations thereof.

As the conductive material, any one paste selected from the group consisting of carbon paste, gold paste, silver paste, aluminum paste, copper paste, SUS paste, and combinations thereof may be used. The coating or printing of the conductive material may be coated by a method that is apparent to those skilled in the art, and may be coated by, for example, a method such as gravure printing, offset printing, digital printing, or transfer. One of ordinary skill in the art can determine the appropriate manner and amount of paste to be printed on the intermediate intermediate sheet to obtain the desired conductivity value.

The intermediate sheet 155 may further include a connection part 156 for electrically connected to the reverse electrodialysis battery part 150. In one embodiment, the intermediate sheet 155 may play a role of allowing the current generated from the reverse electrodialysis battery unit 150 to flow to the base sheet 110.

The reverse electrodialysis battery unit 150 may be activated when the second activating solution is injected. When the second activating solution is injected into the first chamber C1 and the second chamber C2, the flow of ions is generated in the first chamber C1 and the second chamber C2, and the reverse electrodialysis battery unit 150 ), a current is generated.

Referring again to FIGS. 2 and 3, in the apparatus 100 using reverse electrodialysis and oxidation-reduction reaction, electric stimulation is applied to the object by the current supplied from the battery unit and the current generated by the oxidation-reduction reaction, The drug delivery is described below.

<Supplying current by oxidation-reduction reaction>

When the base sheet 110 is dried, the first electrode pattern 120, the second electrode pattern 130, and the third electrode pattern 140 are not activated. When the first activating solution is injected into the base sheet 110, the oxidation-reduction reaction is activated in the first region S1 and the second region S2 of the base sheet 110, respectively.

Looking at the first region S1, an oxidation-reduction reaction is generated in the first electrode pattern 120 and the third electrode pattern 141. The first electrode pattern 120 is a cathode electrode, and the 3a electrode pattern 141 is an anode electrode. If silver chloride (AgCl) is used as the cathode electrode and zinc is used as the anode electrode, the oxidation-reduction reaction is generated as follows.

_{(Cathode): AgCl (s) + e} - -> Ag (s) + Cl - (aq)

_{(Anode): Zn (s) ->} Zn 2+ (S) + 2e -

Electrons generated from the 3a electrode pattern 141 move to the first electrode pattern 120, and chloride ions generated from the first electrode pattern 120 move to the 3a electrode pattern 141.

Looking at the second region S2, an oxidation-reduction reaction is generated in the second electrode pattern 130 and the third electrode pattern 142. The second electrode pattern 130 is an anode electrode, and the 3a electrode pattern 141 is a cathode electrode. If silver chloride (AgCl) is used as the cathode electrode and zinc is used as the anode electrode, the oxidation-reduction reaction is generated as follows.

_{(Cathode): AgCl (s) + e} - -> Ag (s) + Cl - (aq)

_{(Anode): Zn (s) ->} Zn 2+ (S) + 2e -

Electrons generated from the second electrode pattern 130 move to the 3b electrode pattern 142, and chloride ions generated from the 3b electrode pattern 142 move to the second electrode pattern 130.

In addition, electrons are introduced into the first region S1 by the reverse electrodialysis battery unit 150, and electrons are discharged from the second region S2. By the reverse electrodialysis battery unit 150, the first region S1 may supply a source current to the source region, and the second region S2 may supply a sink current to the sink region.

When a drug is stored in the base sheet 110 and the first activating solution is injected, an oxidation-reduction reaction is activated in the first region S1 and the second region S2, respectively, so that the drug D becomes the base. It may be transferred from the sheet 110 to the skin EP of the object. In addition, even when the first activating solution contains the drug (D), when the oxidation-reduction reaction is activated in the first region (S1) and the second region (S2), the drug (D) is transferred from the base sheet 110 to the object. It can be transmitted to the skin (EP) of the person.

The first activation solution is defined as a solution capable of generating an oxidation-reduction reaction by being injected into the base sheet 110. The first activation solution may be variously set according to the purpose of the device 100 using reverse electrodialysis and oxidation-reduction reaction. When used for drug delivery, the activation solution may contain medical drugs, cosmetic drugs, drugs that stimulate intracellular proteins, drugs that stimulate intracellular DNA synthesis, and the like. In addition, when used to generate electrical stimulation in the affected area, an electrolyte for generating an oxidation-reduction reaction may be included.

When the oxidation-reduction reaction is activated by the first activation solution, the first electrode pattern 120 and the third electrode pattern 141 have polarities, respectively, and the second electrode pattern 130 and the third electrode pattern 142 Since silver has different polarities, the drug (D) having polarity can be delivered to the skin (EP) by repulsion. In addition, an electric field and a magnetic field are generated in the first region S1 and the second region S2 by an oxidation-reduction reaction, and the drug D may be transmitted to the skin EP by being affected by the electric and magnetic fields. . In addition, when a polarized solute enters the skin by the repulsive force of each electrode, an osmotic pressure may be generated between the base sheet 110 in which the drug is stored and the skin EP. In order to offset the osmotic pressure, water, which is a solvent, moves to the skin, and nonpolar drugs may also move together.

Referring back to FIG. 2, since electrons generated in the 3a electrode pattern 141 due to the oxidation-reduction reaction move to the first electrode pattern 120, the first point P1 adjacent to the 3a electrode pattern 141 is The electron density decreases and the electron density increases along the first electrode pattern 120. In particular, the electron density is formed with the highest electron density at the second point P2 where the neighboring first electrode patterns 120 intersect.

The arrangement of the first electrode pattern 120 and the 3a electrode pattern 141 according to the present invention creates a potential difference once again after the oxidation-reduction reaction. Accordingly, the first electrode pattern 120 and the 3a electrode pattern 141 may continuously generate a potential difference. The device 100 using reverse electrodialysis and an oxidation-reduction reaction can continuously deliver the drug (D) to the skin (EP) by the potential difference between the first point (P1) and the second point (P2), It can continuously generate electrical impulses.

In addition, since electrons generated in the second electrode pattern 130 due to the oxidation-reduction reaction move to the 3b electrode pattern 142, the electron density in the fourth region P4 adjacent to the 3b electrode pattern 142 increases. , The electron density decreases along the second electrode pattern 130. In particular, the electron density is formed at the lowest level in the third region P3 where the adjacent second electrode patterns 130 intersect.

The arrangement of the second electrode pattern 130 and the 3b electrode pattern 142 according to the present invention creates a potential difference once again after the oxidation-reduction reaction. Accordingly, the second electrode pattern 130 and the 3b electrode pattern 142 may continuously generate a potential difference. The device 100 using reverse electrodialysis and an oxidation-reduction reaction can continuously deliver the drug D to the skin EP due to the potential difference between the third region P3 and the fourth region P4, It can continuously generate electrical impulses.

<Current supply by reverse cell dialysis cell>

The reverse battery dialysis battery unit 150 may supply current to the first electrode pattern 120 and the second electrode pattern 130. When a current is generated in the reverse electrodialysis battery unit 150, a relatively high current is supplied to the first region S1 and the second region S2.

The reverse electrodialysis battery unit 150 may be activated when the second activation solution is injected. The second activation solution is defined as a solution through which the reverse electrodialysis battery unit 150 supplies current, and specifically, it is injected into the first chamber C1 or the second chamber C2 to generate a difference in ion concentration. It is a solution.

The reverse electrodialysis battery unit 150 is not activated when the first chamber C1 and the second chamber C2 are dry, but when the second activation solution is injected, the first chamber C1 and the second chamber C2 ), a difference in ion concentration is generated to generate an electric current. The generated current may be transferred to the first electrode pattern 120 and the second electrode pattern 130 through the connection portion 156 of the intermediate sheet 155.

When current is supplied to the first electrode pattern 120 and the second electrode pattern 130, the first electrode pattern 120 and the second electrode pattern 130 have different polarities. The drug D having polarity may be delivered to the skin EP by a repulsive force generated by the first electrode pattern 120 or the second electrode pattern 130. In addition, an electric field and a magnetic field are generated in the first electrode pattern 120 and the second electrode pattern 130 by the supplied current, and the drug D may be transmitted to the skin EP by being affected by the electric and magnetic fields. have. In addition, when a polarized solute enters the skin by the repulsive force of each electrode, an osmotic pressure may be generated between the base sheet 110 in which the drug is stored and the skin EP. In order to offset the osmotic pressure, water, which is a solvent, moves to the skin, and nonpolar drugs may also move together.

In addition, the reverse battery dialysis battery unit 150 electrically connects the first region S1 and the second region S2. Since the reverse electrodialysis battery unit 150 supplies electrons to the first electrode pattern 120, the first region S1 may be defined as a source region. Further, since the reverse electrodialysis battery unit 150 receives electrons from the second electrode pattern 130, the second region S2 may be defined as a sink region. The movement of electrons may be activated in the entire area of the base sheet 110 by the source area and the sink area.

In the apparatus 100 using reverse electrodialysis and oxidation-reduction reaction according to an embodiment of the present invention, electricity is applied to the skin EP of the subject by the electric current supplied from the battery unit and the potential difference generated by the oxidation-reduction reaction. A stimulus may be generated and a drug may be delivered to the subject's skin EP.

In the apparatus 100 using reverse electrodialysis and oxidation-reduction reaction according to an embodiment of the present invention, a relatively high level of current is supplied from the battery part, and a relatively low level of the electrode pattern Current can be supplied. Since various levels of current are supplied, electrical stimulation of various strengths can be provided to the object, and various kinds of drugs can be delivered to the skin of the object.

In the apparatus 100 using reverse electrodialysis and oxidation-reduction reaction according to an embodiment of the present invention, since a potential difference is continuously generated by the arrangement of the electrode pattern, it is possible to deliver drugs or electric stimulation to a subject for a long time. have. Since the first electrode pattern 120 and the second electrode pattern 130 are each continuously disposed, and the third electrode pattern 140 is disposed inside the first electrode pattern 120 or the second electrode pattern 130, Even if an oxidation-reduction reaction is generated between the first electrode pattern 120 or the second electrode pattern 130 and the third electrode pattern 140, a potential difference may be generated again.

The device 100 using reverse electrodialysis and oxidation-reduction reaction according to an embodiment of the present invention can be safely activated. When the base sheet 110 is dried, the oxidation-reduction reaction is not activated in the electrode pattern, but when the first activating solution is injected into the base sheet, the oxidation-reduction reaction is activated to generate a potential difference. In addition, the reverse electrodialysis battery unit 150 is not activated in a dry state, but when the second activation solution is injected into the chamber, a current is generated. Therefore, the user can use the activation solution safely and quickly.

5A to 5E are views showing a modified example of the apparatus using reverse electrodialysis and oxidation-reduction reaction of FIG. 1.

Referring to FIG. 5A, the device 100a using reverse electrodialysis and oxidation-reduction reaction may include a first electrode pattern 120a and a third electrode pattern 140a filled therein. The apparatus 100a using reverse electrodialysis and the oxidation-reduction reaction may continuously maintain the oxidation-reduction reaction by increasing the third electrode pattern 140a.

Referring to FIG. 5B, the apparatus 100b using reverse electrodialysis and oxidation-reduction reaction may include a first electrode pattern 120b and a circular third electrode pattern 140b. The apparatus 100b using reverse electrodialysis and the oxidation-reduction reaction may have a first electrode pattern 120b and a third electrode pattern 140b having different shapes. Since the adjacent distance between the first electrode pattern 120b and the third electrode pattern 140b changes, the device 100b using reverse electrodialysis and oxidation-reduction reactions can form various potential differences.

Referring to FIG. 5C, the apparatus 100c using reverse electrodialysis and oxidation-reduction reaction may include a first electrode pattern 120c and a second electrode pattern 120c that is circular and filled with the inside. The apparatus 100c using reverse electrodialysis and the oxidation-reduction reaction may continuously maintain the oxidation-reduction reaction by increasing the third electrode pattern 140c. In addition, in the apparatus 100c using reverse electrodialysis and oxidation-reduction reaction, since the adjacent distance between the first electrode pattern 120c and the third electrode pattern 140c is changed, various potential differences can be formed.

Referring to FIG. 5D, the device 100d using reverse electrodialysis and oxidation-reduction reaction may include a circular first electrode pattern 120d and a circular third electrode pattern 140d. The neighboring first electrode patterns 120d may be electrically connected, and the third electrode patterns 140d may be disposed inside the first electrode patterns 120d, respectively. Since the first electrode pattern 120d has a contact section and a non-contact section, various potential differences can be formed.

Referring to FIG. 5E, the device 100e using reverse electrodialysis and oxidation-reduction reaction may include a circular first electrode pattern 120e and a circular third electrode pattern 140e. The apparatus 100e using reverse electrodialysis and the oxidation-reduction reaction may continuously maintain the oxidation-reduction reaction by increasing the third electrode pattern 140e. In addition, since the first electrode pattern 120e has a contact section and a non-contact section, various potential differences can be formed.

5A to 5E show that the first electrode pattern is a cathode electrode, and the third electrode pattern is an anode electrode, but may be disposed in reverse. In addition, the first electrode pattern and the second electrode pattern may be variously formed in a polygonal shape and a circular shape. In addition, the first electrode pattern may be replaced by the second electrode pattern.

6A to 6C are diagrams showing a modified example of the apparatus using the reverse electrodialysis and oxidation-reduction reaction of FIG. 1.

6A, in the apparatus 100-1 using reverse electrodialysis and oxidation-reduction reaction, the first electrode pattern 120-1 and the third electrode pattern 140-1 are the other surfaces of the base sheet 110. Can be placed on When the oxidation-reduction reaction is generated, since one surface of the base sheet 110 is in contact with the skin EP, the drug D can be quickly delivered to the skin EP. In particular, the heavy polar drug D disposed between the first electrode pattern 120-1 and the third electrode pattern 140-1 may also be quickly delivered to the skin by repulsive force.

6B, in the apparatus 100-2 using reverse electrodialysis and oxidation-reduction reaction, a first electrode pattern 120 is disposed on one surface of the base sheet 110, and a third electrode pattern 140-2 ) May be disposed on the other surface of the base sheet 110. The first electrode pattern 120 and the third electrode pattern 140-2 are disposed on different surfaces of the base sheet 110 to maximize a drug delivery effect and an electrical stimulation effect.

Referring to FIG. 6C, in the apparatus 100-3 using reverse electrodialysis and oxidation-reduction reaction, at least one of the first electrode pattern 120-3 and the third electrode pattern 140-3 is a base sheet 110 ) Can be placed inside. Since the first electrode pattern 120-3 and the third electrode pattern 140-3 are disposed inside the base sheet 110, durability of the electrode pattern may be increased, and the oxidation-reduction reaction may last for a long time.

6A to 6C illustrate a first electrode pattern as a cathode electrode and a third electrode pattern as an anode electrode, but may be disposed in reverse. In addition, the first electrode pattern and the second electrode pattern may be disposed by combining the arrangement of the electrode patterns of FIGS. 3 and 6A to 6C. In addition, the first electrode pattern may be replaced by the second electrode pattern.

7 is a diagram showing an apparatus 200 using reverse electrodialysis and an oxidation-reduction reaction according to another embodiment of the present invention.

Referring to FIG. 7, the device 200 using reverse electrodialysis and oxidation-reduction reaction may further include a drug sheet 260. The drug sheet 260 contains a drug (D) therein, and is attached to one surface of the base sheet 110 to provide the first electrode pattern 120, the second electrode pattern 130, and the third electrode pattern 140. Can be activated.

By attaching the drug sheet 260 to the dry base sheet 110, the oxidation-reduction reaction can be activated in the device 200 using reverse electrodialysis and oxidation-reduction reaction, and stored in the drug sheet 260 The drug (D) can be delivered to the skin (EP), that is, the drug (D) in the drug sheet 260 acts as a first activation solution, and the device 200 using reverse electrodialysis and oxidation-reduction reactions. ) Can be driven.

Specifically, the drug sheet 260 includes the drug (D), but may be kept in a wet state. After attaching the drug sheet 260 to the object, a second activation solution is added to the dried base sheet 110 to activate the reverse electrodialysis battery unit 150, and the base sheet 110 is attached to the drug sheet 260. By attaching to the oxidation-reduction reaction can be activated.

In addition, after attaching the drug sheet 260 to the object, the base sheet 110 is attached to the drug sheet 260 to activate the oxidation-reduction reaction, and then the second battery unit 150 is activated. Activation solution can be injected.

In another embodiment, the drug sheet 260 contains a drug (D), and when the first activation solution is injected into the base sheet 110, the drug (D) from the drug sheet 260 is transferred to the skin (EP). Can be delivered.

8 is a cross-sectional view showing an apparatus 300 using reverse electrodialysis and an oxidation-reduction reaction according to another embodiment of the present invention, and FIG. 9 is an enlarged view showing a partial area of FIG. 8.

8 and 9, the apparatus 300 using reverse electrodialysis and oxidation-reduction reaction includes a base sheet 310, a first electrode pattern 320, a second electrode pattern 330, and a third electrode pattern. It may include 340 and a battery unit 350.

The base sheet 310 is divided into a first area S1 and a second area S2 by the separation area 311, and is substantially the same as the base sheet 110 of the aforementioned exemplary embodiment. The battery unit 350 is substantially the same as the battery unit 150 of the above-described embodiment.

The first electrode pattern 320 and the third electrode pattern 340 are disposed in the first region S1 and have an oxidation-reduction reaction similar to the first electrode pattern 120 and the third electrode pattern 141 described above. Is created. When the first activating solution is injected into the first region S1, an oxidation-reduction reaction is generated in the first electrode pattern 320 and the third electrode pattern 340, and an electrical stimulation is generated in the first region S1. , The drug (D) may be delivered to the skin (EP).

The second electrode pattern 330 may be disposed in the second region S2. The second electrode pattern 330 has a pattern similar to the second electrode pattern 130 of the above-described embodiment. However, an additional electrode pattern is not disposed inside the second electrode pattern 330. Therefore, no oxidation-reduction reaction is generated in the second region.

That is, the oxidation-reduction reaction is not generated in the second region S2, but electrical stimulation may be provided to the object or the drug D may be delivered to the object by the current supplied from the battery unit 150.

In another embodiment, in an apparatus using reverse electrodialysis and an oxidation-reduction reaction, the oxidation-reduction reaction may be activated in the second region S2 and the redox reaction may not be activated in the first region S1.

The device 300 using reverse electrodialysis and an oxidation-reduction reaction according to an embodiment of the present invention may provide various levels of electrical stimulation to a subject or deliver various types of drugs. A region in which the oxidation-reduction reaction is activated is divided, so that the first region S1 receives the oxidation-reduction reaction and current from the battery unit, and the second region S2 receives current from the battery unit. By varying the amount of current delivered in each region, the size of the electrical stimulation or the amount of drug delivered can be adjusted.

10 is a cross-sectional view showing an apparatus 400 using reverse electrodialysis and an oxidation-reduction reaction according to another embodiment of the present invention, and FIG. 11 is an enlarged view illustrating a partial area of FIG. 10.

10 and 11, the apparatus 400 using reverse electrodialysis and oxidation-reduction reaction includes a base sheet 410, a first electrode pattern 420 disposed in the first region S1, and a second region. A second electrode pattern 430 disposed in (S2), a first electrode pattern 420, or a third electrode pattern 440 disposed inside the second electrode pattern 430 is provided. The third electrode pattern 440 includes a 3a electrode pattern 441 disposed inside the first electrode pattern 420 and a 3b electrode pattern 442 disposed inside the second electrode pattern 430 can do.

In the third electrode pattern 440, a plurality of electrode ends may be radially disposed. 10 illustrates an embodiment having three electrode ends, but is not limited thereto and may have various shapes. In addition, the electrode end of the third electrode pattern 440 may be formed to decrease in thickness from the center to the end.

When the first electrode pattern 420 is activated as a cathode electrode and the 3a electrode pattern 441 is activated as an anode electrode, electrons generated in the 3a electrode pattern 441 are the first electrode pattern. Moving to 420, chloride ions generated in the first electrode pattern 420 move to the 3a electrode pattern 441.

Since the first electrode pattern 420 and the third a electrode pattern 441 have different distances, the device 400 using reverse electrodialysis and oxidation-reduction reactions can form various potential differences. Since electrons generated in the 3a electrode pattern 441 by the oxidation-reduction reaction move to the first electrode pattern 420, the electron density at the first point Q1 of the 3a electrode pattern 441 decreases.

Meanwhile, the density of electrons disposed on the first electrode pattern 420 varies depending on the distance between the first electrode pattern 420 and the 3a electrode pattern 441. The distance between the electrode end of the 3a electrode pattern 441 and the first electrode pattern 420 is d1, and the distance between the center of the 3a electrode pattern 441 and the first electrode pattern 420 is d2. Comparing the second point Q2 and the third point Q3, the second point Q2 of the first electrode pattern 420 has a relatively low electron density, and the third point Q3 has a relatively low electron density. Is formed high.

The apparatus 400 using reverse electrodialysis and the oxidation-reduction reaction generates a potential difference once again after the oxidation-reduction reaction by the shape of the 3a electrode pattern 441. Accordingly, the first electrode pattern 420 and the 3a electrode pattern 441 may continuously generate a potential difference. The device 400 using reverse electrodialysis and an oxidation-reduction reaction can continuously deliver the drug (D) to the skin (EP), and can continuously generate electrical stimulation.

When the second electrode pattern 430 is activated as an anode electrode and the thirdb electrode pattern 442 is activated as a cathode electrode, electrons generated in the second electrode pattern 430 are converted into the third b electrode pattern. Moving to 442, chloride ions generated in the 3b electrode pattern 442 move to the second electrode pattern 430.

As described above, since the second electrode pattern 430 and the thirdb electrode pattern 442 have different distances, the device 400 using reverse electrodialysis and oxidation-reduction reactions can form various potential differences. The fourth point Q4 has a lower electron density than the fifth point Q5, and the sixth point Q6 receives electrons and has a high electron density.

The device 400 using reverse electrodialysis and the oxidation-reduction reaction generates a potential difference once again after the oxidation-reduction reaction by the shape of the 3b electrode pattern 442. Accordingly, the second electrode pattern 430 and the 3b electrode pattern 442 may continuously generate a potential difference. The device 400 using reverse electrodialysis and an oxidation-reduction reaction can continuously deliver the drug (D) to the skin (EP), and can continuously generate electrical stimulation.

12 is a diagram showing an apparatus using reverse electrodialysis and an oxidation-reduction reaction according to another embodiment of the present invention.

Referring to FIG. 11, the storage kit 1 may include a pouch 10 for storing an apparatus 100 using reverse electrodialysis and an oxidation-reduction reaction.

The pouch 10 has a first storage space 11 for storing the base sheet 110 and a second storage space 12 for storing drugs, and the first storage space 11 and the second storage space 12 ) Is spatially separated by the separation wall (13). The separation wall 13 may have a valve 14 that selectively connects the first storage space 11 and the second storage space 12 to each other.

The device 100 using reverse electrodialysis and oxidation-reduction reaction may be stored in the pouch 10 and used. When the user opens the valve 14 and moves the drug (D) from the second storage space 12 to the first storage space 11, the device 100 using reverse electrodialysis and oxidation-reduction reactions performs oxidation-reduction. The reaction is activated. The user simply attaches the device 100 using the activated reverse electrodialysis and the oxidation-reduction reaction to the skin (EP) of the subject, and delivers the drug (D) to the skin (EP) or electrical stimulation to the skin (EP). Can be created.

In another embodiment, the device 100 using reverse electrodialysis and oxidation-reduction reaction may include a base sheet 110 stored in a pouch 10 and a separate drug sheet 260. When the user opens the valve 14 and moves the first activating solution from the second storage space 12 to the first storage space 11, the base sheet 110 may activate a redox reaction. The user may attach the drug sheet 260 to the base sheet 110 to deliver the drug D present in the drug sheet 260 to the skin EP of the object. In particular, when the drug sheet 260 is stored in a dry state, the first activation solution stored in the pouch 10 is injected into the base sheet 110 to drive the device 100 using reverse electrodialysis and oxidation-reduction reactions. I can make it.

In another embodiment, the device 100 using reverse electrodialysis and an oxidation-reduction reaction may change color depending on whether the drug D is absorbed. The base sheet may be provided with ink that changes color when the drug is absorbed. By recognizing the color change of the device 100 using reverse electrodialysis and oxidation-reduction reaction, the user can recognize whether or not the device 100 is activated using reverse electrodialysis and oxidation-reduction reaction.

In another embodiment, the base sheet may be impregnated with Zion ink, and when the user moves the drug D from the second space 12 of the pouch 10 to the first space 11, the base sheet It discolors due to temperature change Thereby, the user can check the readiness of the device 100 using reverse electrodialysis and oxidation-reduction reaction, and attach the device 100 using reverse electrodialysis and oxidation-reduction reaction with changed color to the skin (EP). Can be used.

In another embodiment, after placing the device 100 using reverse electrodialysis and oxidation-reduction reaction on a tray (not shown), the user pours the drug into the tray and uses reverse electrodialysis and an oxidation-reduction reaction ( 100) can be activated.

FIG. 13 is a graph illustrating a potential difference generated when the first electrode pattern 320 and the second electrode pattern 330 of FIG. 9 are activated.

Referring to FIG. 13, when the device 300 using reverse electrodialysis and an oxidation-reduction reaction is activated by spraying the activation solution on the base sheet 310, the voltage increases rapidly until t1. Since the reverse electrodialysis battery unit 350 has a relatively high voltage and supplies current quickly, the voltage increases rapidly to 2.608V until t1. After that, the voltage decreases rapidly until t2, but remains stable at an average of 1.059V after t2.

The reverse battery dialysis battery unit 350 may supply a relatively high current, but there is a limit to continuously supplying current. However, when the oxidation-reduction reaction is activated in the electrode pattern, the current can be supplied stably and continuously. Current is provided in the oxidation-reduction reaction, and electrons generated in the oxidation-reduction reaction are supplied back to the reverse cell dialysis cell unit 350, thereby increasing the use time of the reverse cell dialysis cell unit 350.

14 is a flow chart showing a drug delivery method using reverse electrodialysis and oxidation-reduction reaction according to another embodiment of the present invention.

Referring to FIG. 14, the drug delivery method using an oxidation-reduction reaction includes attaching a drug sheet to an object (S10), injecting an activating solution into the base sheet (S20), and attaching the base sheet to the drug sheet. (S30) and the step of delivering the drug to the subject (S40).

Attaching the drug sheet to the object (S10) The drug sheet 260 containing the drug is attached to the skin EP of the object.

In the step of injecting the activating solution into the base sheet (S20 ), the second activating solution is injected into the battery unit 150 to activate the battery unit 150.

In the step of attaching the base sheet to the drug sheet (S30), by attaching the base sheet 110 to the drug sheet 260, an oxidation-reduction reaction occurs in the base sheet 110. The drug can act as an activating solution that activates the oxidation-reduction reaction. In another embodiment, the first activation solution may be additionally injected into the base sheet 110 or the drug sheet 260.

In another embodiment, a device using reverse electrodialysis and an oxidation-reduction reaction can deliver a drug to the skin by injecting a drug into the base sheet without a drug sheet.

In detail, by injecting a first activating solution containing a drug into the base sheet, an oxidation-reduction reaction may be activated between the first electrode pattern and the third electrode pattern and between the second electrode pattern and the third electrode pattern. Thereafter, when the second activating solution is injected into the reverse electrodialysis battery unit 150, current is transferred from the reverse electrodialysis battery unit 150 to the first electrode pattern and the second electrode pattern. Thereafter, the drug may be delivered from the base sheet to the skin of the subject.

As described above, the apparatus using reverse electrodialysis and oxidation-reduction reaction includes a base sheet, a first electrode pattern continuously connected to each other in a first region of the base sheet, and a second electrode pattern continuously connected to each other in a second region of the base sheet. A second electrode pattern, a third electrode pattern disposed inside at least one of the first electrode pattern, and the second electrode pattern, and a battery unit connected to the first electrode pattern and the second electrode pattern may be provided.

The first electrode pattern is arranged so that a plurality of closed loop shapes are connected to the first region of the base sheet, and the second electrode pattern is a plurality of closed loop shapes that are connected to the second region of the base sheet. They are arranged to be connected to each other.

A plurality of third electrode patterns may be spaced apart from the inside of the closed loop of the first electrode pattern or the second electrode pattern. In addition, in an apparatus using reverse electrodialysis and an oxidation-reduction reaction, an oxidation-reduction reaction may be activated in electrode patterns disposed in the first region and the second region with a first activation solution.

Injecting the first activating solution into the base sheet (S20) is to inject the first activating solution to be absorbed by the base sheet, or attach the drug sheet to the base sheet to deliver the first activating solution included in the drug sheet to the base sheet. Can be.

An apparatus using reverse electrodialysis and an oxidation-reduction reaction according to an embodiment of the present invention and a method of delivering a drug using the same are provided by the electric current supplied from the battery unit and the potential difference generated by the oxidation-reduction reaction. Electrical stimulation may be generated in the skin EP, and the drug may be delivered to the skin EP of the subject.

An apparatus using reverse electrodialysis and an oxidation-reduction reaction according to an embodiment of the present invention and a method of delivering a drug using the same, are supplied with a relatively high level of current from the battery part, and the oxidation-reduction reaction of the electrode pattern Thus, a relatively low level of current can be supplied. Since various levels of electric current are supplied, electric stimulation of various strengths can be provided to the object and various kinds of drugs can be delivered to the skin of the object.

In the device using reverse electrodialysis and oxidation-reduction reaction according to an embodiment of the present invention and a method of delivering a drug using the same, a potential difference is continuously generated by the arrangement of the electrode pattern, so that the drug is delivered to the subject for a long time. Or electrical stimulation. Since the first electrode pattern and the second electrode pattern are each continuously disposed, and the third electrode pattern is disposed inside the first electrode pattern or the second electrode pattern, it is between the first electrode pattern and the third electrode pattern or the second electrode. Even if an oxidation-reduction reaction is generated between the pattern and the third electrode pattern, a potential difference may be generated again.

The device using reverse electrodialysis and oxidation-reduction reaction according to an embodiment of the present invention and a method of delivering a drug using the same can be safely activated. When the base sheet is in a dry state, the oxidation-reduction reaction is not activated in the electrode pattern, but when the first activating solution is injected into the base sheet, the oxidation-reduction reaction is activated to generate a potential difference. In addition, the reverse electrodialysis battery unit is not activated in a dry state, but when the second activation solution is injected into the chamber, a current is generated. Therefore, the user can use the activation solution safely and quickly.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, but these are only exemplary, and those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. . Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: Device using reverse electrodialysis and oxidation-reduction reaction
110: base sheet
120: first electrode pattern
130: second electrode pattern
140: third electrode pattern
150: battery part

Claims (19)

Base sheet;
A first electrode pattern disposed on an area of the base sheet;
A second electrode pattern disposed in another area of the base sheet and continuously connected to each other;
A third electrode pattern disposed inside at least one of the first electrode pattern and the second electrode pattern; And
Containing, reverse electrodialysis and oxidation-reduction apparatus using a battery unit; one end is electrically connected to the first electrode pattern and the other end is electrically connected to the second electrode pattern. The method of claim 1,
The battery unit is activated to transfer current to the first electrode pattern and the second electrode pattern,
Using reverse electrodialysis and oxidation-reduction reaction in which the oxidation-reduction reaction is activated in the first electrode pattern and the third electrode pattern, or the oxidation-reduction reaction is activated in the second electrode pattern and the third electrode pattern. Device. The method of claim 2,
An apparatus using reverse electrodialysis and an oxidation-reduction reaction in which the oxidation-reduction reaction is not activated when the base sheet is in a dry state, and when the first activating solution is injected into the base sheet, the oxidation-reduction reaction is activated. The method of claim 3,
The first activation solution includes a drug, and when the oxidation-reduction reaction is activated, the drug is delivered to a subject, using reverse electrodialysis and an oxidation-reduction reaction. The method of claim 2,
The battery part is a reversed electrodialysis (RED) battery,
An apparatus using reverse electrodialysis and an oxidation-reduction reaction, wherein the battery part is activated when a second activation solution is injected into the battery part. The method of claim 1,
A plurality of the first electrode patterns having a closed loop shape are disposed to be connected to each other in the one region of the base sheet,
A plurality of the second electrode patterns having a closed loop shape are disposed to be connected to each other in the other region of the base sheet,
The apparatus using reverse electrodialysis and oxidation-reduction reaction, wherein a plurality of the third electrode patterns are spaced apart from the inside of the closed loop of the first electrode pattern or the second electrode pattern. The method of claim 1,
The first electrode pattern is disposed on one surface of the base sheet,
The second electrode pattern is disposed on one surface or the other surface of the base sheet, using reverse electrodialysis and oxidation-reduction reaction. The method of claim 7,
The third electrode pattern is
An apparatus using reverse electrodialysis and an oxidation-reduction reaction, which is disposed on the same side as the first electrode pattern or the second electrode pattern, or disposed on the other side of the base sheet. The method of claim 1,
At least one of the first electrode pattern, the second electrode pattern, and the third electrode pattern is disposed inside the base sheet, using reverse electrodialysis and an oxidation-reduction reaction. The method of claim 1,
The first electrode pattern and the second electrode pattern have the same shape, the device using reverse electrodialysis and oxidation-reduction reaction. The method of claim 1,
The third electrode pattern is
A 3a electrode pattern disposed inside the first electrode pattern; And
A device using reverse electrodialysis and an oxidation-reduction reaction, comprising; a 3b electrode pattern having a polarity different from that of the 3a electrode pattern and disposed inside the second electrode pattern. The method of claim 1,
The first electrode pattern and the second electrode pattern have a polygonal shape or a circular shape, a device using reverse electrodialysis and an oxidation-reduction reaction. The method of claim 12,
The third electrode pattern is a device using reverse electrodialysis and oxidation-reduction reaction, in which a plurality of electrode ends are radially arranged. The method of claim 1,
A device using reverse electrodialysis and an oxidation-reduction reaction, further comprising; a drug sheet containing a drug therein and attached to one surface of the base sheet to activate the first electrode pattern and the second electrode pattern. The method of claim 1,
A first storage space for storing the base sheet;
A second storage space for storing drugs injected into the base sheet; And
A device using reverse electrodialysis and an oxidation-reduction reaction further comprising a; a pouch having a; a valve selectively connecting the first storage space and the second storage space. Attaching the drug sheet to the subject;
Activating the battery unit by injecting a second activating solution into an apparatus using reverse electrodialysis and oxidation-reduction reaction;
Including; attaching the base sheet to which the battery part is attached to the drug sheet,
The device using the reverse electrodialysis and oxidation-reduction reaction includes: a first electrode pattern disposed in a region of the base sheet and continuously connected to each other;
A second electrode pattern disposed in another area of the base sheet and continuously connected to each other; And
A third electrode pattern disposed inside at least one of the first electrode pattern and the second electrode pattern; and
The reverse electrodialysis battery unit is disposed on the base sheet, one end is electrically connected to the first electrode pattern, the other end is electrically connected to the second electrode pattern, using reverse electrodialysis and oxidation-reduction reaction Delivery method. The method of claim 16,
When the base sheet is attached to the drug sheet, an oxidation-reduction reaction is activated in the first electrode pattern and the third electrode pattern, or an oxidation-reduction reaction is activated in the second electrode pattern and the third electrode pattern,
When the second activating solution is injected into the battery unit, the reverse electrodialysis battery unit is activated to transfer current to the first electrode pattern and the second electrode pattern. Drug delivery using reverse electrodialysis and oxidation-reduction reactions Way. The method of claim 17,
The drug sheet includes a first activating solution, and when the first activating solution is absorbed by the base sheet and the oxidation-reduction reaction is activated, reverse electrodialysis and an oxidation-reduction reaction in which the drug is delivered to the subject are performed. Drug delivery method used. The method of claim 17,
A plurality of the first electrode patterns having a closed loop shape are disposed to be connected to each other in the one region of the base sheet,
A plurality of the second electrode patterns having a closed loop shape are disposed to be connected to each other in the other region of the base sheet,
The drug delivery method using reverse electrodialysis and oxidation-reduction reaction, wherein a plurality of the third electrode patterns are spaced apart from the inside of the closed loop of the first electrode pattern or the second electrode pattern.

Images