KR20200108766A - Device using redox activity and method for delivering drug using the same - Google Patents

Abstract

The present invention relates to a device using an oxidation-reduction reaction and a method for delivering a drug by using the same. The present invention comprises: a base sheet; a first electrode pattern disposed on the base sheet and continuously connected to each other; and a second electrode pattern disposed inside the first electrode pattern and spaced apart from the first electrode pattern, wherein the oxidation-reduction reaction is activated in the first electrode pattern and the second electrode pattern. According to the present invention, a user can safely and quickly use the device by injecting an activation solution.

Description

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

The present invention relates to an apparatus and a method, and more particularly, to a device using 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 shape of a face without the need to apply it by hand.It is a product that can cover the entire face or It is available on the market in various forms such as sheets divided into two sheets, and sheets 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, the delivery of useful substances to the skin is limited. 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 an oxidation-reduction reaction with improved electrical stimulation or improved drug absorption and improved 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 side of the present invention includes a base sheet, a first electrode pattern disposed on the base sheet and continuously connected to each other, and a second electrode disposed inside the first electrode pattern and spaced apart from the first electrode pattern. It includes a pattern, and provides an apparatus using an oxidation-reduction reaction in which an oxidation-reduction reaction is activated in the first electrode pattern and the second electrode pattern.

In addition, the first electrode pattern and the second electrode pattern may be activated with different polarities.

In addition, when the base sheet is dried, the first electrode pattern and the second electrode pattern are not activated, and when an activating solution is injected into the base sheet, the oxidation of the first electrode pattern and the second electrode pattern- The reduction reaction can be activated.

In addition, the activating solution includes a drug, and when an oxidation-reduction reaction is activated in the first electrode pattern and the second electrode pattern, the drug may be delivered from the base sheet to the object.

In addition, a plurality of the first electrode patterns are arranged to be connected to each other in a preset area of the base sheet, and a plurality of the second electrode patterns are inside the closed loop of the first electrode pattern. Can be placed at a distance.

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

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

In addition, in the second 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 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 a pouch.

Another aspect of the present invention includes attaching a device using an oxidation-reduction reaction to an object, and injecting an activating solution into a base sheet of the device using the oxidation-reduction reaction, and performing the oxidation-reduction reaction. The device used is an oxidation-reduction comprising a first electrode pattern disposed on the base sheet and continuously connected to each other, and a second electrode pattern disposed inside the first electrode pattern and spaced apart from the first electrode pattern. It provides a drug delivery method using reaction.

In addition, an oxidation-reduction reaction may be activated in the first electrode pattern and the second electrode pattern with the activation solution.

In addition, in the step of injecting the activating solution into the base sheet, the activating solution is injected so that the base sheet absorbs it, or the activating solution contained in the drug sheet is transferred to the base sheet by attaching a drug sheet to the base sheet. I can.

In addition, a plurality of the first electrode patterns are arranged to be connected to each other in a preset area of the base sheet, and a plurality of the second electrode patterns are inside the closed loop of the first electrode pattern. Can be placed at a distance.

In the apparatus using an oxidation-reduction reaction and a method of delivering a drug using the device according to an embodiment of the present invention, since the microcurrent generated by the oxidation-reduction is generated throughout the base sheet, absorption of the drug is improved and , Can improve blood circulation and increase protein synthesis. By the potential difference generated by the oxidation-reduction reaction, electrical stimulation is generated on the skin of the subject, and drugs can be effectively delivered to the skin of the subject.

In the apparatus using an oxidation-reduction reaction and a method of delivering a drug using the device according to an embodiment of the present invention, since a potential difference is continuously generated by the arrangement of the electrode pattern, the drug is delivered to the object for a long time or electrical stimulation is performed. Can give. The first electrode pattern continuously disposed and the second electrode pattern disposed inside the first electrode pattern may generate a potential difference again even if an oxidation-reduction reaction is generated.

An apparatus using an oxidation-reduction reaction according to an embodiment of the present invention and a method of delivering a drug using the same can safely activate the oxidation-reduction reaction. In the dry state, the oxidation-reduction reaction is not activated, but when the activation solution is injected into the base sheet, the oxidation-reduction reaction is activated to create a potential difference. The user can inject the activation solution to use it safely and quickly.

1 is a diagram showing an apparatus using 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 apparatus using the oxidation-reduction reaction of FIG. 1 is activated.
4 is an enlarged view showing an enlarged part of an apparatus using an oxidation-reduction reaction according to another embodiment of the present invention.
5 is a diagram illustrating a cross section in which the apparatus using the oxidation-reduction reaction of FIG. 4 is activated.
6A to 6E are diagrams showing a modified example of the apparatus using the oxidation-reduction reaction of FIG. 1.
7A to 7C are diagrams showing a modified example of the apparatus using the oxidation-reduction reaction of FIG. 1.
8 is a diagram showing an apparatus using an oxidation-reduction reaction according to another embodiment of the present invention.
9 is a diagram showing an apparatus using an oxidation-reduction reaction according to another embodiment of the present invention.
10 is an enlarged view showing a partial area of FIG. 9 on an enlarged scale.
11 is a diagram showing an apparatus using an oxidation-reduction reaction according to another embodiment of the present invention.
12 is a graph showing a potential difference generated when the first electrode pattern and the second electrode pattern of FIG. 2 are activated.
13 is a flow chart showing a drug delivery method using an 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 region or a component is on or on another part, it includes not only the case that is directly above the other part, but also the case where another region, component, etc. is interposed in the middle. do.

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

1 to 3, when the oxidation-reduction reaction is activated, the apparatus 100 using an oxidation-reduction reaction forms a low level electric field (LLEF) or generates a low level electric current. level micro-current; LLMC). The apparatus 100 using an oxidation-reduction reaction may deliver a drug to an object using electrical energy generated by an oxidation reaction and a reduction reaction of a galvanic cell.

Hereinafter, activation is defined as generating an oxidation-reduction reaction in the apparatus 100 using an oxidation-reduction reaction. In addition, the object is a device 100 using an oxidation-reduction reaction is attached, and a drug is delivered using an electrical reaction or an electrical stimulation is applied to the skin, and may be, for example, skin of an animal or human.

The apparatus 100 using an oxidation-reduction reaction is attached to a subject and can deliver a drug to the subject upon activation. In addition, the apparatus 100 using the 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 apparatus 100 using the oxidation-reduction reaction may be 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 an oxidation-reduction reaction may include a base sheet 110, a first electrode pattern 120, and a second electrode pattern 130.

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 according to a location of an object to which the apparatus 100 using an oxidation-reduction reaction is attached. For example, if the apparatus 100 using the 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 the oxidation-reduction reaction is used as a medical patch, the base sheet may be formed in a polygonal or circular shape according to the shape of a portion requiring electrical stimulation or a portion requiring drug delivery. have. 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 not in use, and is activated in a wet state when in use. The base sheet 110 may be formed of a material that is wet with the activation solution and 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 restoring power, and is, 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 first electrode patterns 120 are disposed on the base sheet 110 and may be continuously connected to each other. 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 one embodiment, as shown in FIG. 1, a plurality of first electrode patterns 120 may be disposed over the entire base sheet 110. When an oxidation-reduction reaction is generated in the first electrode pattern 120 and the second electrode pattern 130, the apparatus 100 using the oxidation-reduction reaction is electrically stimulated to the skin of the object over the entire base sheet 110. And drug delivery.

In another embodiment, a plurality of first electrode patterns 120 may be disposed only in a partial area of the base sheet 110. An oxidation-reduction reaction is generated in the first electrode pattern 120 and the second electrode pattern 130, and the apparatus 100 using the oxidation-reduction reaction stimulates the skin of the object only in a local portion of the base sheet 110. And drug delivery.

In another embodiment, one of the first electrode patterns 120 may be disposed on the base sheet 110. A number of first electrode patterns 120 may be disposed in a partial region of the base sheet 110, and second electrode patterns 130 may be disposed therein. An oxidation-reduction reaction is generated in the first electrode pattern 120 and the second electrode pattern 130, and the apparatus 100 using the oxidation-reduction reaction is an electrical stimulation to the skin of the object in a partial area of the base sheet 110. And drug delivery.

The second electrode pattern 130 is disposed inside the first electrode pattern 120 and may be disposed to be spaced apart from the first electrode pattern 120. Referring to FIG. 2, the second electrode pattern 130 may have a shape corresponding to the first electrode pattern 120. For example, the second electrode pattern 130 may also have a hexagonal closed loop shape like the first electrode pattern 120.

Unlike the first electrode pattern 120, the second electrode patterns 130 are disposed to be spaced apart from each other. The second electrode pattern 130 is not connected to the first electrode pattern 120. In addition, the second electrode patterns 130 adjacent to each other are not connected to each other and are disposed to be spaced apart.

The oxidation-reduction reaction is activated in the first electrode pattern 120 and the second electrode pattern 130, and at this time, the first electrode pattern 120 and the second electrode pattern 130 are activated with different polarities. In addition, as shown in FIG. 3, the first electrode pattern 120 and the second electrode pattern 130 may be 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 second electrode pattern 130 are in contact with the skin EP, electrical stimulation may be effectively generated on the skin EP.

The second electrode patterns 130 are arranged in a number corresponding to the first electrode pattern 120. Since the second electrode pattern 130 is disposed inside the first electrode pattern 120, it may be preferably disposed equal to the number of the first electrode patterns 120.

The first electrode pattern 120 is printed on at least one surface of the base sheet 110. The first electrode patterns 120 are printed to be continuous with each other on the base sheet 110.

The first electrode pattern 120 and the second electrode pattern 130 may generate electromotive force with a galvanic battery. The first electrode pattern 120 and the second electrode pattern 130 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 and the second electrode pattern 130 include, but are limited to, zinc-silver, zinc-silver oxide, zinc-silver halide, zinc-silver chloride, zinc-silver bromide, zinc-silver iodide, and zinc-silver fluoride. It doesn't work.

Referring to Figures 2 and 3, the oxidation-reduction reaction is generated in the apparatus 100 using the oxidation-reduction reaction, electric stimulation or delivery of the drug will be described as follows.

When the base sheet 110 is dry, the first electrode pattern 120 and the second electrode pattern 130 are not activated. When the activating solution is injected into the base sheet 110, the oxidation-reduction reaction is activated in the first electrode pattern 120 and the second electrode pattern 130.

The first electrode pattern 120 is a cathode electrode, and the second electrode pattern 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 second electrode pattern 130 move to the first electrode pattern 120, and chloride ions generated from the first electrode pattern 120 move to the second electrode pattern 130.

When the activating solution is injected when the drug is stored in the base sheet 110, an oxidation-reduction reaction is activated, so that the drug D may be transferred from the base sheet 110 to the skin EP of the object. In addition, even when the activating solution contains the drug (D), when the oxidation-reduction reaction is activated, the drug (D) may be delivered from the base sheet 110 to the skin EP of the object.

The activation solution is defined as a solution capable of generating an oxidation-reduction reaction by being injected into the base sheet 110. The activation solution may be variously set according to the purpose of the apparatus 100 using an 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, since the first electrode pattern 120 and the second electrode pattern 130 each have polarity, drugs (D) having different polarities are transferred to the skin (EP) by repulsive force. I can. In addition, the first electrode pattern 120 and the second electrode pattern 130 generate an electric field and a magnetic field, 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.

Since electrons generated in the second electrode pattern 130 by the oxidation-reduction reaction move to the first electrode pattern 120, the electron density at the first point P1 adjacent to the second electrode pattern 130 is lowered, 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 second electrode pattern 130 according to the present invention generates a potential difference once again after the oxidation-reduction reaction. Accordingly, the first electrode pattern 120 and the second electrode pattern 130 may continuously generate a potential difference. The device 100 using the oxidation-reduction reaction by the potential difference between the first point (P1) and the second point (P2) can continuously deliver the drug (D) to the skin (EP), and sustain electrical stimulation. Can be created with

The apparatus 100 using an oxidation-reduction reaction according to an embodiment of the present invention generates electrical stimulation in the skin EP of an object by a potential difference generated by the oxidation-reduction reaction, and Drugs can be delivered.

In the apparatus 100 using an oxidation-reduction reaction according to an embodiment of the present invention, since a potential difference is continuously generated by the arrangement of an electrode pattern, a drug can be delivered to the object or an electrical stimulation can be given for a long time. The first electrode pattern 120 disposed in succession and the second electrode pattern 130 disposed inside the first electrode pattern 120 may generate a potential difference again even if an oxidation-reduction reaction occurs.

The apparatus 100 using an oxidation-reduction reaction according to an embodiment of the present invention can be safely activated. In the dry state, the oxidation-reduction reaction is not activated, but when the activation solution is injected into the base sheet, the oxidation-reduction reaction is activated to create a potential difference. The user can inject the activation solution to use it safely and quickly.

FIG. 4 is an enlarged view showing a part of an apparatus 100 ′ using an oxidation-reduction reaction according to another embodiment of the present invention, and FIG. 5 is an enlarged view illustrating an apparatus 100 ′ using an oxidation-reduction reaction of FIG. 4 It is a diagram showing a cross section in which is activated.

4 and 5, in the apparatus 100 ′ using an oxidation-reduction reaction, a first electrode pattern 120 ′ is an anode electrode, and a second electrode pattern 130 ′ is a cathode. It is an 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 in the first electrode pattern 120 ′ move to the second electrode pattern 130 ′, and chloride ions generated in the second electrode pattern 130 ′ move to the first electrode pattern 120 ′. .

Since electrons generated from the first electrode pattern 120 ′ by the oxidation-reduction reaction move to the second electrode pattern 130 ′, the first point P1 adjacent to the first electrode pattern 120 ′ has an electron density. High, and the electron density decreases along the second electrode pattern 130 ′. In particular, the electron density is formed at the lowest level at the second point P2 where the adjacent second electrode patterns 130 ′ cross each other.

The arrangement of the first electrode pattern 120 ′ and the second electrode pattern 130 ′ according to the present invention creates a potential difference once again after the oxidation-reduction reaction. Accordingly, the first electrode pattern 120 ′ and the second electrode pattern 130 ′ may continuously generate a potential difference. The device 100 ′ using the oxidation-reduction reaction by the potential difference between the first point P1 and the second point P2 can continuously deliver the drug D to the skin EP, and conduct electrical stimulation. Can be continuously generated.

In the apparatus 100 ′ using an oxidation-reduction reaction, when an activating solution is injected when a drug is stored in the base sheet 110 as described above, the oxidation-reduction reaction is activated, and the drug (D) is applied to the base sheet. It may be delivered to the skin (EP) of the subject at 110. In addition, even when the activating solution contains the drug (D), when the oxidation-reduction reaction is activated, the drug (D) may be delivered from the base sheet 110 to the skin EP of the object.

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

Referring to FIG. 6A, the apparatus 100a using the oxidation-reduction reaction may include a first electrode pattern 120a and a second electrode pattern 130a filled therein. The apparatus 100a using the oxidation-reduction reaction may continuously maintain the oxidation-reduction reaction by increasing the second electrode pattern 130a.

Referring to FIG. 6B, the apparatus 100b using the oxidation-reduction reaction may include a first electrode pattern 120b and a circular second electrode pattern 130b. The apparatus 100b using the oxidation-reduction reaction may have a first electrode pattern 120b and a second electrode pattern 130b having different shapes. Since the adjacent distance between the first electrode pattern 120b and the second electrode pattern 130b changes, the apparatus 100b using the oxidation-reduction reaction can form various potential differences.

Referring to FIG. 6C, the apparatus 100c using the 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 the oxidation-reduction reaction may continuously maintain the oxidation-reduction reaction by increasing the second electrode pattern 130c. In addition, in the apparatus 100c using the oxidation-reduction reaction, since the adjacent distance between the first electrode pattern 120c and the second electrode pattern 130c is changed, various potential differences can be formed.

Referring to FIG. 6D, the apparatus 100d using the oxidation-reduction reaction may include a circular first electrode pattern 120d and a circular second electrode pattern 130d. The neighboring first electrode patterns 120d may be electrically connected, and the second electrode patterns 130d 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. 6E, the apparatus 100e using the oxidation-reduction reaction may include a circular first electrode pattern 120e and a circular second electrode pattern 130e therein. The apparatus 100e using the oxidation-reduction reaction may continuously maintain the oxidation-reduction reaction by increasing the second electrode pattern 130e. In addition, since the first electrode pattern 120e has a contact section and a non-contact section, various potential differences can be formed.

6A to 6E show that the first electrode pattern is a cathode electrode and the second 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.

7A to 7C are diagrams showing a modified example of the apparatus using the oxidation-reduction reaction of FIG. 1.

Referring to FIG. 7A, in the apparatus 100-1 using an oxidation-reduction reaction, a first electrode pattern 120-1 and a second electrode pattern 130-1 may be disposed on the other surface of the base sheet 110. have. 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, a heavy polar drug D disposed between the first electrode pattern 120-1 and the second electrode pattern 130-1 may also be quickly delivered to the skin by repulsive force.

Referring to FIG. 7B, in the apparatus 100-2 using an oxidation-reduction reaction, a first electrode pattern 120 is disposed on one surface of the base sheet 110, and a second electrode pattern 130-2 is a base sheet. It can be placed on the other side of (110). Since the first electrode pattern 120 and the second electrode pattern 130-2 are disposed on different surfaces of the base sheet 110, a drug delivery effect and an electrical stimulation effect may be maximized.

Referring to FIG. 7C, in the apparatus 100-3 using an oxidation-reduction reaction, at least one of the first electrode pattern 120-3 and the second electrode pattern 130-3 is inside the base sheet 110. Can be placed. Since the first electrode pattern 120-3 and the second electrode pattern 130-3 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.

7A to 7C show that the first electrode pattern is a cathode electrode and the second 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 disposed by combining the arrangement of the electrode patterns of FIGS. 3 and 7A to 7C.

8 is a view showing an apparatus 200 using an oxidation-reduction reaction according to another embodiment of the present invention.

Referring to FIG. 8, the apparatus 200 using an oxidation-reduction reaction may further include a drug sheet 240. The drug sheet 240 includes a drug D therein, and is attached to one surface of the base sheet 110 to activate the first electrode pattern 120 and the second electrode pattern 130.

By attaching the drug sheet 240 to the dry base sheet 110, the device 200 using an oxidation-reduction reaction can be activated, and the drug D stored in the drug sheet 240 is applied to the skin (EP). Can be delivered as

9 is a view showing an apparatus 300 using an oxidation-reduction reaction according to another embodiment of the present invention, and FIG. 10 is an enlarged view showing a partial area of FIG. 9.

9 and 10, the apparatus 300 using an oxidation-reduction reaction includes a first electrode pattern 320 and a second electrode pattern 330 disposed inside the first electrode pattern 320. . In the second electrode pattern 330, 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 320 is activated as a cathode electrode and the second electrode pattern 330 is activated as an anode electrode, electrons generated in the second electrode pattern 330 are converted into the first electrode pattern. Moving to 320, chloride ions generated in the first electrode pattern 320 move to the second electrode pattern 330.

Since the first electrode pattern 320 and the second electrode pattern 330 have different distances, the apparatus 300 using the oxidation-reduction reaction can form various potential differences. Since electrons generated in the second electrode pattern 330 by the oxidation-reduction reaction move to the first electrode pattern 320, the electron density at the first point Q1 of the second electrode pattern 330 is lowered.

Meanwhile, the density of electrons disposed in the first electrode pattern 320 varies depending on the distance between the first electrode pattern 320 and the second electrode pattern 330. The distance between the electrode end of the second electrode pattern 330 and the first electrode pattern 320 is d1, and the distance between the center of the second electrode pattern 330 and the first electrode pattern 320 is d2. Comparing the second point Q2 and the third point Q3, the second point Q2 of the first electrode pattern 320 has a relatively low electron density, and the third point Q3 has a relatively low electron density. Is formed high.

The apparatus 300 using the oxidation-reduction reaction generates a potential difference once again after the oxidation-reduction reaction by the shape of the second electrode pattern 330. Accordingly, the first electrode pattern 320 and the second electrode pattern 330 may continuously generate a potential difference. The device 300 using the oxidation-reduction reaction can continuously deliver the drug D to the skin EP, and can continuously generate electrical stimulation.

In the apparatus 300 using an oxidation-reduction reaction, when an activating solution is injected when a drug is stored in the base sheet 310, the oxidation-reduction reaction is activated, and the drug D is transferred from the base sheet 310 to the object. It can be transmitted to the skin (EP) of the person. In addition, even when the activating solution contains the drug D, when the oxidation-reduction reaction is activated, the drug D may be delivered from the base sheet 310 to the skin EP of the object.

11 is a diagram showing an apparatus using 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 the apparatus 100 using 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 apparatus 100 using the 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 the oxidation-reduction reaction is activated. The user can simply attach the device 100 using the activated oxidation-reduction reaction to the skin (EP) of the object to deliver the drug (D) to the skin (EP) or to generate an electrical stimulation on the skin (EP). have.

In another embodiment, the color of the device 100 using the oxidation-reduction reaction may change 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 the oxidation-reduction reaction, the user may recognize whether the device 100 is activated using the 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 Accordingly, the user can check the readiness of the device 100 using the oxidation-reduction reaction, and can use the device 100 using the oxidation-reduction reaction of which the color is changed to the skin EP.

In another embodiment, after the device 100 using the oxidation-reduction reaction is placed on a tray (not shown), the user may activate the device 100 using the oxidation-reduction reaction by pouring the drug into the tray.

12 is a graph showing a potential difference generated when the first electrode pattern 120 and the second electrode pattern 130 of FIG. 2 are activated.

Referring to FIG. 12, when the activation solution is sprayed on the base sheet 110 and the device 100 using the oxidation-reduction reaction is activated, the voltage increases up to t1, and then is stably maintained. The potential difference between A and B in FIG. 2 has an average of 0.903V, and is stably maintained at 0.924V after t1 (4 minutes).

13 is a flow chart showing a drug delivery method using an oxidation-reduction reaction according to another embodiment of the present invention.

Referring to FIG. 13, in the drug delivery method using an oxidation-reduction reaction, the step of injecting an activating solution into the base sheet (S10), the step of activating an oxidation-reduction reaction between the first electrode pattern and the second electrode pattern (S20). ), attaching a device using an oxidation-reduction reaction to the subject (S30), and delivering the drug to the subject's skin (S40).

The apparatus using the oxidation-reduction reaction may include a base sheet, a first electrode pattern continuously connected to each other, and a second electrode pattern disposed inside the first electrode pattern, as described above.

A plurality of first electrode patterns having a closed loop shape may be disposed to be connected to each other in a preset region of the base sheet, and a plurality of second electrode patterns may be disposed spaced apart inside the closed loop of the first electrode pattern. . In addition, in the apparatus using the oxidation-reduction reaction, the oxidation-reduction reaction may be activated in the first electrode pattern and the second electrode pattern with an activation solution.

In the step of injecting the activating solution into the base sheet (S10), the activating solution may be injected so that the base sheet absorbs or the activating solution contained in the drug sheet may be delivered to the base sheet by attaching the drug sheet to the base sheet.

In the apparatus using an oxidation-reduction reaction and a method of delivering a drug using the device according to an embodiment of the present invention, since the microcurrent generated by the oxidation-reduction is generated throughout the base sheet, absorption of the drug is improved and , Can improve blood circulation and increase protein synthesis. By the potential difference generated by the oxidation-reduction reaction, electrical stimulation is generated on the skin of the subject, and drugs can be effectively delivered to the skin of the subject.

In the apparatus using an oxidation-reduction reaction and a method of delivering a drug using the device according to an embodiment of the present invention, since a potential difference is continuously generated by the arrangement of the electrode pattern, the drug is delivered to the object for a long time or electrical stimulation is performed. Can give. The first electrode pattern continuously disposed and the second electrode pattern disposed inside the first electrode pattern may generate a potential difference again even if an oxidation-reduction reaction is generated.

An apparatus using an oxidation-reduction reaction according to an embodiment of the present invention and a method of delivering a drug using the same can safely activate the oxidation-reduction reaction. In the dry state, the oxidation-reduction reaction is not activated, but when the activation solution is injected into the base sheet, the oxidation-reduction reaction is activated, creating a potential difference. Users can inject the activation solution to use it 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: apparatus using oxidation-reduction reaction
110: base sheet
120: first electrode pattern
130: second electrode pattern
240: drug sheet

Claims (15)

Base sheet;
A first electrode pattern disposed on the base sheet; And
And a second electrode pattern disposed inside the first electrode pattern and spaced apart from the first electrode pattern,
An apparatus using an oxidation-reduction reaction in which an oxidation-reduction reaction is activated in the first electrode pattern and the second electrode pattern. The method of claim 1,
The first electrode pattern and the second electrode pattern are activated with different polarities from each other, using an oxidation-reduction reaction. The method of claim 1,
When the base sheet is dried, the first electrode pattern and the second electrode pattern are not activated,
When an activating solution is injected into the base sheet, the oxidation-reduction reaction is activated in the first electrode pattern and the second electrode pattern. An apparatus using an oxidation-reduction reaction. The method of claim 3,
The activating solution includes a drug, and when an oxidation-reduction reaction is activated in the first electrode pattern and the second electrode pattern, the drug is delivered from the base sheet to an object. A device using an oxidation-reduction reaction. The method of claim 1,
The first electrode patterns are arranged so that a plurality of closed loop shapes are connected to each other in a preset area of the base sheet,
A plurality of the second electrode patterns are spaced apart from the inside of the closed loop of the first electrode pattern, using an oxidation-reduction reaction. 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 an oxidation-reduction reaction. The method of claim 1,
At least one of the first electrode pattern and the second electrode pattern is disposed inside the base sheet, using an oxidation-reduction reaction. The method of claim 1,
The first electrode pattern has a polygonal shape or a circular shape, an apparatus using an oxidation-reduction reaction. The method of claim 8,
In the second electrode pattern, a plurality of electrode ends are radially arranged, using an oxidation-reduction reaction. The method of claim 1,
An apparatus using 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 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 a device using an oxidation-reduction reaction to an object; And
Including; injecting an activation solution into the base sheet of the device using the oxidation-reduction reaction,
The apparatus using the oxidation-reduction reaction
A first electrode pattern disposed on the base sheet and continuously connected to each other; And
A second electrode pattern disposed inside the first electrode pattern and spaced apart from the first electrode pattern. A drug delivery method using an oxidation-reduction reaction. The method of claim 12,
A drug delivery method using an oxidation-reduction reaction in which an oxidation-reduction reaction is activated in the first electrode pattern and the second electrode pattern with the activation solution. The method of claim 13,
Injecting the activation solution into the base sheet
Or injected so that the base sheet absorbs the activation solution,
A drug delivery method using an oxidation-reduction reaction in which a drug sheet is attached to the base sheet so that the activating solution contained in the drug sheet is delivered to the base sheet. The method of claim 12,
The first electrode patterns are arranged so that a plurality of closed loop shapes are connected to each other in a preset area of the base sheet,
A plurality of the second electrode patterns are spaced apart from the inside of the closed loop of the first electrode pattern, a drug delivery method using an oxidation-reduction reaction.

Images