RU199722U1 - FACE ELECTROPHORESIS MASK - Google Patents

Abstract

The utility model relates to the field of medicine, in particular to cosmetic products for non-invasive or non-injection drug delivery deep into the human skin, and even more specifically to masks for face electrophoresis. The face electrophoresis mask contains a main part, in which holes for the user's eyes are made. The main part is equipped with positive and negative electrodes, each made in such a way that the conductive paths of one of said electrodes cover the central region of the main part, and the conductive paths of the other electrode cover the peripheral region of the main part. The main part is additionally equipped with contact pads that are electrically connected to the indicated electrodes so that an electric current can be supplied to them. The mask for face electrophoresis according to the present invention provides the technical result, which consists in increasing the efficiency of the electrophoresis procedure. 8 p.p. f-ly, 2 dwg

Description

FIELD OF TECHNOLOGY

The present utility model relates to the field of medicine, in particular to cosmetic products for non-invasive or non-injection delivery of drugs deep into human skin, and even more specifically to masks for face electrophoresis.

TECHNOLOGY LEVEL

Currently, various face masks are known that are used in cosmetology for carrying out the procedure of electrophoresis of the user's face, during which the skin of a person's face is complexly exposed to a low-power constant electric current and various drugs.

One of the illustrative examples of masks for face electrophoresis is described in RF patent No. 2290967 (hereinafter RU 2290967) published on May 27, 2005. In particular, patent RU 2290967 discloses a mask for face electrophoresis, comprising a main part in which holes for the user's eyes are made.

The disadvantage of the known mask for face electrophoresis is that not all drugs or not all of their components can be introduced deep into the skin of the user's face during the electrophoresis procedure, since this mask does not allow simultaneously with positively charged ions of the drug to penetrate deep into the skin of the user's face and negatively charged drug ions, which generally have an excellent tissue effect compared to positively charged ions.

Thus, there is an obvious need for further improvement of the known masks for face electrophoresis, in particular, to enable the simultaneous penetration of negatively and positively charged drug ions deep into the skin of the user's face.

Therefore, the technical problem solved by the present utility model is to create a mask for face electrophoresis, which at least partially eliminates the above-mentioned drawback of the known mask for face electrophoresis, which consists in the impossibility of simultaneous penetration of negative and positively charged drug ions deep into the skin of the face. user.

DISCLOSURE OF THE USEFUL MODEL

The objective of the present invention is to provide a mask for face electrophoresis that solves at least the above problem.

The problem is solved in the present utility model due to the fact that in the proposed mask for face electrophoresis, containing the main part, in which the holes for the user's eyes are made, the main part is equipped with positive and negative electrodes, each made in such a way that the conductive paths of one of the indicated electrodes cover the central region of the main part, and the conductive tracks of the other electrode cover the peripheral region of the main part, while the main part is additionally equipped with contact pads electrically connected to the said electrodes so that an electric current can be supplied to them.

The mask for face electrophoresis according to the present utility model provides a technical result, which consists in increasing the efficiency of the electrophoresis procedure. It should be noted that the effectiveness of the electrophoresis procedure achieved using the proposed mask is essentially determined by the qualitative indicators of the effect of the drug ions on the tissues of the user's facial skin, as well as the state of the user's facial skin observed after the electrophoresis procedure using the proposed mask. In particular, the increased efficiency of the electrophoresis procedure provided by the proposed mask is due to the placement of both positive and negative electrodes on the main part of the mask, as a result of which the like charged ions of the drug used together with the proposed mask can be repelled from them, ensuring their penetration deep into the skin of the face user. In addition, the increased efficiency of the electrophoresis procedure provided by the proposed mask is also due to the presence of two holes for the user's eyes, made in the main part of the mask, in particular due to the fact that these holes allow the user to properly position the mask on his face, thereby providing it tight fit to the skin of the user's face, the effect is only on the target areas of the user's face and the exclusion of the presence of target areas that were not targeted during the electrophoresis procedure using the proposed mask, which ultimately contributes to a uniform effect on all target areas of the user's face and, consequently, obtaining subsequently the maximum cosmic effect, expressed in the improved condition of the tissues of the skin of the user's face. In addition, the increased efficiency of the electrophoresis procedure provided by the proposed mask is also due to the fact that the conductive paths of the electrodes cover the peripheral and central areas of the main part of the mask, which ultimately makes it possible to affect most of the user's skin, covering all typical problem areas on the user's face.

In one embodiment of the present invention, each of the positive and negative electrodes in the proposed mask can be bifurcated in such a way that conductive paths of one of its parts and conductive paths of another part of it extend in opposite directions. The bifurcation of each of the electrodes to ensure the passage of the conductive tracks of the bifurcated electrodes in opposite directions also contributes to the above-formulated technical result, which consists in the increased efficiency of the electrophoresis procedure provided by the proposed mask, in particular due to the possibility of a more uniform effect on both halves of the user's face and , therefore, obtaining subsequently a uniform cosmic effect, expressed in an improved condition of the skin tissues of the entire face of the user.

In another embodiment of the present invention, the conductive paths of one of the portions of each bifurcated electrode and the corresponding conductive paths of the other portion of the bifurcated electrode may extend generally symmetrically with respect to a central axis extending in the middle of the main portion between the user's eye holes. The symmetrical passage of the corresponding conductive paths of both parts in each of the bifurcated positive and negative electrodes in the proposed mask also contributes to the technical result formulated above, which consists in the increased efficiency of the electrophoresis procedure provided by the proposed mask, in particular, due to the possibility of the most uniform impact on the corresponding target the area of both halves of the user's face, provided by each bifurcated electrode, and, therefore, obtaining subsequently a uniform cosmic effect, expressed in an improved condition of the skin tissues of the entire user's face.

In yet another embodiment of the present invention, the contact pads of the positive and negative electrodes can be located in the frontal region of the body at a distance from each other, and conductive paths covering the central region of the body and electrically connected to one of said contact pads can each extend through the region of the nose of the main body, followed by coverage of the corresponding one of the holes for the eyes of the user. The passage of each of the conductive paths covering the central region of the main part of the mask through the nose bridge of the main part with the subsequent coverage of the corresponding one of the holes for the user's eyes also contributes to the technical result formulated above, which consists in the increased efficiency of the electrophoresis procedure provided by the proposed mask, in in particular, due to a more uniform action on the frontal region of the user's face, provided by conductive paths covering the peripheral region of the face, extending from the corresponding contact plate located in the forehead region of one electrode, and covering the central region of the face with conductive tracks extending from the corresponding contact plate located in the forehead region of the other electrode. In particular, a more uniform effect on the frontal region of the user's face is due to a decrease in the strength of the current acting on the specified frontal region, due to the fact that the current passing through the conductive paths covering the central region of the face reaches the forehead only after passing through the nasal and infraorbital regions, thereby losing part of its strength due to the intrinsic resistance of these conductive paths, which ultimately prevents the possibility of burns in the forehead and, consequently, the possibility of damage to the tissues of the user's facial skin in the forehead, thereby increasing the efficiency of the electrophoresis procedure in the forehead.

In some embodiments of the present invention, the conductive paths may each be formed from a conductive paint comprising silver (Ag) and water-based acrylic. The execution of conductive tracks from conductive paint containing silver (Ag) and water-based acrylic also contributes to the above-formulated technical result, which consists in the increased efficiency of the electrophoresis procedure provided by the proposed mask, in particular, due to imparting relatively low intrinsic resistance to the conductive tracks , which contributes to a more even distribution of electric current with a given current strength along the entire length of the electrodes, thereby providing a uniform effect on all target areas of the user's face.

In some other embodiments of the present invention, the conductive tracks may each be formed from a conductive paint containing silver (Ag) and a polyolefin. The execution of conductive tracks from conductive paint containing silver (Ag) and polyolefin also contributes to the above formulated technical result, which consists in the increased efficiency of the electrophoresis procedure provided by the proposed mask, in particular, due to imparting relatively low intrinsic resistance to the conductive tracks, which contributes to more uniform distribution of electric current with a given current strength along the entire length of the electrodes, thereby ensuring uniform exposure to all target areas of the user's face.

In other embodiments of the present invention, the conductive paths may be formed on a substrate applied to the body, which substrate may be made of calcium carbonate (CaCO3) and water-based acrylic. The application of conductive paths to the substrate of the main part of the mask, made of calcium carbonate (CaCO3) and water-based acrylic, also contributes to the above-formulated technical result, which consists in the increased efficiency of the electrophoresis procedure provided by the proposed mask, in particular due to the fact that calcium carbonate, which is part of the substrate material, chemically neutralizes the action of hydrochloric acid (HCl) and alkali NaOH (sodium hydroxide), which inevitably form on the electrodes during the electrophoresis procedure, and, therefore, stabilizes the ph level, which does not allow the electrodes to oxidize. in particular, their conductive paths made of conductive paint, and also prevents the formation of AgO / Ag2O / AgCl, preventing the occurrence of chemical burns, which ultimately leads to an increased efficiency of the electrophoresis procedure carried out using the proposed mask, and allows you to achieve the most uniform cosmetic which effect.

According to one embodiment of the present invention, the main body of the mask can be pre-impregnated with serum for electrophoresis. The presence of serum in the main part of the mask also contributes to the above-formulated technical result, which consists in the increased efficiency of the electrophoresis procedure provided by the proposed mask, in particular by providing the possibility of the most uniform effect on all target areas of the user's face during the electrophoresis procedure using the proposed mask ...

According to another embodiment of the present invention, the conductive paths of the positive and negative electrodes may extend substantially at the same distance from each other. The passage of the conductive paths of the electrodes in the proposed mask at the same distance from each other also contributes to the above-formulated technical result, which consists in the increased efficiency of the electrophoresis procedure provided by the proposed mask, in particular, due to obtaining a uniform distribution of the electric field lines throughout the main part of the mask due to the generally equal resistance between these electrodes along their entire length, which ultimately contributes to a more uniform introduction of drugs deep into the skin of the user's face over the entire surface of the electrodes.

BRIEF DESCRIPTION OF DRAWINGS

The accompanying drawings, which are provided to provide a better understanding of the essence of the present utility model, form a part of this document and are included in it to illustrate the following embodiments and aspects of the present utility model. The accompanying drawings, in combination with the description below, serve to explain the essence of the present utility model. In the drawings:

in fig. 1 shows one of the embodiments of a mask for face electrophoresis according to the present invention;

in fig. 2 is a simplified block diagram of a current-generating device used for the mask of FIG. 1.

IMPLEMENTATION OF THE USEFUL MODEL

Some examples of possible variants of implementation of the present utility model are described below, however, it should not be considered that the description below defines or limits the scope of this utility model.

FIG. 1 shows a disposable mask 10 for performing a facial electrophoresis procedure according to the present invention, during which a person's face is complexly exposed to a low-power direct electric current (current is at least 3 mA, and preferably 5 mA) and various drugs. It should be noted that in the prior art, in particular in the field of medical cosmetology, the electrophoresis procedure performed by means of the mask 10 described below shown in FIG. 1 can also be called iontophoresis, ionotherapy, non-injection mesotherapy, or ionic mesotherapy.

The mask 10 shown in FIG. 1 comprises a main body or body 1 shaped and sized to cover substantially the entire face of a wearer, who is an average person, or only the top of it, when the mask 10 is put on or applied to the inside of the wearer's face.

In the body 1 of the mask, two holes 2 for the user's eyes and an opening 4 for the user's mouth are made, which allows the user to properly position the mask 10 on his face, which in turn makes it possible to affect only the target areas of the face when conducting facial electrophoresis using the mask 10 . It should be noted that the holes 2 for the eyes of the user are generally mirror-symmetrical with respect to the central axis of the mask body 1, extending in the middle or in the center of the mask body 1 between said holes 2, dividing the mask body 1 into two generally equal parts, and the opening 4 for the user's mouth is also made mirror-symmetrical with respect to the specified central axis. In addition, the body 1 of the mask has a cutout 3 for the user's nose, made in shape and size so that when the mask 10 is applied to the face of the user, the nose part of the body 1 of the mask moves away from the rest of the body 1 of the mask along the cutout line 3 and covers the whole only the bridge of the wearer's nose, leaving the nostrils of the wearer uncovered, so that the wearer wearing the mask 10 can breathe freely or unimpededly through the nose. It should also be noted that the cutout 3 for the user's nose is also made mirror-symmetrical with respect to the central axis of the mask body 1.

The body 1 of the mask is made multi-layered, and the base layer (not shown) in the body 1 of the mask contacts its inner side directly with the skin of the user's face when the user applies the mask 10 to his face and is made of a material based on polypropylene or polypropylene. However, it should be noted that any suitable woven or non-woven hydrophilic material known in the art and suitable for performing facial electrophoresis, including cellulose, can be used as the material of which the main layer of the mask body 1 is made.

In addition, the main layer of the mask body 1 is at least partially or completely pre-impregnated with a special serum used as a drug for electrophoresis of the user's face using the mask 10, so that the main layer of the polypropylene body 1 of the mask essentially serves as a hydrophilic pad to absorb the specified serum. The serum with which the main layer of the body 1 of the mask is impregnated consists of polyacrylamide gel and calcium carbonate, while, if necessary, various active substances can be added to the composition of this serum, selected depending on the target effect of electrophoresis carried out using the mask 10 in relation to the user's face. In one embodiment of the present invention, the base layer of the body 1 of the polypropylene mask can be impregnated with any drug known in the art for electrophoresis of a human face.

In addition, on the outer side of the main layer of the mask body 1 opposite to the inner side of the main layer of the mask body 1 that contacts the skin of the wearer's face, a substrate (not shown) made of calcium carbonate (CaCO3) and water-based acrylic is printed, and covering essentially the entire surface of said outer side, so that said substrate is essentially another functional layer of the mask body 1, adjoining with its inner side to the base layer of the mask body 1 and connected thereto.

In addition, a contact pad 5 and a contact pad 6 are applied to the substrate from its outer side opposite its inner side adjacent to the main layer of the mask body 1, and the contact pads 5, 6 are located in the frontal region of the mask body 1 at a predetermined distance from each other. other in such a way that the central axis of the body 1 of the mask runs in the middle or in the center of each of the contact pads 5, 6. The contact pads 5, 6 are designed to connect to them the corresponding terminals 60 of the current-generating device 100 described below, fixed on the body 1 of the mask from its outer side and allowing a controlled supply of direct electric current to the contact pads 5, 6 when the said current-generating device is activated or when it is turned on. It should be noted that the contact pads 5, 6 are each made by printing on the substrate from its outside a special paint containing stainless steel powder (medical steel) and water-based acrylic (water-based acrylic copolymer) in a 1: 1 ratio. weight. In one embodiment of the present invention, the contact pads 5, 6 may each be a conductive metal plate.

In addition, on the substrate made on the inner side of the mask body 1, the first group 7 of conductive paths are applied, electrically connected to the contact pad 5 to form a negative electrode (anode), and the second group 8 of conductive paths, electrically connected to the contact pad 6, to form positive electrode (cathode). In one embodiment of the present invention, the first group 7 of conductive tracks applied to the substrate can be electrically connected to the contact pad 5 to form a positive electrode (cathode), and the second group 8 of conductive tracks applied to the substrate can be electrically connected to contact pad 6 to form a negative electrode (anode).

In some embodiments of the present invention, the mask body 1 can be made in a single layer, i.e. exclusively from the above-described base layer of polypropylene, wherein the contact pads 5, 6 and the conductive tracks electrically connected thereto from the first and second groups 7, 8 of conductive tracks can be applied in the above-described manner directly to the polypropylene from its outer side opposite to its inner side, which it is applied to the skin of the user's face.

The first group 7 of conductive paths is formed of two conductive paths extending from the contact pad 5 in opposite directions, with each of these two conductive paths being branched, in particular, it has conductive branches in the form of petals or flowers in some of its sections (see Fig. 1), which makes it possible to expand the area of exposure to the skin of the face in the areas corresponding to the branched sections of the conductive paths from the first group of 7 conductive paths. It should be noted that the conductive paths from the first group 7 of conductive paths, including their above-described conductive branches, are generally mirror-symmetrical with respect to the central axis of the mask body 1. In addition, the conductive paths from the first group 7 of conductive paths first pass along the periphery of the frontal region of the mask body 1, then pass along the periphery of the temporal region of the mask body 1 and the zygomatic region of the mask body 1, and then pass along the periphery of the parotid-chewing region of the mask body 1 and end in the buccal region of the mask body 1, before reaching the chin region of the mask body 1, which ultimately allows the conductive paths from the first group 7 of conductive paths, having conductive branches in some of their sections, to cover most of the peripheral region of the mask body 1. It should also be noted that both conductive paths from the first group 7 of conductive paths have the same number of conductive branches in the corresponding branched sections, with the largest number of conductive branches located on the peripheral portion of the frontal region of the mask body 1, and an increased number of conductive branches located on the peripheral part of the chin and the temporal areas of the body 1 mask. Thus, the negative electrode formed by the above-described branched conductive paths from the first group 7 of conductive paths, electrically connected to the contact pad 5, is bifurcated, and both parts of the bifurcated negative electrode connected to each other by the contact pad 5 have the same or equal length along corresponding to the peripheral parts of the mask body 1, run in opposite directions from the contact pad 5 and are made mirror-symmetrical with respect to the central axis of the mask body 1.

The second group 8 of conductive paths is formed of two conductive paths extending from the contact pad 6 in opposite directions, with each of these two conductive paths being branched, in particular, having conductive branches in the form of petals or flowers in some of its sections (see Fig. 1), which makes it possible to expand the area of exposure to the skin of the face in the areas corresponding to the branched sections of the conductive paths from the second group of 8 conductive paths. It should be noted that the conductive paths from the second group 8 of conductive paths, including their above-described conductive branches, are generally mirror-symmetrical with respect to the central axis of the mask body 1. In addition, the conductive paths from the second group 8 of conductive paths first pass along the portable section of the nose region of the mask body 1 (the nose region of the mask body 1) between the holes 2 for the user's eyes, providing the conductive branches enter the sections of the nose region of the mask body 1, essentially corresponding the wings of the user's nose. In the future, the conductive paths from the second group of 8 conductive paths each go into the corresponding infraorbital region of the body 1 of the mask with the provision of additional bifurcation of each in the specified infraorbital region so that one part of the specified conductive path surrounds the corresponding one of the holes 2 for the user's eyes, passing through the infraorbital the area of the body 1 of the mask, crossing the zygomatic region of the body 1 of the mask and passing along the brow region of the frontal region of the body 1 of the mask with completion near the contact area 6, and the other part of the specified conductive path passes into the buccal region of the body 1 of the mask with completion in the specified buccal region, which ultimately allows the conductive paths from the second group of 8 conductive paths, having conductive branches in some of their sections, cover a large part of the central region of the body 1 of the mask. It should also be noted that both conductive paths from the second group of 8 conductive paths have the same number of conductive branches in the corresponding branched sections, with the largest number of conductive branches located in the superciliary region of the frontal region of the mask body 1, as well as the infraorbital region of the mask body 1 and the central region cheek area of the body 1 mask. Thus, the positive electrode formed by the above-described branched conductive paths from the second group 8 of conductive paths, electrically connected to the contact pad 6, is generally bifurcated, and both parts of the bifurcated positive electrode connected to each other by the contact pad 6 have the same or equal the length along the corresponding central parts of the body 1 of the mask, extend generally in opposite directions from the contact area 6 and are made mirror-symmetrical with respect to the central axis of the body 1 of the mask, and each of these two parts of the bifurcated positive electrode is additionally bifurcated in the corresponding infraorbital region of the body 1 of the mask ...

Note that, as shown in FIG. 1, the conductive paths from the first group 7 of conductive paths are substantially separated from the corresponding conductive paths from the second group of 8 conductive paths along their entire length over the surface of the mask body 1 by an equal or equal distance, generally corresponding to the distance between the contact pads 5, 6, i.e. .e. in fact, the negative and positive electrodes are located essentially at the same or equal distance from each other, corresponding to the distance between the contact pads 5, 6, along their entire length, which allows, in general, to obtain a uniform distribution of the electric field lines throughout the body 1 of the mask when applying electric current to the specified electrodes, in particular due to the same or equal resistance between the specified electrodes over their entire length. The above-described features of applying positive and negative electrodes to a substrate to obtain a pattern of conductive paths from the first and second groups 7, 8 of conductive paths shown in FIG. 1, allow for the uniform introduction of drugs into the skin of the user's face over the entire surface of these electrodes.

In addition, each of the above-described conductive paths from the first and second groups 7, 8 conductive paths is made of conductive paint, in particular from conductive ink, which include or that contain silver (Ag) in the form of microdispersed and nanodispersed silver and water-based acrylic , while for applying conductive ink on the specified substrate can be used by silk-screen printing or gravure printing. In another embodiment of the present invention, the conductive ink may be made of silver (Ag) and a suspension of a polyolefin in an organic solvent, which may be any suitable organic solvent known in the art, while applying the conductive ink to make the mask 10, the indicated solvent evaporates. It should be noted that due to the fact that the conductive paths from the first and second groups 7, 8 conductive paths are each made of conductive ink from silver (Ag) and water-based acrylic or silver (Ag) and polyolefin applied to the substrate in the body 1 of the mask , they have a low intrinsic resistance, which contributes to the most uniform distribution of electric current along the specified conductive paths, including their branches, which in turn contributes to the uniform introduction of the active substances of the serum, which is impregnated with the main layer of the body 1 of the mask, the depth of the user's face along the entire length of the above positive and negative electrodes.

In particular, the above-described conductive ink of silver (Ag) and water-based acrylic can be obtained by performing at least the following technological steps: (i) adding a 10% solution of sodium borohydride (NaBH4) used as a reducing agent to a 5% solution silver nitrate (AgNO3) at room temperature with simultaneous intensive stirring of the resulting solution until the end of the metal silver reduction process, i.e. until the cessation of intense gas evolution; (ii) decanting and multiple (6-8 times) washing the resulting precipitate with excess deionized water; (iii) carrying out drying of the silver (Ag) reduced in the above manner at a temperature in the range of 130 ° C to 150 ° C; and (iv) mixing the dried silver with a water-based acrylic copolymer: to about 1 gram of silver add about 1.1 grams of an acrylic copolymer water-based and 0.02 grams of polymethylsiloxane or polydimethylsiloxane.

Further, in FIG. 2 shows a block diagram of a current-generating device 100, fixed on the body 1 of the mask from its outer side in such a way that its leads 60 are brought into contact with the contact pads 5, 6 deposited on a substrate (not shown) in the body 1 of the mask, while for fastening of the current-generating device 100, any suitable fastening means known in the prior art can be used on the mask body 1, in particular, a snap fastener, a button, a button, hooks, a hook and loop fastener, a universal Velcro tape, an adhesive or adhesive tape, a magnetic tape , contact tape, burdock and / or the like. In one embodiment of the present invention, the body of the current-generating device 100 can be provided with small magnets, so that the current-generating device 100 can be easily attached by the user to the mask body 1 by magnetizing it to the contact pads 5, 6, which can each be configured as described above, in particular, each is made in the form of plates of stainless steel or of conductive ink containing, among other things, stainless steel powder, which makes it possible for the user to position the current-generating device 100 on the mask body 1 in a "blind" mode, ensuring accurate and proper connection of its terminals 60 to the contact pads 5, 6 and, therefore, the possibility of supplying the contact pads 5, 6 with a direct electric current when the current-generating device 100 is activated or when it is turned on. In addition, the current-generating device 100 also provides the ability to control the duration of the electrophoresis procedure on the user's face, as well as the intensity of the specified electrophoresis procedure.

In one embodiment of the present invention, the mask body 1 can be additionally provided with an adhesive or adhesive layer of constant width applied to the mask body 1 from its inner side. The adhesive layer with which the mask body 1 can be provided can extend over the entire or substantially the entire perimeter of the mask body 1, so that the adhesive layer can substantially occupy the edge or edge of the mask body 1 around its entire perimeter or substantially around the entire perimeter of the body 1 of the mask and may generally correspond in shape to the contour of the body 1 of the mask. Alternatively, an adhesive layer of constant width may be attached to the mask body 1 in such a way that it extends outside the mask body 1 and surrounds it at least partially or completely. As the adhesive or adhesive forming the adhesive layer in both of the above-described embodiments, for example, an acrylic copolymer adhesive known in the art, a synthetic rubber hot melt adhesive (SPA adhesive) known in the art, and / or any other suitable adhesive known in the art. In particular, as the adhesive or adhesive forming the adhesive layer, for example, an acrylic copolymer adhesive known in the art, a synthetic rubber hot melt adhesive known in the art (SPA adhesive), and / or any another suitable adhesive known in the art. It should be noted that an acrylic copolymer adhesive suitable for forming an adhesive layer may contain, for example, 49% acrylic and 51% water, while rosin resin may be added to this composition. As the synthetic rubber adhesive suitable for forming the adhesive layer, for example, Adtek (Zakley) 905 M glue, Technomelt PSM 9060 glue, JaourTak 2801HCH glue or the like can be used. It should also be noted that adhesives based on acrylic copolymer and hot melt adhesives based on synthetic rubbers each retain their stickiness even when the user repeatedly puts on / removes or attaches / detaches the mask 10, which makes it possible for the mask body 1 to fit snugly with its inner side to the skin of the face. the user, while these adhesives do not each cause pressure ulcers at the points of attachment of the body 1 of the mask to the skin of the user's face even when the user carries out electrophoresis for a relatively long time using the mask 10, and also do not cause each occurrence of allergies on the skin of the user's face when the mask 10 is used by the user.

In one embodiment of the present invention, zinc oxide (ZnO) may be added to the adhesive forming the adhesive layer with which the mask body 1 may be provided. It should be noted that zinc oxide added to the composition of the adhesive that forms the adhesive layer significantly reduces the likelihood of skin irritation at the points of contact of the adhesive layer with the user's skin, which can distort the surface relief of the facial skin at these contact points (for example, due to the appearance of acne , rash, scratching, etc. in the indicated contact points), as a result of which damage or microcracks may occur in areas or areas with a distorted relief of the facial skin surface, which in turn contribute to a deterioration in the visual effect of using the mask 10 on the user's face , in particular, when moisture gets there in the form of sweat, components of the used whey or chemical products. reactions occurring during the electrophoresis procedure itself using the mask 10. It should also be noted that in order to ensure the above-described advantages of using zinc oxide (ZnO) in the adhesive that forms the adhesive layer, in particular, an adhesive based on an acrylic copolymer or a hot melt adhesive based on synthetic rubbers, it is enough to add ZnO in the amount of 1% by weight of the specified adhesive, i.e. 1 wt%.

In another embodiment of the present invention, the mask 10 can be worn or applied by the user to his or her face using special straps, elastic bands or similar fastening or fixing means, covering the user's head, user's ears or other parts of the user's head, ensuring that the mask is held on the user's face in close contact with the skin of the user's face, which ultimately helps to improve the efficiency of the electrophoresis procedure carried out on the user's face using the mask 10.

In some embodiments of the present invention, the mask 10 can be used several or many times, in particular after proper cleaning of the mask body 1 (for example, washing its base layer in distilled water) followed by re-impregnation of the base layer of the mask body 1 with a special serum or other a drug previously used during electrophoresis of the user's face using a mask 10.

During the electrophoresis procedure, the user applies the serum-impregnated base layer mask 10 shown in FIG. 1, on its face, ensuring its proper positioning, at least by placing its eyes exactly in the holes 2 for the eyes of the user and your mouth exactly in the hole 4 for the mouth of the wearer, and further activates the tocogenerating device 100 attached to the body 1 of the mask, shown in block diagram form in FIG. 2 by pressing a power button (not shown) located on the body of the current-generating device 100. Turning on the current-generating device 100 allows a controlled supply of galvanic (direct) electric current from the current-generating device 100 to the above-described positive and negative electrodes provided on the mask body 1 on the above-described the substrate, which makes it possible for the serum or other drug under the above-described conductive paths from the first and second groups 7, 8 conductive paths, including their corresponding branches, to decompose into ions (charged particles) with the provision of movement of these ions in an electric field, while positively charged serum ions will be repelled from the positive electrode and penetrate deep into the skin (epidermis) of the user's face, while negatively charged serum ions will be repelled from the negative electrode and penetrate deep into the skin (epidermis mis) the user's face as well. Thus, the above-described electrophoresis procedure makes it possible to inject serum or another drug under the skin of the user's face, in particular into the main problem areas of the user's face, while the main routes of drug penetration are the excretory streams of the sweat and sebaceous glands and, to a lesser extent, are skin cells and intercellular cracks. The positively and negatively charged ions introduced in the above described manner into the skin (epidermis) of the user's face accumulate in the upper layers of the dermis, going to a depth of 1.5-2 cm, while in the affected area after the electrophoresis procedure, a skin depot will be formed, from which the drug will gradually penetrate into the cells of the user's face (the period of action of the drug can be from 3 hours to 15-20 days). It should be noted that the amount of ions accumulated under the skin of the user's face using the above-described electrophoresis procedure will depend on the current strength, the duration of exposure to direct current, the concentration of the drug, and the physiological state of the user's facial skin. At a certain concentration of ions, the cells of the facial skin pass into an excited (electrically active) state, the cellular and tissue metabolism, as well as the excitability of these cells, change, while the passive transport of large protein molecules and other substances that do not carry a charge (electrodiffusion) and hydrated ions ( electroosmosis), which means the acceleration of cellular and intracellular renewal: a rapid supply of building material, nutrients and regulating substances, as well as the timely removal of metabolic products from the user's facial skin cell. Thus, the above-described electrophoresis procedure carried out using the mask 10 and the current-generating device 100 attached to it, can accelerate the regeneration of the skin cells of the user's face.

It should also be noted that calcium carbonate, which is part of the above-described serum, preferably used as a drug during the electrophoresis procedure using the mask 10 and the current-generating device 100 attached to it, acts as a ph level stabilizer, since during the electrophoresis procedure, hydrochloric acid (HCl) and alkali NaOH (sodium hydroxide). Calcium carbonate neutralizes the action of HCl and NaOH, chemically neutralizing them. In addition, calcium carbonate does not allow oxidation of the above-described positive and negative electrodes of the mask 10, in particular their conductive paths made of conductive ink, and also prevents the formation of AgO / Ag2O / AgCl, which provides maximum safety for the user, preventing the occurrence of chemical burns, provides an opportunity using the mask 10 with a minimum volume of water, and also provides the possibility of carrying out the electrophoresis procedure in a mode in which the above-described positive and negative electrodes occupy a static position on the skin of the user's face.

It should also be noted that the mask 10 according to the present utility model with a conductive device 100 attached to it is created at the place of its manufacture (for example, in a special workshop or industrial premises) with its subsequent implementation as a final product, but in other embodiments of this useful model, the conductive device 100 can be attached to the mask body 1 as needed, i. e. immediately before using the mask 10 by the user for the electrophoresis procedure.

Further, as shown in FIG. 2, the current-generating device 100 comprises a housing (not shown) in which a rechargeable power supply 40 in the form of a lithium battery (Li-Ion battery) is placed and the hardware is fixed in the form of a single multilayer printed circuit board, on which the control microcontroller 20 is located, among the functional components which has an analog-to-digital converter (ADC) and a pulse-width modulation (PWM) module and which is connected to a power source 40, and an electric field formation unit 30 connected directly to a power supply 40 and connected to the PWM of the microcontroller 20 to enable precise adjustment of the output voltage provided by the electric field generating unit 30 to the terminals 60 connected to the corresponding contact pads 5, 6 of the mask 10 shown in FIG. 1, while the output of the electric field generating unit 30 is additionally connected to a current and voltage feedback circuit 50 connected to the ADC of the microcontroller 20 to enable voltage stabilization at the output of the electric current generating unit 30. In addition, the body of the current-generating device 100 is provided with an on button connected to the microcontroller 20 so that it can be started / turned on 25 or turned off. In addition, a programmer (not shown) is connected to the microcontroller 20, which is located on a multilayer printed circuit board of the current-generating device 100 and provides the ability to program its operation by loading the necessary set of control instructions into the memory of the microcontroller 20. In addition, a charger (not shown) is connected to the power supply 40, allowing the power supply 40 to be charged, while the charger is powered via a microUSB connector. It should be noted that the microcontroller 20 is connected to the power source 40 by means of a linear voltage regulator, which provides a stable supply voltage to the functional units and / or components of the microcontroller 20, including its computing core, radio path, ADC, etc. If necessary, the microcontroller 20 may additionally contain a Bluetooth module.

The electric field generating unit 30 is a 10 pulse boost converter based on the use of an inductive energy storage and a power transistor, while the current and voltage feedback circuit 50 makes it possible to control the voltage parameters output by the electric field generating unit 30 to the terminals 60. Circuit 50 current and voltage feedback contains a shunt in the form of a precision resistor for current control and a voltage divider for voltage control, consisting of two precision resistors and a low-pass filter (LPF).

It should be noted that the PWM control signal is generated by a timer built into the microcontroller 20, and is then fed to the gate of the power transistor, which is part of the boost pulse converter from the electric field generating unit 30, while the boost pulse converter, when operating in the key mode, provides a linear dependence between the voltage at the output of the boost pulse converter and the duty cycle of the control signal, which provides the ability to precisely adjust the output voltage over a very wide range (from 5 V to 100 V). To stabilize the voltage at the output of the boost pulse converter, an ADC of the microcontroller 20 is used, which measures the voltage at the output of the boost pulse converter at a given frequency and makes appropriate adjustments to the duty cycle of the PWM signal. It should also be noted that the shunt included in the current and voltage feedback circuit 50 acts as a sensor that detects the electric current flowing through the user's skin, while the voltage drop across said shunt is measured by the ADC of the microcontroller 20 through the feedback circuit 50 on current and voltage, and depending on the result obtained, control commands are generated for the PWM of the microcontroller 20, which ultimately makes it possible to stabilize the specified electric current, in particular, it maintains with high accuracy the specified current strength, which is about 3mA.

Claims (10)

1. Mask for face electrophoresis, containing main part, in which holes for the user's eyes are made, characterized in that the main part is provided with positive and negative electrodes, each made in such a way that the conductive paths of one of these electrodes cover the central region of the main part, and the conductive paths of the other electrode cover the peripheral region of the main parts, while the main part is additionally equipped with contact pads, electrically connected to the specified electrodes with the possibility of supplying them with electric current. 2. The mask according to claim. 1, in which each of said electrodes is made bifurcated in such a way that conductive paths of one of its parts and conductive paths of another part of it run in opposite directions. 3. The mask of claim 2, wherein the conductive paths of one of the portions of each bifurcated electrode and corresponding conductive paths of the other portion of said bifurcated electrode extend generally symmetrically with respect to a central axis extending midway through the body between the user's eye holes. 4. Mask according to any one of paragraphs. 1-3, in which the said contact pads are located in the frontal region of the main part at a distance from each other, and the conductive paths, covering the central region of the main part and electrically connected to one of the said contact pads, each pass through the region of the bridge of the main part with subsequent coverage corresponding to one of the user's eye holes. 5. Mask according to any one of paragraphs. 1-4, in which the conductive paths are each formed from a conductive paint containing silver (Ag) and water-based acrylic. 6. Mask according to any one of paragraphs. 1-4, in which the conductive tracks are each made of a conductive paint containing silver (Ag) and a polyolefin. 7. Mask according to any one of paragraphs. 1-6, in which the conductive tracks are formed on a substrate applied to the body, said substrate being made of calcium carbonate (CaCO3) and water-based acrylic. 8. Mask according to any one of paragraphs. 1-7, in which the main part is pre-impregnated with serum for electrophoresis. 9. Mask according to any one of paragraphs. 1-8, in which the conductive paths of said electrodes extend substantially at the same distance from each other.

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