JP2023087645A - Nanofiber laminated sheet - Google Patents

Abstract

To provide a sheet and a method for easily forming gel or film in a short time on a surface, a wound area, or the like of a face.SOLUTION: A gel forming sheet has: a substrate sheet; a nanofiber sheet provided on a surface of the substrate sheet; a gelling region regulating sheet provided on a surface of the nanofiber sheet; a cover sheet provided on a surface of the gelling region regulating sheet in a peelable manner. The nanofiber sheet is gelled by the presence of moisture. For example, the present invention provides a sheet and a method for protecting a scratch by cosmetic effect or wound coating, and pasting a medicine.SELECTED DRAWING: None

Description

The present invention relates to gel-forming sheets and methods of using the gel-forming sheets for forming sheet-like gels on the skin.

Most cosmetics achieve their purpose by the method of "coating". Whether it's foundation or lipstick when applying makeup, or serum or cream to improve the skin's function of moisturizing, it can be used with fingers, palms, spatulas, etc. It depends on the method of "painting" on the part to be painted.

Recently, there have been products that apply beauty essence processed into microneedles to the skin and dissolve it to improve the beauty effect of the applied part, but there are only a few of them when compared to cosmetics as a whole. On the other hand, there are many medical devices and pharmaceutical products that achieve their purpose by "pasting" them. In the case of medical equipment, there are sanitary products such as band-aids and wound healing sheets. Patches and the like are common in pharmaceuticals. Until now, many types of beauty ingredients, medical devices, and pharmaceuticals have been developed and provided, but there are individual differences in the parts of the human body to which these are applied, and there are individual differences in the unevenness of the surface. In order to achieve this, various ideas have been devised from the viewpoint of materials, such as changing the material of the patch to a flexible one or a thinner one.

In recent years, as in Patent Document 1 (Patent No. 6480059), a method of creating a thin film such as urethane directly on the surface of the face to hide scratches etc. As in Document 2 (Japanese Patent Application Laid-Open No. 2021-168948), a method has been developed and commercialized to cover scars, wrinkles, sagging, etc. by reacting two types of polymer solutions directly on the skin. However, these methods require a special device (electrospinning device) or a special polymer solution, or use a special jig to apply the polymer solution to the skin in two steps, and it takes a long time to complete the reaction. It was hard to say that it was practical, such as waiting for time.

Patent No. 6480059 Japanese Patent Application Laid-Open No. 2021-168948

An object of the present invention is to provide a sheet and a method for easily forming a gel or film on the surface of the face, a wound site, or the like in a short time. For example, the present invention provides sheets and methods for cosmetic effects, protection of wounds by wound dressing, application of drugs, and the like.

In order to solve the above problems, the present invention has the following features.
(Item 1)
a base sheet, a nanofiber sheet detachably provided on the surface of the base sheet, a gelation region defining sheet provided on the surface of the nanofiber sheet, and peeled from the surface of the gelation region defining sheet and a cover sheet provided thereon.
(Item 2)
A gel-forming sheet comprising a base sheet, a nanofiber sheet provided on the surface of the base sheet, and a cover sheet provided on the surface of the nanofiber sheet, wherein the base sheet is a mesh sheet with a large number of pores.
(Item 3)
3. The gel-forming sheet according to item 2, wherein the base sheet has an initial electrification voltage of more than 0.3 kV as measured by the half-life measuring method specified in JIS L1094.
(Item 4)
2. The gel-forming sheet according to item 1, wherein the nanofiber sheet and the gelation region defining sheet are attached with an adhesive.
(Item 5)
The gel-forming sheet according to item 1, wherein the gelled region defining sheet and the cover sheet are attached with an adhesive.
(Item 6)
3. The gel-forming sheet according to item 1 or 2, wherein the nanofiber sheet is a sheet formed on the surface of the base sheet by an electrospinning method.
(Item 7)
3. The gel-forming sheet according to item 1 or 2, wherein the nanofiber sheet is gelled by the addition of moisture.
(Item 8)
3. The gel-forming sheet according to item 1 or 2, wherein the nanofiber sheet is gelled by moisture on the surface to which the nanofiber sheet is attached.
(Item 9)
3. The gel-forming sheet according to item 1 or 2, wherein the nanofiber sheet contains sodium hyaluronate and polyvinyl alcohol, sodium alginate and polyethylene oxide, collagen, or silk protein.
(Item 10)
3. The gel-forming sheet according to item 1 or 2, wherein the nanofiber sheet carries a positive charge and the base sheet carries a negative charge.
(Item 11)
The gel-forming sheet according to item 1, wherein the base sheet is a nonwoven fabric.
(Item 12)
12. The gel-forming sheet according to item 11, wherein the nonwoven fabric is made of a polymer compound.
(Item 13)
13. The gel-forming sheet according to item 12, wherein the polymer compound is selected from the group consisting of polyethylene, polypropylene, nylon, polyester, polyurethane, polystyrene, and polyethylene-vinyl acetate copolymer.
(Item 14)
3. The gel-forming sheet according to item 2, wherein the base sheet is a plastic mesh sheet.
(Item 15)
15. The gel-forming sheet according to item 14, wherein said plastic mesh sheet is formed from a material selected from the group consisting of polyethylene, polypropylene, nylon, polyester, polyurethane, polystyrene, and polyethylene-vinyl acetate copolymer.
(Item 16)
3. The gel according to item 1 or 2, wherein the nanofiber sheet contains at least one cosmetic selected from the group consisting of moisturizing creams, skin creams, whitening creams, milky lotions, lotions, beauty essences, and beauty gels. forming sheet.
(Item 17)
3. The gel-forming sheet of item 1 or 2, wherein the nanofiber sheet comprises a therapeutic agent.
(Item 18)
A first base sheet, a first nanofiber sheet detachably provided on the surface of the first base sheet, and a gelation region defining sheet provided on the surface of the first nanofiber sheet a second nanofiber sheet provided on the surface of the gelled region defining sheet; and a second base sheet releasably provided on the surface of the second nanofiber sheet. Gel-forming sheet.
(Item 19)
19. The double gel-forming sheet according to item 18, wherein the first nanofiber sheet and the gelled region defining sheet are attached with an adhesive.
(Item 20)
19. The double gel-forming sheet according to item 18, wherein the gelled region defining sheet and the second nanofiber sheet are attached with an adhesive.
(Item 21)
19. The dual gel-forming sheet of item 18, wherein said first and second nanofiber sheets gel with the addition of moisture.
(Item 22)
19. The double gel-forming sheet according to item 18, wherein the first and second nanofiber sheets are gelled by moisture on the surface to which the double gel-forming sheet is attached.
(Item 23)
a first base sheet, a first nanofiber sheet provided on the surface of the first base sheet, and a second nanofiber sheet provided on the surface of the first nanofiber sheet; and a cover sheet releasably provided on the surface of the second nanofiber sheet.
(Item 24)
a first base sheet, a first nanofiber sheet provided on the surface of the first base sheet, and a second nanofiber sheet provided on the surface of the first nanofiber sheet; and a second base sheet provided on the surface of the second nanofiber sheet, wherein the first base sheet and the second base sheet at least one of is releasably disposed on the nanofiber sheet.
(Item 25)
25. The dual gel-forming sheet of item 23 or 24, wherein said first and second nanofiber sheets gel upon the addition of moisture.
(Item 26)
25. The double gel-forming sheet according to item 23 or 24, wherein the first and second nanofiber sheets are gelled by moisture on the surface to which the double gel-forming sheet is attached.

ADVANTAGE OF THE INVENTION According to this invention, the sheet|seat and method for forming a gel or a film easily for a short time on the surface of a face, a wound site, etc. are provided. For example, the present invention provides sheets and methods for cosmetic effects, protection of wounds by wound coating, application of drugs, and the like.

By allowing the nanofiber sheet to contain a predetermined component (cosmetic component, therapeutic component, etc.), a gel containing such a predetermined component can be formed on the skin. In addition, a gel containing such a predetermined component can be formed on the skin by adding a predetermined component (beauty component, therapeutic component, etc.) to the aqueous solution used for gel formation.

1 is a cross-sectional view of a gel-forming sheet according to one embodiment of the present invention; FIG. 1 is a cross-sectional view of a gel-forming sheet according to one embodiment of the invention, comprising an adhesive; FIG. Fig. 3 is a plan view of the gelled region defining sheet shown in Figs. 1 and 2; In FIG. 3, the central portion of the gelled region defining sheet is punched out. It is an example of use of the gel-forming sheet of the present invention. 1 is a schematic illustration of a nanofiber sheet manufacturing apparatus of the present invention. FIG. FIG. 2 shows an example of producing the double gel-forming sheet of the present invention. Fig. 2 shows a double gel-forming sheet of the present invention; 1 is a cross-sectional view of a gel-forming sheet according to one embodiment of the present invention; FIG. 1 is a cross-sectional view of a double gel-forming sheet according to one embodiment of the present invention; FIG. 1 is a cross-sectional view of a double gel-forming sheet according to one embodiment of the present invention; FIG. 1 is a photograph of a facial nanofiber sheet made from a gel-forming sheet according to an example of the present invention. (A) Photograph of the nanofiber sheet for face placed on the face, (B) Photograph of the nanofiber sheet for face placed on the face after being sprayed with purified water.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

As shown in FIG. 1, the gel-forming sheet (10) includes a base sheet (11), a nanofiber sheet (12) detachably provided on the surface of the base sheet (11), and a nanofiber sheet (12). ) and a cover sheet (14) detachably provided on the surface of the gelled region defining sheet (13).
In one aspect of the present invention, as shown in FIG. 8, the gel-forming sheet (10) comprises a base sheet (11), a nanofiber sheet (12) provided on the surface of the base sheet (11), and a cover sheet (14) provided on the surface of the nanofiber sheet (12).

The nanofiber sheet and the gelled region defining sheet may be attached with an adhesive (15). Also, the gelled region defining sheet and the cover sheet may be attached with an adhesive (15).

In the gel-forming sheet (10), the nanofiber sheet (12) and the gelation region defining sheet (13) are attached with an adhesive (15), and the gelation region defining sheet (13) and the cover sheet (14) are attached. FIG. 2 shows a gel-forming sheet (20) prepared by pasting the above with an adhesive (15).

The base sheet, the nanofiber sheet, the gelation region defining sheet, and the cover sheet, even if they have substantially the same planar shape, are further provided with a gripping portion for facilitating operations for attaching and detaching the sheets. may be The gelled area-defining sheet comprises perforated areas and/or missing areas, in which the perforated areas and/or missing areas are targeted for the intended formation of a gel. The site (eg, the area of interest on the skin) is directly contacted with the nanofiber sheet.

FIG. 3 shows an example of the gelled region defining sheet (13). The central portion of the gelled region defining sheet shown in FIG. 3 is punched out. In this punched part, the nanofiber sheet can directly contact the target site such as the skin. The gelled region-defining sheet does not necessarily include a punched region. Formation of a gel may be intended in the region.

FIG. 4 shows an example of gel formation by the gel-forming sheet of the present invention. (a) is the gel-forming sheet of the present invention. (b and c) Peel off the cover sheet from the gel-forming sheet. (d) Affix the surface from which the cover sheet has been removed to a predetermined location on the skin. (e, f, and g) Peel off the base sheet from the sheet attached to a predetermined place such as the skin (this leaves the nanofiber sheet and the gelled area defining sheet on the skin without being peeled off). An aqueous solution or water is added to the nanofiber sheet and the gelled region defining sheet remaining on the skin to gel it. (h) Peel off the gelled region defining sheet. The photograph in Fig. 4h shows that the nanofibers have all gelled and transferred to the skin, leaving only the sheet in the gel-forming region.

Alternatively, in gel formation with the gel-forming sheet of the present invention, an aqueous solution or water is applied to a target area (for example, a skin area) in advance, and the gel-forming sheet of the present invention is attached thereon. , may form a gel. An example of such a procedure includes, for example: (1) peeling the cover sheet from the gel-forming sheet; (3) (a) peel off the base sheet from the sheet attached to the target area, and then peel off the sheet defining the gelled area; or (b) target. By simultaneously peeling off the base sheet and the gelling area defining sheet attached to the target area, the gel formed in the target area remains without being peeled off.

In the present invention, a double gel-forming sheet containing two types of nanofiber sheets as shown in FIG. 7 can be produced. For example, as illustrated in FIG. 6, a first sheet (30) is produced by forming a first nanofiber sheet (32) on a first base sheet (31), and a second base sheet is prepared. A second sheet (40) having a second nanofiber sheet (42) formed thereon (41) is prepared. Next, a double gel-forming sheet is produced by stacking the first sheet and the second sheet so that the gelation region defining sheet (33) is sandwiched between the sheets. In this case, one side or both sides of the gelled region defining sheet may be attached to the nanofiber sheet with an adhesive.

Alternatively, a double gel-forming sheet is produced as described above, and a third sheet is produced by forming a third nanofiber sheet on the third base sheet, and the first nanofiber sheet in the double gel-forming sheet is produced. A triple gel-forming sheet can also be produced by peeling off either one of the base sheet or the second base sheet and attaching the third nanofiber sheet of the third sheet to that surface. can. In the case of producing a triple gel-forming sheet, the gelation region defining sheet is not used when producing the double gel-forming sheet. , a gelled region defining sheet may be sandwiched. A multiple gel-forming sheet containing four types (four sheets) or more of nanofiber sheets can also be produced by a similar method.

For example, in spite of the fact that a plurality of components are required for gel formation, it is difficult to form the plurality of components as the same nanofiber sheet (for example, a combination of hyaluronic acid and collagen). are formed as separate nanofiber sheets to produce a double gel-forming sheet (or a multiple gel-forming sheet, such as a triple gel-forming sheet) as described above, and used as the gel-forming sheet of the present invention to target It is possible to form a gel in the region where

The site where the gel-forming sheet of the present invention forms a gel does not necessarily have to be the skin. The gel-forming sheets of the present invention are capable of forming gels on any surface where gel formation is desired.

(base material sheet)
Examples of the base sheet include polyolefins such as high-density polyethylene, medium-density polyethylene, low-density polyethylene, polypropylene, polyester, polyvinylidene chloride, nylon, chitosan, starch, polyvinyl alcohol, polyvinyl acetate, or copolymers thereof or A sheet made of a modified material or the like can be used.

In particular, polyolefin fibers such as polyethylene (PE) and polypropylene (PP), polyester fibers such as polyethylene terephthalate (PET), polytrimethylene terephthalate (PTT) and polyethylene naphthalate (PEN), polyamide fibers such as nylon, rayon fibers, Nonwoven fabrics made of other synthetic fibers, and nonwoven fabrics produced by mixing Japanese paper, cotton, silk, hemp, pulp (cellulose) fibers, and the like can be used.

Among these nonwoven fabrics, nonwoven fabrics made of rayon fibers, polyolefin fibers, and polyester fibers are preferred. Preferably, the base sheet is a nonwoven fabric made of polypropylene or rayon, and most preferably a nonwoven fabric made of heat-treated (spunbonded) polypropylene or rayon.
As the base sheet, a mesh sheet such as a resin mesh sheet, typically a plastic mesh sheet, may be used. When using a mesh sheet as the base sheet, for example, a mesh sheet having a large number of openings can be used. When the nanofiber sheet is peeled from the base sheet for use, the base sheet needs to be treated to facilitate the peeling of the nanofiber sheet from the base sheet. For example, in Japanese Patent No. 5563908, the initial charged voltage measured by the half-life measurement method specified in JIS L1094 for the base sheet is 0.3 kV or less (or the surface resistivity is 10 ¹² Ω or less, preferably 10 ¹⁰ Ω or less). This is because, in general, when directly spun onto a plastic mesh, the nanofiber sheet, which is prevented by the electrostatic property of the plastic mesh, is strongly bonded to the substrate and cannot be easily peeled off from the substrate. Therefore, in the prior art disclosed in Japanese Patent No. 5563908, etc., when using a plastic mesh, it was necessary to subject the substrate to antistatic treatment in advance. In contrast, in the present invention, it is not always necessary to separate the base sheet from the nanofiber sheet before use. For example, in the present invention, the base sheet and the nanofiber sheet are attached to the target area such as the skin without being peeled off, and the nanofiber sheet is gelled by applying moisture from above. A gel forms on the area. When gel is formed, the base sheet is easily peeled off from the gel.
Therefore, when a mesh sheet (for example, a resin sheet such as a plastic sheet) is used as a base sheet in the present invention, the base sheet does not need to be antistatic in advance. By forming a stable nanofiber sheet on the mesh sheet, it is possible to prevent the nanofibers from coming off or peeling off from the mesh sheet during punching, packaging, and other processes. Therefore, when a mesh sheet is used as a base sheet in the present invention, it is preferable to use a sheet that has not been previously subjected to antistatic treatment. When a mesh sheet is used as a base sheet in the present invention, the initial charged voltage is preferably more than 0.3 Kv, more than 0.31 Kv, more than 0.32 Kv, more than 0.33 Kv, more than 0.34 Kv greater than, greater than 0.35 Kv, greater than 0.36 Kv, greater than 0.37 Kv, greater than 0.38 Kv, greater than 0.39 Kv, or greater than 0.4 Kv. Alternatively, when a mesh sheet is used as a base sheet in the present invention, the surface resistivity is preferably 10 ¹⁰ Ω or more, 10 ¹¹ Ω or more, or 10 ¹² Ω or more.
In the prior art, sheets made on mesh substrates are water-insoluble, requiring conditions for delamination from the substrate. For example, in Japanese Patent No. 5563908, a substrate is subjected to surfactant treatment or corona treatment to reduce the initial withstand voltage to 0.3 kv or less, thereby facilitating delamination. In contrast, in one aspect of the present invention, delamination is not required because the sheet formed on the substrate gels with moisture and separates from the substrate. Rather, when the base material surface has an initial withstand voltage of more than 0.3 kv, the nanofiber layer firmly adheres to the base material, thereby exhibiting an excellent effect of facilitating the subsequent punching process.
In addition, when a mesh sheet is used as a base sheet, the base sheet and nanofibers are applied to an application site such as the skin without peeling off, and the water part that has been present in the application site in advance is used, and/or the moisture content is reduced. is applied from the substrate sheet, it is possible to form a gel at the application site. Therefore, when a mesh sheet is used as the base sheet, it is not always necessary that the base sheet and the nanofibers can be peeled off. In addition, when a mesh sheet is used as the base sheet, the base sheet helps to maintain the shape of the nanofiber sheet when the nanofiber sheet is applied to the application site. The shape of the nanofiber sheet is maintained even without it.

(nanofiber sheet)
The nanofiber sheet as used herein includes, for example, a fibrous structure composed of nanofibers obtained by an electrospinning method (electric field prevention method). A method for producing nanofibers is not particularly limited, and other well-known methods can be used. Nanofibers refer to ultrafine fibers of submicron or nanometer order. Nanofibers obtained by the electrospinning method usually have a length of 100 μm or more and a fiber diameter in the range of 30-2000 nm (especially 50-800 nm). Sheet thickness is typically 5 to 30 microns.

The polymer solution used to prepare the nanofiber sheet is not particularly limited, but is preferably a polymer solution that gels when an aqueous solution or water is applied to the nanofiber sheet. Such polymer solutions include solutions containing hyaluronic acid and polyvinyl alcohol, and solutions containing alginic acid and polyethylene oxide. In addition, water-soluble polymers that are highly soluble in water and that do not form insoluble components in an aqueous solution are also preferred, such as collagen, silk protein, hydroxypropyl cellulose, carboxymethyl cellulose, pectin, locust bean gum, Carrageenan, pullulan, and the like include, but are not limited to. Various polysaccharides and proteins such as collagen, hyaluronic acid, silk protein, alginic acid, and silk protein are particularly preferred in consideration of skin compatibility.

A nanofiber sheet can be produced by spinning and depositing nanofibers on the surface of a substrate sheet using an electrospinning method, but other well-known methods are used to produce the nanofiber sheet. is also possible.

(Electrospinning method)
FIG. 5 shows a schematic of an apparatus 30 for carrying out the electrospinning method. This device 9 comprises a syringe 1 , a high voltage source 3 and a conductive collector 4 . The syringe 1 comprises a cylinder 1a, a piston 1b and many capillaries 1c.

The cylinder 1a is filled with a polymer solution containing a high-molecular compound as a raw material of nanofibers. The positive pole of the high voltage source 3 is in communication with the polymer solution in the syringe 1 . The negative electrode of the high voltage source 3 is grounded. The conductive collector 4 is, for example, a metal plate and is grounded. While a voltage is applied between the syringe 1 and the conductive collector 4, the piston 1b of the syringe 1 is gradually pushed in to push out the polymer solution from the tip of the capillary 1c. The solvent in the extruded polymer solution evaporates, and the solute polymer compound solidifies, forms nanofibers while being stretched and deformed by the potential difference, and is attracted to the conductive collector 4 . By disposing the base sheet 2 on the surface of the conductive collector 4 , nanofibers are deposited on the surface of the base sheet 2 . When a nanofiber sheet is formed by spinning nanofibers onto the base sheet 2 by an electrospinning method, the nanofiber sheet generally carries a positive charge and the base sheet 2 carries a negative charge.

The polymer solution may contain other ingredients in addition to the polymer compound for forming the nanofiber sheet. Such ingredients include, for example, cosmetic ingredients, therapeutic ingredients, color pigments, fragrances, surfactants, antistatic agents, and the like.

(Gelling area regulation sheet)
A gelation area defining sheet may be provided between the nanofiber sheet and the application site to limit the gelation area of the nanofiber sheet. Further, when the nanofiber sheet has the shape of a gel-forming region in advance, it is not necessary to provide the gelled region defining sheet (see FIG. 8). As the gelled region defining sheet, the same material as that of the base sheet may be used, or a material different from that of the base sheet may be used.

Preferably, polyolefin fibers such as polyethylene (PE) and polypropylene (PP), polyester fibers such as polyethylene terephthalate (PET), polytrimethylene terephthalate (PTT), and polyethylene naphthalate (PEN), polyamide fibers such as nylon, and rayon fibers. , nonwoven fabrics made of other synthetic fibers, and nonwoven fabrics produced by mixing cotton, silk, hemp, pulp (cellulose) fibers, and the like.

Among these nonwoven fabrics, nonwoven fabrics made of rayon fibers, polyolefin fibers, and polyester fibers are preferred. Especially preferably, the cover sheet is a nonwoven fabric made of polypropylene or rayon, or a nonwoven fabric made of heat-treated (spunbonded) polypropylene or rayon. Moreover, in the present invention, Japanese paper may be used as the gelled region defining sheet.

The gelled region defining sheet defines a gel-forming region. That is, the gelled region-defining sheet has punched regions and/or missing regions, and the nanofiber sheet directly forms a gel in the punched regions and/or missing regions. Contact the targeted site (eg, skin) where formation is intended.

(cover sheet)
As the cover sheet, the same material as that of the base sheet may be used, or a material different from that of the base sheet may be used.

Preferably, polyolefin fibers such as polyethylene (PE) and polypropylene (PP), polyester fibers such as polyethylene terephthalate (PET), polytrimethylene terephthalate (PTT), and polyethylene naphthalate (PEN), polyamide fibers such as nylon, and rayon fibers. , nonwoven fabrics made of other synthetic fibers, and nonwoven fabrics produced by mixing cotton, silk, hemp, pulp (cellulose) fibers, and the like.

Among these nonwoven fabrics, nonwoven fabrics made of rayon fibers, polyolefin fibers, and polyester fibers are preferred. Especially preferably, the cover sheet is a nonwoven fabric made of polypropylene or rayon, or a nonwoven fabric made of heat-treated (spunbonded) polypropylene or rayon.

(adhesive)
In the gel-forming sheet (10), the nanofiber sheet (12) and the gelation region defining sheet (13) may be attached together with an adhesive (15). If no adhesive is used, they may be attached by electrostatic interaction, hydrophobic interaction, or the like. Furthermore, the gelled area defining sheet (13) and the cover sheet (14) may be attached with an adhesive (15). If no adhesive is used, they may be attached by electrostatic interaction, hydrophobic interaction, or the like.

As the adhesive, for example, an acrylic resin-based or rubber-based adhesive can be used. Examples of the main agent include, but are not limited to, poly(meth)acrylic acid ester, chlorinated rubber, natural rubber, synthetic rubber, and recycled rubber. A preferred adhesive is an acrylic resin-based adhesive.

(Production of gel-forming sheet)
The production of the gel-forming sheet of the present invention is not limited, but is typically
(1) forming a nanofiber sheet on a base sheet;
(2) a step of laminating the gelation region defining sheet on the nanofiber sheet formed on the base sheet; and (3) defining the gelation region of the multilayered sheet formed in (2) above. a step of further attaching a cover sheet onto the sheet to form a multilayer;
may include

Alternatively, in another embodiment, the preparation of the gel-forming sheet of the present invention comprises:
(1) forming a nanofiber sheet on a base sheet;
(2) A step of attaching a cover sheet to the gelled region defining sheet to prepare a multilayered sheet;
(3) A step of laminating the sheet prepared in (2) above on the nanofiber sheet formed on the base sheet, wherein the nanofiber sheet prepared in (2) above is laminated. A step of contacting the surfaces of the gelled region defining sheet of the sheet may be included.

In the multi-layering described above, an adhesive may or may not be used. When no adhesive is used, the layers may be layered by electrostatic interaction, hydrophobic interaction, or the like.

(Use of gel-forming sheet)
For example, when the gel-forming sheet of the present invention is used to form a gel on the skin surface such as the surface of the face or a wound, (1) the cover sheet is peeled off from the gel-forming sheet, (3) peeling off the base sheet from the sheet attached to a predetermined place such as the skin (thus leaving the nanofiber sheet and the gelled region defining sheet on the skin without being peeled off); (4) Add an aqueous solution or water to the nanofiber sheet and gelation area defining sheet remaining on the skin to instantly gel the nanofiber sheet. (5) Remove the gelation area defining sheet to remove the gel. A gel can be formed in the area defined by the transparent area defining sheet. A nebulizer such as a sprayer or a humidifier may be used to add the aqueous solution or water in (4) above.

In another embodiment of the present invention, when the gel-forming sheet of the present invention is used to form a gel on the skin surface such as the surface of the face or a wound site, (1′) the cover sheet is peeled off from the gel-forming sheet. , (2′) A gel can be formed on a predetermined surface such as the skin by applying the surface from which the cover sheet has been peeled off to a predetermined place such as the skin that has been previously coated with an aqueous solution or water. If gel formation is not sufficient, an aqueous solution or water may be added after peeling off the base sheet). After that, (3′) (a) the base sheet is peeled off from the sheet attached to a predetermined place such as the skin, and then the gelled region defining sheet is peeled off, or (b) the The base sheet and the gelled region defining sheet are peeled off from the pasted sheet at the same time.

The aqueous solution or water in (4) above, or the aqueous solution or water previously applied to the target surface in (2′) above, contains a desired substance such as a medical component (such as an antibiotic or an antibacterial agent), or cosmetic ingredients may be included. Alternatively, depending on the physical properties desired in the gel formed, e.g., if it is desired to form a stiff gel, calcium may be added when forming the gel from alginic acid, or hyaluronic acid Zinc, chondroitin sulfate, or the like may be added when a gel is formed from this.

EXAMPLES The present invention will be specifically described below with reference to Examples, but the present invention is not limited to these.

(Example 1: Production of gel-forming sheet)
1. Add 2 g of sodium hyaluronate (sodium hyaluronate HA-LQ average molecular weight of 850,000 manufactured by Kewpie Corporation) and 2.5 g of polyvinyl alcohol (Mitsubishi Chemical polyvinyl alcohol EG-05C) in water to make 100 ml, and dissolve over 4 hours. , to prepare a polymer solution. A hyaluronic acid nanofiber sheet was produced by accumulating nanofibers on a spunbond (base sheet) from this polymer solution by an electric field prevention method under normal conditions.

A 50 μm-thick PET film (gelled region defining sheet) having both sides treated with an adhesive was adhered to the above sheet to form a multilayer structure. This PET film is punched out in the shape of eyebrows at its central portion. This punched part is the part where the nanofiber sheet comes into direct contact with the skin when the gel-forming sheet is applied to the skin. At the same time, the gel sticks to the skin.

(Example 2: Use of gel-forming sheet)
Using the gel-forming sheet of the present invention produced in Example 1, a gel is formed on the surface of the skin such as the surface of the face or a wound site. As a representative method of use, for example, as shown in FIG. 4, (1) the cover sheet is peeled off from the gel-forming sheet, (2) the peeled surface of the cover sheet is applied to a predetermined place such as the skin. (3) Peel off the base sheet from the sheet attached to a predetermined place such as the skin (this leaves the nanofiber sheet and the gelled region defining sheet on the skin without being peeled off), (4) left on the skin Applying an aqueous solution to the nanofiber sheet and the gelation area defining sheet by spraying or the like to instantaneously gel the nanofiber sheet; (5) peeling off the gelation area defining sheet to define the gelation area; A gel can form in the area defined by the sheet.

(Example 3: Makeup product for correcting eye bags)
Aging causes sagging in the front and lower part of the eye, which is called a lacrimal bag. As the size of the tear bags increases, the impression of aging becomes stronger. The gel-forming sheet of the present invention can also be used as a make-up product for correcting lacrimal bags.

10 g of sodium alginate (IL-2, weight average molecular weight: 30,000, manufactured by Kimika) was added to 115 g of water and dissolved with stirring at room temperature to prepare an 8% sodium alginate aqueous solution. Separately, 0.5 g of polyethylene oxide having a weight average molecular weight of 600,000 to 800,000 (Alcox E-45, manufactured by Meisei Chemical Industry Co., Ltd.) was added to 19.5 g of water and stirred at room temperature to dissolve polyethylene oxide. An aqueous solution was prepared. A polymer solution for spinning was prepared by adding and mixing 20 g of an aqueous polyethylene oxide solution to 125 g of an aqueous sodium alginate solution. This solution was electrospun onto a spunbond to obtain an alginate nanofiber sheet.

One side of 50 μm-thick Japanese paper (gelation region defining sheet) treated with an adhesive on both sides was attached to the surface of the alginate sheet (nanofiber sheet) of the alginate nanofiber sheet. A protective non-woven fabric (cover sheet) was attached to the opposite surface of the sheet. This Japanese paper is punched out in the shape of a comma-shaped bead in the center to match the size of the eye bags. After peeling off the cover sheet, it was attached to the skin so that the portion punched out in the shape of a magatama in the Japanese paper was in contact with the tear bag. After peeling off the base material sheet, the alginate nanofiber sheet was sprayed with a liquid obtained by dissolving 0.1% cellulose nanofiber (Sugino Machine) dispersion liquid with 0.1-M calcium chloride to form an alginate nanofiber sheet. A transparent alginate film was constructed on the skin by dissolving and gelling and simultaneously cross-linking on the skin. By waiting for it to dry and then applying foundation, my tear bags became less noticeable and I was able to create a rejuvenated impression.

(Example 4: Attach two types of nanofiber sheets at the same time)
When trying to achieve unprecedented beauty effects and skin care by finishing multiple beauty ingredients into a nanofiber sheet and applying it to the skin, a method of dissolving multiple beauty ingredients together and performing electrospinning. There is For example, it is conceivable to spin hyaluronic acid and collagen into one sheet. However, since hyaluronic acid and collagen cannot be spun together in many cases, two types of nanofiber sheets are electrospun separately to prepare two nanofiber sheets, and then each nanofiber sheet is spun. By preparing a gel-forming sheet (double gel-forming sheet) containing hyaluronic acid and collagen and applying it to the target skin, the same gel-forming effect as applying a single sheet containing hyaluronic acid and collagen to the skin can be obtained. Specifically, a double gel-forming sheet was produced by the following procedure.

1. Collagen nanofiber sheets are difficult to form fibers from collagen alone, so 1 part of water-soluble collagen (Fish Collagen Peptide S, manufactured by Kyokuyo Chemical Industry Co., Ltd.) and polyethylene glycol ( 3 parts of Alkox E-30 manufactured by Meisei Chemical Industry Co., Ltd. and 6 parts of chitosan (Kimika Chitosan Grade F manufactured by Kimika Co., Ltd.) were added and stirred to obtain an aqueous polymer solution. This aqueous polymer solution was electrospun to form a nanofiber layer on the spunbond to obtain a collagen nanofiber sheet.

2. Preparation of hyaluronic acid nanofibers Sodium hyaluronate (Kewpie Co., Ltd. sodium hyaluronate HA-LQ average molecular weight 850,000) and polyvinyl alcohol (Mitsubishi Chemical polyvinyl alcohol EG-
05C) 2.5 g of water was added to make 100 ml and dissolved over 4 hours to prepare a polymer solution. A hyaluronic acid nanofiber sheet was produced by accumulating nanofibers on a spunbond (base sheet) from this polymer solution by an electric field prevention method under normal conditions. Two kinds of nanofiber sheets were prepared in this way, and the respective nanofiber sheets were faced to each other and pasted to prepare a double gel-forming sheet.

3. Use of the double gel-forming sheet Peel off one of the base sheets of the double gel-forming sheet, attach the double gel-forming sheet to the orbital region, which is the target site, and then peel off the other base sheet. After that, the sheet was dissolved by spraying lotion to form a gel of hyaluronic acid and collagen. As a result, a gel was formed in which a synergistic effect of the two cosmetic ingredients was obtained.

(Example 5: Attach two types of thick nanofiber sheets at once)
Conventionally, silicon-based putty is applied to areas with defects and deep unevenness of the skin, dried, and then covered with foundation, etc., to make the defects and unevenness inconspicuous. However, since the putty, which is the base material, is applied with a spatula or the like, it is difficult to smooth the surface, and there are problems such as the inability to change the expression of the face during the drying time. Therefore, attempts have been made to prepare a thick nanofiber sheet and apply it to the skin, but there is a problem that the nanofiber sheet produced by the electrospinning method has a limit in thickness and (basis weight) when manufactured. If you want a thick sheet to be applied to the face, you will have to apply the nanofiber sheet that has been spun to the maximum thickness and apply it multiple times.

With the gel-forming sheets of the present invention, areas of skin targeted by dual gel-forming sheets (or multiple gel-forming sheets, such as triple gel-forming sheets) comprising multiple nanofiber sheets spun to maximum thickness. It is applied to the target skin area (such as the face) and sprayed with water or lotion to instantly melt two (or three or more) sheets into a gel to form a gel. A gel can be formed on (parts to be pasted, such as the face).

In this example, two nanofiber sheets having a basis weight of 3 g/m ² , which is the maximum thickness of a hyaluronic acid nanofiber sheet, were electrospun onto a substrate sheet by the method of Example 1 to prepare two sheets. A double gel-forming sheet was produced by laminating these two sheets with the nanofiber sheets facing each other. One base sheet is peeled off and applied to the concave portion of the skin defect on the face, the other base sheet is peeled off, and then the two sheets are simultaneously dissolved by spraying lotion to dissolve the skin defect. formed a gel. The skin defects were smoothed with hyaluronic acid gel, and after the gel had dried, the skin defects became inconspicuous by covering them with foundation or the like.
(Example 6: Production of gel-forming sheet using mesh-shaped base sheet)
Using a mesh-shaped base sheet, a gel-forming sheet of the present invention was produced as follows.
1. Add water to 2 g of sodium hyaluronate (sodium hyaluronate HA-LQ average molecular weight of 850,000 manufactured by Kewpie Co., Ltd.) and 2.5 g of polyvinyl alcohol (Mitsubishi Chemical polyvinyl alcohol EG-05C) to make 100 ml, and apply at 60 ° C. for 4 hours. to prepare a polymer solution. Nanofibers of hyaluronic acid were accumulated on the surface of a polyethylene mesh sheet Sunsannet SL-6500 (manufactured by Japan Wide Cloth Co., Ltd.) as a base sheet by using the electric field prevention method with this polymer solution under normal conditions. A sheet was produced. If desired, place a cover sheet over the nanofiber sheet. The cover sheet is preferably releasably arranged relative to the nanofiber sheet.
(Use of gel-forming sheet)
This sheet is punched into an eyebrow shape, and the surface of the nanofiber sheet is applied to the skin that has been applied with purified water or lotion in advance, and the sheet is gelled on the skin, or the nanofiber sheet is applied to the skin, and the base sheet Purified water was sprayed from the surface to dissolve the nanofiber sheet and create a hyaluronic acid gel layer on the skin. It was confirmed that the sheet was instantly dissolved by purified water that had passed through the mesh sheet of the base material, transferred to the skin, and turned into a gel.
(Example 7: Makeup product for correcting eye bags)
Aging causes sagging in the front and lower part of the eye, which is called a lacrimal bag. As the size of the tear bags increases, the impression of aging becomes stronger. The gel-forming sheet of the present invention can also be used as a make-up product for correcting lacrimal bags.
10 g of sodium alginate (IL-2, weight average molecular weight: 30,000, manufactured by Kimika) was added to 115 g of water and dissolved with stirring at room temperature to prepare an 8% sodium alginate aqueous solution. Separately, 0.5 g of polyethylene oxide having a weight average molecular weight of 600,000 to 800,000 (Alcox E-45, manufactured by Meisei Chemical Industry Co., Ltd.) was added to 19.5 g of water and stirred at room temperature to dissolve polyethylene oxide. An aqueous solution was prepared. A polymer solution for spinning was prepared by adding and mixing 20 g of an aqueous polyethylene oxide solution to 125 g of an aqueous sodium alginate solution. An alginate nanofiber sheet was obtained by electrospinning this solution onto polyethylene mesh Sun Sun Net Soflight SL-6500.
This alginate nanofiber sheet was punched into a magatama shape, and after peeling off the cover sheet, the sheet was attached to the skin so that the nanofiber portion was in contact with the lacrimal bag. A solution obtained by dissolving 0.1 M calcium chloride in a 0.1% cellulose nanofiber (Suginomachine) dispersion is sprayed on this nanofiber sheet from the base mesh side to dissolve the alginate nanofiber sheet. When the mesh sheet of the base material was peeled off, it gelled and at the same time cross-linked on the skin, a transparent alginic acid film was constructed on the skin. By waiting for it to dry and then applying foundation, my tear bags became less noticeable and I was able to create a rejuvenated impression.
(Example 8: Preparation of a double gel-forming sheet using an additional mesh sheet)
The gel-forming sheet made according to Example 6 can be further modified to make a double gel-forming sheet. for example,
(1) According to Example 6, fabricate the first nanofiber sheet (32) on the surface of the mesh sheet, which is the first base sheet (31);
(2) making a second nanofiber sheet (42) on the surface of the first nanofiber sheet (32) of the sheet made in (1) above;
(3) placing a cover sheet (14) on the surface of the second nanofiber sheet (42);
(see FIG. 9). Optionally, a third nanofiber sheet, a fourth nanofiber sheet, etc. can be further disposed on the surface of the second nanofiber sheet (42).
or,
(1) According to Example 6, fabricate the first nanofiber sheet (32) on the surface of the mesh sheet, which is the first base sheet (31);
(2) making a second nanofiber sheet (42) on the surface of the mesh sheet, which is the second base sheet (41), according to Example 6;
(3) the above (1) so that the first nanofiber sheet (32) of the sheets prepared in (1) above and the second nanofiber sheet (42) of the sheets prepared in (2) above are in contact with each other; It can also be produced by superimposing the sheet produced in (2) on the sheet produced in (2) above (see FIG. 10). In this case, at least one (preferably only one) of the first base sheet or the second base sheet is peelable from the nanofiber sheet. A pressure-sensitive adhesive may be used for the superposition of (3) above. Alternatively, in the superposition of (3) above, a gelation region defining sheet may be sandwiched between two nanofiber sheets.
(Example 9: Nanofiber sheet for face)
According to the method of Example 6, a nanofiber sheet having a size to cover the face was produced. Next, this was punched into a face shape to produce a nanofiber sheet for the face. This facial nanofiber sheet was placed on the face (Fig. 11A). Next, when purified water was sprayed on this, the nanofiber sheet gelled and migrated to the face, leaving only the mesh (Fig. 11B).
Thus, using the gel-forming sheet of the present invention, a gel could be formed on the entire facial surface.
While the invention has been illustrated using the preferred embodiments thereof, it is understood that the invention is to be construed in scope only by the claims. It is understood that the patents, patent applications and publications cited herein are hereby incorporated by reference in their entirety to the same extent as if the content itself were specifically set forth herein. be understood

ADVANTAGE OF THE INVENTION According to this invention, the sheet|seat and method for forming a gel or a film easily for a short time on the surface of a face, a wound site, etc. are provided. For example, the present invention provides sheets and methods for cosmetic effects, protection of wounds by wound coating, application of drugs, and the like.

2 base sheet 10 gel-forming sheet 11 base sheet 12 nanofiber sheet 13 gelation region defining sheet 14 cover sheet 15 adhesive 20 gel-forming sheet 30 first sheet 31 first base sheet 32 first nanofiber Sheet 33 Gelation Region Defining Sheet 40 Second Sheet 41 Second Base Sheet 42 Second Nanofiber Sheet 50 Double Gel Forming Sheet

Claims (26)

a base sheet, a nanofiber sheet detachably provided on the surface of the base sheet, a gelation region defining sheet provided on the surface of the nanofiber sheet, and peeled from the surface of the gelation region defining sheet and a cover sheet provided thereon. A gel-forming sheet comprising a base sheet, a nanofiber sheet provided on the surface of the base sheet, and a cover sheet provided on the surface of the nanofiber sheet, wherein the base sheet is a mesh sheet with a large number of pores. 3. The gel-forming sheet according to claim 2, wherein the base sheet has an initial charged voltage exceeding 0.3 kV as measured by a half-life measuring method specified in JIS L1094. 2. The gel-forming sheet according to claim 1, wherein said nanofiber sheet and said gelation region defining sheet are attached with an adhesive. 2. The gel-forming sheet according to claim 1, wherein the gelled region defining sheet and the cover sheet are attached with an adhesive. 3. The gel-forming sheet according to claim 1, wherein the nanofiber sheet is a sheet formed on the surface of the base sheet by an electrospinning method. 3. The gel-forming sheet according to claim 1, wherein said nanofiber sheet is gelled by the addition of moisture. 3. The gel-forming sheet according to claim 1, wherein the nanofiber sheet is gelled by moisture on the surface to which the nanofiber sheet is attached. 3. The gel-forming sheet according to claim 1 or 2, wherein the nanofiber sheet contains sodium hyaluronate and polyvinyl alcohol, sodium alginate and polyethylene oxide, collagen, or silk protein. 3. The gel-forming sheet according to claim 1 or 2, wherein the nanofiber sheet carries a positive charge and the base sheet carries a negative charge. 2. The gel-forming sheet according to claim 1, wherein the base sheet is a nonwoven fabric. 12. The gel-forming sheet according to claim 11, wherein said nonwoven fabric comprises a polymer compound. 13. The gel-forming sheet according to claim 12, wherein said polymer compound is selected from the group consisting of polyethylene, polypropylene, nylon, polyester, polyurethane, polystyrene, and polyethylene-vinyl acetate copolymer. 3. The gel-forming sheet according to claim 2, wherein said base sheet is a plastic mesh sheet. 15. The gel-forming sheet according to Claim 14, wherein said plastic mesh sheet is formed from a material selected from the group consisting of polyethylene, polypropylene, nylon, polyester, polyurethane, polystyrene, and polyethylene-vinyl acetate copolymer. 3. The nanofiber sheet according to claim 1 or 2, wherein the nanofiber sheet contains at least one cosmetic selected from the group consisting of moisturizing cream, skin cream, whitening cream, milky lotion, lotion, serum, and beauty gel. Gel-forming sheet. 3. The gel-forming sheet according to claim 1 or 2, wherein the nanofiber sheet contains a therapeutic agent. A first base sheet, a first nanofiber sheet detachably provided on the surface of the first base sheet, and a gelation region defining sheet provided on the surface of the first nanofiber sheet a second nanofiber sheet provided on the surface of the gelled region defining sheet; and a second base sheet releasably provided on the surface of the second nanofiber sheet. Gel-forming sheet. 19. The double gel-forming sheet according to claim 18, wherein said first nanofiber sheet and said gelled region defining sheet are attached with an adhesive. 19. The double gel-forming sheet according to claim 18, wherein the gelled region defining sheet and the second nanofiber sheet are attached with an adhesive. 19. The dual gel-forming sheet of claim 18, wherein said first and second nanofiber sheets gel with the addition of moisture. 19. The double gel-forming sheet according to claim 18, wherein the first and second nanofiber sheets are gelled by moisture on the surface to which the double gel-forming sheet is attached. a first base sheet, a first nanofiber sheet provided on the surface of the first base sheet, and a second nanofiber sheet provided on the surface of the first nanofiber sheet; and a cover sheet releasably provided on the surface of the second nanofiber sheet. a first base sheet, a first nanofiber sheet provided on the surface of the first base sheet, and a second nanofiber sheet provided on the surface of the first nanofiber sheet; and a second base sheet provided on the surface of the second nanofiber sheet, wherein the first base sheet and the second base sheet at least one of is releasably disposed on the nanofiber sheet. 25. The dual gel-forming sheet of claim 23 or 24, wherein said first and second nanofiber sheets gel upon addition of moisture. 25. The double gel-forming sheet according to claim 23 or 24, wherein said first and second nanofiber sheets are gelled by moisture on the surface to which said double gel-forming sheet is attached.

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