JP2018177744A - Skin pasting laminated body and packaging body thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a skin laminate body which is a sheet for supplying moisture by attachment of an extremely thin Aphanothece sacrum-derived polysaccharide sheet to the skin, and which can be also produced readily.SOLUTION: A skin attachment layer 13 containing sacran as a main component is formed on a support 11 through a water-soluble resin layer 12. The thickness of this skin attachment layer 13 is 40 to 300 nm. The skin attachment layer 13 can be formed by, for example, gravure-coating a solution containing Aphanothece sacrum-derived polysaccharide. Moreover, since this layer is extremely thin, it does not cause wrinkles, detachment, breakage, falling off or the like following the irregularities of the skin when attached to the skin, and the presence itself is difficult to be recognized. Since this layer contains polysaccharide derived from Aphanothece sacrum as a main component, it has an extremely high moisture retention, and it can supply moisture to the skin.SELECTED DRAWING: Figure 1

Description

  TECHNICAL FIELD The present invention relates to a skin bonding laminate in which the skin is rehydrated using a Suizenjinori-derived polysaccharide. The Suizenjinori-derived polysaccharide is known by the name of "Sakuran" (registered trademark of Green Science Materials, Inc.).

  Suizenjinori-derived polysaccharide is a polysaccharide collected from Suizenjinori and is a high molecular weight anionic polymer having an average molecular weight of over 1,000,000. And, this Suizenjinori-derived polysaccharide has the property of being able to store a large amount of water inside thereof, and utilizing this property, it is a moisturizing agent that rehydrates skin (eg, face, hands, etc.) It is used as an agent. For example, Patent Document 1 manufactures nanosheets having a total thickness of 300 nm or less by alternately laminating the Suizennori-derived polysaccharide and a cationic polymer, and by bonding the nanosheets to the skin, the skin is rehydrated. Describes the technology to

  In this technique, each layer is made into a thin film by alternately laminating a Suizenjinori-derived polysaccharide (anionic polymer) and a cationic polymer. That is, when the cationic polymer is applied on the layer of the polysaccharide derived from Suizenji nori (anionic polymer), the two electrostatically attract each other, so that the cationic polymer is extremely thin on the layer of the polysaccharide derived from Suizennori (anionic polymer) A layer of polymer is formed. Ideally, it is a monomolecular film. In addition, when the Suizenji nori derived polysaccharide (anionic polymer) is applied on the layer of the cationic polymer, a very thin layer of the Suizenji nori derived polysaccharide (anionic polymer) is formed for the same reason.

  And, in this technology, the nanosheets formed by alternately laminating the Suizenjinori-derived polysaccharide (anionic polymer) and the cationic polymer are extremely thin and have high flexibility and stretchability, and therefore, they make the skin uneven. There is no risk of wrinkles, peeling, breakage, falling off, etc. For example, even when there are irregularities such as pores and acne, the nanosheet follows the irregularities and fits the skin exactly. Moreover, because of its thinness, there is no sense of incongruity in the bonded skin, and the presence of the sheet itself is difficult to recognize. And for this reason, according to this nanosheet, it becomes possible to supply water to the skin without being aware of the state where they are laminated. And, the nanosheet laminated to the skin loses its moisture naturally and dries. The dried nanosheets can be easily peeled off from the skin.

JP, 2013-184970, A

  However, in this technology, since it is necessary to laminate alternately the Suizennori-derived polysaccharide (anionic polymer) and the cationic polymer to produce a nanosheet, an extremely complicated manufacturing process is required. In addition, it requires high manufacturing costs.

  Then, this invention is a sheet | seat which bonds the sheet | seat of extremely thin Suizenjiori origin polysaccharides on skin, and it supplies water, and it aims at providing the skin bonding laminated body which can be manufactured easily. .

That is, the invention according to claim 1 is a skin bonding laminate having a skin bonding layer releasably on a support,
The skin bonding layer is characterized in that the skin bonding layer is a layer in a dry state or a wet state with the polysaccharide from Suizenjinori derived as a main component, and the thickness of the skin bonding layer in the dry state is 40 to 300 nm. It is a laminate.

  Next, the invention according to claim 2 is the skin bonding laminate according to claim 1, characterized in that the skin bonding layer contains 10% by mass or more of a Suizenji nori derived polysaccharide.

  Next, invention of Claim 3 is a skin bonding laminated body of Claim 1 or 2 characterized by the said support body being comprised by the nonwoven fabric.

Next, invention of Claim 4 is a package which sealed the skin bonding laminated body in any one of Claims 1-3 inside the container, Comprising:
The said skin bonding layer is a package of the skin bonding laminated body characterized by being a wet state of water content 50-90 mass%.

  Since the skin bonding layer of the present invention is composed of a single layer having a thickness of 40 to 300 nm in a dry state, the skin bonding layer being mainly composed of a polysaccharide derived from Suizenji nori, for example, a polysaccharide derived from Suizenji nori The solution containing the body can be formed by gravure coating.

  Moreover, since this layer has a dry thickness of 40 to 300 nm, it does not cause wrinkles, peeling, breakage, dropping, etc. following the irregularities of the skin when it is attached to the skin, and moreover, its presence It is difficult to recognize itself. And, since this layer contains the polysaccharide from the Suizenji nori as a main component, it has extremely high moisture retention, and it is possible to rehydrate the skin.

FIG. 1 is a cross-sectional explanatory view showing a specific example of the skin bonding laminate of the present invention. FIG. 2: is cross-sectional explanatory drawing which shows the manufacturing process of the skin bonding laminated body of this invention. FIG. 3 is a perspective view showing a specific example of a package configured by sealing the skin bonding laminate in a packaging bag.

  Hereinafter, the present invention will be described with reference to the drawings. FIG. 1 of the drawings is a cross-sectional explanatory view showing a specific example of the skin bonding laminate of the present invention.

  The skin bonding laminated body 1 of this invention laminates | stacks the skin bonding layer 13 on the support body 11 so that peeling is possible. In order to make it easy to peel off the support 11 and the skin bonding layer 13, it is desirable to interpose the water-soluble resin layer 12 between the two layers 11 and 13.

  The support 11 may be a sheet of any material, but in order to peel off the support 11 in a state in which the skin bonding laminate 1 is attached to the skin, it is desirable that the material is permeable to moisture. For example, it is a non-woven fabric.

The water-soluble resin layer 12 has a function of applying and dissolving water thereto to make the support 11 and the skin bonding layer 13 easy to peel off. Water can be supplied through the support 11. As the water-soluble resin layer 12, polyvinyl alcohol, starch, carboxymethyl cellulose or the like can be used.

  The skin bonding layer 13 is to be directly bonded to the skin to rehydrate the skin. For this reason, it is necessary to be exposed on the surface of the skin bonding laminate 1. However, a release sheet may be stacked on the skin bonding layer 13 and supplied to the consumer with its surface protected. In this case, after peeling and removing the peeling sheet to expose the skin bonding layer 13 to the surface, it is necessary to bond to the skin.

  In addition, since the skin bonding layer 13 is intended to rehydrate the skin, it is necessary to use a water-based polysaccharide excellent in moisture retention as the main component. In addition to this, it may be blended with various drugs. For example, anti-inflammatory agents, hemostatic agents, vasodilators, cosmetic ingredients, pigments and the like. Examples of cosmetic ingredients include almond oil, ascorbic acid, brown algae extract, caffeine, salicylic acid, tocophenol and the like. A naphthol dye, an azo dye, etc. can be illustrated as a pigment | dye. As described above, even when various agents are blended in the skin bonding layer 13, the skin bonding layer 13 has 10% by mass or more of the dry state polysaccharide-removed polysaccharide based on the dried state from which water is removed. It is desirable to occupy. In the case where the polysaccharide derived from Suizenji nori is 10% by mass or more of the skin bonding layer 13, the skin bonding layer 13 has a high water retention capacity of 1000 ml / g or more.

  In addition, although the skin bonding layer 13 may be a wet state containing water, it may be a dry state. When the skin bonding layer 13 is in a dry state, it is desirable to supply water to the skin bonding layer 13 to sufficiently absorb water before bonding to the skin.

  In addition, when the skin bonding layer 13 is bonded to the skin, the thickness of the skin bonding layer 13 conforms closely to the irregularities of the skin and conforms well, and furthermore, the presence itself is difficult to recognize, so the thickness of the dry state is It needs to be 300 nm or less. If it is thicker than this range, wrinkles, breakage, drop-off, etc. may occur due to the unevenness of the skin (e.g., acne, moles, blowouts, etc.). In addition, it may be partially peeled off from the skin, causing discomfort in the skin, and the presence of the skin bonding layer 13 may be easily recognized. In addition, if the skin bonding layer 13 has a thickness of 40 nm or more, sufficient moisture can be supplied to the skin.

  Next, this skin bonding laminate 1 can be manufactured by the following method. That is, first, as shown to Fig.2 (a), the peeling sheet 21 is prepared and the skin bonding layer 13 is formed on this peeling sheet 21. As shown in FIG. The skin bonding layer 13 can be formed by dissolving the Suizenjinori-derived polysaccharide and the necessary drug in a solvent and applying and drying. As the solvent, water or an aqueous solution of inorganic salts can be preferably used. Moreover, as a coating method, a gravure coating method, a roll coating method, etc. can be utilized. Although it is not impossible to dry the applied film until this film is completely dried, as mentioned above, the water-staining ability of the water repellent is high, and the water is retained to form a gel, so it is completely dried. It is difficult. Therefore, it may be semi-dried until the water borne polysaccharide derived from Suizenjinori has water retention and becomes gel-like. Desirably, it is dried to a wet state with a water content of 50 to 90% by mass.

  Next, a water-soluble resin is applied onto the support 11 and dried to form the water-soluble resin layer 12. This application is also possible by methods such as gravure coating and roll coating. And as shown in FIG.2 (b), it laminates | stacks so that the skin bonding layer 13 may face the water soluble resin layer 12, and both are laminated | stacked. When the skin bonding layer 13 is in a wet state, the water contained in the skin bonding layer 13 slightly dissolves the surface of the water-soluble resin layer 12, so direct lamination is carried out without using an adhesive or the like. Is possible.

Finally, the skin bonding laminate 1 can be manufactured by peeling and removing the peeling sheet 21. However, as described above, it is also possible to ship the release sheet 21 with the release sheet 21 laminated without peeling and removing the release sheet 21. In this case, when using the skin bonding laminate 1, it is desirable to peel off the release sheet 21.

  Next, when the skin bonding layer 13 is in a wet state, in order to maintain the wet state, it is desirable to seal and store the skin bonding laminate 1 in a container which is impermeable to water. As a container, a rigid container or a flexible film packaging bag can be used. FIG. 3 is a perspective view showing an example of the package 3 configured by sealing the skin bonding laminate 1 in such a packaging bag 31. As shown in FIG.

  Whether the container is a rigid container or a packaging bag, it is desirable that the packaging material of the container is made of a material that is impermeable to water. For example, it is a polyolefin-based material such as polyethylene or polypropylene. Moreover, you may use the packaging material which has metal foil, a metal vapor deposition layer, or an inorganic vapor deposition layer in the layer structure. Thus, when sealed in the inside of a water blocking container, for example, the moisture content of the skin bonding layer 13 can be maintained and maintained at 50 to 90% by mass.

  Next, this skin bonding laminate 1 can be used as follows. That is, first, the skin bonding layer 13 in a wet state is stuck to the skin surface. The wet skin bonding layer 13 is in the form of gel and has a slight adhesiveness, so that it can be bonded in direct contact with the skin. Moreover, since this skin bonding layer 13 is comprised by the very thin film with a thickness of 40-300 nm, it follows the unevenness | corrugation of skin and it fits perfectly.

  Next, the water-soluble resin layer 12 is dissolved, and the support 11 is peeled and removed. Since the skin bonding layer 13 is in a wet state containing water, the surface of the water-soluble resin layer 12 is dissolved by the water contained in the skin bonding layer 13, and the support 11 can be peeled off as it is. is there. Further, after the water-soluble resin layer 12 is further supplied with water and dissolved, the support 11 can be peeled off. If the support 11 is made of non-woven fabric, moisture can also be supplied through the support 11.

  Since the skin bonding layer 13 left on the skin by peeling off the support 11 is extremely thin, it conforms to the unevenness of the skin and does not cause discomfort. It is difficult to recognize its existence itself.

  In addition, since the water | moisture content is supplied to a skin, or it evaporates and is lost, the skin bonding layer 13 bonded together to the skin dries naturally. Since the skin bonding layer 13 loses its adhesive power upon drying, it can be easily peeled off and removed from the skin.

1: Skin-bonded laminate 11: Support 12: Water-soluble resin layer 13: Skin-bonded layer 21: Release sheet 3: Package 31: Packaging bag

Claims (4)

A skin bonding laminate having a skin bonding layer releasably on a support, comprising:
The skin bonding layer is characterized in that the skin bonding layer is a layer in a dry state or a wet state with the polysaccharide from Suizenjinori derived as a main component, and the thickness of the skin bonding layer in the dry state is 40 to 300 nm. Stack.   The skin bonding laminate according to claim 1, wherein the skin bonding layer contains 10% by mass or more of a Suizenjinori-derived polysaccharide.   The skin bonding laminate according to claim 1 or 2, wherein the support is made of a non-woven fabric. It is the package which sealed the skin bonding laminated body in any one of Claims 1-3 inside a container, Comprising:
The package of a skin bonding laminate, wherein the skin bonding layer is in a wet state with a water content of 50 to 90% by mass.

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