Patent Grant
9585461
1. Technical Field
The present disclosure relates to methods of producing an adhesive sheet for skin, cosmetic methods and adhesive sheets for skin.
2. Description of the Related Art
Direct printing on substrates having low ink absorbability such as plastic sheets encounters a problem that the substrates repel aqueous inks generally used in ink jet printing.
For example, Japanese Unexamined Patent Application Publication No. 2-276670 solves this problem by applying inks to an ink absorptive alumina hydrate layer stacked onto a transparent film having low ink absorbability.
In such printing methods where inks are applied to an ink absorptive layer stacked onto a sheet with low (or no) ink absorbability, a problem remains in that the thickness of the stack is large.
One non-limiting and exemplary embodiment provides an adhesive sheet for skin having small thickness.
In one general aspect, the techniques disclosed here feature a method of producing an adhesive sheet for skin including attaching a water-absorptive support to a water-permeable biocompatible film to prepare a stack including the biocompatible film and the support, applying an aqueous ink including water and a functional material to the biocompatible film side of the stack thereby to fix the functional material to the biocompatible film, and separating the biocompatible film having the functional material fixed thereto from the support.
It should be noted that general or specific embodiments may be implemented as an apparatus, a system, a sheet, a method, or any selective combination thereof.
The method of producing an adhesive sheet for skin of the present disclosure may produce adhesive sheet for skins having small thickness. Additional benefits and advantages of the disclosed embodiments will become apparent from the specification and drawings. The benefits and/or advantages may be individually obtained by the various embodiments and features of the specification and drawings, which need not all be provided in order to obtain one or more of such benefits and/or advantages.
Underlying Knowledge Forming Basis of the Present Disclosure
The present inventors have studied cosmetic sheets for use in such fields as cosmetics and medical cares which may be applied to skin as makeup to conceal scars on the skin or to minimize the appearance of spots or wrinkles. The studies by the present inventors have revealed that thick sheets do not look like normal skin and are difficult to affix to skin without adhesives. Thus, the present inventors have found that such sheets need to be thin. Further, the present inventors have noticed that previously colored sheets often do not agree with the actual color of skin, and are applicable to a limited number of makeup patterns. With such problems, the present inventors have studied sheet-printing techniques in order to obtain such colored sheets that makeup patterns and colors may be customized to individuals. However, it has been found that printing on thin sheets results in a failure for the inks to fix on the sheets due to the low water absorbability of such thin sheets.
The present inventors have studied printing methods capable of fixing inks onto thin sheets. As a result, it has been found that a stack in which a support having high water absorbability is disposed under a water-permeable thin sheet layer can allow an ink containing at least water to be fixed to the thin sheet, the ink being applied from the thin sheet side. Further, the present inventors have also found that a print composed of the thin sheet may be obtained by separating the support after the printing.
As mentioned earlier, the conventional sheets are coated with ink receptor layers because of the inability of the sheets to be colored directly on the surface. Thus, conventional prints obtained by applying inks to the receptor layers have a problem in that the thickness of the final prints is large. This problem may be remedied by the above findings.
One general aspect of the present disclosure resides in a method of producing an adhesive sheet for skin including attaching a water-absorptive support to a water-permeable biocompatible film to prepare a stack including the biocompatible film and the support, applying an aqueous ink including water and a functional material to the biocompatible film side of the stack thereby to fix the functional material to the biocompatible film to obtain the adhesive sheet for skin comprising the biocompatible film having the functional material fixed thereto and the support, and separating the biocompatible film having the functional material fixed thereto from the support.
The aqueous ink may be applied by printing. The biocompatible film may have a film thickness of 10 nm to 800 nm both inclusive. The ink may further include glycerol. The ink may further include a diol solvent. The support may have a water absorbing capacity of not less than 1 mg per 1 mm2.
Another general aspect of the present disclosure resides in a cosmetic method including attaching a water-absorptive support to a water-permeable biocompatible film to prepare a stack including the biocompatible film and the support, applying an aqueous ink including water and a coloring material to the biocompatible film side of the stack thereby to fix the coloring material to the biocompatible film, separating the biocompatible film having the coloring material fixed thereto from the support, and applying the separated biocompatible film to skin.
Another general aspect of the present disclosure resides in an adhesive sheet for skin including a water-permeable biocompatible film to which an aqueous ink including a functional material has been applied and fixed and a water-absorptive support detachably attached to the biocompatible film.
The aqueous ink may have been applied by printing. The biocompatible film may have a film thickness of 10 nm to 800 nm both inclusive. The ink may further include glycerol. The ink may further include a diol solvent. The support may have a water absorbing capacity of not less than 1 mg per 1 mm2. The functional material may be a coloring material, and the adhesive sheet for skin may be a cosmetic sheet.
Embodiments discussed below illustrate specific examples of the present disclosure. The configurations described in the following embodiments such as values, shapes, constituent elements and materials are only illustrative and do not limit the scope of the present disclosure. Of the constituent elements in the following embodiments, those that are not described in independent claims representing the broadest concept are illustrated as optional constituent elements. The respective contents in all the embodiments may be appropriately combined.
The following embodiments illustrate a dermatological cosmetic sheet as an example.
A printing method in one embodiment will be described below.
After the fixation, the thin cosmetic sheet 101 and the support 102 are separated from each other. This results in a thin print in which a pattern is printed in the thin cosmetic sheet. This print may be applied to the skin of a face as easy makeup. Since the print is thin, the print adheres to the skin by itself without adhesives.
While the present embodiment illustrates an ink jet method as the printing method, the printing method is not limited to an ink jet method. The ink may be applied by any method other than printing, for example, by a blowing method such as spraying.
The ink used in the ink jet printing is an aqueous mixture. The solvent other than water of the mixture is not particularly limited but desirably includes glycerol. Glycerol has a higher boiling point than water and is water-absorptive. Thus, the addition of glycerol makes the ink resistant to drying and thereby suppresses the occurrence of the clogging of a nozzle of an ink jet head. Further, it is desirable that the ink include glycerol and at least one diol solvent. Diol solvents have a lower viscosity than water or glycerol and also have low surface tension. These properties provide good wetting properties with respect to sheets. Consequently, the ink exhibits enhanced penetration or permeation properties and the ink fixation is facilitated. Examples of the diol solvents in the present embodiment include diethylene glycol, propane diol, butylene glycol, pentane diol and hexane diol.
The aqueous ink may further include a water-insoluble colorant, a surfactant or a mixture thereof.
Of the water-insoluble colorants, pigments are desirably used. Pigments are insoluble or negligibly soluble in water and are resistant to fading due to light, gas or the like. Thus, pigmented ink compositions can give print records which may be stored in a good state because of the excellent resistance to water, gas, light and the like. The pigments may be any of known inorganic pigments, organic pigments and carbon blacks.
It is also desirable that the aqueous ink further include a water-soluble resin and/or thermoplastic resin particles. With this configuration, the resin increases the adhesion of the colorant to the sheets. That is, friction resistance or rubbing resistance may be imparted to the prints, and the printed thin cosmetic sheet may be worn on a face while being prevented from fading due to friction in daily life.
Here, the thin cosmetic sheet 101 is a biocompatible material. The biocompatible materials as the thin films 101 are not particularly limited and may be any such thin films. Examples of the materials for the thin films in the present embodiment include polyesters such as polyglycolic acid, polylactic acid, polycaprolactone, polyethylene succinate, polyethylene terephthalate and copolymers thereof, polyethers such as polyethylene glycol and polypropylene glycol, polyamides such as nylon, polyglutamic acid, polyasparaginic acid and salts thereof, polysaccharides such as pullulan, cellulose, starch, chitin, chitosan, alginic acid, hyaluronic acid and corn starch, salts of these polysaccharides, silicones such as acrylic silicone and trimethylsiloxysilicic acid, acrylic acids such as alkyl acrylates, silicone acrylates, acrylic acid amides and copolymers thereof, polyvinyl alcohols, polyurethanes, polycarbonates, polyacid anhydrides, polyethylenes and polypropylenes.
Although the present embodiment illustrates the dermatological cosmetic sheets having a biocompatible material, the biocompatible materials are not necessarily used in other applications. That is, the use of other materials is within the scope of the present disclosure. The thickness of the thin cosmetic sheet 101 is desirably 10 nm to 3000 nm (or 10 nm to 3 μm), both inclusive. In particular, the thickness is desirably 10 nm to 1000 nm both inclusive. One of the reasons why such a film thickness is desirable is because sheets having a smaller film thickness exhibit higher water permeability and allow for easy penetration of the liquid component in the ink that has been applied. Another reason is because a decrease in film thickness results in an increase in the adhesion with respect to the support and also leads to a decrease in the amount of an air layer present between the thin cosmetic sheet and the support, thus making it easier for the water that has permeated the thin cosmetic sheet to be absorbed into the water-absorptive support.
The support 102 may be a material having high water absorbability, with examples including paper, cloth, nonwoven fabrics, woven fabrics, porous layer coating sheets, nanofiber sheets, water-absorptive polymers and water-soluble polymers. The amount of water absorption per unit area of the support is desirably not less than 1 mg, more desirably not less than 3 mg, and still more desirably not less than 4 mg per 1 mm2. The water absorption rate is appropriately such that the support can absorb as much water as not less than 10%, desirably not less than 50%, and more desirably not less than 100% by weight relative to the weight of the support itself. The thickness of the support 102 is not particularly limited, but is desirably not less than 10 μm. The material of the support 102 formed in such a thickness ensures a high water absorption rate. Further, an increase in the thickness of the support 102 increases the speed of water absorption and thus promotes ink fixation. Furthermore, the support 102 having such a thickness can absorb a large volume of water and is not saturated even when an increased amount of the ink is applied.
(Measurement of Water Absorbing Capacity of Materials Used as Supports)
The water absorbing capacity of materials used as supports in Examples described later was measured.
Specifically, three types of sheets: filter paper, cellulose nonwoven fabric and photographic glossy printing paper were provided. Each of the sheets was soaked in water for 1 minute, and the weight of the sheet before and after the absorption of water was measured. The water temperature was 22° C. The water absorption rate was calculated from the change in the weight of the sheet. Further, the sheet area was measured, and the amount of water absorption per unit area was calculated.
Here, the water absorption rate was determined using the equation: Water absorption rate={(M2−M1)/M1}×100%, wherein M1 is the weight of the sheet before the soaking in water (namely, in a dry state) and M2 is the weight of the sheet after the soaking in water.
The amount of water absorption per unit area (mg/mm2) was determined using the equation: Amount of water absorption=(M2−M1)/A, wherein A is the area of the sheet.
Here, the measurement data were obtained by averaging the results of three experiments performed with respect to three samples (each sample tested one time) fabricated from the same material by the same method. The results are described in Table 1.
Of the support materials used in Examples below, glass and PET films were not subjected to the measurement of water absorbing capacity. The water absorbing capacity of such materials is estimated to be substantially zero.
Because the present inventors have conducted experiments focused in particular on thin cosmetic sheets (thin films) 101 including polylactic acid, there will be described below Examples involving polylactic acid sheets.
Polylactic acid sheets having a film thickness of 200 nm were attached to each of the five types of supports: filter paper, cellulose nonwoven fabric, photographic glossy printing paper, glass and PET film. Specifically, each of the mating surfaces of the polylactic acid sheet and the support was wet with water, and the wet surfaces of the sheet and the support were attached to each other and were dried for at least 12 hours. With use of an ink jet printer, a square solid pattern image 5 mm in length and 15 mm in width was printed on the polylactic acid sheet side of the printing stack sheet fabricated above. The ink used had a composition including water as a medium, 10 wt % of glycerol and 10 wt % of propanediol as additional solvents, 25 wt % of a dispersion of yellow iron oxide as an inorganic pigment (WD-TIOY30 manufactured by DAITO KASEI KOGYO CO., LTD.), and 2.5 wt % of an acrylic emulsion (DAITOSOL 3000SLPN manufactured by DAITO KASEI KOGYO CO., LTD.). The printed sheets were allowed to stand at room temperature or 50° C. for a prescribed time, and the ink fixation properties under the respective conditions of the standing for the prescribed time were evaluated. The ink fixation properties were evaluated based on whether or not the ink was transferred to a piece of tissue paper pressed against the printed pattern, and were rated in 4 grades: ⊙: The ink was fixed within 5 minutes. ◯: The ink was fixed within 10 minutes. Δ: The ink was fixed within 30 minutes. x: The ink was not fixed in 30 minutes.
Table 2 describes the results of the experiments which evaluated the ink fixation properties of the 200 nm polylactic acid sheets stacked onto the various supports.
The results described in Table 2 show that the ink fixation properties were greatly changed depending on the types of supports. It was demonstrated that desirable results were obtained when the supports were made of materials having high water absorbability, namely, filter paper, nonwoven fabric and printing paper. On the other hand, ink fixation failed when the supports were glass or PET films having low water absorbability.
Polylactic acid sheets having a film thickness of 200 nm were attached to filter paper. Specifically, each of the mating surfaces of the polylactic acid sheet and the support was wet with water, and the wet surfaces of the sheet and the support were attached to each other and were dried for at least 12 hours. With use of an ink jet printer, a square solid pattern image 5 mm in length and 15 mm in width was printed on the polylactic acid sheet side of the printing stack sheet fabricated above. The five types of inks described in Table 3 were used in the ink jet printing.
The printed sheets were allowed to stand at room temperature or 50° C. for a prescribed time, and the ink fixation properties under the respective conditions of the standing for the prescribed time were evaluated. The ink fixation properties were evaluated based on whether or not the ink was transferred to a piece of tissue paper pressed against the printed pattern, and were rated in 4 grades: ⊙: The ink was fixed within 5 minutes. ◯: The ink was fixed within 10 minutes. Δ: The ink was fixed within 30 minutes. x: The ink was not fixed in 30 minutes.
Table 4 describes the results of the experiments which evaluated the ink fixation of the inks described in Table 3 to the 200 nm polylactic acid sheets.
The results described in Table 4 show that the ink fixation properties were changed depending on the compositions of the inks. It was demonstrated that desirable results were obtained when the ink was based on a mixed solvent including water, glycerol and a diol, namely, propanediol or pentanediol, as compared to when the ink was based on a mixed solvent including water and glycerol.
Polylactic acid sheets having a film thickness of 200 nm, 500 nm or 1000 nm were attached to filter paper. Specifically, each of the mating surfaces of the polylactic acid sheet and the support was wet with water, and the wet surfaces of the sheet and the support were attached to each other and were dried for at least 12 hours. With use of an ink jet printer, a square solid pattern image 5 mm in length and 15 mm in width was printed on the polylactic acid sheet side of the printing stack sheet fabricated above. The ink used had a composition including water as a medium, 10 wt % of glycerol, 10 wt % of propanediol, 25 wt % of a dispersion of yellow iron oxide particles as an inorganic pigment (WD-TIOY30 manufactured by DAITO KASEI KOGYO CO., LTD.), and 2.5 wt % of DAITOSOL 3000SLPN (manufactured by DAITO KASEI KOGYO CO., LTD.) including an acrylic emulsion as a main component. The printed sheets were allowed to stand at room temperature or 50° C. for a prescribed time, and the ink fixation properties under the respective conditions of the standing for the prescribed time were evaluated. The ink fixation properties were evaluated based on whether or not the ink was transferred to a piece of tissue paper pressed against the printed pattern, and were rated in 4 grades: ⊙: The ink was fixed within 5 minutes. ◯: The ink was fixed within 10 minutes. Δ: The ink was fixed within 30 minutes. x: The ink was not fixed in 30 minutes.
Table 5 describes the results of the experiments which evaluated the ink fixation properties of the polylactic acid sheets having the various thicknesses.
The results described in Table 5 show that the ink fixation properties were changed depending on the film thicknesses of the polylactic acid sheets. The polylactic acid sheets having a larger film thickness showed lower water permeation properties and also exhibited lower adhesion with respect to the filter paper as the support. Consequently, the efficiency in the absorption of water into the support was decreased and poor ink fixation properties were caused. Thus, it was demonstrated that the film thickness of the polylactic acid sheets was desirably not more than 500 nm, and more desirably not more than 200 nm.
While the printing method in the present disclosure has been illustrated hereinabove, the configurations shown in the specification are only illustrative and various modifications thereto are possible without departing from the spirit of the present disclosure. Further, it is needless to mention that the configurations described in the specification provide other various effects.
The present disclosure may provide a printing method and a printing apparatus for applying inks to thin sheets, and thus may provide cosmetic sheets or wound-protection medical sheets which may be applied to the skin without the use of adhesives.
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