RU2436559C1 - Cosmetic agent of dermal administration and method for preparing it - Google Patents

Abstract

FIELD: medicine. ^ SUBSTANCE: invention refers to cosmetology, and concerns a cosmetic agent of dermal action representing a multiple emulsion containing an external water phase with an included oil phase in which an internal water phase is dispersed, characterised by the fact that the water phases of the multiple emulsion contain a perfluorocarbon microemulsion in the concentration 0.1 to 20 % each. ^ EFFECT: invention provides prolonged skin mosturising, nutrition and oxygenation. ^ 5 cl, 4 ex, 4 dwg

Description

The invention relates to the field of cosmetology and relates to cosmetics containing as an active principle an aqueous emulsion of perfluorocarbons.

At the end of the 70s of the last century, it was found that perfluorocarbons are excellent solvents for the gases vital to a living organism - oxygen and carbon dioxide. These results, as well as the chemical and biological inertness of perfluorocarbons served as the basis for the creation of blood substitutes with gas transport functions - Fluosal-DA (Japan), Oxygent (USA), Perftoran (Russia).

It also turned out that perfluorocarbons are promising compounds for cutaneous application.

Later it was patented, in particular, the use of perfluorocarbons as part of agents that improve the metabolism in integumentary tissues, and also to stimulate the healing of micropores and skin cracks (RF patent 2033163, A61K 33/19, 1995).

It is known to use an emulsion of perfluorocarbons as a means for biological rejuvenation of skin tissue by shifting biochemical processes towards indicators characteristic of a physiologically younger age (RF patent 2119790, A61K 7/00 1996).

It is known to use an aqueous emulsion of perfluorocarbons stabilized by phospholipids as a means of exhibiting a hydrating effect against integumentary tissues (RF patent 2102972, A61K 7/00 1997).

One of the disadvantages of all perfluorocarbon emulsions is the high volatility of the main component, perfluorocarbons, and the difficulty in obtaining a stable emulsion with small particle sizes, since the large particle size negatively affects the stability of the emulsions and their effectiveness.

In addition, despite repeated references in the literature that the content of the perfluorocarbon emulsion in the cosmetic product reaches 60 vol.% And even 95 vol.%, Which increases the effectiveness of the drug, the studies of the authors showed that when perfluorocarbon emulsions are introduced into the cosmetic product in a concentration , greater than 10 wt.%, the effect of using the product is not enhanced, but remains the same.

Apparently, this is due to the fact that such cosmetics, when applied to the skin, release the entire amount of the active substance immediately and most of the microemulsion of perfluorocarbons, not having time to absorb, disappears from the surface of the skin.

It is known that the effectiveness of any cosmetic product depends on its two important components: on the composition and purpose of the active substances and on the characteristics of the base emulsion in which they are dissolved. If the emulsion will not hold active components on the skin surface and facilitate their penetration into deeper layers, then the effect of using even good components will be minimal.

Closest to the proposed cosmetic product and method for its preparation is a cosmetic product containing a multiple emulsion described in patent US 5567426 from 04/26/1994 (Loreal). The emulsion contains an external aqueous gel phase; an oil phase dispersed in said external aqueous phase; and an internal aqueous phase dispersed in an oil phase. The oily phase may be perfluorinated oil.

A method of obtaining such a product includes the preparation of a reverse emulsion, where the oil phase contains perfluorocarbons, and its further dispersion in an external aqueous medium, where an acrylic or methacrylic polymer or copolymer combined with polyglyceryl methacrylate is used as a gelling polymer.

The disadvantage of the described multiple emulsion is that the oxygen-transporting components - perfluorocarbons - are contained in only one phase (oil), which does not allow to achieve a prolonged effect. In addition, perfluorocarbons are part of this product in the form of individual substances with high volatility, that is, most of the perfluorocarbons will be ineffective, since they will not be retained on the surface of the skin.

The technical task of the present invention is the creation of a stable cosmetic product that provides instant and lasting exposure to the skin of the active components and their optimal biological absorption by the skin, as well as a method for producing such a product.

The technical effect of using such a product is prolonged hydration, nutrition and oxygenation of the skin; the proposed cosmetic product has good sensory and protective properties.

To solve this technical problem, a skin-based cosmetic agent has been proposed, which is a multiple emulsion containing an external aqueous phase with an oil phase incorporated in it, in which the internal aqueous phase is dispersed, while the aqueous phases of the multiple emulsion contain a microemulsion of perfluorocarbons in a concentration of from 0.1 to 20% in each.

Preferably, additionally add dextran sodium sulfate in an amount of from 0.01 to 5.0% in the external and internal aqueous phases.

Dextran sodium sulfate is a donor of nitric oxide (NO). NO is involved in the synthesis of collagen, stimulates the process of differentiation - cell division, enhances microcirculation in skin tissues.

Preferably, water-retaining components are further added to the external aqueous phase of the agent.

This allows more water with active components dissolved in it to remain on the surface of the skin, and, therefore, the effectiveness of the product will be greater. Also, water-retaining components give the cosmetic property the property of additional moisturizing.

As water-holding components, sorbitol and / or polysaccharides can be used.

The applicant also proposed a method for producing the agent according to claim 1, characterized in that the water-in-oil reverse emulsion is prepared and dispersed in the presence of an emulsifier in the external aqueous phase until a multiple emulsion is obtained, wherein a microemulsion of perfluorocarbons is first introduced into the internal aqueous phase of the reverse emulsion and the perfluorocarbon microemulsion is introduced into the external aqueous phase in the process of producing a multiple emulsion. Poloxamer-407 is used as an emulsifier, and Ultres-10 carbopol is used as a stabilizer and viscosity regulator.

Using a combination of Poloxamer-407 and carbopol Ultrez-10 allows you to create a stable long-term composition. The product can withstand a load at a temperature of 40 ° C for more than 6 months, and at a temperature of 50 ° C for more than 3 months.

It is possible in the proposed method, the steps for preparing the reverse and multiple emulsions to be carried out simultaneously, while as a combination of emulsifiers use stearet-21, stearet-2 and PEG-30 dipolyhydroxystearate in a ratio of 2.5: 2.5: 0.5, respectively.

This can significantly reduce the preparation time of the product.

Schematically, the proposed tool is shown in figure 1, which shows the multiple emulsion W1 / O / W2 (water 1 / oil / water 2) and where 1 is the aqueous phase 1; 2 - oil phase, 3 - aqueous phase 2; 4 - microemulsion of perfluorocarbons.

Figure 2 shows a photograph of a multiple emulsion prepared as in Example 1. The photograph was taken on an Olympus inverted microscope (1000x magnification).

It is seen that the emulsion consists of three layers: large oil droplets are clearly visible in the external aqueous phase, in which small droplets of the internal aqueous phase are dispersed.

The main advantages of the proposed cosmetic product are long-term hydration due to the presence of an internal aqueous phase with moisturizing components dissolved in it, restoration of the skin due to the presence of an oil phase with the necessary components dissolved in it, and the possibility of providing a gradual prolonged release of the active components from the cosmetic product.

The prolonged action and the gradual release of the active components from the multiple emulsion is ensured by the presence of two aqueous phases separated from each other by the oil phase. Therefore, first the perfluorocarbon microemulsion will enter the skin from the external aqueous phase, and then from the internal one, which allows the full use of the effect of the use of perfluorocarbon microemulsion and other active components of the cosmetic product.

The proposed cosmetic skin application is obtained as follows:

First, a perfluorocarbon microemulsion is prepared.

To do this, calculated quantities of an aqueous solution of an emulsifier, in particular a block copolymer of ethylene and propylene oxides (at a concentration of 5.0-20.0 wt.%), And emulsion wax in an amount of (0, 1-5.0 wt.%) To obtain a transparent homogeneous mass.

Perfluorocarbons (in an amount of 0.2-140.0 wt./vol.%) Are gradually added to the mass cooled to a temperature of 40 ° C and intensively mixed on an ultra-mixer (speed up to 15000 rpm). The resulting microemulsion is homogenized on a high pressure homogenizer (3-5 cycles) at a pressure of 250-600 bar.

As perfluorocarbons perfluoroalkanes and cycloalkanes, perfluorinated amines and ethers of various structures, bis (perfluoroalkyl) ethylenes, perfluorooctyl bromide, and also mixtures thereof can be used.

Then, the resulting microemulsion of perfluorocarbons is introduced into an emulsion of the type "water / oil / water" (multiple), receiving the proposed cosmetic product.

To prepare a multiple emulsion, the reverse water-in-oil emulsion is first prepared. For this, the aqueous and oil phases are heated separately. A microemulsion of perfluorocarbons (0.1-20%), other active components, and also a preservative are introduced into the aqueous phase. The oil phase (from 10 to 50%) consists mainly of liquid emollients, such as isopropyl isostearate, isohexadecane, and natural vegetable oils. Also, the oil phase may include waxes, for example, beeswax, substances that restore the lipid barrier of the skin (cholesterol, ceramides), and the PEG-30 dipolyhydroxystearate emulsifier (from 0.5 to 5%), whose low HLB (hydrophilic-lipophilic balance) provides it has good properties as an emulsifier for inverse emulsions. After heating to 70-75 ° C, the aqueous phase is gradually poured into the oil phase with vigorous stirring, homogenized on an Ultra Turrax until a homogeneous emulsion is formed, and cooled to room temperature. Then prepare emulsifier solutions with a high number of HLB (hydrophilic-lipophilic balance), in this case, Poloxamer-407 (from 0.5 to 5%) and carbopol Ultrez-10 (from 0.1 to 1.0%) in water are used. Then the emulsifier solution and the swollen polymer are mixed, the active components, the perfluorocarbon emulsion (0.1-20%) and the preservative are added. With constant stirring, the reverse emulsion prepared in advance is introduced (from 30 to 80%), then Ultrez-10 carbopol is neutralized with triethanolamine and a homogeneous water / oil / water emulsion is obtained.

It is possible to prepare the proposed cosmetic product in the following way.

Separately, the oil and water phases are heated to 70-75 ° C. The oil phase contains synthetic emollients, natural oils, waxes, other active components, as well as a system of emulsifiers stearet-21, stearet-2 and PEG-30 dipolyhydroxystearate in a ratio of 2.5: 2.5: 0.5. This emulsifier system provides a stable multiple emulsion. An emulsion of perfluorocarbons is introduced into the aqueous phase at a concentration of from 0.1 to 30% by weight. The aqueous phase may also contain any stabilizing additives, active ingredients, preservative. After heating, the oil phase is added to the aqueous phase with vigorous stirring and homogenized on an Ultra Turrax until a homogeneous water / oil / water emulsion is formed.

The following examples illustrate the preparation of various variants of a cosmetic product with a description of the method for their preparation, without limiting the invention in essence.

Example 1. Moisturizing and nourishing night cream gel for dry skin

Take 3 g of the PEG-30 dipolyhydroxystearate emulsifier, 20 g of vegetable oils and synthetic oil substitutes (e.g. macadamia oil, jojoba oil, isopropyl myristate, capric / capric triglycerides and any others), 1 g of cholesterol, 1 g of tocopherol, are heated to 75 ° C. In hot water (up to 100 g), 10 g of perfluorocarbon microemulsion (a mixture of perfluorocarbons consisting of perfluorodecalin and perfluoropolyether in a ratio of 7: 3), 3 g of Dextran sodium sulfate and 0.7 g of Germaben II preservative are added. With vigorous stirring, the aqueous phase is slowly poured to the oil phase, then homogenized on an Ultra Turrax for 5 minutes at a speed of 15,000 rpm. Then 3 g of Poloxamer-407 emulsifier is dissolved in water, mixed with 0.3 g of Germaben II preservative, with 15 g of a 2% solution of Karbopol Ultrez-10 polymer, with 10 g of perfluorocarbon microemulsion (a mixture of perfluorocarbons consisting of perfluorodecalin and perfluoropolyether in 7: 3 ratio) and with 3 g of Dextran sodium sulfate. This solution is poured with vigorous stirring, the previously obtained reverse emulsion, and then neutralized with triethanolamine. Then add 3 g of sorbitol, 3 g of polysaccharides, 0.4 g of perfume.

The resulting product is a multiple emulsion, has moisturizing and nourishing properties, improves blood microcirculation and saturates the skin with oxygen, providing a long-term effect on the skin.

Example 2. Moisturizing day cream for dry skin

Take 2.5 g of emulsifiers stearet-21 and stearet-2, 0.5 g of emulsifier PEG-30 dipolyhydroxystearate, 5 g of isopropyl isostearate, 1 g of cetyl alcohol, 1 g of beeswax, 0.5 g of tocopherol acetate, 2 g of almond oil, 3 g of cyclopentasiloxane, heated to a temperature of 75 ° C. Separately, heat water (up to 100 g) to 75 ° C, add moisturizing components (2.5 g glycerol, 0.5 g urea), 0.5 g D-panthenol, 1 g Germaben II preservative, 15 g perfluorocarbon microemulsion (65% perfluorodecalin and 35% perfluoromethylcyclohexylpiperidine). With stirring, the oil phase is added to the aqueous phase and homogenized on an Ultra Turrax for 5 minutes at a speed of 15,000 rpm. After obtaining a homogeneous emulsion, 5 g of perfluorocarbon microemulsion (65% perfluorodecalin and 35% perfluoromethylcyclohexylpiperidine) are added. At 40 ° C, 3 g of sorbitol, 0.4 g of perfume are introduced.

The resulting product is a multiple emulsion and has moisturizing, regenerating and protective properties, improves blood microcirculation and saturates the skin with oxygen, providing a long-term effect on the skin.

Example 3. Known cosmetic cream, which is a direct emulsion with perfluorocarbons

Take 3 g of the emulsifier stearet-21, 2 g of the co-emulsifier glyceryl monostearate, 3 g of isopropyl isostearate, 2 g of isohexadecane, 1 g of cetyl alcohol, 1 g of beeswax, 0.5 g of tocopherol acetate, 2 g of almond oil, 3 g of cyclopentasiloxane , heated to a temperature of 75 ° C. Separately, heat water (up to 100 g) to 75 ° C, add moisturizing components (2.5 g glycerol, 0.5 g urea), 0.5 g D-panthenol, 1 g Germaben II preservative, 5 g dextran sulfate sodium. With stirring, the oil phase is added to the aqueous phase and homogenized on an Ultra Turrax for 5 minutes at a speed of 15,000 rpm. After obtaining a homogeneous oil-in-water emulsion, 20 g of perfluorocarbon microemulsion (85 vol.% Perfluorodecalin, 5 vol.% Perfluoroethers and 10 vol.% Perfluoroamines) are added. At 40 ° C, 3 g of polysaccharides, 0.4 g of perfume are introduced.

Example 4. The cosmetic product of the prototype, patent US 5567426 (Loreal). Body gel

Take 0.8 g of the emulsifier Abil WE 09, 2.6 g of silicone oil Volatil Silicone 7158, 1.4 g of fluorinated silicone oil FL 100/450 and perfume (q.s.), heated to 70 ° C. 0.16 g of sodium chloride, 4 g of propylene glycol and 0.4 g of glycerin and a preservative (q.s.) are added to hot water (10.64 g). With vigorous stirring, the aqueous phase is slowly poured to the oil phase, then homogenized on an Ultra Turrax for 5 minutes at a speed of 15,000 rpm. Then 0.8 g of the PEMULEN TR 1 fat-chain gelling agent is dissolved in water (up to 100 g), mixed with 10 g of butylene glycol, 5 g of glycerin, a preservative (q.s.) and 0.8 g of triethanolamine is added with stirring. To this solution, the previously obtained reverse emulsion is poured with vigorous stirring. The resulting tool is a multiple emulsion, has emollient properties.

The agents of examples 1 and 2 are multiple emulsions, the aqueous phases of which contain a microemulsion of perfluorocarbons, and the agent of example 3 is an emulsion, the external phase of which is water, within which the oil phase is dispersed (conventional direct emulsion). The funds are similar in composition, the same amount of perfluorocarbon microemulsion (20 g each) is introduced into each of them. The tool according to example 4, although it is a multiple emulsion, but does not contain perfluorocarbon microemulsion in the aqueous phases, but contains fluorinated silicone oil in the oil phase of the multiple emulsion.

As the studies of the authors showed, the agent according to example 3, when applied to the skin, immediately releases the entire amount of microemulsion of perfluorocarbons, that is, a high concentration of the active substance is created on the skin surface immediately after application of the agent, due to which part of the active component will volatilize and not penetrate the skin therefore, oxygen saturation of the skin is not prolonged.

The funds of examples 1 and 2 release the perfluorocarbon microemulsion gradually, first from the external phase, and after the active substances penetrate the skin from the internal phase, so the effect of using the active components will be stronger and longer, oxygen saturation of the skin is prolonged.

The agent of Example 4, although it is a multiple emulsion, but instead of the microemulsion of perfluorocarbons in the aqueous phases, contains only fluorinated silicone oil in the oil phase of the multiple emulsion. Accordingly, the saturation of the skin with oxygen is not prolonged.

The applicant, together with Croda (Great Britain), conducted a study to study the profile of the release of water from cosmetics.

In the experiment, cosmetics corresponding to examples 1, 2, 3 and 4 were compared.

In this case, a layer of the agent with a thickness of 200 μm was applied to a plate with a known mass using a special device. Using an analytical balance, the weight of the plate with the agent was fixed at the time of application and every five minutes for 3 hours. Water released from the cosmetic product evaporated from the surface of the plate. Thus, the weight of the plate with the agent applied to it decreased. The more plate weight remains at the end of the study, the less water is released from the cosmetic product. That is, the longer the emulsion retains water and the substances dissolved in it, the longer the effect of using the product will be.

Figure 3 shows the profiles of the release of water from the proposed cosmetics (1 and 2) and known (3 and 4). As can be seen from the graph, the proposed funds retain 25% more water and active components 3 hours after the start of the experiment compared with the means in examples 3 and 4.

The applicant conducted a study to study the dynamics of oxygen saturation of the skin (dynamics of transdermal oxygen tension (tc pO2)) using the described cosmetics. In the experiment, cosmetics corresponding to examples 1, 2, 3 and 4 were compared.

The study of tc pO2 was carried out using a TCM 4 apparatus (Radiometer, Denmark). The calculation of tc pO2 is based on direct polarographic measurement based on an electrochemical electrode circuit consisting of a platinum cathode (electrode-sensor) and a silver anode (reference electrode). The end of the electrode is covered with a thin membrane that stabilizes the diffusion processes in it. Oxygen from the skin penetrates through this membrane to the cathode, where there is a decrease in its amount, which is characterized by a quantitative value, converted to volts and processed digitally. The received digital signal is then processed by a computer, as a result of which the tc pO2 value is displayed in mm Hg on the display.

Before the start of the study, the skin at the selected points was previously cleaned with 70% ethanol. After that, an oxygen sensor was installed using a special locking ring. His testimony was recorded on a monitor in the form of a graph until reaching a "plateau" and then for 20-25 minutes. Next, a cosmetic product was applied to the skin and exposed for 120 minutes, after which the study of tc pO2 at this point was repeated according to the program described above.

Figure 4 shows the dynamics of skin oxygen saturation when using cosmetics (1 and 2) and known (3 and 4). As can be seen from the graph, the proposed funds gradually saturate the skin with oxygen and their effect is prolonged compared with the funds in examples 3 and 4.

Thus, the authors obtained a stable cosmetic product that provides instant and lasting exposure to the skin of the active components and their optimal biological absorption by the skin. The effect of using such a product is instant and prolonged hydration and oxygenation of the skin. The instant effect is provided by the release of active components from the external aqueous phase, and the prolonged one from the internal aqueous phase. The proposed cosmetic product has good sensory, nutritional and protective properties, since it includes natural oils, waxes, vitamins.

Claims (5)

1. Cosmetic skin action, which is a multiple emulsion containing an external aqueous phase with an included oil phase, in which the internal aqueous phase is dispersed, characterized in that the aqueous phases of the multiple emulsion contain a microemulsion of perfluorocarbons in a concentration of from 0.1 to 20% in each. 2. The tool according to claim 1, characterized in that it further comprises dextran sodium sulfate in an amount of from 0.01 to 5.0% in the external and internal aqueous phases. 3. The tool according to claim 1, characterized in that it further comprises water-retaining components in the external aqueous phase. 4. The tool according to claim 3, characterized in that sorbitol and / or polysaccharides are used as water-retaining components. 5. The method of obtaining funds according to claim 1, characterized in that the reverse water-in-oil emulsion is prepared and dispersed in the presence of the Poloxamer-407 emulsifier and the Ultresrez-10 carbopol stabilizer in the external aqueous phase until a multiple emulsion is obtained, wherein first, a perfluorocarbon microemulsion is introduced into the internal aqueous phase of the reverse emulsion, and perfluorocarbon microemulsion is introduced into the external aqueous phase in the process of producing a multiple emulsion.

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