DE10322444A1 - Cosmetic compositions with decorative and antimicrobial effects contain bioactive glass, colored glass, glass-ceramic, glass powder, glass-ceramic powder and/or a glass/nanoparticle composite - Google Patents

Abstract

Sun-cream, eye-shadow, hair shampoo, lipstick, face mask, make-up foundation cream, nail lacquer and rouge compositions each contain 0.01-30 (especially 0.01-5) wt.% of a bioactive glass, colored glass (composition), glass-ceramic, glass powder, glass-ceramic powder and/or a glass/nanoparticle composite.

Description

The invention relates to formulations of cosmetic products with bioactive glass or colored glasses or glass powder or colored glass powder or glass ceramic powder or composite materials comprising glass and nanoparticles.

Glasses with an antimicrobial effect come from a variety of fonts known.

For example, US Pat. No. 5,290,544 describes water-soluble glasses for use in cosmetic products with very low SiO ₂ and very high B ₂ O ₃ or high P ₂ O ₅ contents. The glasses have silver concentrations greater than 0.5% by weight. These glasses have an extremely low hydrolytic resistance and tend to completely dissolve in water. The Ag and / or Cu ions released here have an antibacterial effect. JP-A-92178433 also describes a water-soluble glass powder with SiO ₂ <37% by weight as a polymer additive with high silver concentrations> 1% by weight.

No. 6,143,318 describes silver-containing phosphate glasses which are used as an antimicrobial material for wound infection treatment with combinations of Cu, Ag and Zn. These are also water-soluble glasses that have low SiO ₂ concentrations and very high P ₂ O ₅ contents.

Because of their low hydrolytic resistance, these glasses are only very good limited suitable for grinding in aqueous media.

Antimicrobial silver-containing borosilicate glasses or borophosphate glasses are used in the documents JP 10218637, JP 08245240, JP 07291654, JP 03146436, JP 2000264674, JP 2000203876. Most of these glasses feature have good hydrolytic resistance and can therefore be used in aqueous media be ground.

Find zeolites that contain silver that is introduced by ion exchange also used as an antibacterial agent. This is for example in the US 6,245,732 and WO 0038552.

Glasses free of heavy metals, in which an antimicrobial effect has been demonstrated can be found in DE 199 32 238, DE 199 32 239 and WO 01/03650 described.

In those from DE 199 32 338, DE 199 32 239 and WO 01/03650 known glasses are bioactive glasses with a significant Phosphorus content> 1% by weight.

The essential properties of bioactive glass are known to the person skilled in the art known and described for example in US-A 5,074,916. After that bioactive glass differs from conventional lime sodium silicate Glasses by binding living tissue.

For example, bioactive glass refers to a glass that has a firm bond with it Body tissue enters, whereby a hydroxyl apatite layer is formed. Under bioactive glass is also understood to be a glass that is antimicrobial and / or shows anti-inflammatory effects.

Colored glasses refer to glasses that have a color effect. This Color effect can, for example, by ions or nanoparticles, for example Metal or semiconductor nanoparticles are generated. The colored glasses become Coloring of the cosmetic products or for UV and / or IR absorption related.

The object of the invention is to formulate cosmetic products with bioactive glasses or colored glasses or colored glass powders or glass powders or Glass ceramic powders or composite materials comprising a glass and Nanoparticles. In particular, the glass powder should comprise a bioactive glass, for example an antimicrobial glass.

This task is accomplished by a cosmetic formulation according to one of the Claims 1 to 8 solved.

According to the invention, these are the most varied cosmetic formulations such as color cosmetics, skin care, hair care, sun creams, eye shadows, shampoos, lipsticks, Face masks, makeup compositions, nail polish compositions, Blush compositions, aftershave, shaving cream, mouthwash, Foundations, mascara, nail cream, face powder and face cream.

The cosmetic compositions according to the invention contain bioactive Glass or glass powder or glass ceramic powder or composite materials comprising glass and nanoparticles, which are preferred on an industrial scale Standard procedures can be made.

The glasses or glass powder or glass ceramic powder or composite compositions added to the cosmetic compositions comprise glasses, which preferably comprise the following components:
SiO ₂ : 35-80% by weight
Na ₂ O: 0-35% by weight
P ₂ O ₅ : 0-80% by weight
MgO: 0-5% by weight
Ag ₂ O: 0-0.5% by weight
AgJ: 0-0.5% by weight
NaJ: 0-5% by weight
TiO ₂ : 0-5% by weight
K ₂ O: 0-35% by weight
ZnO: 0-10% by weight
Al ₂ O ₃ : 0-25% by weight
B ₂ O ₃ : 0-25% by weight

Furthermore, ions such as Fe, Co, Cr, V, Ce, Cu, Mn, Ni, Bi, Sn, Ag, Au, J individually or in total up to 10% by weight are added to achieve, for example, a color effect antimicrobial or anti-inflammatory effects.

A colored glass composition can be as follows:
SiO ₂ : 35-80% by weight
Na ₂ O: 0-35% by weight
P ₂ O ₅ : 0-80% by weight
MgO: 0-5% by weight
Ag ₂ O: 0-0.5% by weight
AgJ: 0-0.5% by weight
NaJ: 0-5% by weight
TiO ₂ : 0-5% by weight
K ₂ O: 0-35% by weight
ZnO: 0-10% by weight
Al ₂ O ₃ : 0-25% by weight
B ₂ O ₃ : 0-25% by weight
SnO: 0-5% by weight
CeO ₂ : 0-3% by weight
Au: 0.001-0.1% by weight

Preferred exemplary embodiments of such basic glasses are in the appendix in Table 1 given.

The basic glasses can also be used for the production of composite materials with nanoparticles. Such nanoparticles are, for example. TiO ₂ , ZnO; ZrO ₂ , metallic silver or gold. Such nanoparticles are less than 500 nm, less than 200 nm, less than 100 nm, less than 50 nm, preferably less than 10 nm. The proportions by weight of the nanoparticles in the composite composition are less than 30% by weight, less than 15% by weight, less than 5 % By weight, preferably less than 1% by weight, particularly preferably less than 0.1% by weight.

The glasses can be mixed in different grinding media, for example water Glass powder should be ground as this is a sufficient hydrolytic Resistance.

In the present application, granules and Glass beads understood.

The glass powders show a biocidal or a biostatic effect; are skin-friendly in contact with humans, toxicologically harmless and especially suitable for consumption.

Due to the requirements for the toxicological safety of the Glass powder and its suitability for consumption is particularly pure. Heavy metal pollution is low. So that is Maximum concentration in the field of cosmetic formulations preferably for Pb <20 ppm, Cd <5 ppm, As <5 ppm, Sb <10 ppm, Hg <1 ppm, Ni <10 ppm.

Using antimicrobial glass powders can preserve them the cosmetic compositions or formulations themselves or an antimicrobial effect can be achieved to the outside.

As skin irritation occurs in the field of cosmetic compositions play an important role, it is advantageous if the glass powder, in particular with antimicrobial properties, is skin-friendly.

It is particularly advantageous if the glass powder has the specified cosmetic Compositions have an antimicrobial effect. With certain Glass powders depend on the average particle size of the glass powder given the antimicrobial effect. The smaller the average particle size, the higher the antimicrobial effect due to the increase in reactive Surface of the glass.

In the case of glass powders with an antimicrobial effect, alkalis of the glass are replaced by H ⁺ ions of the aqueous medium by reactions on the surface of the glass. The antimicrobial effect of the ion exchange is based, among other things, on an increase in the pH value and the osmotic effect on microorganisms.

Ion-exchangeable glass powders according to the invention have an antimicrobial effect in aqueous media by increasing the pH by ion exchange between a metal ion, such as, for example, an alkali metal or alkaline earth metal ion and the H ⁺ ions of the aqueous solution, and by ion-induced impairment of cell growth (osmotic pressure, disturbance of Metabolic processes of the cells).

The particle sizes of the glass powders are preferably <100 μm, expediently <50 μm or 20 µm. Particle sizes <10 µm and smaller than 5 µm are particularly suitable. Particle sizes of <1 µm have proven to be particularly suitable.

Mixtures of different glass powders from the composition range different compositions and grain sizes are possible to to combine certain effects.

Depending on the particle size, concentration and the composition of the powder pH values of up to 13 are reached.

As stated earlier, the glass powder of different cosmetic Compositions skin-friendly even at high concentrations with high pH values.

Instead of glasses or glass powders, glass ceramics or Glass ceramic powder are used, the starting glasses preferably the include components specified above. The main crystalline phase of the Glass ceramics consist of alkali-alkaline earth silicates and / or alkaline earth silicates and / or alkali silicates.

The glass ceramic or the glass ceramic powder is characterized in that it a defined scattering and Shows reflection effect. In the case of cosmetic use, this can be the visual one Reduce the appearance of skin folds. The glass ceramic also shows a biocide against bacteria, fungi and viruses, definitely one biostatic effect. However, the glass ceramic is in contact with people skin-friendly and toxicologically harmless.

When using glass ceramics in the cosmetic field, the Maximum concentration of heavy metals, for example for Pb <20 ppm, Cd <5 ppm, As <5 ppm, Sb <10 ppm, Hg <1 ppm, Ni <10 ppm.

The unceramized starting glass, which is used for the production of the glass ceramic according to the invention, contains SiO ₂ as a network former between 35-80% by weight. At lower concentrations, the spontaneous tendency to crystallize increases sharply and the chemical resistance decreases sharply. At higher SiO ₂ values, the crystallization stability can decrease and the processing temperature is increased significantly, so that the hot forming properties deteriorate. SiO ₂ is also a component of the crystalline phases formed during the ceramization and, if high crystalline phase fractions are to be set by the ceramization, must be present in the glass in correspondingly high concentrations.

Na ₂ O is used as a flux when melting the glass. At concentrations less than 5%, the melting behavior is negatively influenced. Sodium is part of the phases that form during the ceramization and, if high crystalline phase fractions are to be set by the ceramization, must be present in the glass in correspondingly high concentrations. K ₂ O acts as a flux when melting the glass. Potassium is also released in aqueous systems. If there are high potassium concentrations in the glass, potassium-containing phases such as calcium silicates are also eliminated.

In the case of silicate glasses, glass ceramics or composites, the chemical resistance of the glass and thus the release of ions in aqueous media can be adjusted via the P ₂ O ₅ content. In the case of phosphor glasses, P ₂ O _{5 is} network images. The P ₂ O ₅ content is between 0 and 80% by weight.

In order to improve the meltability, the glass can contain up to 25% by weight of B ₂ O ₃ .

Al ₂ O ₃ is used to adjust the chemical resistance of the glass.

To strengthen the antimicrobial, especially the antibacterial Properties of the glass ceramic can have antimicrobial ions such as B. Ag, Au, I, Ce, Cu, Zn can be contained in concentrations of less than 5% by weight.

Coloring ions such as B. Mn, Cu, Fe, Cr, Co, V, can be individually or combined in a total concentration of less than 1% by weight.

The glass ceramic is usually used in powder form. The ceramization can either be done with a glass block or glass ribbons or with Glass powder. After the ceramization, the glass ceramic blocks or ribbons be ground into powder. If the powder has been ceramized, it may be necessary can also be re-ground to form agglomerates which during the Ceramization step are to be removed.

The grindings can be dry as well as in aqueous or non-aqueous Grinding media are carried out.

The particle sizes are usually less than 500 µm. Have as appropriate particle sizes <100 µm or <20 µm were found. Are particularly suitable Particle sizes <10 µm as well as less than 5 µm and less than 2 µm. As a whole Particle sizes of <1 µm have proven particularly suitable.

Mixtures of different glass powders from the composition range different compositions and grain sizes are possible to to combine certain effects.

Light scattering effects to achieve optical effects such as transparency, Reflection and scatter result from the different calculation indices of glass phase and crystal phase as well as the set crystallite sizes.

When dissolving the crystalline phase in water or aqueous solution remain honeycomb surface structures, in particular the optical Properties such as transmission, reflection and light scattering of the powder in Affect formulations. The powders are due to the light scattering effects suitable for soft focus applications.

The invention is described below using the exemplary embodiments become.

embodiments

Embodiment 1 specifies a sunscreen cream composition with glass powders with a particle size <1.6 μm and glass powders with a particle size <0.77 μm. A total of four formulations are given. Embodiment 1 sunscreen cream compositions

Embodiment 2 shows an eyeshadow composition with a Mixture of a glass powder with a particle size <4 µm and Mearlmica® SVA.

The eyeshadow composition comprises two phases, phase A and phase B. Phase A is mixed and dispersed in suitable mixing-dispersing devices. The components of phase B are then placed in an auxiliary vessel and heated and mixed there until a uniform mixture is obtained. Phase B is then sprayed into premixed phase A and pulverized and mixed until a uniform mixture is obtained. Embodiment 2 eyeshadow composition

Examples 3A and 3B show hair shampoo compositions, a glass powder with a particle size <5 microns was used.

The initial pH of the hair shampoo compositions according to Embodiment 3A was in the hair shampoo composition I -8.3, at the hair shampoo composition II -4.6, in which Hair shampoo composition III -3.9 and at the Hair shampoo composition IV -3.5.

The initial pH values of the hair shampoo compositions according to embodiment 3B were -8.9 for composition I, -8.2 for composition II, -5.7 for composition III, and -4.8 for composition IV. Embodiment 3A hair shampoo compositions

Embodiment 3B hair shampoo compositions

Exemplary embodiments 4A, 4B and 4C show exemplary embodiments for lipstick compositions. In the exemplary embodiment according to FIG. 4A, a glass powder with a particle size <4 μm with 5% by weight was used as a constituent. Overall, the lipstick composition according to embodiment 4A is a three-phase system.

The composition was prepared by weighing all the components phase A into a heated vessel and raising the temperature to 85 +/- 3 degrees Celsius, stir the phase until melted and uniform. Add phase B and mix until all pearl pigments are well dispersed. Then add phase C and mix with constant stirring. thereupon Pour at 75 +/- 5 degrees Celsius. Then melting, cooling and lighting the lipsticks.

Exemplary embodiments 4B and 4C show lipstick compositions with glass powder with a particle size <1.6 μm and in exemplary embodiment 4C lipstick compositions with glass powder with particle sizes <4 μm, <1.6 μm and <0.7 μm. Embodiment 4A lipstick composition

Embodiment 4B lipstick compositions

Embodiment 4C lipstick compositions

Exemplary embodiment 5 is an exemplary embodiment of a face mask composition consisting of two phases, a phase A and a phase B, phase B comprising a glass powder with a particle size <4 μm with a proportion of 10% by weight. First the Carbopol Aqua SF-1 acrylate copolymer and deionized or deionized water are mixed with moderate stirring. Then predisperse the glass powder with glycerin in a separate vessel until the mixture is soft and even, then add water and mix for 15 to 20 minutes with little warming of about 40 degrees Celsius. Add phenoxyethanol and Flamenco Satin Pearl 3500. Then mix until you get an even mix. In a last step, phase A is added to phase B with vigorous stirring. Embodiment 5 face mask compositions

Embodiment 6 specifies a make-up foundation cream composition with a total of 5 phases A, B, C, D and E, phase D comprising glass powder with particle sizes <1.6 μm or 0.7 μm. Embodiment 6 Makeup Foundation Cream Compositions

Embodiment 7 shows a nail polish composition with a glass powder with particle sizes <4 microns. The nail polish composition is a single phase composition in which all components are mixed in one vessel with a Lightnin propeller stirrer until a uniform mixture is achieved. Embodiment 7 nail polish composition

In embodiment 8 is a blush composition with a total of three Phases A, B and C indicated. Phase A includes a glass powder Particle sizes <4 µm. The blush composition is obtained by phase A is mixed and dispersed in a suitable manner. Then they will Phase B ingredients mixed in an auxiliary vessel that is heated until mixed gives a uniform mixture. Then phase B is premixed Phase A injected and mixed continuously.

The mixture of phase B and phase A is then pulverized and returned to the mixer. Then phase C is added to the mixture of phases A and B and stirred until a uniform mixture is obtained. Embodiment 8 blush composition

All components in the exemplary embodiments 1 to 8 are according to the CTFA International Buyersguide 2002 edited by John A. Wenninger and G. N. Mc Iwen, edited by The Cosmetic, Toiletery, and Fragrance Association, 110117TH Street, N.W., Suite 300, Washington DC, 20036-4702, Volume 2, Section 7, Technical / Trade / INCI names classified. The scope this publication will be included in full in this application locked in.

Instead of glass powders can be in all the specified compositions also glass ceramic powder or bioactive glasses or composite materials extensively used glass and nanoparticles.

A total of 21 examples of bioactive glass compositions Glasses or starting glasses for glass ceramics are in Table 1 in the Appendix specified in this application. The glass compositions can too Glass powders with the grain sizes mentioned above are ground. Instead of Glass powders can also include glass ceramic powders such Starting glasses or composite materials comprising such starting glasses and nanoparticles are used.

The present application makes formulations more cosmetic for the first time Products with bioactive glasses and / or glass ceramics and / or glass powders and / or glass ceramic powders and / or composite materials comprising a glass and nanoparticles.

Claims (14)

1. Sunscreen composition comprising 1. 1.1 a sunscreen formulation 2. 1.2 at least 0.01-30% by weight, preferably 0.01-10% by weight, particularly preferably 0.01-5% by weight of bioactive glass and / or colored glass and / or colored glass compositions and / or glass ceramic and / or glass powder and / or glass ceramic powder and / or composite material comprising a glass and nanoparticles. 2. An eyeshadow composition comprising 1. 2.1 an eyeshadow formulation 2. 2.2 at least 0.01-30% by weight, preferably 0.01-10% by weight, particularly preferably 0.01-5% by weight of bioactive glass and / or colored glass and / or glass ceramic and / or glass powder and / or glass ceramic powder and / or colored glass powder and / or composite material comprising a glass and nanoparticles. 3. A hair shampoo composition comprising 1. 3.1 a hair shampoo formulation 2. 3.2 at least 0.01-30% by weight, preferably 0.01-10% by weight, particularly preferably 0.01-5% by weight of bioactive glass and / or colored glass and / or glass ceramic and / or glass powder and / or colored glass powder and / or glass ceramic powder and / or composite material comprising a glass and nanoparticles. 4. A lipstick composition comprising 1. 4.1 a lipstick formulation 2. 4.2 at least 0.01-30% by weight, preferably 0.01-10% by weight, particularly preferably 0.01-5% by weight of bioactive glass and / or colored glass and / or glass ceramic and / or glass powder and / or colored glass powder and / or glass ceramic powder and / or composite material comprising a glass and nanoparticles. 5. Face mask composition comprising 1. 5.1 a face mask formulation 2. 5.2 at least 0.01-30% by weight, preferably 0.01-10% by weight, particularly preferably 0.01-5% by weight of bioactive glass and / or colored glass and / or glass ceramic and / or glass powder and / or colored glass powder and / or glass ceramic powder and / or composite material comprising a glass and nanoparticles. 6. A makeup foundation cream composition comprising 1. 6.1 a makeup foundation cream formulation; 2. 6.2 at least 0.01-30% by weight, preferably 0.01-10% by weight, particularly preferably 0.01-5% by weight of bioactive glass and / or colored glass and / or glass ceramic and / or glass powder and / or colored glass powder and / or glass ceramic powder and / or composite material comprising a glass and nanoparticles. 7. A nail polish composition comprising 1. 7.1 a nail polish formulation; 2. 7.2 at least 0.01-30% by weight, preferably 0.01-10% by weight, particularly preferably 0.01-5% by weight of bioactive glass and / or colored glass and / or glass ceramic and / or glass powder and / or colored glass powder and / or glass ceramic powder and / or composite material comprising a glass and nanoparticles. 8. Blush composition comprising 1. 8.1 a blush composition formulation 2. 8.2 at least 0.01-30% by weight, preferably 0.01-10% by weight, particularly preferably 0.01-5% by weight of bioactive glass and / or colored glass and / or glass ceramic and / or glass powder and / or colored glass powder and / or glass ceramic powder and / or composite material comprising a glass and nanoparticles. 9. Cosmetic formulation according to one of claims 1 to 8, characterized in that the bioactive glass, the glass of the glass ceramic powder, the starting glass of the glass ceramic, the glass of the colored glass, the starting glass of the glass ceramic powder, the glass of the composite material or the glass of the colored glass powder following Components include:
SiO ₂ : 35-80% by weight
Na ₂ O: 0-35% by weight
P ₂ O ₅ : 0-80% by weight
MgO: 0-5% by weight
Ag ₂ O: 0-0.5% by weight
AgJ: 0-0.5% by weight
NaJ: 0-5% by weight
TiO ₂ : 0-5% by weight
K ₂ O: 0-35% by weight
ZnO: 0-10% by weight
Al ₂ O ₃ : 0-25% by weight
B ₂ O ₃ : 0-25% by weight 10. Cosmetic formulation according to one of claims 1 to 8, characterized in that the colored glass comprises the following components:
SiO ₂ : 35-80% by weight
Na ₂ O: 0-35% by weight
P ₂ O ₅ : 0-80% by weight
MgO: 0-5% by weight
Ag ₂ O: 0-0.5% by weight
AgJ: 0-0.5% by weight
NaJ: 0-5% by weight
TiO ₂ : 0-5% by weight
K ₂ O: 0-35% by weight
ZnO: 0-10% by weight
Al ₂ O ₃ : 0-25% by weight
B ₂ O ₃ : 0-25% by weight
SnO: 0-5% by weight
CeO ₂ : 0-3% by weight
Au: 0.001-0.1% by weight 11. Cosmetic formulation according to one of claims 1 to 10, characterized characterized in that the glass powder and / or the glass ceramic powder and / or colored glass powder has an average particle size <100 μm. 12. Cosmetic formulation according to one of claims 1 to 10, characterized characterized in that the glass powder and / or the glass ceramic powder and / or colored glass powder an average particle size <50 microns, preferably < 20 µm. 13. Cosmetic formulation according to one of claims 1 to 10, characterized characterized in that the glass powder and / or the glass ceramic powder and / or colored glass powder an average particle size <10 microns, preferred <5 µm. 14. Cosmetic formulation according to one of claims 1 to 10, characterized characterized in that the glass powder and / or the glass ceramic powder and / or colored glass powder has an average particle size <1 μm.