DE2012928A1 - Dentifrice - Google Patents

Abstract

Cleaning and polishing mixtures essentially consist of between 0.1% and 80 wt.% of zirconium dioxide (ZrO2), usually 0.1-2.0 wt.% with particle sizes up to 50 micron, generally up to 5 micron, and the remainder of zirconium silicate (ZrSiO4) with particle size up to 10 microns, generally up to 5 microns.

Description

Cleaning preparation for dentures The invention relates to Cleaning and polishing agents made from zirconium silicate (ZrSiO4) and zirconium dioxide (ZrO2> as well as approaches and the use of preparations that such cleaning and Contains polishing agents. In particular, the invention relates to cleaning and polishing or cleaning preparations for dentures, which such cleaning and Contains polishing agents.

It has been shown that the difficulty in achieving a good Oral hygiene in persons using dentures is not less than for people who still have their natural teeth. Dental research has shown that full or partial dentures very prone to the formation and accumulation of tartar are. Also are the methyl methacrylate part of dentures and the area around the neck of prosthetic teeth are very sensitive against the formation and accumulation of various spots. It can be any part of the Dentition through various common agents normally used with human Ingested, stained or stained. For example, result Coloring on dentures usually from the use of tobacco, coffee, Tea, certain fruit juices, and some jellies and jams, as well as others Types of food.

Tests have shown that many of the stains mentioned are extremely difficult to if not impossible with the various denture cleaners out there at the moment are commercially available. Even if the accumulated stains and the stone can sometimes be removed by extensive brushing have become In addition, the commercially available denture cleaners are all considered deficient in proved another important relationship. For example, many leave behind such Cleaner on the surface of the denture a matt, unpolished coating, which promotes the formation of additional spots and films. It's a highly polished smooth surface is desirable as it increases the sensitivity of the surface of education and / or the accumulation of tartar, stains and bad breath reduced.

Also, there are some preparations that are commonly used to cleanse Dentures used are extremely abrasive and scratch the material, from which the denture is made, typically an acrylic resin such as methyl methacrylate. As the vast majority of denture wearers use a method of the best or use a combination of brushing and dipping to clean your dentures, must be an abrasive that is used in combination with a denture cleaner, Carefully selected and manufactured so that the cleaning and polishing properties of the preparation reach a maximum and at the same time the grinding of the teeth, that is achieved by brushing with the preparation is reduced to a minimum will.

Accordingly, it is the main object of the invention to be effective To create cleaning and polishing compound.

Furthermore, according to the invention, a preparation is to be produced which cleans and polishes with minimal abrasion.

Furthermore, an essential object of the invention is to provide one Denture cleaning preparation, which is a cleaning and polishing agent of the described Type contains.

Zirconium silicate has of course been used as a technical polishing agent been used for glass. In U.S. Patent 2,427,799 there is a zirconium silicate preparation for polishing glass, in which at least 908 of the used in the preparation Particles are 2 microns or less (diameter) in fineness. In the U.S. Patent 2,694,004 is a preferred zirconium silicate polishing material in which essentially all particles are mainly in the range from to about 3 microns. Although in the two U.S. patents zirconium silicate glass polish are described, there is no suggestion that the preparations in question as Polishing agents can be used for softer plastic materials that are more delicate Against abrasion than glass, such as methyl methacrylate, which is used in the manufacture of dentures is used. In US Pat. No. 3,151,210, abrasive dentifrices are included a content of ZrSiO4 for use in natural teeth. These However, known preparations can only be used successfully by on ZrSiO4 applies a thermoplastic resin coating. The one in the United States patent However, the coating described in 3 151 210 changes the ZrSiO4. In contrast got to it should be emphasized that the ZrSi04, which is used according to the invention, is not Is coated and directly on the dentition surface without the interposition of a plastic coating works.

In U.S. Patent Application Serial No. 703,874 are newer and more effective Cleaning and polishing preparations called, which contain zirconium silicate (ZrSiO4) with particles in the range of up to about 10 microns and zirconium dioxide tZrO2) with particles in the Particle size ranges up to about 50 microns, with the greater portion and preferably about at least 75% of the particles are between 10 and 20 microns. Such a mixture contains at least about 20% by weight and up to about 80% by weight ZrO2, remainder ZrSi04, (that is, weight ratios of ZrSiO4: ZrO2 = 4: 1 to 1: 4).

It has now been found that even better results with mixtures zirconium silicate having particles ranging from at least about 10 microns and off at least about 1%, based on the weight of the mixture, of micronized ground Dioxide (i.e., ZrO particles less than about 1 micron particle size) will.

Accordingly, the basic idea of the invention lies in the application of Mixtures of zirconium silicate and zirconium oxide, which contain about 0.1 to 80% by weight Contain ZrO2. In each At least about 90% of the ZrSiO4 particles are located in the range of up to about 5 microns in particle size. The mentioned cleaning and Polishing preparations are preferably in one in the denture cleaning preparation The order of magnitude of about 20 to 90% by weight of the preparation is provided. By using The cleaning and polishing agents of the invention can overcome the difficulties that experience has shown occur with the known cleaning and polishing preparations, be overcome, and the means of the invention can be used for preparing preparations, which excellent cleaning and polishing abilities and minimal abrasion exhibit.

According to the invention it has been found that through the use a mixture of zirconium silicate (ZrSiO4) with particles in the range of up to about 10 microns with at least about 90% of the particles ranging up to about 5 microns, and zirconia (zur02) with particles ranging up to about 50 micron particle size a cleaning and polishing preparation optimal cleaning and polishing properties are imparted. Such mixtures preferably contain about 0.1 to about 80 wt% ZrO2.

If relatively large ZrO2 particles are used, the larger one will be Proportion and preferably at least about 75% of the particles in the range of 10-20 Micron. Such a mixture contains at least about 20 to about 8% by weight 80 Weight% large ZrO2 particles and the remainder ZrSiO4 (i.e., weight ratios of ZrSiO4 to ZrO2 = 4: 1 to 1: 4). However, micron-finely ground zirconium dioxide is preferred (ZrO2), ZrO2, the total particle size of which is essentially less than 1 micron are used, and in this case the mixture should be from about 0.1 to about 2.0 % By weight ZrO2, preferably about 0.5% by weight ZrO2.

The cleaning and polishing component is preferably in a denture cleaning preparation present on the order of about 20 to 90 weight percent.

The particle size in cleaning and polishing preparations can be numerous various ways are expressed, the most common of which is the mean diameter " is, that is, the arithmetic mean of the diameter of particles in a representative Sample. As used herein, the term "particle size" relates refer to the value of the mean diameter.

The manufacture of zirconium silicate of a suitable particle size can be achieved by standard procedures as known in the art will. In principle, these working methods consist of grinding zirconium silicate ore (ZirkonL with subsequent standard sieving or (air separation) around the desired Separate particle size. Different milling methods can be used will, to obtain the desired surface configuration for the zirconium silicate particles. The particles can be prepared by grinding with a ball mill. Preferably contain the cleaning and polishing agents of the invention a mixture of ball-milled and hammer milled particles.

As is known in the art, hammer mills use a high speed rotating shaft with a multitude of hammers or striking elements mounted on it. The hammers can be T-shaped elements, rods or rings that can be rotated on the shaft or on Discs mounted on the shaft are attached or rotatably mounted. The shaft runs in a housing which contains grinding plates or inserts. The grinding action results from the blow between the ground material and the movement of the hammers. if Zirconium ore is ground using an abrasion technique, such as a hammer mill, relatively raw, serrated particles are produced. Particles with a serrated surface configuration act in a relatively superior way in the denture cleaning standpoint Compared to smoother configured particles.

Similarly, a ball mill includes one around a horizontal one Axis rotating cylindrical or conical shell made with a grinding medium such as Steel balls, Flintstone or porcelain is loaded. the Grinding is achieved by the drum action of the balls on the material to be ground. Particles of zirconium silicate treated in a ball mill of the type described have relatively smooth surface configurations and act from the point of view polishing better than more jagged configured particles.

As mentioned, the zirconium silicate produced according to the invention used, particles ranging up to about 10 microns with at least about 908 of the particles ranging up to about 5 microns.

Zirconia, ZrO2, can be made by the same known milling and grinding processes Sieving technology can be produced, with the particles in the range of up to about 50 Micron particle size. The ZrO2 particles are preferably micron-finely ground, i.e. they are primarily all less than 1 micron in particle size, with such particles are suitable for giving the surface to be treated a high degree of polishing. If relatively large ZrO2 particles are used, the mass of the ZrO2 particles will be (i.e., preferably at least 75z) in the range of about 10 to 20 microns, where the remainder being substantially evenly distributed between the range from 0 to 10 microns and 20 to 50 microns. -A particularly proven approach from a large-scale ZrO2 mixture contains about 86% particles between 10 and 20 microns, about ~ 8 * ~ between 0 and 10 microns and about 6% between 20 and 50 microns.

If micron-fine milled ZrO2 is used, the cleaning agent contains and polishing agents of the invention have relative proportions of ZrSiO4 and ZrO2 within the Range from about 0.1 to about 2.0% ZrO2, the remainder being ZrSiO4.

Optimal results are achieved with about 0.58 Zr02, based on weight of the cleaning and polishing agent.

If relatively large ZrO2 particles are used, they contain Cleaning and polishing agents of the invention have relative proportions of ZrSiO4 and ZrO2 within the range from about 20% by weight to about 80% by weight ZrO2, the remainder being ZrSi04 (i.e., a ZrSiO4 to ZrO2 weight ratio range of 4: 1 to 1: 4). Preferably such agents contain about 20 to 50% ZrSiO4 and about 50 to 80% ZrO2 (i.e. about a weight ratio of ZrSiO4 to ZrO2 = 1.1 to 1: 4). Best results are achieved with a mixture of ZrSiO4 to Zr02 of 1: 3.

The cleaning and polishing agents made of zirconium silicate (ZrSi04) and Zirconia (ZrO2) of the invention are commonly used in denture cleaner preparations within the range of about 20% to about 90% by weight, as the case may be Desired approach, used as known to those skilled in the art. Denture cleaner contained in paste form preferably about 20 to 70 in total % By weight cleaning and polishing agent, whereas denture cleaner in powder form preferably contain about 60 to 90 wt .-% cleaning and polishing agents.

Denture preparations using cleaning and polishing preparations of the invention are manufactured in the usual manner and can contain ordinary additional Contain components that make the overall preparation economical for the consumer make acceptable.

In particular, a denture paste generally requires a binding substance, to achieve the desired structural properties. Natural binder Gums, such as gum tragacanth, Indian tragacanth, gum arabic and the like, tank derivatives, like domestic moss and alginates: as well as water-soluble cellulose derivatives, like Hydroxyethyl cellulose and sodium carboxymethyl cellulose can be used for this purpose be used. Texture enhancements can also be made by including additional Materials such as colloidal magnesium aluminum silicate can be achieved.

Thickening agents in amounts from 0.5 to 5.0% by weight can be used to form a satisfactory denture paste can be used.

Denture pastes usually also contain foaming agents. Suitable Foam agentsIndu.a. water-soluble alkyl sulfates with 8 to 18 carbon atoms im Alkyl radical, such as sodium lauryl sulfate, water-soluble salts of sulfonated monoclycerides of fatty acids with 10 to 18 carbon atoms in the alkyl radical, such as sodium coconut monoglyceride sulfonate, Salts of fatty acid amides of taurines such as sodium N-methyl palmityl tauride and salts of fatty acid esters of isethionic acid.

Foaming agents can be used in the preparations of the invention in an amount from about 0.5 to about 5.0% by weight, based on the total preparation, can be used.

It is also desirable to have some humectant in a denture paste incorporated to keep it from becoming hard. Usually for this purpose The materials used include glycerine, sorbitol and other polyhydric alcohols. Humectants can contain up to about 35% by weight of the denture paste preparation turn off.

In the following examples are some preparations for denture attachments specified using the cleaning and polishing agents of the invention.

Examples 1 and 2 also illustrate preferred preparations of the invention a content of micron-fine ground zirconium dioxide.

Example 1 Ingredients Parts by Weight (%) Zirconium Silicate 47.31 Zirconia (ground micron) 0.22 Distilled water 19.47 Glycerine 13.00 Sorbitol (70% aqueous solution) 14.00 sodium monoglyceride sulfonate 1.00 sodium lauryl sulfate 1.00 Magnesium Aluminum Silicate (Veegum) 1.00 Sodium Carboxymethyl Cellulose 1.00 Flavoring agents, coloring agents and the like 2.00 Example 2 Ingredients Parts by weight (%) Zirconium Silicate 48.55 Zirconium Dioxide (micronized) 0.06 Distilled Water 18.39 glycerine 13.00 sorbitol (70% aqueous solution) 14.00 example 2 (continued) Ingredients Parts by weight (%) Sodium Monoglyceride Sulphonate 1.00 Sodium Lauryl Sulphate 1.00 Magnesium Aluminum Silicate (Veegum) 1.00 Sodium Carboxymethyl Cellulose 1.00 Flavorants, Colorants, and the like 2.00 Example 3 illustrates a denture cleaner approach using a preferred mixture of zirconium silicate and large zirconia particles. im Weight ratio 1: 3.

Example 3 Ingredients Parts by weight (%) zirconium silicate 12.00 Zirconium Dioxide 36.00 Distilled Water 19.00 Glycerin 13.00 Sorbitol (70% aqueous solution) 14.00 sodium coconut monoglyceride sulfonate 1.00 sodium lauryl sulfate 1.00 Magnesium Aluminum Silicate (Veegum) 1.00 Sodium Carboxymethyl Cellulose 1.00 Flavoring agents, coloring agents, and the like 2.00 In the following examples further tooth cleaning approaches are given, containing cleaning and polishing agents made of zirconium silicate and zirconium dioxide.

Example 4 Ingredients Parts by Weight (8) Zirconium Silicate 24.00 Zirconia 24.00 Distilled water. 19.00 glycerine 13.00 sorbitol (70% aqueous solution) 14.00 sodium coconut monoglycard sulfonate 1.00 sodium lauryl sulfate 1.00 Magnesium Aluminum Silicate (Veegum) 1, OO Sodium Carboxymethyl Cellulose 1.00 Flavoring agents, coloring agents and the like 2.00 Example 5 Ingredients Parts by weight ($) Zirconium Silicate 10.00 Zirconium Dioxide 40.00 Distilled Water 17.00 Glycerin 13.00 Sorbitol (70% aqueous solution) 14.00 Sodium coconut monoglyceride sulfonate 1, 00-.

Sodium Lauryl Sulphate 1.00 -Magnesium Aluminum Silicate (Veegum) 1.00 Sodium carboxymethyl cellulose 1.00 Flavorings, coloring agents and the like Z 2.00 the superior cleaning, polishing and abrasion properties of the invention Mixtures of zirconium silicate and zirconium oxide were made by the following experimental Ratings noted. In principle, the polishing and abrasion properties of the materials tested was determined by applying test abrasives to methyl methacrylate bridges applies, while the cleaning properties are determined by the fact that who uses abrasives on plexiglass blocks.

To carry out the polishing method, square, heat-hardened Methyl methacrylate blocks with an edge length of 1.27 cm (1/2 "square) produced in this way that the surface to be polished is smooth and free from defects.

The surface is then covered with a washer of green dedico rubber (Dedico = distilled Rhizinenfettsäuxe), which on a standard handpiece for Dental treatment was mounted, matted. The blocks are then attached to a micrometer mount of a reflectometer is attached, and there will be an initial reflectometer reading recorded using low radiation intensity. The test mixes are made from 25.0 g of abrasive and 50 ml of an aqueous, show carboxymethyl cellulose solution mixed. Then the test blocks are mounted on a tooth-burst machine, and the test mixture is applied to the test surface by soft toothbrushes a tension of 150 g and using of 1000 double lines upset. After finishing the brushing method, the numbered blocks are removed, carefully rinsed with distilled water and covered with a soft, absorbent Tissue wiped dry. The blocks are then reattached to the reflectometer, and the highest deflection of reflection at any part of the surface of each block is recorded as the final reading.

The difference between the final average readings and the average initial readings are used as a measure of relative polishability of the test agent.

The relative cleanability of abrasives is thereby measured that one square Plexiglas blocks with an edge length of 1.27 cm (1/2 "square).

Before use, the blocks are protected by adhesive paper to prevent scratching of the block surface.

To carry out the working method, the adhesive backing is applied from one side of each block to be used removed and the exposed side cleaned to remove any Remove foreign material. The blocks are then placed under a ventilation hood laid out in groups of 5 or 6 pieces.

After drying, the blocks are coated with an enamel coating, which is covered with Ethyl acetate in a ratio of 1: 1 was mixed, sprayed and soaked with ethyl acetate Dixie bowls covered. After about 2 hours of drying, the paint is finished and The overlap procedure is repeated and the blocks are about 24 hours long left to dry. The ReElectometer used in connection with the cleaning procedure is standardized by setting the deflection to an assumed number of 5.0, when a high intensity beam reflects off a standard black carrara glass sample held in a fixed micrometer position. When the reflectometer standardized in the above manner, the dried, with the paint provided blocks each give a deflection of about 6.0. Those, who do not give a reading of 6.0, generally have an uneven paint mixture surface and are discarded.

The test mixes are made up of 25.0 grams of a test abrasive and 50.0 ml of an aqueous, 1.0% gen carboxymethyl cellulose solution mixed. Afterward the blocks are numbered and mounted on a brushing machine. The test mix is applied to the surface of the block by using a soft toothbrush Tension of 150 g and 1000 lines applied. The blocks are then extracted from the Removed from the brushing machine, washed with distilled water and brushed with a soft, absorbent fabric wiped dry. Each block is then individually placed in the reflectometer and the lowest deflection is recorded. The difference between the initial or control deflection of about 6.0 and the final deflection after the brushing is taken as a measure of the cleanability of the test mixture.

To evaluate the abrasion properties of a test mixture, a weight loss method. applied.

Numbered methyl methacrylate blocks are made and 6 through 8 Put in a humidifier for hours. Then the blocks are 1 hour long allowed to air dry and weighed on an analytical balance. The weight is recorded as the initial wet weight. The blocks are then in air at 650C Dried for 3 hours, allowed to cool for 20 minutes and put back on an analytical Weighed the scales. The second weight is recorded as the initial dry weight.

A test mixture of 25.0 g of abrasive and 50.0 ml mixed with an aqueous, 3.0% strength carboxymethyl cellulose solution. For examination Blocks of the mixture are mounted on a brush machine and the mixture is on the surface of the blocks with medium brushes with the application of tension of 150 g and 50,000 double strokes. There will be a stirrer on the brush holder mounted to keep the test abrasive in solution and allow the particles to settle to prevent.

After brushing, the blocks are removed from the brushing machine and rinsed thoroughly with distilled water to remove all traces of abrasive. The blocks are then wiped dry with soft, absorbent tissue and 1 Allowed to air dry for 1 hour.

The blocks are weighed again on an analytical balance, and the resulting weight is recorded as the final wet weight. The blocks will then air-dried at 65 ° C. for 3 hours and mechanically cooled for 20 minutes. The blocks are then weighed again and the resulting weight becomes recorded as final dry weight. The average of the wet weights and the dry weights is assumed as the weight loss of the acrylic blocks due to abrasion, and the results are recorded in milligrams of weight loss.

There were cleaning and polishing grindings in the above manner for a mixture of ZrSiO4 and micron-fine milled ZrO2 with about 5.08 ZrSiO4, for a mixture of zirconium silicate and zirconium dioxide in a weight ratio of 1; 3 obtained, and for comparison purposes, similar values have been used for several commercially available denture cleaners obtained, which are the most widely used as the main cleaning and polishing components Denture cleaning abrasive, calcium hydrogen phosphate dihydrate (CaHPO4 2H30) 1 Contained sodium carbonate (Na2CO31OH20> and sodium bicarbonate (NaHC03) Data listed in Table I. are, show that at the minimum at least a 35% improvement in the polishing effect (over 100% in the case of the microfine ZrO2 agent) obtained according to the invention without reducing the cleaning performance will. The cleaning value obtained with the blend of the invention is at least 5% higher (19% in the case of the micronized zrO2 agent) than the values for CaHPO42H20.

Similarly, the means of the invention are essentially less abrasive than usual means.

The mark-off values on thermoset acrylic blocks on both wet and also on a dry basis for a ZrSiO4-ZrO2 mixture in a weight ratio of 1: 3 and for the same commercially available denture cleaners as listed above were obtained in the above manner.

These data, which are also given in Table I, show that the compositions of the invention are significantly less abrasive (i.e., at the minimum over 30% less abrasive and in the case of the micron-fine ZrO2 agent over 4081 as CaHP042H2O.

Table I Acrylic Po Cleaning Acrylic Abrasion Weight Loss Main Ingredients of the lier- (mg) denture cleaner sanding sanding wet dry NaCl 0.80 0.33 # 0.11 * N.A. ** N / A.

Na2CO3 + Na2CO3 10H2O 0.70 0.38 # 0.05 N.A. N / A.

Na2MPO4 1.50 0.43 # 0.08 N.A. N / A.

NaHCO3 + NaBO3 # H2O 1.30 0.43 # 0.13 N.A. N / A.

Na3PO4 + Na2CO3 0.60 0.50 # 0.11 N.A. N / A.

Na2CO3 + Na5P3O10 (II) 1.70 0.30 # 0.07 N.A. N / A.

NaHCO3 1.60 0.40 # 0.08 N.A. N / A.

NaHCO3 + Na2CO3 # 10H2O 0.50 0.43 # 0.09 N.A. N / A.

CamPO4 # 2H2O 2.25 4.80 # 0.18 7.50 # 0.78 8.23 # 0.97 CaHPO4 # 2H2O 1.15 4.90 # 0.14 6.63 # 0.79 5.90 # 0.81 ZrSiO4 + ZrO2 (1: 3) *** 3.05 5.15 # 0.13 4.43 # 0.63 3.68 # 0.75 ZrSiO4 + ZrO2 (94: 6) **** 4.54 5.84 # 0.15 4.21 # 0.49 3.52 # 0.67 * mean standard source of error ** not applicable (no insoluble Abrasives in the system) *** approach from example 3 **** approach from example 1 It changed the cleaning and polishing effect for different mixtures ZrSiO4 and large-scale ZrO2 determined experimentally in the above manner and shown in Table II. These data show that the effect of the invention is one includes a wide range of contents of ZrSiO4 and large ZrO2, namely about Gemisuche with ZrSiO4 and large-scale ZrO2 in a ratio of about 1: 4 to 4: 1, whereby a mixture in the ratio of 1: 3 is preferred.

Table II Abrasion System Acrylic Polishing Cleansing Abrasion Relative Parts by weight cut off (mg weight loss) FrSiO4 ZrO2 * 100 0 2.55 1.90 80 20 2.85 1.95 75 25 2.85 2.00 67 33 t 2.95 1.99 50 50 3.60 1.95 33 67 4.40 1.85 25 75 4.50 1.95 20 80 4.10 1.85 0 100 3.70 1.60 relatively large ZrO2 (main mass in the area from 10 to 20 microns) In Table III data are given showing the change show the polishing effectiveness for different masses of ZrSiO4 and ZrO2. These Data make it clear that the addition of only 0.06% of micronized grind ZrO2, based on the weight of the entire cleaner, (about 0.12 wt .- * of the cleaning agent and polishing mix) obviously improves results beyond those which are obtained with each of the components separately.

Table III Overview of the acrylic polishing values, polishing values ++++ cleaning and Po- 100 lines 500 lines 1000 lines polishing agent polishing polishing polishing Polishing- Polishing- Polishing-ZrSiO4 ZrO2 ++ ZrO2 +++ grinding increase grinding increase Grinding increase 49.00 ----- ----- 2.05 # 0.14 0.55 # 0.14 2.98 # 0.27 1.48 # 0.27 4.31 # 0.24 2.81 # 0.24 ----- 49.00 ----- 1.99 # 0.03 0.49 # 0.03 2.77 # 0.14 1.26 # 0.14 4, 34 # 0.23 2.84 # 0.23 ----- ----- 24.50 1.98 # 0.10 0.48 # 0.10 3.06 # 0.27 1.56 # 0.27 4.39 # 0.42 2, 89 # 0.42 48.22 0.78 ----- 1.96 # 0.10 0.46 # 0.10 3.28 # 0.15 1.78 # 0.15 4.20 # 0.37 2.70 # 0.37 47.63 1.32 ----- 2.51 # 0.36 1.01 # 0.36 3.85 # 0.30 2.35 # 0.30 4.34 # 0.25 2.84 # 0.23 46.06 2.94 ----- 2.84 # 0.12 1.36 # 0.12 4.19 # 0.11 2.69 # 0.11 4.78 # 0.23 3.28 # 0.23 43.12 5.88 - --- 2.49 # 0.11 0.99 # 0.11 4.18 # 0.20 2.68 # 0.20 4.75 # 0.08 3.25 # 0.08 48.55 ----- 0.06 2.16 # 0.12 0.66 # 0.12 5.01 # 0.22 3.51 # 0.22 4.24 # 0.29 2.74 # 0.29 48.22 ----- 0.10 2.78 # 0.14 1.28 # 0.14 3.88 # 0.21 2.38 # 0.21 5.11 # 0.16 3.62 # 0.16 47.31 ----- 0.22 3.29 # 0.13 1.79 # 0.31 5.41 # 0.19 3.91 # 0.19 6.04 # 0.33 4.54 # 0.33 45.62 ----- 0.44 2.73 # 0.07 1.23 # 0.07 4.34 # 0.26 2.85 # 0.26 4.95 # 0.28 3.45 # 0.28 42.24 ----- 0.88 2.91 # 0.18 1.41 # 0.18 4.93 # 0.17 3.43 # 0.17 5.13 # 0.12 3.63 # 0.12 + expressed as a percentage of the total denture cleaning preparation at a content of the cleaning and polishing system of 49% above.

++ Relatively large ZrO2 particles.

+++ Micronized ZrO2.

++++ Expressed as the mean # mean standard error.

It can thus be seen that the zirconium silicate-zirconia agents of the invention, in particular the micron-fine milled ZrO2 agents, the three basic criteria meet which are used to evaluate a denture cleaning device namely high cleaning and polishing ability with minimal abrasion.

In addition to the use of the zirconium silicate described according to the invention and zirconia agents for cleaning and polishing dentures made from acrylic resins The invention of course also includes the use of these agents for cleaning and Polishing of dentures made of other materials as well as other objects made of acrylic resins and similar plastics. So are the means of the invention usable for all cleaning and polishing purposes, which the precise combination require cleaning and polishing ability with low abrasion caused by the Means of the invention is achieved.

Claims (5)

Claims (1). Cleaning and polishing compound, characterized by a content on a mixture of about 0.1 to about 80% by weight of zirconium dioxide (ZrO2> with a Particle size in the range of up to about 50 microns and a balance of zirconium silicate, (ZrSiO4) with a particle size in the range of up to about 10 microns. 2. Mass according to claim 1, characterized in that at least 90% of the zirconium silicate particles range in size from bits to about 5 microns and essentially all of the zirconia particles have a particle size of less than about 1 micron, the mixture being about 0.1 to 2.0% by weight, preferably 0.5% by weight, zirconium dioxide and the remainder zirconium silicate. 3. Mass. according to one of the preceding claims, characterized in that that at least about 75% of the zirconia particles have a particle size of about 10 to 20 microns with the mixture about 20 to 80 wt. * Zirconia and SO contains up to 20 wt% zirconium silicate. 4. Mass according to one of the preceding claims, characterized in that that the zirconia particles and the zirconium silicate particles in a weight ratio from about 1: 1 to about 3: 1, preferably about 3: 1. 5. Use of the mass according to one of the preceding claims as part of a denture cleaning preparation in a proportion of about 20 to 90% by weight of the preparation.