RU2478364C1 - Method of increasing microhardness of tooth enamel - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, namely to therapeutic dentistry. In order to realise method of increasing microhardness of enamel preliminary preparation of teeth surface is performed by application on them of 3% hydrogen peroxide solution and drying with air jet, after which, on teeth surface applied is composition, which contains 0.5-2.5% in weight solution of titanium (IV) tetra-n-butoxide in monoatomic alcohols, drying is repeated and teeth surface is exposed to UF light with wavelength from 240 to 300 nm power 4 W for 1-3 min, even distribution of light flow on teeth surface being carried out during exposure. Method application results in increased microhardness of tooth enamel due to application of protective titanium oxide coating.

EFFECT: claimed method is characterised by simplicity of operation performance and safety of carrying out procedure of protective coating formation, makes it possible to solve problems of whitening and giving luster of teeth enamel, provides antibacterial effect.

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Description

The invention relates to medicine, namely to therapeutic dentistry, and can be used to increase the microhardness of tooth enamel by applying a protective coating. For this, before exposure to ultraviolet (UV) radiation, the gum mucosa is isolated with rubber dam, then a 3% hydrogen peroxide solution is applied to the tooth surface and dried with an air stream, after which a composition containing monohydric alcohol and titanium tetra-n-butoxide is applied to the teeth surface ( IV), re-drying and exposing the tooth surface with UV light with a wavelength of 240 to 300 nm with a power of 4 W for 1-3 minutes, and when exposed, uniform distribution of the light flux over the surface of the teeth is carried out. This method guarantees the effectiveness and safety of the procedure for the formation of a protective coating, allows you to solve the problem of whitening and glossing the enamel of the teeth, provides antibacterial action, is easy to perform operations.

A known method of increasing the microhardness of enamel, including the use of topical agents, such as varnishes, films, gels, creams and solutions based on calcium and / or fluorine-containing compounds (e.g. Maksimovskaya L.N., Roshchina P.I. Dentistry: Reference. - M .: Medicine, 2000; RU No. 2115405, 2179454, 2238078; US No. 5037639, 5460803, 5437857). This category of funds is aimed at the prophylactic strengthening of enamel due to its remineralization. Funds are applied or tightly fixed on the surface of the teeth and gums and are held for several hours, which ensures the simultaneous entry of strictly controlled amounts of calcium and fluoridion into the affected area of enamel. The disadvantage of this group of funds is the need for daily course treatment lasting several months, which, combined with the duration of the daily procedure (hours), causes a number of functional inconveniences in patients. Remineralization is achieved only in thin surface layers of enamel. In addition, an analysis of the formulations used showed their insecurity for human health, because inorganic water-soluble fluorides such as tin, copper, nickel, palladium, barium fluorides and antimicrobial agents such as phenol and its derivatives are used. (RU No. 2179454, 2238078).

Another way to increase the hardness and caries of tooth enamel is based on exposure to laser radiation on the surface of the teeth.

Known methods for continuous enamel irradiation with a CO ₂ laser (Stern RH, Vahl J., Sognnaes RF // J. Dent. Res. 1972, 51,455-460; Beeking P.-O., Herrmann C., Zuhrt R. // Dtsch Stomatol. 1990, 40, 490-492) and pulsed Nd: YAG laser irradiation (RU No. 2127137, 2275217; US No. 7354448). In these methods, microhardness is increased due to structural crystallographic effects and phase changes in the surface layer of enamel, which, with continuous laser irradiation, reaches a depth of 50 microns. The advantage of pulsed lasers over cw lasers is the significantly lower levels of stored energy. In this case, a pulsed laser creates a temperature increase on the tooth surface of more than 1000 ° C, sufficient for splicing and fusion of enamel crystals. The surface flash zone is usually about 5 microns. Laser processing technology is short in time (as a rule, does not exceed 3-5 minutes) and does not require repeated visits to the doctor. The disadvantages of continuous laser exposure are unwanted side effects - overheating of the pulp, partial loosening of tissues, the appearance of microcracks of enamel, which increase with increasing laser power, as well as the need for additional selection and introduction of a chromophore, which determines the depth of penetration of the laser beam. The result of exposure to high temperatures during pulsed laser irradiation is carbonization of the tissue (carbon formation) and, as a result, darkening of the enamel. Exposure to high pressure Nd: YAG laser light and shock waves cause additional mechanical stresses in the tooth structure, leading to the formation of microcracks and possible tooth decay.

There is also known a method based on the artificial cultivation of a protective layer on the surface of tooth enamel, the so-called "synthetic enamel" (Oliveira M., Mansur N. // Mat. Res. 2007, 10, 115-118; Yamagishi K, Onuma K, et al. // Nature. 2005, 433, 819-819). For successful implantation into the tooth surface, it is necessary that the material of “synthetic enamel” possess a characteristic structure of tooth enamel and, as a result, properties that are as close as possible to natural tooth enamel (mechanical strength, resistance to chemical agents in the oral cavity). As a rule, the syntheses include the stage of crystallization of calcium fluorohydroxyapatite from paste, the composition of which includes calcium, phosphate, and fluoridions. The method is notable for its high cost, laboriousness and duration, both in terms of preparing the initial composition, and in the subsequent growth of fluorohydroxyapatite crystals directly on tooth enamel.

The closest in technical essence to the claimed invention is a method (US No. 6951463), based on the use of a composition containing photocatalytic titanium dioxide powder with a particle size of from 0.001 to 0.5 μm or a product of hydrolytic decomposition of titanium-containing precursors (titanium tetraethoxide, titanium tetrabutoxide, tetra titanium n-propoxide, titanium tetramethoxide) and a silicon-containing binder (tetraethoxysilane) in an aqueous-ethanol medium at various ratios of components. The prepared paste composition is dissolved in ethanol, then glycerol and polyoxyethylene glycol with molecular weights of 400 and 4000 are successively added. The resulting paste is applied to the affected area of the tooth and exposed to visible light, after which the excess paste is completely removed by washing with water and dried. The use of this composition provides an antibacterial effect that prevents the onset and development of caries.

The disadvantage of this method is the multi-stage preparation of the working composition, the need to use silicon-containing binders. In addition, the proposed photocatalytic titanium dioxide is not sensitive to light in the visible spectrum.

The aim of the proposed method is to increase the strength of tooth enamel due to the formation of a coating of titanium dioxide, adhesive active with respect to the main component of enamel - calcium hydroxyapatite.

This goal is achieved by photostimulated hydrolysis of 0.5-2.5% by weight solutions of titanium tetra-n-butoxide in an alcohol medium.

The essence of the invention lies in the fact that photostimulated hydrolysis of titanium tetra-n-butoxide leads to the formation of titanium oxide (IV). The hydrolysis is accompanied by the photo-crosslinking of titanium (IV) oxide with hydroxyapatite of tooth enamel with the formation of strong bonds -Ca-O-Ti≡, which ensures the adhesive strength of the coating and prevents its peeling. A prerequisite for the formation of titanium oxide (IV) and its crosslinking with the enamel surface is the use of UV light with a wavelength in the range from 240 to 300 nm (Roslov I.I., Gorbunova V.V., Boytsova TB, Photochemical silver deposition method on the surface of quartz modified with polybutoxy titanium // Journal of General Chemistry. 2009. V.79. Issue 4. P.547-552; Roslov II, Gorbunova VV, Boytsova TB Photochemical method of deposition of copper particles on the surface of quartz modified with polybutoxy titanium // Journal of General Chemistry. 2009. V.79. Issue 12. S.1958-1964; Boitsova T., Roslov I., Bartak D. Precipitat ion of gold nanoparticles on the quartz surface modified by titanium (IV) butoxide // Journal of Nanoparticle Research. 2010. V.12. N 4. P.1479-1488).

The advantage of the proposed method is to increase the microhardness of tooth enamel. Additional advantages of the method are:

- the safety of performing the procedure for forming a protective coating of titanium (IV) oxide by choosing the optimal UV exposure parameters for the initial titanium (IV) compound (intensity and energy of exciting light, geometry of the light flux). The choice of optimal parameters eliminates the heat load acting on the surface and internal tissues of the tooth, and ensures uniform coating formation. The coating thickness according to scanning microscopy is 70-100 nm. The coating has a slightly pronounced relief - the range of profile changes according to atomic force microscopy does not exceed 50 nm; resistant to the action of "food" acids (pH = 1.5); resistant to abrasion; increases the microhardness of tooth enamel by 5-30% compared to the original sample (Vickers evaluation);

- whitening and glossing of tooth enamel (reflection coefficient up to 0.95-1.00 in the range of 400-590 nm);

- antibacterial action created by its own antimicrobial ability of titanium dioxide;

- simplicity of operations. Preparation of the working composition does not require preparatory stages of synthesis, is based on the use of commercial chemicals and can be implemented directly in dental offices in the presence of the patient.

To obtain a uniform, continuous coating with good adhesion to tooth enamel hydroxylapatite, the concentration of titanium tetra-n-butoxide should be at least 0.5% by weight. When the content of titanium tetra-n-butoxide is more than 2.5% by weight, it is not possible to obtain films that are optically transparent in the visible range of the spectrum due to their significant thickness and cracking ability.

The following are examples of specific implementations of the method.

Example 1

Preliminary preparation of the tooth consists in its treatment with a 3% (hereinafter by weight) hydrogen peroxide solution, washing with water and drying with a stream of air. A composition containing a 0.5% solution of titanium tetra-n-butoxide in propanol-1 is applied to the prepared tooth surface section, repeated drying is carried out, and the tooth surface is exposed to UV light with a wavelength of 254 nm with a power of 4 W for 3 minutes. Exposure is carried out with a uniform distribution of light flux over the surface of the tooth.

The results of x-ray microanalysis of the samples, wt.%, Found: Ti - 36.78; O - 37.17; C - 26.05; calculated TiO ₂ - 61%.

The results of atomic force microscopy: the range of changes in the coating profile in the area 1000 × 1000 nm ² - 50-100 nm.

A comparative assessment of the microhardness of the treated and untreated tooth sections was performed according to the Vickers method with a pyramid load of 200 g for 15 s. After that, the teeth were cleaned with an electric toothbrush for 10 minutes and re-tested for microhardness. To obtain reliable data, ten measurements were performed on each sample (Table).

Example 2

A composition containing a 1% solution of titanium tetra-n-butoxide in propanol-2 is applied onto the previously prepared tooth surface in analogy to Example 1, re-drying is carried out, and the tooth surface is exposed to UV light with a wavelength of 254 nm with a power of 4 W for 2 min.

The results of x-ray microanalysis of the samples, wt.%, Found: Ti - 57.14; O - 38.14; C 4.72; calculated TiO ₂ - 95%.

The results of atomic force microscopy: the range of changes in the coating profile in the area of 1000 × 1000 nm ² - 30-50 nm.

Reflection coefficient: 0.95-1.00 in the range of 400-590 nm

Assessment of the microhardness of the tooth is similar to example 1.

Example 3

All operations are similar to example 2, but as a solution, a composition containing a 2% solution of titanium tetra-n-butoxide in propanol-2 is applied.

The results of x-ray microanalysis of the samples, wt.%, Found: Ti - 50.26; O - 37.96; C - 11.78; calculated: TiO ₂ - 83%.

The results of atomic force microscopy: the range of changes in the coating profile in the area of 1000 × 1000 nm ² - 20-100 nm.

Example 4

All operations are similar to example 2, but as a solution, a composition containing a 2.5% solution of titanium tetra-n-butoxide in propanol-2 is applied.

The results of x-ray microanalysis of the samples, wt.%, Found: Ti - 38.05; O - 25.47; C 36.48; calculated: TiO ₂ - 63%.

The results of atomic force microscopy: the range of changes in the coating profile in the area 1000 × 1000 nm ² - 50-100 nm.

Example 5

A composition containing a 2% solution of titanium tetra-n-butoxide in absolute ethanol is applied to the previously prepared tooth surface in analogy to Example 1, repeated drying is performed, and the tooth surface is exposed to UV light with a wavelength of 254 nm with a power of 4 W for 2 min.

The results of x-ray microanalysis of the samples, wt.%, Found: Ti - 48.75; O - 37.45; C - 13.80; calculated TiO ₂ - 81%.

The results of atomic force microscopy: the range of changes in the coating profile in the area of 1000 × 1000 nm ² - 50-100 nm.

Assessment of the microhardness of the tooth is similar to example 1.

The results of the evaluation of the microhardness of tooth sections Example No. Without cover Coated The degree of change,% After cleaning The degree of change,% one 430.7 435.7 +1.2 452.7 +5.1 2 342.0 440.2 +23.0 420,2 +28.0 3 397.5 439.1 +10.5 486.5 +22.4 four 391.7 423.3 +8.1 441.3 + 12.7 5 435.0 477.7 +9.8 492.3 +13.2

Claims (1)

A method of increasing the microhardness of tooth enamel, including preparing a working composition based on titanium tetra-n-butoxide, applying the working composition to a previously prepared tooth surface, followed by drying with an air stream, exposing the coating with UV light, characterized in that the tooth surface is pretreated by treating the teeth A 3% by weight solution of hydrogen peroxide, washed with water and dried with a stream of air, use a 0.5-2.5% by weight solution as the working composition Etra-n-butoxide titanium monohydric alcohols photostimulated hydrolysis is performed in the exposure of UV light having a wavelength of 240 to 300 nm power of 4 watts for 1-3 minutes, and the exposure is carried out with a uniform light distribution on the surface of teeth.