JP2010155785A - Bleaching agent and method for bleaching tooth - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bleaching agent which has a further improved bleaching action without affecting a target object such as a tooth as much as possible. <P>SOLUTION: This bleaching agent contains a strong base as a bleaching-promoting ingredient. The bleaching agent contains a calcium salt, and potassium phosphate or sodium phosphate. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a bleaching agent for an object such as a tooth and a method for bleaching a tooth.

As this kind of bleaching agent, a bleaching agent containing titanium dioxide and hydrogen peroxide (peroxide as a bleaching accelerator) is known (see Patent Document 1). In this bleaching agent, the photocatalytic action of titanium dioxide can be promoted by free radicals generated by contact between hydrogen peroxide and air. The tooth coloring is removed by the bleaching action of hydrogen peroxide and the photocatalytic action of titanium dioxide.
Japanese Patent Laid-Open No. 11-92351

In recent years, from the viewpoint of cosmetics and the like, a treatment (so-called whitening) for removing pigments on teeth and skin has been attracting attention, and further improvement of the bleaching action of the bleaching agent has been demanded.
However, in the above-mentioned known technology, a peroxide having a tissue corrosive property is used, and therefore, considering the adverse effect on the object such as teeth, there is a certain limit to increasing the peroxide content (improving the bleaching action of the bleaching agent). (See paragraph [0008] in the specification of Patent Document 1).
Thus, the present invention has been devised in view of the above points, and the problem to be solved by the present invention is to further improve the bleaching action without adversely affecting the object such as teeth. There is.

As a result of intensive studies to solve the above-mentioned problems, the inventors have found that the use of a relatively small amount of strong base improves the bleaching action of the bleaching agent without adversely affecting the object such as teeth. As a result, the present invention has been completed.
That is, as a means for solving the above-mentioned problems, the bleaching agent of the first invention of the present invention contains a strong base (strong base as a bleaching accelerator) such as potassium hydroxide or sodium hydroxide. In the present invention, the bleaching action of the bleaching agent can be improved with a relatively small amount of a strong base (a strong base that does not exhibit tissue corrosivity or is extremely weak) without adversely affecting an object such as a tooth. .

  In the bleaching method of the second invention, the bleaching agent according to the first invention containing a photocatalyst is applied to an object such as a tooth, and then the object is bleached by irradiation with ultrasonic waves. According to the bleaching method of the present invention, a suitable bleaching action can be exhibited under either alkaline conditions or acidic conditions.

  The bleaching agent of the third invention is the bleaching agent of the first invention, and contains a calcium salt, potassium phosphate, and sodium phosphate. The bleaching agent of the present invention can promote the formation of calcium phosphate (for example, hydroxyapatite) without adversely affecting the above-mentioned bleaching action.

  A tooth bleaching method according to a fourth aspect of the present invention is the bleaching method according to the second aspect of the present invention, wherein after applying any one of potassium phosphate, sodium phosphate, and calcium salt to the tooth, the other is different from the above one. A step of imparting to the teeth. According to the bleaching method of the present invention, a suitable bleaching action can be achieved, and tooth remineralization (reconstruction of tooth enamel) can be promoted.

  According to the first aspect of the present invention, it is possible to further improve the bleaching action without adversely affecting an object such as a tooth as much as possible. Moreover, according to the 2nd invention, more effective bleaching effect can be produced. According to the third invention, a bleaching agent suitable for tooth bleaching can be provided. According to the fourth aspect of the invention, the tooth can be recalcified and bleached.

Hereinafter, the best mode for carrying out the present invention will be described.
The bleaching agent of this example is exclusively for bleaching objects such as teeth. And this kind of bleaching agent is requested | required of the further improvement of a bleaching effect | action, without giving a bad influence to an object as much as possible.
Therefore, in this example, by using various components described later (a bleaching acceleration component (essential component) different from a peroxide, a photocatalyst, a simulated body fluid component), the bleaching action can be achieved without adversely affecting the object as much as possible. It was decided to improve.

[Object]
The object of the present embodiment can be exemplified by easily colored portions (for example, teeth, skin, nails, body hair, and shells) of living organisms (living organisms such as humans, plants, animals, birds, fishes, and crustaceans). Examples of the object include wood (paper chopsticks, paper such as pulp, fiber), foods (such as casserole and cocoons), structures (particularly walls and floors), and jewelry such as pearls.
Among these, a tooth (unmyelinated tooth, myelinated tooth) is a site that is easily colored due to an extrinsic or intrinsic cause. Examples of exogenous coloring causes include deposition of colored substances (cigarettes, tea astringents, etc.), pigment-producing bacteria, discoloration of restorations (mainly composite resins), and coloring with metal salts (mainly amalgam, silver nitrate, silver ammonia). . Examples of intrinsic coloring causes include aging, chemical substances and drugs (fluorine, tetracycline, etc.), metabolic abnormalities, genetic diseases, and tooth injury.
Skin is also a site that is easily colored due to exogenous or intrinsic causes. Examples of exogenous coloring causes include deposition of colored substances and coloring by pigment-producing bacteria. Examples of intrinsic coloring causes include endogenous deposition such as aging (deposition of pigment components such as melamine pigment), chemical substances and drugs, metabolic abnormalities, genetic diseases, and skin damage.
And the bleaching agent of a present Example can bleach the target object colored by various causes comparatively safely by the various components demonstrated below.

[Various components of bleaching agent]
(Bleaching acceleration component)
The bleaching accelerating component (essential component) of this example is a strong base. For example, a base having an acid pKa of 15 or more is preferred. Examples of the strong base include organic strong bases (alkyl metal, metal alkoxide, acetylide, organic metal amide, etc.) and inorganic strong bases (metal hydride, metal hydroxide, inorganic metal amide, etc.). . These strong bases may be used alone or in combination.
Among them, metal hydroxides such as potassium hydroxide (KOH), sodium hydroxide (NaOH), calcium hydroxide (Ca (OH) ₂ ) and barium hydroxide (Ba (OH) ₂ ) are relatively easily available. Therefore, it can be suitably used as a bleaching acceleration component in this example. Furthermore, since potassium hydroxide and sodium hydroxide have an excellent bleaching action, they can be particularly preferably used as a bleaching acceleration component in this example.
In the bleaching agent of this example, the bleaching action can be improved without adversely affecting the above-mentioned object by using a strong base having a lower structure corrosivity than the peroxide.

The content of the strong base is not particularly limited as long as the bleaching acceleration effect is exerted without adversely affecting the object. For example, the content of the strong base is preferably 0.01% or more by weight with respect to the total weight of the bleaching agent (the total amount of the aqueous solvent and various components). If the content of the strong base is less than 0.01%, there is a possibility that the desired bleaching acceleration effect may not be achieved.
Further, the strong base can be added until the aqueous solvent is saturated (potassium hydroxide is up to 52.8%). When the living body is a target, the upper limit value of the strong base is desirably 1.0% or less by weight ratio with respect to the total weight of the bleaching agent, and more preferably less than 1.0%. Furthermore, by setting the content of the strong base to 0.2% to 0.5% (relatively small amount), a suitable bleaching action can be exerted without adversely affecting the living body as much as possible.

(photocatalyst)
A photocatalyst is a particle that radicalizes oxygen in the atmosphere using light or the like (has a photocatalytic effect). The particle size of the photocatalyst is preferably 1 nm to 200 nm.
Examples of the photocatalyst include metal oxide semiconductors (including transition metal oxides), sulfide semiconductors, metal-supported semiconductors in which a metal such as platinum is supported on the semiconductors, and metal complex particles.
Among these, particles of titanium dioxide (TiO ₂ , an example of a metal oxide semiconductor) have excellent photocatalytic activity and are easily available, and thus are preferably used as the photocatalyst of this example. Titanium dioxide may be any of anatase type, rutile type, and flukeite type.

  The content of the photocatalyst is not particularly limited as long as it exhibits a photocatalytic action, but it is preferably 0.001% to 0.1% by weight with respect to the total weight of the bleach. If the content of the photocatalyst is less than 0.001%, the desired photocatalytic action may not be achieved. On the other hand, when the content of the photocatalyst is more than 0.1%, the cost is increased and the photocatalytic action may be slightly lowered due to deterioration of light transmittance.

(Pseudo body fluid component)
The simulated body fluid component is a body fluid-like component capable of forming so-called apatite. Here, the apatite is a substance represented by the chemical formula Ca ₁₀ (PO ₄ ) ₆ X ₂ , and fluorapatite (fluorapatite) or chlorapatite where X is F, Cl, OH, or CO ₃ , respectively. Examples thereof include hydroxyapatite (hydroxyapatite) and carbonate apatite.

In particular, when the object is a tooth, it is preferably a simulated body fluid component capable of forming calcium phosphate such as hydroxyapatite. For example, a simulated body fluid component having a calcium salt and sodium phosphate and potassium phosphate (buffer component) can be exemplified. According to this simulated body fluid component, formation of calcium phosphate can be promoted efficiently.
Here, the calcium salt is preferably a calcium salt that can be dissolved in an aqueous solvent, and examples thereof include calcium chloride, calcium sulfate, calcium lactate, and calcium acetate.

And the content of calcium salt, sodium phosphate and potassium phosphate (phosphate) is not particularly limited as long as it can form calcium phosphate.
Preferably, the calcium salt is 0.125% to 0.75% by weight with respect to the total weight of the bleach. If the calcium salt content is less than 0.125%, the desired calcium phosphate forming action may be reduced. Further, the content of calcium salt may be more than 0.75%, but the cost is increased because an extreme increase in calcium phosphate forming action is not observed.

Further, sodium phosphate is 0.03% to 0.345% by weight with respect to the total weight of the bleaching agent. When the content of sodium phosphate is less than 0.03%, there is a possibility that the formation action of desired calcium phosphate may be reduced. Further, the content of sodium phosphate may be more than 0.345%, but the cost is increased because an extreme increase in calcium phosphate forming action is not observed.
And potassium phosphate is 0.005%-0.06% by weight ratio with respect to the bleaching agent total weight. When the content of potassium phosphate is less than 0.005%, there is a possibility that the formation action of desired calcium phosphate is lowered. Further, the content of potassium phosphate may be more than 0.06%, but the cost is increased because an extreme increase in calcium phosphate forming action is not observed.

(Content ratio of calcium salt and phosphate)
It is desirable that the content ratio of the calcium salt and phosphate (sodium phosphate and potassium phosphate) can form, for example, hydroxyapatite efficiently.
Here, as described above, hydroxyapatite is represented by the stoichiometric composition (Ca / P molar ratio is 1.67) represented by the chemical formula: Ca ₁₀ (PO ₄ ) ₆ (OH) ₂ . Hydroxyapatite is known to exhibit the properties of hydroxyapatite and have an apatite structure even in a non-stoichiometric case where the Ca / P molar ratio is not 1.67.
For this reason, it is preferable that the content ratio of the calcium salt and the phosphate is appropriately adjusted so that the Ca / P molar ratio is in the vicinity of 1.67 (range of 1.4 to 1.9).

(Other ingredients)
In addition to the above components, various components can be added to the bleaching agent of this example. For example, when the bleaching agent is used as acidic as will be described later, citric acid or trisodium citrate (buffer) can be appropriately added to the bleaching agent to adjust its pH to 5 or less. In addition, sodium chloride (sodium salt) or potassium chloride (potassium salt) is added to the bleaching agent to bring it close to (or the same as) the salinity concentration of the body fluid, so that the bleaching agent is easily adapted to the living body.

[Bleaching method]
In this embodiment, there is a first step of applying a simulated body fluid component to a tooth and a second step of applying a bleaching agent to the tooth. And in a 2nd process, a target object is bleached by irradiating the light (ultraviolet ray) and an ultrasonic wave which are mentioned later. Hereinafter, each process is explained in full detail.

(First step)
In the first step, after applying potassium phosphate and sodium phosphate (phosphate) to a tooth, a calcium salt is applied to the tooth. That is, in this embodiment, after phosphate (minus ion) is applied to the tooth, calcium (plus ion) is mixed on the tooth to bind calcium and phosphorus on the tooth.
Thus, by preparing the pseudo body fluid component on the tooth (forming calcium phosphate on the tooth), remineralization of the tooth can be favorably promoted. Furthermore, the simulated body fluid component does not inhibit the bleaching action in the second step described later as much as possible.

And although processing time is not specifically limited, For example, even if it is 30 minutes-60 minutes (relatively short period) after providing a calcium salt to a tooth, the remineralization effect | action of a tooth can be show | played. In addition, by preliminarily keeping the phosphate and calcium salt at around body temperature (30 ° C. to 50 ° C.), formation of calcium phosphate can be preferably promoted in about 1 minute to 5 minutes.
In addition, formation confirmation of calcium phosphate can be discriminate | determined, for example with a predetermined measuring instrument or visual observation (whether the tooth became cloudy).

The simulated body fluid component is preferably in a neutral range (pH 6 to pH 8). Thus, the remineralization of a tooth can be favorably promoted by accelerating the formation of apatite under neutral range conditions close to a living body.
For example, by setting the content ratio of potassium phosphate (A) and sodium phosphate (B) to A: B = 1: 5 to 1:10 by weight ratio, the pseudo body fluid component on the tooth is made neutral. be able to.

(Second step)
And in a 2nd process, after giving a bleaching agent with respect to the tooth after a 1st process, the below-mentioned light or an ultrasonic wave is irradiated.
In addition, as a method of attaching a bleaching agent to an object such as a tooth, various methods such as application and spraying of a bleaching agent can be taken. Further, the bleaching agent may be attached to the object once or may be attached a plurality of times. When attaching the bleaching agent a plurality of times, it is usually sufficient to attach the bleaching agent to the object about every 1 to 20 minutes, and the interval and frequency are appropriately set according to the coloring state of the object. be able to.

(Light irradiation)
The light (ultraviolet light) of the present embodiment may be light having a wavelength that can cause the photocatalyst to act on the photocatalyst (wavelength capable of photoexciting titanium dioxide), and is light having a less adverse effect on the living body. It is desirable.
For example, when using titanium dioxide as a photocatalyst, typically, light having a wavelength of 300 to 500 nm is used (the wavelength for photoexciting rutile titanium dioxide is around 415 nm, and the wavelength for photoexciting anatase titanium dioxide is 380 nm or less. Is). In addition, when the light exceeding wavelength 500nm is irradiated for a long time, the temperature rise of a target object may become large.
The ultraviolet intensity of the light is appropriately changed depending on the coloring state of the object. Typically, it is desirable that the ultraviolet intensity is stronger than sunlight (light having an ultraviolet intensity of about 1 mW / cm ² ).

Examples of the light source include black light, exothermic lamp, fluorescent lamp, halogen lamp, metal halide lamp, xenon lamp, mercury lamp, UV lamp, LED (light emitting diode), and semiconductor laser.
Then, after the unnecessary wavelength is cut by the optical filter, the object to which the bleaching agent is applied is irradiated with the light from the light source. The time of light irradiation can be appropriately adjusted according to the wavelength of light and the colored state of the object.

(Ultrasonic irradiation)
Moreover, the ultrasonic wave of a present Example should just be an ultrasonic wave which has a frequency (frequency which can generate cavitation in a bleaching agent) which can produce a photocatalytic action to a photocatalyst, and is a frequency with few bad influences with respect to a biological body. It is desirable.
The above-described ultrasonic waves are preferably ultrasonic waves having a frequency of about 20 kHz to 50 kHz, and more preferably ultrasonic waves having a frequency of about 25 kHz to 35 kHz. Here, ultrasonic waves of less than 20 kHz may cause adverse effects such as damage to an object due to cavitation or generation of operation noise.
The frequency of the ultrasonic wave may exceed 50 kHz, but no extreme increase in photocatalytic action is observed. For this reason, it is desirable that the frequency of the ultrasonic wave be 50 kHz or less in consideration of adverse effects on the living body.
And the ultrasonic wave is irradiated to the target object which apply | coated the bleaching agent. The time and output (electric power) of ultrasonic irradiation can be appropriately adjusted according to the frequency of the ultrasonic wave and the coloring state of the object.

And when irradiating a tooth | gear (object) with an ultrasonic wave, even if a bleaching agent is either acidic (when it is less than pH 7) or alkaline (when it exceeds pH 7), there exists a suitable bleaching effect | action.
Here, tooth whitening is often performed under alkaline conditions in consideration of the fact that teeth are resistant to alkali. And the tooth | gear whitened under alkaline conditions will be in the bleaching state with a transparent feeling.
In addition, teeth that have been whitened under acidic conditions have some unevenness on the surface due to the acid, so that the apparent whiteness increases. Therefore, when white teeth are desired, whitening is preferably performed under acidic conditions. And in the bleaching method of a present Example, tooth whitening can be performed suitably also on acidic conditions by the synergistic effect of the said various components and an ultrasonic wave.

As described above, according to the bleaching agent of the present embodiment, the bleaching action can be further improved with a relatively small amount of strong base without adversely affecting an object such as a tooth.
Further, in this embodiment, the remineralization of the teeth can be promoted by the simulated body fluid component.
And in the bleaching method of a present Example, the variation of tooth whitening can be increased by the synergistic effect of various components and an ultrasonic wave.

[Test example]
Hereinafter, although this Embodiment is demonstrated based on a test example, this invention is not limited to a test example.
Example 1
The bleaching agent of Example 1 (pH 10 or more) was prepared by adding 0.25 g of potassium hydroxide (Kanto Chemical Co., Inc.) to 100 ml of purified water.
(Example 2)
The bleaching agent of Example 2 (pH 10 or more) was prepared by adding 0.25 g of potassium hydroxide and 0.03 g of titanium dioxide (Aerosil Co.) to 100 ml of purified water.
(Example 3)
For 100 ml of purified water, 0.25 g of potassium hydroxide, simulated body fluid component (0.5 g of calcium chloride, 1.15 g of disodium hydrogen phosphate, 0.05 g of potassium dihydrogen phosphate, both of which are Wako Co., Ltd. The bleach (pH 10 or more) of Example 3 was prepared.
Example 4
The bleaching agent (pH 10 or more) of Example 4 was prepared by adding 0.25 g of potassium hydroxide, 0.03 g of titanium dioxide, and the above-mentioned simulated body fluid component to 100 ml of purified water.

(Example 5)
To the bleaching agent of Example 1, 2 g of citric acid (Kanto Chemical Co., Inc.) and 3 g of trisodium citrate (Kanto Chemical Co., Ltd.) were added to prepare the bleaching agent of Example 5 (pH 5 or lower).
(Example 6)
The bleaching agent of Example 6 (pH 5 or less) was prepared by adding 2 g of citric acid and 3 g of trisodium citrate to the bleaching agent of Example 2.
(Example 7)
The bleaching agent of Example 7 (pH 5 or less) was prepared by adding 2 g of citric acid and 3 g of trisodium citrate to the bleaching agent of Example 3.
(Example 8)
The bleaching agent of Example 8 (pH 5 or less) was prepared by adding 2 g of citric acid and 3 g of trisodium citrate to the bleaching agent of Example 4.

(Comparative Example 1)
A bleaching agent of Comparative Example 1 was prepared by adding 10% of oxidol (Kenei Pharmaceutical) to 100 ml of purified water.
(Comparative Example 2)
The bleaching agent of Comparative Example 2 was prepared by adding 0.03 g of titanium dioxide to the bleaching agent of Comparative Example 1.

(Test method)
1. Bleaching test with test paper Glossy film (Epson) dyed with ethanol solution containing hematoporphyrin was used as test paper. Each of the bleaching agents of Examples 1 to 4 was applied to a test paper and allowed to stand for 5 minutes. This operation was repeated 4 times.
The color of the test paper after the test was measured, and the degree of bleaching with the bleaching agents of Examples 1 to 4 was evaluated. As a colorimeter, a spectral colorimeter for dentistry (GC Corporation, trade name: VITA Easyshade (registered trademark)) was used. And the measured value (L value: brightness) by the spectrophotometer for dentistry was classified into the ranks of 1 to 5, and the degree of bleaching of the test paper was evaluated (see [Table 1] below).
And the bleaching test of comparative examples 1 and 2 was done by the same procedure.

2. Bleaching test using eggshell Brown eggshell (production farm: Otomo Sangyo Co., Ltd., distributor: Chubu Feed Co., Ltd., trade name “Gamatamago”) was used as the test eggshell. Each of the bleaching agents of Examples 5 to 8 was applied to the test eggshell and allowed to stand for 5 minutes. This operation was repeated 4 times.
The test eggshell after the test was color-measured, and the degree of bleaching with the bleaching agents of Examples 5 to 8 was evaluated. As the colorimeter, the above-mentioned spectrophotometer for dentistry was used. And the measured value by the spectrophotometer for dentistry was classified into the rank of 1-5, and the bleaching degree of the test eggshell was evaluated (refer to the following [Table 2]).

3. Bleaching test by light A black light (Toshiba Corp., product number: EFD15BLB-T (100V, 15W)) was used as a light source. This black light was placed 3 cm away from the test paper.
And after apply | coating the bleaching agent of Example 2, 4 to a test paper, respectively, it was left to stand for 5 minutes, irradiating black light (wavelength: 352 nm). This operation was repeated 4 times. The test paper after the test was color-measured to evaluate the degree of bleaching.
The bleaching test of Comparative Example 2 was performed in the same procedure.
The bleaching tests of Examples 6 and 8 were performed in the same procedure using test eggshells.

4). Ultrasonic Bleaching Test An ultrasonic generator for dentistry (Satelec Acryon Group (France), trade name: Sprason P-MAX) was used as an ultrasonic wave generation source. An ultrasonic irradiation port (Slapson chip # 2) was attached to this dentistry ultrasonic generator, and this irradiation port was set 1 mm away from the test paper.
And after dripping the bleaching agent of Example 2 and 4 on a test paper, respectively, the ultrasonic wave (frequency: 27-31 kHz, electric power: 1W) was irradiated for 5 minutes, adding each bleaching agent suitably (an irradiation port is an opening). And soaked in bleach). This operation was repeated 4 times. The test paper after the test was color-measured to evaluate the degree of bleaching.
The bleaching test of Comparative Example 2 was performed in the same procedure.
The bleaching tests of Examples 6 and 8 were performed in the same procedure using test eggshells.

5). Bleaching test using ultrasonic waves and light The above-described black light was used as a light source. Moreover, the above-mentioned dentistry ultrasonic generator was used as an ultrasonic wave generation source.
And after apply | coating the bleaching agent of Example 2, 4 to a test paper, respectively, it was left to stand for 5 minutes, irradiating an ultrasonic wave and light. This operation was repeated 4 times. The test paper after the test was color-measured to evaluate the degree of bleaching.
The bleaching test of Comparative Example 2 was performed in the same procedure.
The bleaching tests of Examples 6 and 8 were performed in the same procedure using test eggshells.

6-a. Remineralization confirmation test (1)
As a test sample, a human extracted tooth (extracted tooth which has not been subjected to dental preservation or prosthetic treatment) was used (see comparative sample (S0), FIG. 1 (a) and FIG. 2 (a)). In addition, the dirt and deposits on the enamel surface of the extracted tooth were removed in advance.
The phosphate buffer was prepared by adding 4 g of dipotassium hydrogen phosphate and 23 g of disodium hydrogen phosphate to 2000 ml of purified water (pH 6-8). The calcium chloride solution was prepared by adding 10 g of calcium chloride to 100 ml of purified water. Each of these solutions was stirred (always) at 37 ° C to 39 ° C. Each reagent used was one manufactured by Wako.

Then, the extracted tooth of the test sample was put into 1750 ml of purified water, 200 ml of phosphate buffer was added, and then 50 ml of calcium chloride solution was added. Then, the extracted tooth of the test sample was allowed to stand for 1 minute, and then washed with distilled water was used as the extracted tooth (S1) of Sample 1 (see FIGS. 1B and 2B).
The extracted tooth of the test sample was allowed to stand for 5 minutes and then washed with distilled water to obtain the extracted tooth (S2) of Sample 2 (see FIGS. 1 (c) and 2 (c)).
The extracted tooth of the test sample was allowed to stand for 10 minutes and then washed with distilled water to obtain the extracted tooth (S3) of Sample 2 (see FIGS. 1 (d) and 2 (d)).
The extracted tooth of the test sample was allowed to stand for 30 minutes and then washed with distilled water to obtain the extracted tooth (S4) of Sample 2 (see FIGS. 1 (e) and 2 (e)).
The extracted tooth of the test sample was allowed to stand for 60 minutes and then washed with distilled water to obtain the extracted tooth (S5) of Sample 2 (see FIGS. 1 (f) and 2 (f)).
And the surface (after drying) of each sample was image | photographed by the magnification of 400 times and 1000 times, and the presence or absence of remineralization was confirmed (refer FIG.1 and FIG.2). A desktop scanning electron microscope (JEOL Ltd., trade name: NeoScope JCM-5000) was used for photographing.

6-b. Remineralization confirmation test (2)
In this test, 1 g of purified water was charged with 5 g of potassium hydroxide and 0.6 g of titanium dioxide. The extracted tooth of the test sample was put into this purified water, 200 ml of phosphate buffer was added, and then 50 ml of calcium chloride solution was added.
Then, the extracted tooth of the test sample was allowed to stand for 10 minutes, and then washed with distilled water was used as the extracted tooth (S6) of Sample 6 (see FIG. 3). Other test methods and imaging methods were the same as the remineralization confirmation test (1) described above.

(Test results and discussion)
The test results are shown in the following [Table 3] to [Table 5].

(Strong base)
The bleaching agents of Examples 1 to 4 were improved in the degree of bleaching compared to the bleaching agents of Comparative Examples 1 and 2 (see [Table 3] and [Table 4]). The bleaching agents of Examples 5 to 8 exhibited bleaching action comparable to that of the comparative example even under acidic conditions (see [Table 5]).
From this, it was found that the bleaching agents of Examples 1 to 8 exhibited an excellent bleaching action (or maintained a bleaching action) with a relatively small amount of potassium hydroxide (strong base).

(photocatalyst)
Moreover, the bleaching degree of Example 2 and Example 4 further improved the bleaching degree by irradiation with at least one of light (ultraviolet rays) and ultrasonic waves (see [Table 4]).
From this, it was found that the bleaching agents of Example 2 and Example 4 exhibited a more excellent bleaching action due to the synergistic effect of potassium hydroxide (strong base), titanium dioxide (photocatalyst) and light or ultrasonic waves.

(Ultrasonic)
The bleaching agents of Examples 5 and 8 maintained a suitable bleaching action even under acidic conditions by irradiation with ultrasonic waves (see [Table 5]).
From this, it was found that the bleaching agents of Examples 5 and 8 exhibited excellent bleaching action even under acidic conditions due to the synergistic effect of various components such as titanium dioxide (photocatalyst) and ultrasonic waves.

(Remineralization)
With reference to FIG.1 and FIG.2, it has confirmed that remineralization had arisen all in the extraction tooth | gear (S1) of the sample 1-the extraction tooth | gear (S5) of the sample 5 ((b)-of each figure). (See (f)). From this, it was found that according to the method of this example, the formation of calcium phosphate was promoted to exert an excellent remineralization action. In particular, since remineralization occurred in the extracted tooth (S1) of Sample 1, it was found that calcium phosphate (for example, hydroxyapatite) was formed even in a relatively short time (about 1 minute) in this method. It was also found that sufficient remineralization occurred in the extracted tooth (S4) of sample 4 and the extracted tooth (S5) of sample 5. From this, according to this method, it turned out that sufficient remineralization of a tooth | gear can be achieved by the process for 30 minutes-60 minutes.
Furthermore, the bleaching agents of Example 3 and Example 4 exhibited an excellent bleaching action even in the presence of a simulated body fluid component. This indicates that the simulated body fluid component does not adversely affect the tooth bleaching action.
When these results were put together, it was found that the bleaching agent or bleaching method of this example promotes remineralization of teeth (reconstruction of tooth enamel) and exhibits a suitable bleaching action.

And with reference to FIG. 3, it has confirmed that remineralization had arisen also in the extraction tooth | gear (S6) of the sample 6. FIG. From this, it was found that the bleach-accelerating component (potassium hydroxide) and the photocatalyst (titanium dioxide) do not adversely affect the calcium phosphate forming action and the tooth remineralization action.
As a result, according to the bleaching agent or the bleaching method of this example, it was confirmed more reliably that the tooth remineralization (reconstruction of tooth enamel) was promoted and a suitable bleaching action was achieved.

The bleaching agent and the bleaching method according to the present embodiment are not limited to the above-described embodiments, and can take other various embodiments.
(1) The bleaching agent of the present embodiment can be used alone, or can be used by being mixed with a favorite product such as a dentifrice, a mouthwash, or a chewing gum.
(2) In this example, an example of promoting the formation of calcium phosphate (an example using a simulated body fluid component) has been described. In the bleaching agent of the present embodiment, a component that promotes the formation of fluorapatite, chlorapatite or carbonate apatite can be blended. By carrying out like this, the bleaching agent of a present Example can be used suitably with respect to the structure which has various apatites.
(3) In the first step of the present embodiment, an example in which potassium phosphate and sodium phosphate (phosphate) are applied to a tooth and then a calcium salt is applied to the tooth has been described.
Unlike this, potassium phosphate, sodium phosphate and calcium salt (simulated body fluid component) can be simultaneously applied to the teeth. Moreover, a simulated body fluid component and a bleaching acceleration component (or photocatalyst) can be simultaneously applied to the teeth.
(4) Moreover, in the present Example, the 2nd process was performed after the 1st process. Unlike this, the second step may be performed before the first step.
(5) Moreover, in the present Example, after giving potassium phosphate and sodium phosphate (phosphate) to a tooth, the example which provides a calcium salt to a tooth was demonstrated. Unlike this, after giving calcium salt to a tooth, you may give potassium phosphate and sodium phosphate (phosphate) to a tooth.
(6) In the bleaching method of this example, potassium phosphate and sodium phosphate were exemplified as examples of the phosphate. In the bleaching method of this example, various phosphates can be used.

It is a 400 times enlarged view of the tooth surface for demonstrating remineralization. It is a 1000 times enlarged view of the tooth surface for demonstrating remineralization. (A) is a 400 times enlarged view of a tooth surface for explaining remineralization in another test, and (b) is a 1000 times enlarged tooth surface for explaining remineralization in another test. FIG.

Claims (4)

  A bleaching agent containing a strong base as a bleach accelerating component. While the bleach of Claim 1 contains a photocatalyst,
A method of bleaching an object, wherein the object is bleached by irradiating ultrasonic waves after applying the bleaching agent to an object such as a tooth.   The bleaching agent of Claim 1 containing a calcium salt, potassium phosphate, and sodium phosphate. The bleaching method according to claim 2, further comprising the step of applying one of potassium phosphate and sodium phosphate and a calcium salt to the tooth, and then applying the other to the tooth.