JP5241249B2 - Caries treatment kit - Google Patents

Description

  The present invention relates to kits and compositions for treating stage C1 or stage C2 caries and root caries. The present invention also relates to kits and compositions for enamel care. The invention also relates to kits and compositions for enamelling exposed root surfaces of teeth. The invention also relates to kits and compositions for the treatment of hypersensitivity due to exposure of dentinal tubules. The present invention also relates to a dentifrice for caries treatment.

  Caries are parenchymal defects caused by decalcification of the tooth by organic acids produced by oral bacteria present on the tooth surface, and are generally known as caries. In recent years, it has been found that a phenomenon called initial caries or subsurface demineralization occurs before caries occurs. The initial caries means a state in which no substantial loss of the tooth has occurred and the surface of the tooth surface is retained, but calcium is lost from under the surface of the tooth surface. FIG. 1 shows a cross-sectional photograph of bovine teeth that have undergone initial caries, that is, subsurface demineralization. In this photo, there is a white layer with a high degree of calcification in the outermost layer of the enamel, and a black layer under it. This black layer is a demineralized part. When initial caries occurs, the loss of calcium causes the crystal structure to change and the tooth surface to appear white. Since caries is a real defect, it cannot be repaired naturally, and the defect cannot be filled without treatment by a dentist. On the other hand, initial caries takes time, but can be naturally restored. This is usually due to the occurrence of dental demineralization and remineralization in the oral cavity.

  Various treatments have been tried for the initial caries. For example, fluorine is often used to treat teeth as it strengthens the tooth structure. However, when fluorine is applied at a high concentration, only the surface layer is strongly remineralized while the demineralized layer below the surface layer is not recalcified, so that the tooth surface remains as a white spot. In addition, since the surface layer is solid, phosphate ions, calcium, etc. do not reach the layer below it, so that the part cannot be subjected to remineralization that occurs naturally in the oral cavity. The demineralized part of the skin does not heal and cannot return to its natural color. FIG. 2 shows a case where high concentration fluorine was continuously applied to the initial caries for a long period of time. In FIG. 2, a state where only the surface layer is highly remineralized by fluorine application and the portion that has turned white inside remains in a band shape on the tooth surface near the gums. Therefore, the other method which can accelerate | stimulate remineralization from the deashing deep part is searched.

  Non-abrasive nanoparticulate hydroxyapatite-containing pastes that have been studied as enamel modifiers for early caries are enamel that has been damaged by initial demineralized lesions, after whitening, after debonding, or by routine PMTC. Expected to be effective in restoring quality. Non-Patent Document 1 discloses a dental-specific apa guard linen which is a non-abrasive compounded nanoparticle hydroxyapatite-containing paste (enamel-supplemented dentifrice). Patent Document 1 describes a chewing gum containing hydroxyapatite.

  However, it was necessary to consider the presence of organic inhibitors such as biofilms, pellicles and stains in order to maximize the effects in actual clinical practice. Therefore, the present inventors have devised a new tooth surface restoration care using an organic solubilizing agent in order to ensure that nano-sized HAP reaches the enamel wound and the fine structure of the demineralized part. The effectiveness has been examined. This is because D.C. D. S. Based on the concept of (Drug Delivery System). D. D. S. The basic elements of Target, 2. Size, 3. Adsorption, 4. Time (sustained release). The target here is the initial caries site. The enamel is made up of a number of enamel trabeculae, and the spacing between the trabeculae is about 50 nm. It is also known that a recess of about 200 m is formed on the surface of the enamel. Therefore, when considering the size of the material for filling minute enamel scratches, ionic fillers, crystalline fillers, particulate fillers, and the like are conceivable.

  As for caries, until now, it has been impossible to fill defects caused by caries without using artificial fillers such as resins. Caries are divided into C1 to C4 depending on the degree of progress. C1 stage caries is caries confined to enamel and is also called enamel caries. C2 stage caries are caries that have reached the dentin, and are also called dentin caries. C3 stage caries are caries that have reached the pulp, and C4 stage caries are caries that have a residual root due to the collapse of the crown. The treatment of caries in stage C1 and stage C2 that is the subject of the present invention has been conventionally performed by directly removing a caries portion using a rotary cutting tool or a laser and then directly filling a composite resin material or a ceramic material or a metal material. This is done by making the padding indirectly on the model using and then wearing it. Root caries are also dealt with in the same way, but depending on the site of occurrence, it is often difficult to treat with such fillings.

  In these conventional treatments, all are artificial materials, which are substances that do not exist in the living body. For example, a resin is a plastic material, and is easily soiled. It is difficult to maintain because it is deteriorated, worn out, or scraped. Use of metallic materials may cause allergies and is not aesthetically pleasing.

In normal healthy teeth, the pulp is in the dentin, and the enamel covers the dentin in the crown. Dentin and enamel differ in composition, structure, critical pH, hardness and the like. Enamel has a high content of hydroxyapatite [Ca ₁₀ (PO ₄ ) ₆ (OH) ₂ ] of about 96%, and the others are composed of organic matter, water, and the like. It is composed of hydroxyapatite, which is a crystal structure of calcium and phosphoric acid. Enamel is the hardest part of the tooth, and precious calcium and phosphate are dissolved from the inside of the enamel by the action of organic acids produced by bacteria in plaque and acids contained in food (decalcification). Is prevented.

  On the other hand, the hydroxyapatite content of dentin is as low as about 70%, and it contains a large amount of organic matter, so it is vulnerable to caries. Enamel withstands up to about pH 5.5, whereas dentin dissolves at about pH 6.2. A large number of holes called dentinal tubules are opened in the dentin, and the density thereof is about 2 to 50,000 per 1 mm square. The diameter of the dentinal tubule is usually about 1 to 3 μm. Since the diameter of the dentinal tubule is larger than the diameter of the bacterium, when the dentinal tubule is exposed, the bacteria can enter the dentinal tubule and propagate there. On the other hand, the size of white blood cells that normally act on bacterial defense in the body is much larger than the size of dentinal tubules. The diameter of neutrophils is about 13 μm, the diameter of eosinophils is about 15 μm, the diameter of basophils is about 13 μm, the diameter of monocytes is about 16 μm, and the diameter of lymphocytes is about 13 μm. It is. Therefore, white blood cells cannot enter the dentinal tubules and cannot fight bacteria. Therefore, when the dentinal tubule is exposed, bacteria enter and propagate easily, and the progress of caries is accelerated.

  Usually, the dentin at the crown is covered with enamel and the dentin at the root is covered with gingiva, so it is not exposed in the oral cavity and caries does not easily occur. However, if the caries progresses to the dentin or the gums retract due to periodontal treatment, aging, occlusion, excessive brushing, etc., the dentin on the root surface is exposed, that is, the dentinal tubules are exposed There is. As for hypersensitivity, the opening of dentinal tubules has been confirmed as a phenomenon. For the above reasons, it is considered preferable to prevent the dentin from being exposed and fill the opening of the dentinal tubule. However, no preventive method for such exposed root surface has been established, and it is a part where the systemic difference from enamel is strongly felt in clinical practice. When the opening of the dentinal tubule is filled with an adhesive resin, which is a conventional dental material, the resin is easily soiled and deteriorated, diminished, or scraped and difficult to maintain. Therefore, it is preferable to fill the opening by a method other than resin.

On the other hand, it is known that products containing phosphorylated oligosaccharides are effective in treating initial touch (for example, Patent Documents 2 and 3). However, phosphorylated oligosaccharides can be treated only in the initial palpation, and palpation after C1 in which a substantial defect of enamel has occurred cannot be treated with phosphorylated oligosaccharides.
Oral Care catalog “Hydroxyapatite for Nanoparticle Medicinal Products” JP 2005-34127 A JP 2002-325557 A JP 2006-62993 A

  The present invention is intended to solve the above-described problems, and an object thereof is to provide a kit and a composition for treating caries and root caries in stage C1 or C2. The present invention also aims to provide kits and compositions for enamel care. The present invention also aims to provide kits and compositions for enamelling exposed root surfaces of teeth. The present invention also aims to provide kits and compositions for the treatment of hypersensitivity. Another object of the present invention is to provide a dentifrice for caries treatment.

  As a result of intensive studies to solve the above-mentioned problems, the present inventors have filled dental hydroxyapatite particles in a tooth defect and then acted on phosphorylated saccharide calcium to cause caries in C1 and C2 stages. It was found that root caries can be treated and the present invention was completed based on this.

  More specifically, when POs-Ca was used in combination for the purpose of leading recrystallization from hydroxyapatite to remineralization, clinical effects were confirmed. Furthermore, the repair effect was recognized also by applying HAP and POs-Ca also to the case where the subsurface demineralization part progressed and the substantial defect | deletion was produced.

  This is thought to be based on the following theory. When hydroxyapatite particles are used for initial caries, hypersensitivity, tooth surface roughness, etc., a filling effect is obtained and the hydroxyapatite particles are recrystallized. When phosphorylated saccharide calcium is supplied to the filled portion, the phosphorylated saccharide calcium permeates between the hydroxyapatite particles and bonds these hydroxyapatite particles to each other. In addition, remineralization occurs and the tooth surface is restored.

  Dentin root caries is partly due to the presence of dentinal tubules. As for hypersensitivity, the opening of dentinal tubules has been confirmed as a phenomenon. Therefore, it is of great clinical significance to block the dentinal tubules on the surface of the exposed dentin and to modify it into an apatite-rich surface (namely, enamelization). When hydroxyapatite particles and POs-Ca were applied to dentin, the progression of root caries stopped and it was found to be effective in hypersensitive cases.

  On the other hand, in the preventive action, conventionally, a post-procedure of removing deposits on the tooth surface by performing Professional Mechanical Tooth Cleaning (PMTC) and scaling (calculus removal) has been mainly performed. It was. On the other hand, according to the present invention, it is possible to perform a pretreatment that makes it difficult to attach biofilm, plaque, tartar, and other deposits that cause caries and periodontal disease by modifying the condition of the tooth surface. become. That is, it is possible to change the concept from PMTC as simple tooth surface cleaning and tooth surface polishing to active care. This is because, by using the present invention, it is possible to regenerate and restore the tooth surface instead of cutting the tooth surface. That is, the concept can be changed from tooth surface polishing to tooth surface restoration.

In order to achieve the above object, the present invention provides, for example, the following means:
(Item 1)
A caries treatment kit comprising:
(1) a hydroxyapatite particle-containing composition and (2) a phosphorylated saccharide calcium-containing composition, wherein the caries are C1 or C2 caries and root caries, and the phosphorylated saccharide calcium is a sugar A kit comprising a moiety and a calcium salt of a phosphate group, wherein the sugar moiety is a glucan having a polymerization degree of 2 to 8, and the number of phosphate groups is 1 to 2.

(Item 2)
(I) filling the hydroxyapatite particle-containing composition into a defect portion due to dental caries and then applying the phosphorylated saccharide calcium-containing composition to the filling portion; or (ii) the defect portion due to dental caries 2. The kit according to item 1, wherein the mixture is filled with the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition.

(Item 3)
(3) The kit according to item 1, further comprising an organic solubilizer.

(Item 4)
The organic dissolution agent is applied to the defect part due to dental caries to remove the organic substance of the defect part to expose the surface of the tooth defect part, and then (i) the exposed defect part contains the hydroxyapatite particles The composition is filled, and then the phosphorylated saccharide calcium-containing composition is applied to the filled portion, or (ii) the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition in the exposed defect portion 2. The kit according to item 1, which is filled with a mixture with the product.

(Item 5)
A composition for treating caries comprising hydroxyapatite particles and phosphorylated saccharide calcium, wherein the caries are C1 stage or C2 stage caries and root caries, and the phosphorylated saccharide calcium comprises a saccharide moiety and a phosphate group. A composition in which the sugar moiety is a glucan having a degree of polymerization of 2 to 8, and the number of phosphate groups is 1 to 2.

(Item 6)
Item 6. The composition according to Item 5, wherein the composition is in powder form.

(Item 7)
A kit for enamel care when a tooth enamel is damaged, the kit comprising:
(1) a hydroxyapatite particle-containing composition and (2) a phosphorylated saccharide calcium-containing composition, wherein the phosphorylated saccharide calcium comprises a saccharide moiety and a calcium salt of a phosphate group, and the saccharide moiety is polymerized A glucan having a degree of 2 to 8, the number of the phosphate groups being 1 to 2,
(I) applying the hydroxyapatite particle-containing composition to the damaged portion and then applying the phosphorylated saccharide calcium-containing composition to the portion; or
(Ii) A kit in which a mixture of the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition is applied to the damaged part.

(Item 8)
8. Kit according to item 7, wherein the damage is caused by debonding, whitening, professional mechanical toe screening, polishing or orthodontic treatment.

(Item 9)
A composition for enamel care when dental enamel is damaged, the composition comprising hydroxyapatite particles and phosphorylated saccharide calcium, wherein the phosphorylated saccharide calcium comprises a saccharide moiety and a phosphate group. A composition in which the sugar moiety is a glucan having a degree of polymerization of 2 to 8, and the number of phosphate groups is 1 to 2.

(Item 10)
10. A composition according to item 9, wherein the damage is caused by debonding, whitening, professional mechanical toe screening, polishing or orthodontic treatment.

(Item 11)
A kit for enamelling the exposed root surface of a tooth, the kit comprising:
(1) a hydroxyapatite particle-containing composition and (2) a phosphorylated saccharide calcium-containing composition, wherein the phosphorylated saccharide calcium comprises a saccharide moiety and a calcium salt of a phosphate group, and the saccharide moiety is polymerized A glucan having a degree of 2 to 8, the number of the phosphate groups being 1 to 2,
(I) applying the hydroxyapatite particle-containing composition to an exposed root surface of a tooth and then applying the phosphorylated saccharide calcium-containing composition to the root surface, or
(Ii) A kit for applying a mixture of the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition to an exposed root surface of a tooth.

(Item 12)
A composition for enamelling the exposed root surface of a tooth, the composition comprising hydroxyapatite particles and phosphorylated sugar calcium, wherein the phosphorylated sugar calcium is a calcium salt of a sugar moiety and a phosphate group A composition in which the sugar moiety is a glucan having a degree of polymerization of 2 to 8, and the number of phosphate groups is 1 to 2.

(Item 13)
A kit for treating hypersensitivity, the kit comprising:
(1) a hydroxyapatite particle-containing composition and (2) a phosphorylated saccharide calcium-containing composition, wherein the phosphorylated saccharide calcium comprises a saccharide moiety and a calcium salt of a phosphate group, and the saccharide moiety is polymerized A glucan having a degree of 2 to 8, the number of the phosphate groups being 1 to 2,
(I) applying the hydroxyapatite particle-containing composition to a tooth-sensitive surface and then applying the phosphorylated saccharide calcium-containing composition to the surface; or
(Ii) A kit for applying a mixture of the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition to a hypersensitive surface of a tooth.

(Item 14)
A composition for treating hypersensitivity, the composition comprising hydroxyapatite particles and phosphorylated saccharide calcium, the phosphorylated saccharide calcium comprising a saccharide moiety and a phosphate salt calcium salt, wherein the saccharide moiety comprises A composition having a polymerization degree of 2 to 8 and having 1 to 2 phosphate groups.

(Item 15)
A dentifrice for caries treatment, the dentifrice comprising hydroxyapatite particles and calcium phosphate sugar, wherein the caries is C1 or C2 caries and root caries, and the phosphorylated sugar calcium is a sugar A dentifrice comprising a part and a calcium salt of a phosphate group, wherein the sugar part is a glucan having a degree of polymerization of 2 to 8, and the number of phosphate groups is 1 to 2.

  Remineralization was efficiently promoted by the filling effect of hydroxyapatite particles and the penetration effect of phosphorylated oligosaccharide calcium. Furthermore, securing the stagnation time on the tooth surface, which has been a problem in the past, has been greatly improved by using a phosphorylated oligosaccharide calcium solution. This is presumably because the phosphorylated oligosaccharide calcium solution has inherent viscosity, and therefore the pack effect can be obtained by using the phosphorylated oligosaccharide calcium solution. According to the present invention, it is possible to obtain a repair effect of a C1 phase substantial defect portion. According to the present invention, effects such as promotion of remineralization of early demineralized lesions; disappearance of cloudy parts; stain, biofilm adhesion inhibitory effect; dentinal tubule blockage; root caries inhibitory effect; Since hydroxyapatite particles and phosphorylated oligosaccharide calcium have high biological safety and are considered suitable for continuous use, a method using both office care and self-care is promising in actual clinical practice. The present invention can also be used as a reliable and fast-acting prophylactic method.

  Hereinafter, the present invention will be described in detail.

(1. Materials used in the present invention)
In the present invention, hydroxyapatite particles and calcium phosphate phosphor are used. Other materials can also be used if desired.

(1a. Hydroxyapatite particles)
Hydroxyapatite refers to a compound represented by Ca ₁₀ (PO ₄ ) ₆ (OH) ₂ . Hydroxyapatite has a crystal structure. The hydroxyapatite used in the present invention is particulate. The average particle diameter of the hydroxyapatite particles used in the present invention is preferably about 10 nm or more. The average particle size of the hydroxyapatite particles may also be about 15 nm or more, about 20 nm or more, about 25 nm or more, about 30 nm or more, about 35 nm or more, about 40 nm or more, about 45 nm or more, about 50 nm or more, and the like. The average particle diameter of the hydroxyapatite particles used in the present invention is preferably about 400 nm or less, more preferably about 100 nm or less, particularly preferably about 80 nm or less, and most preferably about 70 nm or less. In addition, when mentioning a hydroxyapatite particle | grain in this specification, an average particle diameter means a median diameter on a volume basis. The size of the hydroxyapatite particles can be measured by a light scattering type particle size distribution measuring device and a laser diffraction / scattering type particle size distribution measuring device (for example, a laser diffraction / scattering type particle size distribution measuring device LA-920 manufactured by Horiba, Ltd.). .

  In one embodiment, the size of the hydroxyapatite particles is preferably uniform with no variation.

  In one embodiment, the hydroxyapatite particles can be a mixture of hydroxyapatite particles of various sizes. For example, it may be a mixture of relatively large hydroxyapatite particles having a diameter of about 1 μm to 3 μm and relatively small hydroxyapatite having a diameter of about 20 nm to 30 nm. Since a composite resin, which is a typical conventional dental filler, has used a mixture of particles (fillers) of various sizes, such a mixture of hydroxyapatite of various sizes is a conventional filler. Suitable for use as well.

  Hydroxyapatite particles can be produced by methods known in the art and are commercially available. For example, Sangi Co., Ltd. manufactures a dentifrice (trade name: dental-specific linamel PMTC final finish paste) containing hydroxyapatite nanoparticles with an average particle size of 50 nm (50-100 nm and occupies about 90% of the powder volume) It is sold by Oral Care Co., Ltd. In the present specification, the dental final linamel PMTC final finishing paste is also simply referred to as linamel. Linamel is a white paste and contains no abrasive.

(1b. Phosphorylated sugar calcium)
The phosphorylated saccharide calcium used in the present invention comprises a saccharide moiety and a phosphate group calcium salt. As used herein, the term “phosphorylated sugar” refers to a sugar having at least one phosphate group in the molecule. As used herein, the term “phosphorylated saccharide calcium” refers to a calcium salt of phosphorylated saccharide. In the phosphorylated saccharide calcium used in the present invention, the sugar moiety is a glucan having a polymerization degree of 2 to 8, and the number of phosphate groups is 1 to 2. The number of calcium ions in the phosphorylated saccharide calcium is 1 to 2, and preferably the number of phosphate groups in the phosphorylated saccharide calcium is equal to the number of phosphate ions.

  The phosphorylated saccharide calcium used in the present invention may be used as a pure one type of compound or as a mixture of a plurality of types. The phosphorylated saccharide calcium used in the present invention is preferably a phosphorylated saccharide calcium described in JP-A-8-104696. When produced according to the method described in JP-A-8-104696, a mixture of a plurality of types of phosphorylated saccharide calcium is obtained. The mixture may be used as it is, or after separation into a pure compound, only one kind of compound may be selected and used. Phosphorylated saccharide calcium exhibits excellent performance both when used as a mixture and as a mixture.

  The phosphorylated saccharide calcium can be produced, for example, by phosphorylating a known saccharide to obtain a phosphorylated saccharide, and then converting the phosphorylated saccharide into a calcium salt. A method for producing phosphorylated saccharide is described in JP-A-8-104696. Phosphorylated sugar calcium powder is also sold as phosphorylated oligosaccharide calcium by Ezaki Glico Co., Ltd.

(1c. Other materials)
In the kit, composition and dentifrice of the present invention, any material usually used in the intended kit can be used as long as it does not interfere with the action of the hydroxyapatite particles and calcium phosphate sugar.

  An example of such a material is casein phosphopeptite-amorphous phosphate (CPP-ACP; MI paste). This can be mixed with hydroxyapatite particles as three-digit nanoparticles (average particle size 200 nm to 300 nm).

  Sodium hypochlorite can also be used as an organic solubilizer. An organic solubilizer containing 10% sodium hypochlorite is manufactured by Kuraray Medical Co., Ltd. as an AD gel and sold by Morita Co., Ltd.

Another example of such a material is inorganic phosphoric acid. Hydroxyapatite (which is represented by Ca ₁₀ (PO ₄ ) ₆ (OH) ₂ ), which is the main component of tooth enamel, has a Ca / PO ₄ ratio of about 1.67. in the composition forming, Ca / PO ₄ ratio is 1.0~1.67 _(PO 4 / Ca ratio = 0.6 to 1.0). Therefore, the Ca / PO ₄ ratio 1.0~1.67 _(PO 4 / Ca ratio = 0.6 to 1.0), so preferably closer to 1.67 _(PO 4 / Ca ratio = 0.6) Further, remineralization of enamel can be promoted by supplying phosphate ions and calcium ions. In the present invention, when only phosphorylated saccharide calcium is used, only calcium ions are supplied, and as they are, phosphate ions are insufficient for more efficient remineralization.

  Therefore, in the kit, composition and dentifrice of the present invention, it is preferable to use inorganic phosphoric acid as a phosphate ion source at the same time. In this specification, the source of phosphate ions is referred to as a phosphate source compound. A phosphoric acid source compound means a phosphoric acid compound.

  The phosphate source compound that can be used in the present invention can be any compound as long as it is a compound that releases phosphate ions when dissolved in water. The phosphate source compound is preferably a water-soluble phosphate or inorganic phosphoric acid. Examples of such phosphate source compounds include phosphoric acid, sodium phosphate, potassium phosphate, polyphosphoric acid and salts thereof, cyclic phosphoric acid and salts thereof, and the like. Examples of sodium phosphate include sodium metaphosphate, disodium hydrogen phosphate, sodium dihydrogen phosphate, trisodium phosphate, sodium pyrophosphate, sodium hydrogen pyrophosphate, and the like. Examples of potassium phosphate include potassium dihydrogen phosphate, dipotassium hydrogen phosphate, and tripotassium phosphate. Polyphosphoric acid is a compound formed by condensation of two or more phosphoric acids. The degree of polymerization in the polyphosphoric acid is arbitrary as long as it is 2 or more. For example, it is 2 or more and 10 or less. Examples of polyphosphoric acid include pyrophosphoric acid, triphosphoric acid, trimetaphosphoric acid, tetrametaphosphoric acid and the like. These polyphosphoric acid salts may also be used, preferably sodium or potassium salts. Examples of cyclic phosphoric acid include hexametaphosphoric acid. These cyclic phosphate salts can also be used, preferably sodium or potassium salts.

This phosphate source compound has a Ca / PO ₄ ratio of 1.0 to 1.67 (PO ₄ / Ca ratio = 0.6 to 1.0), preferably 1.67 (PO ₄ / Ca ratio = 0.0). It can be added alone or in combination in the kits, compositions and dentifrices of the present invention to approximate 6).

(3. Kit of the present invention)
In this specification, “kit” refers to a combination of two or more components. The kit of the present invention is used to treat caries, to care for enamel, to enamelize the exposed root surface of teeth, or to treat hypersensitivity. As used herein, “treatment” not only completely cures or partially improves an existing caries, but also prevents caries as well as completely cures or partially cures hypersensitivity. It also includes ameliorating and preventing hypersensitivity.

  In one embodiment, the kit of the present invention is a caries treatment kit.

  In one embodiment, the kit of the present invention is an enamel care kit.

  In one embodiment, the kit of the present invention is a kit for enamelling exposed root surfaces of teeth.

  In one embodiment, the kit of the invention is a kit for the treatment of hypersensitivity.

  The kit of the present invention comprises a hydroxyapatite particle-containing composition and a phosphorylated saccharide calcium-containing composition. In the kit of the present invention, the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition are separate compositions. The hydroxyapatite particle-containing composition can be in the form of powder, granules, paste, cream, gel or suspension. Since the hydroxyapatite particles tend to aggregate and form a large lump in the powder state, the hydroxyapatite particle-containing composition is preferably in the form of a paste.

  The content of the hydroxyapatite particles in the hydroxyapatite particle-containing composition can be arbitrarily set. For example, the content of hydroxyapatite particles in the composition containing hydroxyapatite particles is preferably about 1% by weight or more, more preferably about 2% by weight or more, and further preferably about 3% by weight or more. Particularly preferred is about 4% by weight or more, and most preferred is about 5% by weight or more. For example, the content of the hydroxyapatite particles in the hydroxyapatite particle-containing composition is, for example, about 90% by weight or less, about 80% by weight or less, about 70% by weight or less, about 60% by weight or less, about 50% by weight or less, It may be about 40% or less, about 30% or less, about 20% or less, about 10% or less, and the like.

  Examples of other materials that can be included in the hydroxyapatite particle-containing composition include a phosphate source compound, a solvent, a base material, a bactericide, a wetting agent, a sweetener, a solubilizer, a fragrance, and an antiseptic. . The solvent can be water. Examples of the substrate include silicic anhydride and crystalline cellulose. The composition containing hydroxyapatite particles can be produced by any method known in the art using these materials.

  When the hydroxyapatite particle-containing composition contains a phosphate source compound, the content of the phosphate source compound in the composition can be arbitrarily set. For example, the content of the phosphoric acid source compound in this composition is preferably about 1% by weight or more, more preferably about 5% by weight or more, further preferably about 10% by weight or more, particularly preferably. Is about 15% by weight or more, most preferably about 20% by weight or more. For example, the content of the phosphate source compound in this composition is preferably about 50% by weight or less, more preferably about 40% by weight or less, still more preferably about 35% by weight or less, and particularly preferably. Is less than about 30% by weight, and most preferably less than about 25% by weight.

  The phosphorylated saccharide calcium-containing composition can be in the form of powder, granules, paste, cream, gel, or solution. The phosphorylated saccharide calcium-containing composition is preferably in the form of a powder.

  The content of phosphorylated saccharide calcium in the phosphorylated saccharide calcium-containing composition can be arbitrarily set. For example, the content of phosphorylated saccharide calcium in the phosphorylated saccharide calcium-containing composition is preferably about 0.1% by weight or more, more preferably about 1% by weight or more, and further preferably about 3% by weight. More preferably, it is about 4% by weight or more, and most preferably about 5% by weight or more. For example, the content of phosphorylated saccharide calcium in the phosphorylated saccharide calcium-containing composition is, for example, about 90% by weight or less, about 80% by weight or less, about 70% by weight or less, about 60% by weight or less, about 50% by weight. The amount may be about 40% by weight or less, about 30% by weight or less, about 20% by weight or less, about 10% by weight or less.

  Other materials that can be included in the phosphorylated saccharide calcium-containing composition include phosphate source compounds. The phosphorylated saccharide calcium-containing composition can be produced by any method known in the art using these materials.

  In one embodiment of the kit of the present invention, the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition can be placed in separate containers and combined to be packaged as one kit.

  When the phosphorylated saccharide calcium-containing composition contains a phosphate source compound, the content of the phosphate source compound in the composition can be arbitrarily set. For example, the content of the phosphate source compound in the composition is preferably about 0.1% by weight or more, more preferably about 1% by weight or more, and further preferably about 10% by weight or more. Particularly preferred is about 15% by weight or more, and most preferred is about 20% by weight or more. For example, the content of the phosphate source compound in this composition is preferably about 50% by weight or less, more preferably about 40% by weight or less, still more preferably about 35% by weight or less, and particularly preferably. Is less than about 30% by weight, and most preferably less than about 25% by weight.

  The kit of the present invention may also comprise components other than the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition. Examples of such components include organic solubilizers, drug retainers, and phosphate source compound-containing compositions.

  An example of the organic solubilizer is sodium hypochlorite. The organic solubilizer can also be packaged as a kit in combination with the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition in separate containers. The organic solubilizer containing sodium hypochlorite is manufactured by Kuraray Medical Co., Ltd. under the trade name AD gel and sold by Morita Co., Ltd. The AD gel is a milky white gel containing 10% sodium hypochlorite and contains an alumina-based microfiller as a thickener.

(4. Method of using the kit of the present invention)
Although the kit of this invention is used as follows, for example, it is not limited to such a usage method.

(4a. How to use a caries treatment kit)
When treating caries using the caries treatment kit of the present invention, either of the following two methods of use may be employed:
(I) First, a hydroxyapatite particle-containing composition is filled in a dental caries defect part, and then a phosphorylated saccharide calcium-containing composition is applied to the filling part; and (ii) dental caries defect A method of use in which a portion is filled with a mixture of a composition containing hydroxyapatite particles and a composition containing calcium phosphate phosphor.

  That is, the hydroxyapatite particle-containing composition may be allowed to act in advance, and then the phosphorylated saccharide calcium-containing composition may be used, or the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition may be allowed to act simultaneously. Good. It is preferable to act the hydroxyapatite particle-containing composition in advance.

  In the embodiment in which the hydroxyapatite particle-containing composition is allowed to act and then the phosphorylated saccharide calcium-containing composition is allowed to act, first, the hydroxyapatite particle-containing composition is applied to a desired tooth surface (for example, a carious portion). It is preferable that the hydroxyapatite particle-containing composition is applied to the tooth surface using an instrument such as a PMTC-specific contra or a hand brush equipped with a rubber cup. During and after application of the hydroxyapatite particle-containing composition, it may be in contact with saliva, but it is preferable to take measures to reduce contact with saliva so that the applied hydroxyapatite particles do not flow out. . For example, it is preferable to remove saliva. The time for taking measures to reduce contact with saliva is preferably continued for about 1 minute or more, more preferably about 2 minutes or more from the start of application of the composition containing hydroxyapatite particles, more preferably about 3 minutes or more. Is most preferred. There is no particular upper limit to the time for taking measures to reduce contact with saliva, but for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 minutes from the start of applying the composition containing hydroxyapatite particles Hereinafter, it may be about 20 minutes or less.

  Next, the composition containing the hydroxyapatite particles is rinsed lightly without rinsing, or in the case of rinsing so that all of the filled hydroxyapatite does not run off, and then the calcium phosphate-containing composition is applied to the same part. The It is preferable that the phosphorylated saccharide calcium-containing composition is also applied to the tooth surface using an instrument such as a PMTC exclusive contra or hand brush equipped with a rubber cup. Take measures to reduce contact with saliva so that it may come into contact with saliva during and after application of the phosphorylated sugar calcium-containing composition, but the applied phosphorylated sugar calcium does not flow out Is preferred. For example, it is preferable to remove saliva. The time for taking measures to reduce contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, and more preferably about 15 minutes or more from the start of applying the calcium phosphate-containing composition. Most preferred. There is no particular upper limit to the time for taking measures to reduce contact with saliva, but for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 or less from the start of applying the phosphorylated saccharide calcium-containing composition. Or less, about 20 minutes or less. When calcium phosphate phosphoric acid penetrates after filling with hydroxyapatite particles, remineralization is remarkably promoted.

  In the embodiment in which the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition are allowed to act simultaneously, the kit of the present invention can be used as follows. First, the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition are applied to a desired tooth surface (for example, a carious portion) almost simultaneously. These compositions may be pre-mixed immediately before application to the tooth surface, or may be applied separately to the tooth surface and mixed there. These compositions are preferably applied to the tooth surface using a device such as a PMTC exclusive contra or hand brush equipped with a rubber cup. During and after application of these compositions, it may be in contact with saliva, but measures are taken to reduce contact with saliva so that applied hydroxyapatite particles and calcium phosphate sugar do not flow out. It is preferable. For example, it is preferable to remove saliva. The time taken to reduce the contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, most preferably about 15 minutes or more from the start of application of these compositions. preferable. There is no particular upper limit to the time for taking measures to reduce contact with saliva, for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 minutes or less after starting to apply these compositions, Such as about 20 minutes or less. When calcium phosphate phosphoric acid penetrates after filling with hydroxyapatite particles, remineralization is remarkably promoted.

  Since organic substances such as biofilm, pellicle and stain are deposited on the tooth surface, it is preferable to remove these organic substances before the action of the hydroxyapatite particle-containing composition. For example, it is preferable to remove organic matter by applying an organic solubilizer after cleaning the tooth surface with a hand brush or removing tartar or plaque with a dedicated instrument. In such a case, and when the kit of the present invention includes an organic dissolution agent, first, the organic dissolution agent is applied to a defect portion due to dental caries to remove the organic matter in this portion, thereby exposing the defect portion. Even if an organic solubilizer is not provided in the kit, an organic solubilizer available separately may be used instead. It is desirable to avoid contact with saliva during and after application of the organic solubilizer, and steps may be taken to reduce contact with saliva to prevent the organic matter from reattaching to the tooth surface. preferable. For example, it is preferable to remove saliva. The time for taking measures to reduce contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, and most preferably about 15 minutes or more from the start of applying the organic dissolution agent. . It is preferable to rinse the tooth surface with water or the like before performing the next step. This subsequent step can be performed in the same manner as in the two embodiments relating to the use of the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition. That is, (i) the exposed surface is filled with a composition containing hydroxyapatite particles, and then the calcium phosphate-containing composition is applied to the filling portion, or (ii) the exposed surface contains hydroxyapatite particles It is preferable to apply a mixture of the composition and the phosphorylated saccharide calcium-containing composition.

  Furthermore, after removing the organic matter as necessary, the hydroxyapatite particle-containing composition is applied to the tooth surface, and then the phosphorylated saccharide calcium-containing composition is applied, and then the application site is irradiated using a laser device. Then, the remineralization effect is promoted. When repeating the application of the hydroxyapatite particle-containing composition and the application of the phosphorylated saccharide calcium-containing composition, that is, when laminating the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition on the tooth surface, Each time the phosphorylated saccharide calcium-containing composition is applied, the recalcification effect is further promoted by irradiating the application site using a laser device. Laser equipment that can be used in the present invention is a dental laser known in the art, represented by a CO2 laser.

(4b. How to use the enamel care kit)
When caring for enamel using the enamel care kit of the present invention, either of the following two methods of use may be employed:
(I) First, the hydroxyapatite particle-containing composition is applied to the damaged part, and then the phosphorylated saccharide calcium-containing composition is applied to this part; and (ii) the hydroxyapatite particle-containing composition And a method of applying a mixture of a calcium phosphate-containing composition to a damaged part.

  That is, the hydroxyapatite particle-containing composition may be allowed to act in advance, and then the phosphorylated saccharide calcium-containing composition may be used, or the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition may be allowed to act simultaneously. Good. It is preferable to act the hydroxyapatite particle-containing composition in advance.

  Enamel damage can be caused by a variety of causes. Examples of causes of such damage include debonding, whitening, professional mechanical toe screening, polishing and orthodontic treatment.

  In the embodiment in which the hydroxyapatite particle-containing composition is allowed to act and then the phosphorylated saccharide calcium-containing composition is allowed to act, first, the hydroxyapatite particle-containing composition is applied to the damaged tooth surface. It is preferable that the hydroxyapatite particle-containing composition is applied to the tooth surface using an instrument such as a PMTC-specific contra or a hand brush equipped with a rubber cup. During and after application of the hydroxyapatite particle-containing composition, it may be in contact with saliva, but it is preferable to take measures to reduce contact with saliva so that the applied hydroxyapatite particles do not flow out. . For example, it is preferable to remove saliva. The time for taking measures to reduce contact with saliva is preferably continued for about 1 minute or more, more preferably about 2 minutes or more from the start of application of the composition containing hydroxyapatite particles, more preferably about 3 minutes or more. Is most preferred. There is no particular upper limit to the time for taking measures to reduce contact with saliva, but for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 minutes from the start of applying the composition containing hydroxyapatite particles Hereinafter, it may be about 20 minutes or less.

  Next, the composition containing the hydroxyapatite particles is rinsed lightly without rinsing, or in the case of rinsing so that all of the filled hydroxyapatite does not run off, and then the calcium phosphate-containing composition is applied to the same part. The It is preferable that the phosphorylated saccharide calcium-containing composition is also applied to the tooth surface using an instrument such as a PMTC exclusive contra or hand brush equipped with a rubber cup. Take measures to reduce contact with saliva so that it may come into contact with saliva during and after application of the phosphorylated sugar calcium-containing composition, but the applied phosphorylated sugar calcium does not flow out Is preferred. For example, it is preferable to remove saliva. The time for taking measures to reduce contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, and more preferably about 15 minutes or more from the start of applying the calcium phosphate-containing composition. Most preferred. There is no particular upper limit to the time for taking measures to reduce contact with saliva, but for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 or less from the start of applying the phosphorylated saccharide calcium-containing composition. Or less, about 20 minutes or less. When calcium phosphate phosphoric acid penetrates after filling with hydroxyapatite particles, remineralization is remarkably promoted.

  In the embodiment in which the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition are allowed to act simultaneously, the kit of the present invention can be used as follows. First, the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition are applied to the damaged tooth surface almost simultaneously. These compositions may be pre-mixed immediately before application to the tooth surface, or may be applied separately to the tooth surface and mixed there. These compositions are preferably applied to the tooth surface using a device such as a PMTC exclusive contra or hand brush equipped with a rubber cup. During and after application of these compositions, it may be in contact with saliva, but measures are taken to reduce contact with saliva so that applied hydroxyapatite particles and calcium phosphate sugar do not flow out. It is preferable. For example, it is preferable to remove saliva. The time taken to reduce the contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, most preferably about 15 minutes or more from the start of application of these compositions. preferable. There is no particular upper limit to the time for taking measures to reduce contact with saliva, for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 minutes or less after starting to apply these compositions, Such as about 20 minutes or less. When calcium phosphate phosphoric acid penetrates after filling with hydroxyapatite particles, remineralization is remarkably promoted.

  Since organic substances such as biofilm, pellicle and stain are deposited on the tooth surface, it is preferable to remove these organic substances before the action of the hydroxyapatite particle-containing composition. For example, it is preferable to remove organic matter by applying an organic solubilizer after cleaning the tooth surface with a hand brush or removing tartar or plaque with a dedicated instrument. In such a case, and when the kit of the present invention includes an organic dissolving agent, the tooth surface is first exposed by applying the organic dissolving agent to the damaged tooth surface to remove the organic matter in this portion. Even if an organic solubilizer is not provided in the kit, an organic solubilizer available separately may be used instead. It is desirable to avoid contact with saliva during and after application of the organic solubilizer, and steps may be taken to reduce contact with saliva to prevent the organic matter from reattaching to the tooth surface. preferable. For example, it is preferable to remove saliva. The time for taking measures to reduce contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, and most preferably about 15 minutes or more from the start of applying the organic dissolution agent. . It is preferable to rinse the tooth surface with water or the like before performing the next step. This subsequent step can be performed in the same manner as in the two embodiments relating to the use of the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition. That is, (i) the exposed surface is filled with a composition containing hydroxyapatite particles, and then the calcium phosphate-containing composition is applied to the filling portion, or (ii) the exposed surface contains hydroxyapatite particles It is preferable to apply a mixture of the composition and the phosphorylated saccharide calcium-containing composition.

  Furthermore, after removing the organic matter as necessary, the hydroxyapatite particle-containing composition is applied to the tooth surface, and then the phosphorylated saccharide calcium-containing composition is applied, and then the application site is irradiated using a laser device. Then, the remineralization effect is promoted. When repeating the application of the hydroxyapatite particle-containing composition and the application of the phosphorylated saccharide calcium-containing composition, that is, when laminating the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition on the tooth surface, Each time the phosphorylated saccharide calcium-containing composition is applied, the recalcification effect is further promoted by irradiating the application site using a laser device. Laser equipment that can be used in the present invention is a dental laser known in the art, represented by a CO2 laser.

(4c. How to use the kit for enamelling the exposed root surface of teeth)
When enamelling the exposed root surface of the tooth using the kit for enamelling the exposed root surface of the present invention, either of the following two methods of use may be employed:
(I) First, the hydroxyapatite particle-containing composition is applied to the exposed root surface of the tooth, and then the phosphorylated saccharide calcium-containing composition is applied to the root surface; and (ii) the hydroxyapatite particle-containing composition A method of applying a mixture of a composition and a calcium phosphate-containing composition to an exposed root surface of a tooth.

  That is, the hydroxyapatite particle-containing composition may be allowed to act in advance, and then the phosphorylated saccharide calcium-containing composition may be used, or the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition may be allowed to act simultaneously. Good. It is preferable to act the hydroxyapatite particle-containing composition in advance.

  The root surface of the tooth can be exposed for various reasons. Examples of causes of such exposure include periodontal treatment, aging, occlusion and excessive brushing.

  In the embodiment in which the hydroxyapatite particle-containing composition is allowed to act and then the phosphorylated saccharide calcium-containing composition is allowed to act, first, the hydroxyapatite particle-containing composition is applied to the exposed root surface of the tooth. It is preferable that the hydroxyapatite particle-containing composition is applied to the exposed root surface using an instrument such as a PMTC-specific contra or a hand brush equipped with a rubber cup. If it is difficult to apply to the exposed root surface using a normal device, and to increase the action time on the exposed root surface, treat the drug with a drug retainer that can be immersed to the root of the tooth. It is preferable to efficiently reach the site. Since each tooth has a different shape, it is preferable that the drug retainer is made in accordance with the tooth shape of each person. Use of a drug retainer is advantageous because contact with saliva is also suppressed. When a drug retainer is used, the hydroxyapatite particle-containing composition is applied by filling the drug retainer with the hydroxyapatite particle-containing composition and placing it on the teeth. During and after application of the hydroxyapatite particle-containing composition, it may be in contact with saliva, but it is preferable to take measures to reduce contact with saliva so that the applied hydroxyapatite particles do not flow out. . For example, it is preferable to remove saliva. The time for taking measures to reduce contact with saliva is preferably continued for about 1 minute or more, more preferably about 2 minutes or more from the start of application of the composition containing hydroxyapatite particles, more preferably about 3 minutes or more. Is most preferred. There is no particular upper limit to the time for taking measures to reduce contact with saliva, but for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 minutes from the start of applying the composition containing hydroxyapatite particles Hereinafter, it may be about 20 minutes or less.

  Next, the composition containing the hydroxyapatite particles is rinsed lightly without rinsing, or in the case of rinsing so that all of the filled hydroxyapatite does not run off, and then the calcium phosphate-containing composition is applied to the same part. The It is preferable that the phosphorylated saccharide calcium-containing composition is also applied to the tooth surface using an instrument such as a PMTC exclusive contra or hand brush equipped with a rubber cup. In the case where it is difficult to apply the exposed root surface using a normal instrument, and in order to prolong the action time on the exposed root surface, it is preferable to use a drug retainer that can be immersed up to the root of the tooth. When a drug retainer is used, the phosphorylated saccharide calcium-containing composition is applied by filling the drug retainer with the phosphorylated saccharide calcium-containing composition and placing it on the teeth. Take measures to reduce contact with saliva so that it may come into contact with saliva during and after application of the phosphorylated sugar calcium-containing composition, but the applied phosphorylated sugar calcium does not flow out Is preferred. For example, it is preferable to remove saliva. The time for taking measures to reduce contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, and more preferably about 15 minutes or more from the start of applying the calcium phosphate-containing composition. Most preferred. There is no particular upper limit to the time for taking measures to reduce contact with saliva, but for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 or less from the start of applying the phosphorylated saccharide calcium-containing composition. Or less, about 20 minutes or less. When calcium phosphate phosphoric acid penetrates after filling with hydroxyapatite particles, remineralization is remarkably promoted.

  In the embodiment in which the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition are allowed to act simultaneously, the kit of the present invention can be used as follows. First, the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition are applied to the exposed root surface almost simultaneously. These compositions may be pre-mixed immediately before application to the root surface, or may be applied separately to the tooth surface and mixed there. These compositions are preferably applied to the tooth surface using a device such as a PMTC exclusive contra or hand brush equipped with a rubber cup. In the case where it is difficult to apply the exposed root surface using a normal instrument, and in order to prolong the action time on the exposed root surface, it is preferable to use a drug retainer that can be immersed up to the root of the tooth. When a drug retainer is used, these compositions are applied by filling a mixture of the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition in the drug retainer and placing the mixture on the teeth. During and after application of these compositions, it may be in contact with saliva, but measures are taken to reduce contact with saliva so that applied hydroxyapatite particles and calcium phosphate sugar do not flow out. It is preferable. For example, it is preferable to remove saliva. The time taken to reduce the contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, most preferably about 15 minutes or more from the start of application of these compositions. preferable. There is no particular upper limit to the time for taking measures to reduce contact with saliva, for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 minutes or less after starting to apply these compositions, Such as about 20 minutes or less. When calcium phosphate phosphoric acid penetrates after filling with hydroxyapatite particles, remineralization is remarkably promoted.

  Since organic substances such as biofilm, pellicle and stain are deposited on the tooth surface, it is preferable to remove these organic substances before the action of the hydroxyapatite particle-containing composition. For example, it is preferable to remove organic matter by applying an organic solubilizer after cleaning the tooth surface with a hand brush or removing tartar or plaque with a dedicated instrument. In such a case, and when the kit of the present invention includes an organic solubilizer, first, the organic solubilizer is applied to the exposed root surface to remove the organic matter in this portion, thereby exposing the exposed root surface and sterilizing. Even if an organic solubilizer is not provided in the kit, an organic solubilizer available separately may be used instead. It is desirable to avoid contact with saliva during and after application of the organic solubilizer, and steps may be taken to reduce contact with saliva to prevent the organic matter from reattaching to the tooth surface. preferable. For example, it is preferable to remove saliva. The time for taking measures to reduce contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, and most preferably about 15 minutes or more from the start of applying the organic dissolution agent. . It is preferable to rinse the tooth surface with water or the like before performing the next step. This subsequent step can be performed in the same manner as in the two embodiments relating to the use of the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition. That is, (i) the exposed surface is filled with a composition containing hydroxyapatite particles, and then the calcium phosphate-containing composition is applied to the filling portion, or (ii) the exposed surface contains hydroxyapatite particles It is preferable to apply a mixture of the composition and the phosphorylated saccharide calcium-containing composition.

  Furthermore, after removing the organic matter as necessary, the hydroxyapatite particle-containing composition is applied to the tooth surface, and then the phosphorylated saccharide calcium-containing composition is applied, and then the application site is irradiated using a laser device. Then, the remineralization effect is promoted. When repeating the application of the hydroxyapatite particle-containing composition and the application of the phosphorylated saccharide calcium-containing composition, that is, when laminating the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition on the tooth surface, Each time the phosphorylated saccharide calcium-containing composition is applied, the recalcification effect is further promoted by irradiating the application site using a laser device. Laser equipment that can be used in the present invention is a dental laser known in the art, represented by a CO2 laser.

(4d. How to use the kit for the treatment of hypersensitivity)
When treating hypersensitivity using the kit for the treatment of hypersensitivity of the present invention, either of the following two methods of use may be employed:
(I) a method of use in which a hydroxyapatite particle-containing composition is first applied to a tooth-sensitive surface and then a phosphorylated saccharide calcium-containing composition is applied to this surface; and (ii) a hydroxyapatite particle-containing composition; A method of use wherein a mixture with a phosphorylated saccharide calcium-containing composition is applied to the hypersensitive surface of a tooth.

  That is, the hydroxyapatite particle-containing composition may be allowed to act in advance, and then the phosphorylated saccharide calcium-containing composition may be used, or the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition may be allowed to act simultaneously. Good. It is preferable to act the hydroxyapatite particle-containing composition in advance.

  In hypersensitivity, the opening of dentinal tubules has been confirmed as a phenomenon.

  In the embodiment in which the hydroxyapatite particle-containing composition is allowed to act and then the phosphorylated saccharide calcium-containing composition is allowed to act, first, the hydroxyapatite particle-containing composition is applied to the hypersensitive surface of the tooth. It is preferable that the hydroxyapatite particle-containing composition is applied to the tooth surface using an instrument such as a PMTC-specific contra or a hand brush equipped with a rubber cup. During and after application of the hydroxyapatite particle-containing composition, it may be in contact with saliva, but it is preferable to take measures to reduce contact with saliva so that the applied hydroxyapatite particles do not flow out. . For example, it is preferable to remove saliva. The time for taking measures to reduce contact with saliva is preferably continued for about 1 minute or more, more preferably about 2 minutes or more from the start of application of the composition containing hydroxyapatite particles, more preferably about 3 minutes or more. Is most preferred. There is no particular upper limit to the time for taking measures to reduce contact with saliva, but for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 minutes from the start of applying the composition containing hydroxyapatite particles Hereinafter, it may be about 20 minutes or less.

  Next, the composition containing the hydroxyapatite particles is rinsed lightly without rinsing, or in the case of rinsing so that all of the filled hydroxyapatite does not run off, and then the calcium phosphate-containing composition is applied to the same part. The It is preferable that the phosphorylated saccharide calcium-containing composition is also applied to the tooth surface using an instrument such as a PMTC exclusive contra or hand brush equipped with a rubber cup. Take measures to reduce contact with saliva so that it may come into contact with saliva during and after application of the phosphorylated sugar calcium-containing composition, but the applied phosphorylated sugar calcium does not flow out Is preferred. For example, it is preferable to remove saliva. The time for taking measures to reduce contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, and more preferably about 15 minutes or more from the start of applying the calcium phosphate-containing composition. Most preferred. There is no particular upper limit to the time for taking measures to reduce contact with saliva, but for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 or less from the start of applying the phosphorylated saccharide calcium-containing composition. Or less, about 20 minutes or less. When calcium phosphate phosphoric acid penetrates after filling with hydroxyapatite particles, remineralization is remarkably promoted.

  In the embodiment in which the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition are allowed to act simultaneously, the kit of the present invention can be used as follows. First, the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition are applied to the tooth hypersensitive surface almost simultaneously. These compositions may be pre-mixed immediately before application to the tooth surface, or may be applied separately to the tooth surface and mixed there. These compositions are preferably applied to the tooth surface using a device such as a PMTC exclusive contra or hand brush equipped with a rubber cup. During and after application of these compositions, it may be in contact with saliva, but measures are taken to reduce contact with saliva so that applied hydroxyapatite particles and calcium phosphate sugar do not flow out. It is preferable. For example, it is preferable to remove saliva. The time taken to reduce the contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, most preferably about 15 minutes or more from the start of application of these compositions. preferable. There is no particular upper limit to the time for taking measures to reduce contact with saliva, for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 minutes or less after starting to apply these compositions, Such as about 20 minutes or less. When calcium phosphate phosphoric acid penetrates after filling with hydroxyapatite particles, remineralization is remarkably promoted.

  Since organic substances such as biofilm, pellicle and stain are deposited on the tooth surface, it is preferable to remove these organic substances before the action of the hydroxyapatite particle-containing composition. For example, it is preferable to remove organic matter by applying an organic solubilizer after cleaning the tooth surface with a hand brush or removing tartar or plaque with a dedicated instrument. In such a case, and when the kit of the present invention includes an organic solubilizing agent, first, the tooth surface is exposed by applying an organic solubilizing agent to the hypersensitive surface of the tooth to remove the organic matter in this portion. Even if an organic solubilizer is not provided in the kit, an organic solubilizer available separately may be used instead. It is desirable to avoid contact with saliva during and after application of the organic solubilizer, and steps may be taken to reduce contact with saliva to prevent the organic matter from reattaching to the tooth surface. preferable. For example, it is preferable to remove saliva. The time for taking measures to reduce contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, and most preferably about 15 minutes or more from the start of applying the organic dissolution agent. . It is preferable to rinse the tooth surface with water or the like before performing the next step. This subsequent step can be performed in the same manner as in the two embodiments relating to the use of the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition. That is, (i) the exposed surface is filled with a composition containing hydroxyapatite particles, and then the calcium phosphate-containing composition is applied to the filling portion, or (ii) the exposed surface contains hydroxyapatite particles It is preferable to apply a mixture of the composition and the phosphorylated saccharide calcium-containing composition.

  Furthermore, after removing the organic matter as necessary, the hydroxyapatite particle-containing composition is applied to the tooth surface, and then the phosphorylated saccharide calcium-containing composition is applied, and then the application site is irradiated using a laser device. Then, the remineralization effect is promoted. When repeating the application of the hydroxyapatite particle-containing composition and the application of the phosphorylated saccharide calcium-containing composition, that is, when laminating the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition on the tooth surface, Each time the phosphorylated saccharide calcium-containing composition is applied, the recalcification effect is further promoted by irradiating the application site using a laser device. Laser equipment that can be used in the present invention is a dental laser known in the art, represented by a CO2 laser.

(5. Composition of the present invention)
The composition of the present invention used as a caries treatment composition, an enamel care composition, a composition for enamelling the exposed root surface of teeth, or a composition for the treatment of hypersensitivity is a hydroxy Contains apatite particles and calcium phosphate sugar. The composition of the present invention may be in the form of powder, granules, paste, cream, gel or suspension.

  In one embodiment, the composition of the present invention is a caries treatment composition.

  In one embodiment, the composition of the present invention is an enamel care composition.

  In one embodiment, the composition of the present invention is a composition for enamelling exposed root surfaces of teeth.

  In one embodiment, the composition of the present invention is a composition for the treatment of hypersensitivity.

  The composition of the present invention may be composed only of hydroxyapatite particles and calcium phosphate sugar, but may contain other materials.

  The composition of the present invention can be produced by mixing materials such as hydroxyapatite particles and phosphorylated saccharide calcium by a conventionally known method.

  The content of hydroxyapatite particles in the composition of the present invention can be arbitrarily set. For example, the content of hydroxyapatite particles in the composition of the present invention is preferably about 1% by weight or more, more preferably about 5% by weight or more, and further preferably about 10% by weight or more. Preferably it is about 15% by weight or more, and most preferably about 20% by weight or more. For example, the content of hydroxyapatite particles in the composition of the present invention is preferably about 50% by weight or less, more preferably about 40% by weight or less, still more preferably about 35% by weight or less. Preferably it is about 30 wt% or less, and most preferably about 25 wt% or less.

  The content of phosphorylated saccharide calcium in the composition of the present invention can be arbitrarily set. For example, the content of phosphorylated saccharide calcium in the composition of the present invention is preferably about 0.1% by weight or more, more preferably about 1% by weight or more, and further preferably about 10% by weight or more. Particularly preferably about 15% by weight or more, and most preferably about 20% by weight or more. For example, the content of phosphorylated saccharide calcium in the composition of the present invention is preferably about 50% by weight or less, more preferably about 40% by weight or less, further preferably about 35% by weight or less, Particularly preferred is about 30% by weight or less, and most preferred is about 25% by weight or less.

  The composition of the present invention may also contain a phosphate source compound. When the phosphate source compound is included in the composition of the present invention, the content of the phosphate source compound in the composition can be arbitrarily set. For example, the content of the phosphate source compound in the composition is preferably about 0.1% by weight or more, more preferably about 1% by weight or more, and further preferably about 10% by weight or more. Particularly preferred is about 15% by weight or more, and most preferred is about 20% by weight or more. For example, the content of the phosphate source compound in this composition is preferably about 50% by weight or less, more preferably about 40% by weight or less, still more preferably about 35% by weight or less, and particularly preferably. Is less than about 30% by weight, and most preferably less than about 25% by weight.

(5. Method of using the composition of the present invention)
Although the composition of this invention is used as follows, for example, it is not limited to such a usage method.

(5a. Method of Using Caries Treatment Composition)
When treating caries using the composition for caries treatment of the present invention, it can be used as follows.

  First, the composition for caries treatment of the present invention is applied to the caries portion. This composition is preferably applied to the tooth surface using an instrument such as a PMTC exclusive contra or hand brush equipped with a rubber cup. Take measures to reduce contact with saliva so that applied hydroxyapatite particles and phosphorylated sugar calcium may not flow out during and after application of this composition and thereafter Is preferred. For example, it is preferable to remove saliva. The time taken to reduce the contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, most preferably about 15 minutes or more from the start of application of these compositions. preferable. There is no particular upper limit to the time for taking measures to reduce contact with saliva, for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 minutes or less after starting to apply these compositions, Such as about 20 minutes or less. Before applying the composition for caries treatment of the present invention to the tooth surface, it is preferable to use an organic dissolving agent as described in the method of using the kit of the present invention.

  Furthermore, after removing the organic matter as necessary, the recalcification effect is promoted by applying the caries treatment composition of the present invention to the tooth surface and then irradiating the application site using a laser device. Even when the application of the caries treatment composition is repeated, that is, when the caries treatment composition is laminated on the tooth surface, every time the caries treatment composition is applied, the application site is reapplied by irradiating the application site with a laser device. The calcification effect is further promoted. Laser equipment that can be used in the present invention is a dental laser known in the art, represented by a CO2 laser.

(5b. Method of using enamel care composition)
When enamel is cared for using the enamel care composition of the present invention, it can be used as follows.

  First, the enamel care composition of the present invention is applied to a damaged tooth surface. This composition is preferably applied to the tooth surface using an instrument such as a PMTC exclusive contra or hand brush equipped with a rubber cup. Take measures to reduce contact with saliva so that applied hydroxyapatite particles and phosphorylated sugar calcium may not flow out during and after application of this composition and thereafter Is preferred. For example, it is preferable to remove saliva. The time taken to reduce the contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, most preferably about 15 minutes or more from the start of application of these compositions. preferable. There is no particular upper limit to the time for taking measures to reduce contact with saliva, for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 minutes or less after starting to apply these compositions, Such as about 20 minutes or less. Before applying the enamel care composition of the present invention to the tooth surface, it is preferable to use an organic solubilizer as described in the method of using the kit of the present invention.

  Furthermore, after removing the organic matter as necessary, after applying the enamel care composition of the present invention to the tooth surface, the recalcification effect is promoted by irradiating the application site using a laser device. Even when the application of the enamel care composition is repeated, that is, when the enamel care composition is laminated on the tooth surface, each time the enamel care composition is applied, the application site is determined using a laser device. Irradiation further promotes the remineralization effect. Laser equipment that can be used in the present invention is a dental laser known in the art, represented by a CO2 laser.

(5c. Method of using the composition for enamelling the exposed root surface of teeth)
When enamelling the exposed root surface of the tooth using the composition for enamelling the exposed root surface of the present invention, it can be used as follows.

  First, the composition for enamelling the exposed root surface of the tooth of the present invention is applied to the exposed root surface. This composition is preferably applied to the exposed root surface using an instrument such as a PMTC exclusive contra or hand brush equipped with a rubber cup. In the case where it is difficult to apply the exposed root surface using a normal instrument, and in order to prolong the action time on the exposed root surface, it is preferable to use a drug retainer that can be immersed up to the root of the tooth. Since each tooth has a different shape, it is preferable that the drug retainer is made in accordance with the tooth shape of each person. Use of a drug retainer is advantageous because contact with saliva is also suppressed. When a drug retainer is used, the composition of the present invention is applied by filling the drug retainer with the composition for enamelling the exposed root surface of the tooth according to the present invention and placing the composition on the tooth. Take measures to reduce contact with saliva so that applied hydroxyapatite particles and phosphorylated sugar calcium may not flow out during and after application of this composition and thereafter Is preferred. For example, it is preferable to remove saliva. The time taken to reduce the contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, most preferably about 15 minutes or more from the start of application of these compositions. preferable. There is no particular upper limit to the time for taking measures to reduce contact with saliva, for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 minutes or less after starting to apply these compositions, Such as about 20 minutes or less. Before applying the composition for enamelling the exposed root surface of the tooth of the present invention to the tooth surface, it is preferable to use an organic dissolving agent as described in the method of using the kit of the present invention.

  Furthermore, after removing the organic matter as necessary, after applying the composition for enamelling the exposed root surface of the tooth of the present invention to the tooth surface, when the application site is irradiated using a laser device, recalcification is performed. The effect is improved. Even when the composition for caries treatment is repeatedly applied, that is, when the composition for enamelling the exposed root surface of the tooth is laminated on the tooth surface, every time the composition for enamelling is applied. When the application site is irradiated using a laser device, the remineralization effect is further promoted. Laser equipment that can be used in the present invention is a dental laser known in the art, represented by a CO2 laser.

(5d. Method of using the composition for the treatment of hypersensitivity)
In treating hypersensitivity using the composition for the treatment of hypersensitivity of the present invention, it can be used as follows.

  First, the composition for the treatment of hypersensitivity of the present invention is applied to the hypersensitive tooth surface. This composition is preferably applied to the tooth surface using an instrument such as a PMTC exclusive contra or hand brush equipped with a rubber cup. Take measures to reduce contact with saliva so that applied hydroxyapatite particles and phosphorylated sugar calcium may not flow out during and after application of this composition and thereafter Is preferred. For example, it is preferable to remove saliva. The time taken to reduce the contact with saliva is preferably continued for about 5 minutes or more, more preferably about 10 minutes or more, most preferably about 15 minutes or more from the start of application of these compositions. preferable. There is no particular upper limit to the time for taking measures to reduce contact with saliva, for example, about 1 hour or less, about 45 minutes or less, about 30 minutes or less, about 25 minutes or less after starting to apply these compositions, Such as about 20 minutes or less. Before applying the composition for the treatment of hypersensitivity of the present invention to the tooth surface, it is preferable to use an organic dissolution agent as described in the method of using the kit of the present invention.

  Furthermore, after removing the organic matter as necessary, after applying the composition for treatment of hypersensitivity of the present invention to the tooth surface, irradiating the application site with a laser device promotes the remineralization effect. The Even when the application of the composition for caries treatment is repeated, that is, when the composition for treatment of hypersensitivity is laminated on the tooth surface, the laser device is used each time the composition for treatment of hypersensitivity is applied. Irradiation of the application site further promotes the remineralization effect. Laser equipment that can be used in the present invention is a dental laser known in the art, represented by a CO2 laser.

(6. Dentifrice of the present invention)
The dentifrice for caries treatment of the present invention contains hydroxyapatite particles and calcium phosphate sugar.

  The content of the hydroxyapatite particles in the dentifrice for caries treatment of the present invention can be arbitrarily set. For example, the content of hydroxyapatite particles in the dentifrice for caries treatment of the present invention is preferably about 1% by weight or more, more preferably about 2% by weight or more, and further preferably about 3% by weight or more. Particularly preferably about 4% by weight or more, and most preferably about 5% by weight or more. For example, the content of the hydroxyapatite particles in the hydroxyapatite particle-containing composition is, for example, about 90% by weight or less, about 80% by weight or less, about 70% by weight or less, about 60% by weight or less, about 50% by weight or less, It may be about 40% or less, about 30% or less, about 20% or less, about 10% or less, and the like.

  The content of the hydroxyapatite particles in the dentifrice for caries treatment of the present invention can be arbitrarily set. For example, the content of phosphorylated saccharide calcium in the dental caries treatment dentifrice of the present invention is preferably about 0.1% by weight or more, more preferably about 1% by weight or more, and further preferably about 3% by weight. % Or more, particularly preferably about 4% by weight or more, and most preferably about 5% by weight or more. For example, the content of phosphorylated saccharide calcium in the phosphorylated saccharide calcium-containing composition is, for example, about 90% by weight or less, about 80% by weight or less, about 70% by weight or less, about 60% by weight or less, about 50% by weight. The amount may be about 40% by weight or less, about 30% by weight or less, about 20% by weight or less, about 10% by weight or less.

  The dentifrice for caries treatment of the present invention may contain components usually contained as a dentifrice in addition to the hydroxyapatite particles and calcium phosphate phosphor. The dentifrice for caries treatment of the present invention may contain a phosphate source compound. In the case where the dentifrice for caries treatment contains a phosphate source compound, the content of the phosphate source compound in the composition can be arbitrarily set. For example, the content of the phosphate source compound in the dentifrice is preferably about 0.1% by weight or more, more preferably about 1% by weight or more, and further preferably about 10% by weight or more. Particularly preferred is about 15% by weight or more, and most preferred is about 20% by weight or more. For example, the content of the phosphate source compound in the dentifrice is preferably about 50% by weight or less, more preferably about 40% by weight or less, still more preferably about 35% by weight or less, particularly preferably. Is less than about 30% by weight, and most preferably less than about 25% by weight.

  The dentifrice for caries treatment of the present invention can be used in the same manner as a normal dentifrice.

(7. Home care)
The kit and composition of the present invention may be used by professionals such as dentists, dental hygienists, nurses, nursing assistants, etc., and may be used by ordinary people at home.

  Since the cycle of demineralization and remineralization occurs constantly in the oral cavity, it is preferable to care not only by professional care but also at home.

  Home care is preferably performed daily after each meal, for example.

  For home care, for example, a toothbrush, a hand mirror, a phosphorylated oligosaccharide calcium-containing gum, and a hydroxyapatite-containing toothpaste can be used in a hospital bag.

(Phosphorylated sugar calcium)
The phosphorylated saccharide calcium used in the following examples and reference examples was prepared from potato starch using calcium chloride instead of sodium chloride in the procedure of Example 1 of JP-A-8-104696. Point to. That is, phosphorylated saccharides in which 1 to 2 phosphate groups are bonded in the molecule to oligosaccharides composed of 2 to 8 glucoses linked with α-1,4, and calcium is bonded to each of these phosphorylated saccharides. It is a mixture of calcium. In this phosphorylated saccharide calcium, one phosphate group is bonded to an oligosaccharide consisting of 3, 4 or 5 glucose in the molecule, and calcium is bonded to this phosphate group. This is a mixture of an oligosaccharide composed of 7 or 8 glucoses with two phosphate groups bound in the molecule and calcium bound to the phosphate groups. Here, the molar ratio of the one having one phosphate group bonded to the one having two phosphate groups bonded is about 8: 2. In the following Examples and Test Examples, the salt thus prepared was used. In addition to this method using an ion exchange resin, phosphorylated saccharides of various metal salts can be easily prepared by adding each metal salt after desalting by general electrodialysis. In addition, about the calcium salt of phosphorylated saccharide, what is marketed as phosphorylated oligosaccharide calcium from Ezaki Glico Co., Ltd. can be used suitably. Phosphorylated oligosaccharide calcium is used as a powder or a solution.

  The organic solubilizers used in the following examples and reference examples are manufactured by Kuraray Medical Co., Ltd. under the trade name AD gel and sold by Morita Co., Ltd. The AD gel is a milky white gel containing 10% sodium hypochlorite and contains an alumina-based microfiller as a thickener.

  As the hydroxyapatite particles used in the following examples and reference examples, dentifrices (trade name: dental) containing hydroxyapatite nanoparticles having an average particle diameter of 50 nm (50 to 100 nm and occupying about 90% of the powder volume) are used. Dedicated Linamel PMTC Final Finish Paste (Sangi Co., Ltd. and Oral Care Co., Ltd.) was used.

  Further, in the following examples and reference examples, when treatment is performed in the oral cavity, unless otherwise noted, opening with an opening device, saliva removal, and moisture-proofing treatment that are normally performed during dental treatment are performed.

(Reference Example 1: Application of hydroxyapatite particles after removal of biofilm)
There are organic inhibitors such as biofilms and pellicles on the tooth surface. A biofilm is a film formed on the surface of a tooth by aggregating bacteria such as mutans bacteria that cause caries. If there is an organic inhibitor such as biofilm, even if hydroxyapatite or the like is applied, it cannot enter the inside of the tooth, and its effect is low. Therefore, in order to ensure that nano-sized hydroxyapatite can reach the target by enamel scratches and the fine structure of the demineralized part and to maximize the effect of hydroxyapatite, organic inhibitors on the tooth surface must be used. It is important to dissolve. The present inventors first studied the application of hydroxyapatite after dissolving the organic inhibitor on the tooth surface.

  An organic solubilizer (trade name: AD gel; Kuraray Medical) is applied to the crown of the tooth, washed with distilled water, and then a paste containing nano-hydroxyapatite particles (trade name: linamel PMTC final finish paste for dentistry; Sangi Co., Ltd.) And Oral Care Co., Ltd.) and washed with distilled water. The surface of the enamel before the treatment, after the treatment with the organic solvent and after the treatment with the hydroxyapatite particles was observed with a microscope. As a result, the unevenness of the enamel surface was not so clear before the treatment with the organic solubilizer, but the unevenness of the enamel surface became clear by the treatment with the organic solubilizer. And it turned out that the unevenness | corrugation of the surface is buried by processing with a hydroxyapatite particle.

  Moreover, the surface of the enamel before the treatment of the biofilm adhesion site and the biofilm non-adhesion site, after the treatment with the organic dissolving agent, and after the treatment with the hydroxyapatite particles was also observed with a scanning probe microscope (SPM). At the biofilm adhesion site, the surface irregularities of the enamel are not very clear before being treated with the organic solubilizing agent, but it was found that there were some irregularities. After the treatment with the organic solubilizer, it was found that many holes having a diameter of about 5 to 10 μm were formed on the enamel surface. After treatment with the hydroxyapatite particles, it was confirmed that the surface irregularities were buried. The average surface roughness (Ra) before the treatment with the organic solubilizer was 133.1 nm, and the average surface roughness (Ra) after the treatment with the organic solubilizer was 220.3 nm, which was treated with the hydroxyapatite particles. The later average surface roughness (Ra) was 103.3 nm.

  At the biofilm non-adhered site, the biofilm does not appear to adhere to the naked eye before being treated with the organic dissolution agent. However, when observed with SPM, the amount of biofilm attached is observed with the naked eye. It was found that the surface unevenness was not exposed, but a certain amount was attached, although it was smaller than the attachment site. After the treatment with the organic solubilizer, it was found that many holes having a diameter of about 5 to 10 μm were formed on the enamel surface. After treatment with the hydroxyapatite particles, it was confirmed that the surface irregularities were buried. The average surface roughness (Ra) before the treatment with the organic solubilizer was 107.6 nm, and the average surface roughness (Ra) after the treatment with the organic solubilizer was 171.8, which was treated with the hydroxyapatite particles. The later average surface roughness (Ra) was 81.94 nm.

  As a result, it was confirmed that the hydroxyapatite is efficiently filled into the tooth surface by decomposing organic matter on the tooth surface and applying the hydroxyapatite after exposing the tooth material.

(Reference example 2: Restoration of enamel cloudy part in the eruption period)
The enamel surface during the eruption period and several years after the eruption has minute irregularities derived from the development of teeth, and the degree of calcification is low. Therefore, the management of teeth during the eruption period and years after eruption is extremely important. This reference example is a clinical study on tooth surface restoration by HAP using an organic solubilizer.

  Considering the presence of organic inhibitors such as biofilms, pellicles and stains in order to ensure that nanoparticulate hydroxyapatite reaches the microscopic defects and scratches or the fine structure of the demineralized area in clinical settings. There is a need to. The inventors of the present invention have devised a new tooth surface restoration care using an organic solubilizing agent and studied its clinical effectiveness. In this reference example, SPM observation using freshly extracted teeth is described.

  Apply an organic solubilizer (AD gel) to the tooth surface of freshly extracted teeth with enamel vitiligo, leave it for 2 minutes, wash with distilled water, attach a rubber cup to the contra and hydroxyapatite (dental) A special linamel PMTC final finish paste) was applied for about 30 seconds, followed by ultrasonic cleaning for about 1 minute.

  The surface of the enamel in the vitiligo portion was observed with a scanning probe microscope (SPM) before the treatment, after the treatment with the organic dissolving agent, and after the treatment with hydroxyapatite.

  As a result, it was found that the enamel surface of the vitiligo before treatment with the organic solubilizer had a very large unevenness (distance between peaks and peaks) and some irregularities. After the treatment with the organic solubilizer, it was found that many holes having a diameter of about 5 to 10 μm were formed on the enamel surface. After treatment with the hydroxyapatite particles, it was confirmed that the surface irregularities were buried. The average surface roughness (Ra) before treatment with the organic solubilizer was 173.3 nm, and the average surface roughness (Ra) after treatment with the organic solubilizer was 219.5 nm, which was treated with the hydroxyapatite particles. Later, the average surface roughness (Ra) was 140.7 nm (Masaharu Kato, Manami Aizawa: Study on tooth surface restoration by HAP using organic solubilizer-1st report: Clinical course of enamel cloudy part in eruption stage -Journal of the Japan Dental Conservation Society 49 Spring Special Issue, 102, 2006).

  The results of this reference example are summarized below. Contaminants are deposited on the surface layer of the enamel cloudy part before the organic dissolution treatment (Ra = 173.3). By treating with an organic solubilizer (AD gel) for 2 minutes, the organic pollutants were dissolved and removed, and the enamel structure was exposed (Ra = 219.5). A rubber cup was attached to the contra, and hydroxyapatite (dental linamel PMTC final finishing paste) was applied at 750 rpm for about 30 seconds. After ultrasonic cleaning for about 1 minute, the microstructure of the enamel surface layer was repaired by HAP. It was found that the surface roughness was improved (Ra = 140.7).

(Reference Example 3: Initial Caries Management 1)
This reference example describes the clinical course of a case applied to an enamel cloudy part (ie, early demineralized lesion) in the eruption stage. An enamel cloudy area was seen on the front teeth (upper left and right central incisors) of a 6-year-old man in the eruption period. A photograph of the preoperative teeth taken from the front is shown on the left of FIG. After cleaning the upper and lower middle incisors (front teeth) with a hand brush, leave the organic solubilizer (AD gel) almost evenly applied to the entire tooth surface for 1-2 minutes and wash with purified water. did. The photograph which image | photographed the tooth | gear after wash | cleaning with purified water from the front is shown on the right of FIG. After washing with purified water, a rubber cup was attached to the contra, and hydroxyapatite (final dental linamel PMTC final finish paste) was applied at 750 rpm for about 30 seconds. After that, the chair side was instructed to chew two gums containing phosphorylated oligosaccharide calcium (manufactured by Ezaki Glico; poscam) for about 20 minutes. The patient was also instructed to prescribe a gum containing phosphorylated oligosaccharide calcium (poscam; manufactured by Ezaki Glico) and to chew this gum as a home care after eating every day and whenever appropriate.

  Cleaning with a hand brush, application of an organic solvent, washing with purified water, and application of hydroxyapatite were repeated about once a month. In the meantime, this patient is prescribed a phosphorylated oligosaccharide calcium-containing gum (poscam; manufactured by Ezaki Glico), and as a home care, chewing two gums at a time after meals and whenever appropriate. Continued. A photograph taken from the front with the teeth meshed two months after the first treatment of the initial decalcified lesion is shown in the upper left of FIG. A photograph taken from the front with the teeth meshed three months after the first treatment of the initial decalcified lesion is shown in the lower right of FIG. As can be seen from FIG. 4, the area of the decalcified portion (namely, the whitened portion) of the tooth surface significantly decreased after 3 months of treatment. Therefore, treatment with hydroxyapatite and treatment with phosphorylated oligosaccharide calcium are very effective for early caries management during the eruption stage, and are effective in promoting remineralization of early demineralized lesions and disappearance of cloudiness. I found out.

(Reference Example 4: Initial Caries Management 2)
Also in this reference example, the clinical course of a case applied to an enamel cloudy part in the eruption stage is described. In the eruption period, since the tooth quality is very weak, even if the clouded area is treated once by treatment, decalcification often occurs again. This reference example is a clinical example in such a case, and is a clinical result from the time point 9 months after Reference Example 3 for the same male as Reference Example 3. The male anterior teeth (the left and right central incisors) showed enamel cloudiness. The upper left and right middle incisors of the upper jaw and the left and right middle incisors and side incisors of the lower jaw before operation (before professional care) are shown in the upper left of FIG.

  After cleaning the upper and lower middle incisors (front teeth) with a hand brush, leave the organic solubilizer (AD gel) almost evenly applied to the entire tooth surface for 1-2 minutes and wash with purified water. The photograph which image | photographed the tooth surface after having performed is shown in the upper stage right of FIG. From this photograph, the progress of the demineralization of the enamel hidden by the organic matter can be clearly understood by the removal of the organic matter and the exposure of the enamel.

  After washing with purified water, a rubber cup was attached to the contra, and hydroxyapatite (final dental linamel PMTC final finish paste) was applied at 750 rpm for about 30 seconds. After that, the chair side was instructed to chew 2 gums containing phosphorylated oligosaccharide calcium (Ezaki Glico; Poscam) for about 20 minutes. A photograph of the teeth taken from the front after chewing the gum is shown in the lower center of FIG. From this picture, it can be seen that the teeth have become glossy and the area of the cloudy area has decreased. From this, it can be seen that by performing remineralization treatment with hydroxyapatite and phosphorylated oligosaccharide calcium, the tooth surface becomes smooth and remineralization of the demineralized portion occurs.

  This indicates that treatment with hydroxyapatite and calcium phosphorylated oligosaccharides is very effective for early caries management during the eruption stage, and is effective in promoting remineralization of early demineralized lesions and disappearance of cloudiness. all right.

(Example 1: Repair of the depressed portion of the subsurface demineralized portion)
As can be seen from the reference examples, by using sodium hypochlorite, which is an organic solubilizer, the organic matter on the tooth surface is decomposed and the tooth is exposed. It was thought that the inhibitory factor was removed by exposing the tooth surface, and the effect of each operation was improved. Furthermore, we thought that the remineralization of this hydroxyapatite could be promoted by reclaiming micro-defects (ie, tooth surface irregularities) with nano-sized hydroxyapatite paste and powder, and further by acting phosphorylated oligosaccharides. .

  A photograph of the depression of the subsurface demineralized part in front of the upper right middle incisor of a 31-year-old man is shown in the upper left of FIG. A distorted circular depression is seen near the gum of the upper right middle incisor. This is a C1 stage caries because the lesion is confined to the enamel layer. An organic solubilizer (AD gel) was applied to almost the upper half of the front surface of the tooth and allowed to act using a one-tuft brush for 1 minute. The photograph which image | photographed the tooth surface of the state which apply | coated the organic dissolving agent is shown in the upper right of FIG. The photograph which image | photographed the state which is making the organic dissolving agent act using a one tuft brush is shown in the lower left of FIG. Thereafter, the organic solvent was washed away with purified water. The photograph which image | photographed the tooth surface after washing | cleaning with purified water is shown in the lower right of FIG.

  Next, a rubber cup was attached to the contra and the hydroxyapatite (dental dedicated linamel PMTC final finishing paste) was applied to the tooth surface after cleaning with purified water at 750 rpm for about 30 seconds. A photograph of a state in which hydroxyapatite is applied with a rubber cup attached to the contra is shown in the upper left of FIG. Thereafter, the hydroxyapatite is lightly rinsed with purified water, and then phosphorylated oligosaccharide calcium-containing powder (prepared according to Example 1 of JP-A-8-104696; carbohydrate about 80%, Ca content about 5%) about 0.5 g Was sprinkled over the entire front surface of the teeth including the depression and left lightly wet with purified water for about 15 minutes. When the phosphorylated oligosaccharide calcium-containing powder is dissolved in a small amount of water, it becomes a viscous liquid, so that the tooth surface is packed. When the phosphorylated oligosaccharide calcium-containing powder and purified water are used on the hydroxyapatite-coated surface, the viscosity specific to the phosphorylated oligosaccharide calcium solution is exerted, and the hydroxyapatite is detached and hardly flows out. Furthermore, calcium ions are gradually released from phosphorylated oligosaccharide calcium and calcified with hydroxyapatite.

  A series of treatments from treatment with this organic solubilizer to treatment with powder containing phosphorylated oligosaccharide calcium was performed about once every two weeks. This patient was prescribed a phosphorylated oligosaccharide calcium-containing gum (poscam; manufactured by Ezaki Glico), and continued to chew two gums at a time after meals and whenever appropriate for home care. . The upper right photograph in FIG. 7 shows the treatment before the second treatment in the series of treatment from the treatment with the organic lysing agent to the treatment with the powder containing phosphorylated oligosaccharide calcium, and the lower left photograph in FIG. 7 shows the figure after the third treatment. 7 The lower right photo shows the state after the fourth treatment.

  A photograph of the tooth surface before the first treatment is shown in the upper left of FIG. 8, and a photograph of the tooth surface taken about two weeks after the first treatment (before the second treatment) is shown in the upper right of FIG. A photograph of the tooth surface taken about 4 weeks after treatment (immediately after the third treatment) is shown in the lower left of FIG. 8, and about 6 weeks after the first treatment (immediately after the fourth treatment). The photograph which image | photographed the tooth surface is shown in the lower right of FIG. These photographs are photographs in which colors (black and white) (that is, photographs at the upper left of FIG. 6, the upper right of FIG. 7, the lower left of FIG. 7, and the lower right of FIG. 7) are reversed in order to make the depressed portion easy to see. As can be seen from a comparison between the upper left photograph in FIG. 8 and the lower right photograph in FIG. 8, the depressed portion was hardly noticeable after about 6 weeks. That is, the C1 stage enamel parenchyma defect was repaired. This is very surprising from a dentistry point of view. This is because the conventional common sense of dentistry could not treat caries with substantial defects unless it was filled with an artificial material such as a resin. Since hydroxyapatite is almost the same material as the composition of human teeth, the portion treated with the present invention and where the depression is buried cannot be integrated with the original tooth and cannot be distinguished, and does not cause allergies. This is very beneficial for health.

  Thus, it has been found that treatment with hydroxyapatite and phosphorylated oligosaccharide calcium is effective for repairing mild parenchymal defects.

  Furthermore, this tooth surface was restored to the cloudy part of the upper left central incisor of the same patient. In this case, the surface layer of the upper left central incisor was highly remineralized and it was difficult to approach the subsurface demineralized area, so the minimum cutting and phosphoric acid etching of only the outermost layer was performed. is there. A photograph before the treatment of the upper left central incisor after the treatment of the depressed portion is shown in the upper left of FIG. First, the outermost layer of the upper left middle incisor was deleted by polishing. A photograph of the tooth surface after the outermost layer is deleted is shown in the upper right of FIG. Next, phosphoric acid etching was performed by applying a 40% normal phosphoric acid aqueous solution to the upper left central incisor and leaving it for about 5 seconds. As a result, the enamel surface was decalcified and the cut pieces (smear layer) were removed, resulting in a rough surface. A photograph of the tooth surface after phosphoric acid etching is shown in the lower left of FIG. Next, an organic solubilizer (AD gel) was applied to the entire front surface of the left and right upper central incisors and allowed to act for one minute using a one-tuft brush. The photograph of the tooth surface which apply | coated the organic dissolving agent is shown in the lower right of FIG.

  Thereafter, the organic solubilizer was washed away with purified water, and the tooth surface was dried to prevent moisture. A photograph of the moisture-proof tooth surface is shown in the upper left of FIG. Next, a rubber cup was attached to the entire lip surface of the left and right upper central incisors, and a hydroxyapatite particle paste (dental dedicated linamel PMTC final finish paste) was applied at 750 rpm for about 30 seconds. A photograph taken with the hydroxyapatite particle paste applied to the lip of the upper left central incisor with a rubber cup attached to the contra is shown in the upper right of FIG. Thereafter, a paste of excess hydroxyapatite particles is wiped off, and a powder containing phosphorylated oligosaccharide calcium (prepared according to Example 1 of JP-A-8-104696; about 80% saccharide and about 5% Ca content) is further added thereto. .5 g was sprinkled and lightly wetted with purified water and left for about 15 minutes. Since the phosphorylated oligosaccharide calcium-containing powder dissolves in a small amount of water, it becomes a viscous liquid, so that the tooth surface is packed. The photograph which image | photographed the tooth surface of the state which is making this phosphorylated oligosaccharide calcium act is shown in the lower left of FIG. Thereafter, the tooth surface was washed away with purified water. This patient was prescribed a phosphorylated oligosaccharide calcium-containing gum (poscam; manufactured by Ezaki Glico), and continued to chew two gums at a time after meals and whenever appropriate for home care. . Two weeks later, a series of treatments from treatment with this organic solubilizer to treatment with phosphorylated oligosaccharide calcium-containing powder was repeated. A photograph of the tooth surface after the end of the series of treatments after 2 weeks is shown in the lower right of FIG.

  As a summary of these treatments, a photograph of the tooth surface before the treatment of the depressed portion of the upper right middle incisor and the whitened portion of the upper left middle incisor is shown in the upper left of FIG. 11, and the treatment of the depressed portion of the upper right middle incisor and the upper left middle A photograph of the tooth surface after the surface treatment of the incisor is shown in the lower right of FIG. Comparing these photographs, it can be seen that the depressed portion of the upper right central incisor is buried so cleanly that it is unknown where the depressed portion is, and has a smooth surface integrated with the surrounding portions. The vitiligo portion of the upper left central incisor was only slightly visible with a white portion on the periphery, resulting in a nearly normal tooth surface. Moreover, the coloring part of the upper left central incisor disappeared, and it became a glossy tooth surface. Thus, it has been found that treatment with hydroxyapatite and phosphorylated oligosaccharide calcium is effective for repairing a substantial defect by a biomaterial.

(Example 2: Synergistic effect of total care)
Both dental care and home care at home are important for dental health. It is important to tilt the demineralization and remineralization cycle that is constantly taking place in the oral cavity to the remineralization side, thereby providing care in a direction that promotes health.

  The photograph which image | photographed the tooth | gear of the 38-year-old woman from the front in the state which engaged the tooth before the treatment by a dentist is shown in the upper right of FIG. There is pigmentation on the tooth surface. For this tooth surface, an organic solubilizer (AD gel) is applied almost evenly over the entire tooth surface for 1 to 2 minutes using a one-tuft brush, washed with purified water, and then with purified water. After washing, a rubber cup was attached to the contra, and a hydroxyapatite paste (dental dedicated linamel PMTC final finishing paste) was applied at 750 rpm for about 30 seconds. After washing with purified water, it was instructed to chew 2 tablets 20 minutes of gum containing phosphorylated oligosaccharide calcium (Poscam; manufactured by Ezaki Glico) on the chair side.

  For professional care, professional mechanical toe screening, application of organic solubilizer, cleaning with purified water, application of hydroxyapatite paste, intake of phosphorylated oligosaccharide calcium-containing gum (poscam; manufactured by Ezaki Glico) in about one month Repeated once. In addition, self-care was based on the use of a non-abrasive nanoparticulate hydroxyapatite-containing dentifrice. Furthermore, a gum containing phosphorylated oligosaccharide calcium (poscam; manufactured by Ezaki Glico) was formulated, and chewing of this gum for 2 minutes was continued for 20 minutes after meals and whenever appropriate.

  A photograph taken from the front in the state after the first AD gel treatment is shown in the lower left of FIG. 12, and a photograph taken from the front in a state where the teeth are engaged before the treatment at the visit 3 months after the first treatment is shown in the right of FIG. Shown below.

  Similarly, FIG. 13 shows an enlarged photograph taken from the front with the teeth meshed before the treatment at the visit 3 months after the first treatment. The demineralized part was not seen, and the tooth surface shined smoothly. The original coloration of the tooth surface, which was the main complaint, was not seen, indicating that the tooth surface, to which contaminants do not adhere, can be acquired and maintained without using abrasives. That is, this indicates that the dental health has been maintained.

(Reference Example 5: In vitro “enamelization” of exposed dentin surface)
The root caries caused by gingival retraction caused by periodontal treatment, aging, and occlusion is one factor that accelerates the progression of dentinal tubules. As for hypersensitivity, the opening of dentinal tubules has been confirmed as a phenomenon. A preventive method for such exposed root surface has not been established, and it is a part where the systematic difference from enamel is strongly felt in clinical practice. Therefore, it is of great clinical significance to seal the dentin tubules of the exposed dentin surface layer and modify it to an apatite-rich surface layer (enamelization). So far, the present inventors have devised a tooth surface restoration care using a nanoparticulate hydroxyapatite (nanoHAP) -containing paste using an organic solubilizing agent for the purpose of suppressing decalcification of enamel and promoting remineralization, and clinically effective. I have examined the sex. In the present example, if applying dental restoration with a nanoparticle hydroxyapatite (nanoHAP) -containing paste to which an organic solubilizing agent is applied to dentin, acquisition of resistance to root caries and an effect of suppressing hypersensitivity can be expected. The possibility was examined by a test using human extracted teeth.

  Using human extracted teeth stored in physiological saline, the dentin outermost layer was excised with a microcutter (ISOMET Buhler) so that the samples were parallel. For dental restoration using nano-particle hydroxyapatite (nanoHAP) containing organic solubilizer, apply organic solubilizer “AD Gel” (Kuraray Medical), act for 2 minutes using a one-tuft brush, and then use distilled water. Washed with. Furthermore, a nano-HAP-containing paste “dental-use linamel PMTC final finishing paste” (Sangi) was applied to the dentin surface treated with AD gel, and a rubber cup was attached to the PMTC-dedicated contra and allowed to act at low speed (1000 rpm) for 20 seconds. Thereafter, it was washed with distilled water. The surface of each untreated, AD gel-treated, and linamel-treated sample was observed over time using SPM (Seiko Instruments), and the dentin shape (planar image, three-dimensional image, cross-sectional profile) and average surface roughness Was measured. Moreover, the sample for SEM observation was produced according to the conventional method, and the difference in the surface state by each process was observed using FE-SEM (HITACHI).

  As a result of SPM observation of the extracted tooth sample, the average surface roughness was temporarily increased by the AD gel treatment, but after the linamel treatment, it was improved as compared with the untreated case. In SEM observation, an opening of the dentinal tubule was observed in the untreated sample, but an image in which the dentinal tubule was uniformly sealed by the linamel process could be confirmed.

  From the above results, it is shown that AD gel treatment dissolves organic matter in and inside the dentinal tubules such as collagen and applies nanohydroxyapatite to block the dentinal tubules and modify them into an apatite-rich surface layer. It was done.

(Reference Example 6: Enamelization treatment of dentinal tubules in situ)
If this method is applied clinically to dentin, it can be expected to acquire resistance to root caries and suppress hypersensitivity. In this example, we examined the possibility of this in an in situ test (Masato Kato, Aizawa). Manami: Research on "enamelization" of exposed dentin surface, Journal of the Japan Dental Preservation Society 50 Autumn Special, 173, 2007).

  In the in situ test, a mandibular wisdom tooth (life tooth) scheduled for extraction was used, and the crown was cut smoothly with an air turbine under infiltration anesthesia. 40% phosphoric acid was allowed to act on the exposed dentin for 10 seconds to remove the smear layer and washed with purified water. Subsequently, AD gel and linamel were allowed to act in the same manner under moisture proofing, and then immediately extracted and stored in physiological saline. Thereafter, SEM observation of the sample was performed on the surface and the cut surface.

  In-situ experiments will be described. Under infiltration anesthesia, the crown was cut smoothly with an air turbine. Since a cut piece generated by cutting was clogged into the dentinal tubule and a smear layer was formed, 40% phosphoric acid was applied to the exposed dentin for 10 seconds to remove the smear layer and washed with purified water. Subsequently, an organic solubilizer (“AD gel”, manufactured by Kuraray Medical) was applied as a tooth surface restoration care in the same manner under moisture proof, allowed to act for 2 minutes using a one-tuft brush, and then washed with purified water. Next, a nanohydroxyapatite-containing paste (“dental-use linamel PMTC final finish paste”, made by Sangi) is applied to this exposed dentin, and a rubber cup is attached to the PMTC-dedicated contra, acting at low speed (1000 rpm) for 20 seconds. And then washed with purified water. After rinamel was acted and washed with purified water, the teeth were immediately extracted, and the teeth were stored in physiological saline.

  SEM observation was performed about the tooth extracted after treating in situ. SEM observation was performed on the surface and the fractured surface. Many dentinal tubules were confirmed to be filled with hydroxyapatite.

  As a result, in the SEM observation of the sample surface subjected to the in situ test, it was confirmed that the dentinal tubule was sealed and the surface was further coated with nanohydroxyapatite. In the observation of the fractured surface, it was also observed that nanohydroxyapatite penetrated several μm into the dentinal tubule.

  Therefore, in the in situ test as well, tooth surface restoration care dissolves the organic matter in and inside the dentinal tubules such as collagen, and seals the dentinal tubules with the action of nanohydroxyapatite to form an apatite-rich surface layer. It was suggested that this method is clinically useful in preventing root caries and suppressing hypersensitivity, which were difficult until now. Since nanohydroxyapatite is considered to be highly safe and suitable for continuous use, in actual clinical practice, there is a method that combines dental restoration as office care and self-care using an apatite preparation in a drug retainer. I think it is promising.

(Example 3: Inhibition of root caries 1)
An approach to root caries was performed to demonstrate the effectiveness of dental restoration care in the clinic. A photograph taken from the front with the teeth of a 41-year-old man engaged is shown in the upper left of FIG. Caries are formed on the root surfaces of the lower right first molar and second molar. A photograph of the lower right first molar and second molar taken from the side is shown in the upper middle of FIG. It can be seen that the root surface is discolored and caries are formed. An organic solubilizer (“AD gel”, manufactured by Kuraray Medical) was applied to the root surface portion, allowed to act for 2 minutes using a one-tuft brush, and then washed with purified water. A photograph of teeth in a state where an organic solubilizer is applied is shown in the upper right of FIG. After removal with purified water, a nanohydroxyapatite-containing paste ("final dental linamel PMTC final finishing paste", made by Sangi) is applied to this root surface, and a rubber cup is attached to the PMTC exclusive contra, and rotated at a low speed (1000 revolutions). After acting for 2 seconds, it was washed with purified water. A photograph of teeth in a state where a hydroxyapatite-containing paste is applied is shown in the lower left part of FIG. 14, after the hydroxyapatite-containing paste is applied and washed with purified water, the chair side gum containing phosphorylated oligosaccharide calcium (Poscam; manufactured by Ezaki Glico) was instructed to chew 2 grains for 20 minutes. In self-care, it was prescribed that a gum containing phosphorylated oligosaccharide calcium (poscam; manufactured by Ezaki Glico) was taken after each meal and as needed. Tooth surface restoration care was performed a total of 4 times, and a photograph of the teeth in the state after 9 months from the initial care is shown in the lower right of FIG. The hardness of the surface, which had been decalcified and softened by root caries, improved to such an extent that palpation did not make a difference with enamel, and a very smooth surface texture was obtained. From this, it was found that treatment with hydroxyapatite and phosphorylated oligosaccharide calcium is effective in suppressing root caries.

(Example 4: Inhibition of root caries 3)
Hereinafter, actual clinical examples will be described. Treated periodontal disease in a 50-year-old woman. A photograph of the teeth and gums taken from the front with the teeth engaged before periodontal treatment is shown in the upper left of FIG. You can see that the gums are red and swollen. After periodontal treatment, photographs of the teeth and gums taken from the front are shown in the lower right of FIG. 15 and the upper left of FIG. The swelling of the gums has become severe due to the swelling.

  After periodontal treatment, an organic solubilizer (“AD gel”, manufactured by Kuraray Medical) was applied to the root surface of the tooth, allowed to act for 2 minutes using a one-tuft brush, and then washed with purified water. A photograph of a tooth in a state where an organic solubilizer is applied is shown in the upper right part of FIG. 16, and a photograph of a state in which the teeth are washed with purified water after the organic solubilizer is applied is shown in the lower left part of FIG. . A photograph of the moisture-proof tooth after washing with purified water is shown in the lower right of FIG. Next, a nanohydroxyapatite-containing paste (“dental-use linamel PMTC final finish paste”, made by Sangi) is applied to this exposed dentin, and a rubber cup is attached to the PMTC-dedicated contra, acting at low speed (1000 rpm) for 20 seconds. And then washed with purified water. A photograph of the state in which the hydroxyapatite-containing paste is applied is shown in the upper left of FIG. 17 and the upper right of FIG. In the upper left photograph of FIG. 17, hydroxyapatite is applied to the tooth surface with a rubber cup, and in the upper right photograph of FIG. 17, hydroxyapatite is applied to the gap between the teeth with a rubber cone. A photograph showing a state after hydroxyapatite is washed with purified water is shown in the lower left of FIG. Thereafter, a drug retainer filled with a hydroxyapatite-containing paste was placed on the teeth and left for 5 minutes. The photograph which image | photographed the state which covered the drug retainer on the tooth | gear from the front is shown in the lower right of FIG. After that, it was washed with purified water, and then a phosphorylated oligosaccharide calcium 30% aqueous solution was allowed to act on each tooth root part sufficiently. Since the phosphorylated oligosaccharide calcium 30% aqueous solution is a viscous liquid, the tooth surface is in a packed state. A photograph showing the action of this 30% aqueous solution of phosphorylated oligosaccharide calcium is shown on the left of FIG. The photograph which image | photographed the tooth | gear after a treatment from the front is shown on the right of FIG. These treatments blocked the dentinal tubules on the root surface. As a result, the effect of suppressing hypersensitivity was recognized at the same time as preventing root caries. From this, it was found that treatment with hydroxyapatite and phosphorylated oligosaccharide calcium is effective in suppressing root caries.

(Example 5: Suppression of hypersensitivity)
The application to hypersensitivity was also examined. Hypersensitivity occurs when the dentin at the root of the tooth is exposed and external stimuli reach the pulp. The photograph which image | photographed the tooth | gear on the right side in the state which engaged the 28-year-old female patient with hypersensitivity is shown in FIG. It can be seen that the gum of the upper right first premolar retreats and the portion of the root portion where no enamel is present is exposed. An organic solubilizer (“AD gel”, manufactured by Kuraray Medical) was applied to this patient, allowed to act for 2 minutes using a one-tuft brush, and then washed with purified water. Next, a nano-hydroxyapatite-containing paste (“dental-use linamel PMTC final finish paste”, made by Sangi) is applied to the exposed dentin, and a rubber cup is attached to the PMTC-dedicated contra, acting at low speed (1000 rpm) for 20 seconds. And then washed with purified water. After that, it was washed with purified water, and then allowed to sufficiently spread over the tooth root of a 30% aqueous solution of phosphorylated oligosaccharide calcium. Since the phosphorylated oligosaccharide calcium 30% aqueous solution is a viscous liquid, the tooth surface is in a packed state. In self-care, it was prescribed that a gum containing phosphorylated oligosaccharide calcium (poscam; manufactured by Ezaki Glico) was taken after each meal and as needed. It was instructed to use only the dentifrice containing nanoparticulate hydroxyapatite. The patient no longer felt hypersensitive at the visit 2 weeks later. From this, it was found that treatment with hydroxyapatite and phosphorylated oligosaccharide calcium is effective in suppressing hypersensitivity.

  As mentioned above, although this invention has been illustrated using preferable embodiment of this invention, this invention should not be limited and limited to this embodiment. It is understood that the scope of the present invention should be construed only by the claims. It is understood that those skilled in the art can implement an equivalent range based on the description of the present invention and the common general technical knowledge from the description of specific preferred embodiments of the present invention. Patents, patent applications, and documents cited herein should be incorporated by reference in their entirety, as if the contents themselves were specifically described herein. Understood.

  The present invention can be applied as a dental material. Examples of such dental materials can be used for temporary sealing materials; back layer materials; root filling materials; hypersensitivity suppression materials; surgical packs; The temporary sealing material is used for temporarily filling a hole when cutting teeth, for example. The back layer material is used, for example, for filling the inside of the thinned tooth from the inside. For example, the root filler is used as a material for filling the root after taking a nerve in order to prevent the strength of the teeth from decreasing. Surgical packs are used, for example, to protect the surgical site with something like gum after periodontal disease surgery. The present invention can also be used as a hypersensitivity inhibitor; pH control (drug); According to the present invention, a filling effect of substantial defects other than the composite resin can be obtained. By using the kit of the present invention, it is possible to repair and prevent mild caries by taking care of teeth not only at the dental clinic but also at home, and enamelling the root dentin. Can be used to prevent root caries and suppress hypersensitivity.

FIG. 1 shows a cross-sectional photograph of bovine teeth that have undergone subsurface demineralization. FIG. 2 is a photograph showing the merits and demerits of high concentration fluorine application. The left of FIG. 2 is a photograph taken from the front with the teeth engaged, and the right of FIG. 2 is an enlarged photograph of the upper left and right canines. In these photographs, a state where only the surface layer is highly remineralized by fluorine application and the white color inside remains in a band shape on the tooth surface of the upper left and right central incisors close to the gums. It is a photograph of the front teeth (upper right and left central incisors) of a 6-year-old man in the eruption period. The left photograph in FIG. 3 is a pre-operative photograph, and the right photograph in FIG. 3 is a tooth after cleaning with a hand brush, applying an organic dissolving agent for 1 to 2 minutes, and washing with purified water. It is a picture of the surface. The upper left photograph in FIG. 4 is a photograph taken from the front of the same male as in Reference Example 3 with the teeth meshed two months after the first treatment of the initial demineralized lesion. The photograph is a photograph taken from the front with the teeth meshed after 3 months from the first treatment of the initial demineralized lesion. The upper left of FIG. 5 shows the same male as in Reference Example 3 before surgery of the front teeth (upper left and right central incisors and lower left and right central incisors to side incisors) 9 months after Reference Example 3. This is the previous photo. The upper right of FIG. 5 is a photograph of the maxillary left and right central incisors after removal of organic matter by treatment with an organic dissolving agent. The lower center of FIG. 5 is a photograph of teeth taken from the front after chewing gum containing phosphorylated oligosaccharide calcium after hydroxyapatite treatment. The upper left photograph in FIG. 6 is a photograph showing the depression of the subsurface demineralized part in front of the upper right middle incisor of a 31-year-old man. The photograph on the upper right of FIG. 6 is a photograph of the tooth surface in a state where an organic dissolving agent is applied. The lower left photograph in FIG. 6 is a photograph of a state in which an organic solvent is applied using a one-tuft brush. The photograph on the lower right of FIG. 6 is a photograph of the tooth surface after washing with purified water and washing away the organic dissolving agent. The upper left photograph in FIG. 7 is a photograph of a state in which hydroxyapatite is applied with a brush with a rubber cup on the contra. The upper right photo in FIG. 7 is the state before the second implementation, the lower left photo in FIG. 7 is the third implementation, and the lower right photo in FIG. 7 is the fourth implementation. The upper left photograph in FIG. 8 is a photograph of a tooth surface of a 31-year-old male before the treatment of the depression of the subsurface demineralized portion in front of the upper right middle incisor. The upper right photograph in FIG. 8 is a photograph of the tooth surface taken about two weeks after the first treatment (before the second treatment). The lower left photograph in FIG. 8 is a photograph of the tooth surface taken approximately 4 weeks after the first treatment (immediately after the third treatment). The lower right photograph in FIG. 8 is a photograph of the tooth surface taken about 6 weeks after the first treatment (immediately after the fourth treatment). Note that these photographs are photographs in which colors (black and white) are reversed in order to make the depressed portion easy to see. The upper left photograph in FIG. 9 is a photograph of the upper left central incisor taken after the treatment of the depressed part of a 31-year-old man before the treatment. The upper right photograph in FIG. 9 is a photograph of the tooth surface after the outermost layer is deleted. The lower left photograph in FIG. 9 is a photograph of the tooth surface after phosphoric acid etching. The photograph on the lower right of FIG. 9 is a photograph of a tooth surface to which an organic dissolving agent has been applied. The photograph at the upper left of FIG. 10 is a photograph of a tooth surface that has been moisture-proof after washing away the organic removal agent. The upper right photograph in FIG. 10 is a photograph taken in a state where the paste of hydroxyapatite particles is applied with a rubber cup on the lip of the upper left central incisor and applied with a brush. The lower left photograph in FIG. 10 is a photograph of the tooth surface in a state where phosphorylated oligosaccharide calcium is acting. The lower right photograph of FIG. 10 is a photograph of the tooth surface taken after the end of a series of treatments after 2 weeks. The upper left photograph of FIG. 11 is a photograph of the tooth surface of a 31-year-old male before the treatment of the depressed portion of the upper right middle incisor and the whitened portion of the upper left middle incisor. The lower right photograph in FIG. 11 is a photograph of the tooth surface after the treatment of the depressed portion of the upper right middle incisor and the surface treatment of the upper left middle incisor. The photograph on the upper right of FIG. 12 is a photograph of the teeth of a 38 year old woman taken from the front with the teeth engaged before treatment by the dentist. The photograph on the lower left of FIG. 12 is a photograph taken from the front after the initial AD gel treatment. The photograph on the lower right of FIG. 12 is a photograph taken from the front with the teeth engaged before the visit treatment at 3 months after the first treatment. FIG. 13 is a photograph taken from the front with the teeth engaged before the visit treatment at 3 months after the first treatment. The upper left photograph in FIG. 14 is a photograph taken from the front with the teeth of a 41-year-old man engaged. The upper middle photograph in FIG. 14 is a photograph of the lower right first molar and second molar taken from the side. The upper right photograph in FIG. 14 is a photograph of a tooth in a state where an organic solubilizer is applied. The lower left photograph in FIG. 14 is a photograph of a tooth in a state where a hydroxyapatite-containing paste is applied. The photograph on the lower right of FIG. 14 is a photograph of the teeth in a state where nine months have passed since the initial care after tooth surface restoration care was performed a total of four times. The upper left photograph in FIG. 15 is a photograph of teeth and gums taken from the front before periodontal disease treatment. The photograph on the lower right in FIG. 15 is a photograph of the teeth and gums taken from the front with the teeth engaged after periodontal treatment. The upper left photograph in FIG. 16 is a photograph of the teeth and gums taken from the front after periodontal treatment. The upper right photograph in FIG. 16 is a photograph of a tooth in a state where an organic dissolving agent is applied. The photograph on the lower left of FIG. 16 is a photograph of a state in which teeth are washed with purified water after an organic dissolving agent is applied. The lower right photograph in FIG. 16 is a photograph of the moisture-proof tooth after washing. The upper left and upper right photographs in FIG. 17 are photographs in a state where the hydroxyapatite-containing paste is acting. In the upper left photo of FIG. 17, hydroxyapatite is applied to the tooth surface with a large rubber cup, and in the upper right photo of FIG. 17, hydroxyapatite is applied to the gap portion between the teeth with a smaller rubber cup. . The lower left photograph of FIG. 17 is a photograph showing a state after hydroxyapatite is washed with purified water. The photograph on the lower right in FIG. 17 is a photograph taken from the front of the state where the drug retainer is placed on the teeth. The left photograph of FIG. 18 is a photograph showing a 30% aqueous solution of phosphorylated oligosaccharide calcium. The right photograph in FIG. 18 is a photograph of the treated tooth taken from the front. FIG. 19 is a photograph of the right tooth taken with a 28-year-old female patient with hypersensitivity engaged.

Claims (13)

A kit for treating a caries defect , the kit comprising:
(1) a hydroxyapatite particle-containing composition and (2) a phosphorylated saccharide calcium-containing composition, wherein the caries is selected from the group consisting of C1 or C2 caries and root caries, A kit wherein calcium is composed of a sugar moiety and a phosphate salt calcium salt, the sugar moiety is a glucan having a polymerization degree of 2 to 8, and the number of phosphate groups is 1 to 2.   (I) filling the hydroxyapatite particle-containing composition into a defect portion due to dental caries and then applying the phosphorylated saccharide calcium-containing composition to the filling portion; or (ii) the defect portion due to dental caries The kit according to claim 1, wherein the mixture is filled with the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition.   (3) The kit according to claim 1, further comprising an organic dissolving agent.   The organic dissolution agent is applied to the defect part due to dental caries to remove the organic substance of the defect part to expose the surface of the tooth defect part, and then (i) the exposed defect part contains the hydroxyapatite particles The composition is filled, and then the phosphorylated saccharide calcium-containing composition is applied to the filled portion, or (ii) the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition in the exposed defect portion The kit according to claim 1, wherein the kit is filled with a mixture. A composition for treating a caries defect part, comprising hydroxyapatite particles and phosphorylated saccharide calcium, wherein the caries is selected from the group consisting of C1 or C2 stage caries and root caries, and the phosphorylated saccharide calcium Is a glucan having a degree of polymerization of 2 to 8 and a number of the phosphate groups of 1 to 2 consisting of a sugar moiety and a calcium salt of a phosphate group.   The composition according to claim 5, wherein the composition is in powder form. A kit for enamel care when a tooth enamel is damaged, the kit comprising (1) a hydroxyapatite particle-containing composition and (2) a phosphorylated saccharide calcium-containing composition, Phosphorylated sugar calcium is composed of a sugar moiety and a calcium salt of a phosphate group, the sugar moiety is a glucan having a polymerization degree of 2 to 8, and the number of phosphate groups is 1 to 2,
(I) applying the hydroxyapatite particle-containing composition to the damaged portion and then applying the phosphorylated saccharide calcium-containing composition to the portion; or
(Ii) applying a mixture of the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition to the damaged part ;
A kit wherein the damage is caused by debonding, whitening, professional mechanical toe screening, polishing or orthodontic treatment . A composition for enamel care when dental enamel is damaged, the composition comprising hydroxyapatite particles and phosphorylated saccharide calcium, wherein the phosphorylated saccharide calcium comprises a saccharide moiety and a phosphate group. consists of calcium salts with a glucan in the sugar moiety polymerization degree 2 to 8, the number of the phosphate group is 1-2 Kodea is, the injury is, debonding, whitening, professional mechanical Two screening, A composition that is caused by polishing or orthodontic treatment . A kit for enamelling the exposed root surface of a tooth, the kit comprising:
(1) a hydroxyapatite particle-containing composition and (2) a phosphorylated saccharide calcium-containing composition, wherein the phosphorylated saccharide calcium comprises a saccharide moiety and a calcium salt of a phosphate group, and the saccharide moiety is polymerized A glucan having a degree of 2 to 8, the number of the phosphate groups being 1 to 2,
(I) applying the hydroxyapatite particle-containing composition to an exposed root surface of a tooth and then applying the phosphorylated saccharide calcium-containing composition to the root surface, or
(Ii) A kit for applying a mixture of the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition to an exposed root surface of a tooth.   A composition for enamelling the exposed root surface of a tooth, the composition comprising hydroxyapatite particles and phosphorylated sugar calcium, wherein the phosphorylated sugar calcium is a calcium salt of a sugar moiety and a phosphate group A composition in which the sugar moiety is a glucan having a degree of polymerization of 2 to 8, and the number of phosphate groups is 1 to 2. A kit for treating hypersensitivity, the kit comprising:
(1) a hydroxyapatite particle-containing composition and (2) a phosphorylated saccharide calcium-containing composition, wherein the phosphorylated saccharide calcium comprises a saccharide moiety and a calcium salt of a phosphate group, and the saccharide moiety is polymerized A glucan having a degree of 2 to 8, the number of the phosphate groups being 1 to 2,
(I) applying the hydroxyapatite particle-containing composition to a tooth-sensitive surface and then applying the phosphorylated saccharide calcium-containing composition to the surface; or
(Ii) A kit for applying a mixture of the hydroxyapatite particle-containing composition and the phosphorylated saccharide calcium-containing composition to a hypersensitive surface of a tooth.   A composition for treating hypersensitivity, the composition comprising hydroxyapatite particles and phosphorylated saccharide calcium, the phosphorylated saccharide calcium comprising a saccharide moiety and a phosphate salt calcium salt, wherein the saccharide moiety comprises A composition having a polymerization degree of 2 to 8 and having 1 to 2 phosphate groups. A dentifrice for treating a caries defect , the dentifrice comprising hydroxyapatite particles and phosphorylated saccharide calcium, wherein the caries is selected from the group consisting of C1 or C2 stage caries and root caries, A dentifrice wherein the phosphorylated saccharide calcium comprises a sugar moiety and a calcium salt of a phosphate group, the sugar moiety is a glucan having a polymerization degree of 2 to 8, and the number of phosphate groups is 1 to 2 .