JP5442414B2 - Cutting training model teeth - Google Patents

Description

  The present invention relates to a cutting training model tooth. More specifically, the present invention relates to a cutting training model tooth that can be suitably used for dental practice of a student majoring in dentistry.

  As a cutting training model tooth used for dental practice of a student majoring in dentistry, a tooth made of melamine resin is widely used. Recently, several studies have been conducted to bring the cutting feeling of cutting training model teeth closer to that of natural teeth. For example, in Patent Document 1, the cutting training model tooth composition is made of an alumina-based, zirconia-based, gypsum-based, or silica-based material, and the cutting feeling of the cutting training model tooth is brought close to the cutting feeling of a natural tooth. Has been proposed.

  In addition, in order to bring the cutting feeling of the cutting training model tooth closer to the cutting feeling of the natural tooth, a cutting training model tooth having a two-layer structure consisting of a dentin inner layer and an enamel surface layer as well as a natural tooth has been proposed. . For example, in Patent Document 2, an alumina powder having an average particle diameter of 1 to 8 μm is kneaded with a binder and injection-molded to prepare a dentin part, and then an alumina powder having an average particle diameter of 1 to 8 μm is kneaded with a binder. There has been proposed a method of producing a model tooth for cutting training having a two-layer structure by a multilayer molding method in which an enamel part is produced by injection molding.

JP 2006-163330 A JP 2007-31840 A

  When the cutting training model teeth are used for cutting training, the powder of the material constituting the cutting training model teeth may scatter and the cutting training worker may inhale this powder. Therefore, it can be said that it is desirable to use a safe material that does not pose a risk to health even if it enters the human body as the material constituting the cutting training model tooth.

  However, a material that is currently used for cutting training model teeth that is currently widely used is a melamine resin that has been pointed out to be carcinogenic. Therefore, if this cutting training model tooth is subjected to cutting training, there is a risk of harming the health of the cutting training worker.

  The materials used for the cutting training model teeth proposed in Patent Document 1 and Patent Document 2 are also alumina-based, zirconia-based, gypsum-based, and silica-based minerals whose dust can cause pneumoconiosis. Material. Therefore, even when this cutting training model tooth is used for cutting training, the risk of harming the health of the cutting training worker cannot be completely denied.

  Therefore, there is a demand for a cutting training model tooth that can provide a cutting feeling close to that of a natural tooth while using a safe material that does not pose a risk to health even if it enters the human body.

  Further, in the model tooth for cutting training proposed in Patent Document 2, when the timing of injection molding of the enamel portion of the surface layer after the injection molding of the dentin portion is delayed, the molded body is denatured and internal stress is reduced. There is a problem that peeling or chipping is likely to occur over time (see paragraph [0029] of Patent Document 2). In this way, when the joint between the surface enamel part and the inner dentin part is peeled off or chipping is likely to occur, during the cutting, during the transition from the enamel part to the dentin part A sense of incongruity occurs and a real cutting feeling cannot be obtained.

  The present invention has been made in view of such problems, and it is close to natural teeth while using a safe material that does not harm health even if a student who performs cutting training inhales powder scattered by cutting. It aims at providing the model tooth for cutting training from which cutting feeling is obtained.

  In addition, the present invention provides a two-layered model tooth for cutting practice that can obtain a cutting feeling closer to natural teeth while using a safe material that does not harm health even if a student who performs cutting practice inhales. The purpose is to do.

  In order to solve this problem, the inventors of the present application have made extensive studies, and by using casein, which is a protein derived from milk that is harmless to the human body, it is safe without harming health even if students who perform cutting training inhale. I thought it was possible to secure the sex.

  Therefore, as a result of further studies by the inventors of the present application, it has been found that a cutting feel similar to natural teeth can be obtained by using a casein resin as a main component of a cutting training model tooth. Over time, the present invention has been completed.

  That is, the cutting training model tooth of the present invention is mainly composed of casein resin.

  Here, in the cutting training model tooth of the present invention, it is preferable that the Shore hardness D is in the range of 74 to 86. In this case, the hardness of the cutting training model tooth can be matched with the hardness of the natural tooth enamel, and the natural tooth enamel cutting feeling can be easily obtained.

  In the cutting training model tooth of the present invention, it is preferable that the Shore hardness D is in the range of 55 to 73. In this case, the hardness of the cutting training model tooth can be matched with the hardness of the dentin of the natural tooth, and the cutting feeling of the dentin of the natural tooth can be easily obtained.

  Furthermore, it is preferable that the white pigment is dispersed in the cutting training model tooth of the present invention. By dispersing the white pigment, it becomes a realistic cutting training model tooth whose appearance is approximated to a natural tooth by setting the cutting training model tooth color to be close to the color of the natural tooth.

In the cutting training model tooth of the present invention, the white pigment is preferably titanium oxide (TiO ₂ ). Titanium oxide has no toxicity to the human body, and even if the powder is inhaled, it does not harm health. Therefore, the cutting training model tooth color is close to that of natural teeth, and the appearance of the cutting training model tooth is realistic, while ensuring the safety of the cutting training model tooth to the human body. be able to.

  Further, in the cutting training model tooth of the present invention, the white pigment is preferably contained in an amount of 0.1 to 0.5% by weight. When white pigments are included in this range, combined with the ivory color of the cutting training model teeth when no white pigments are added, the appearance is more closely approximated to natural teeth, as it is very close to natural teeth. Can be very realistic.

  Here, it is preferable that the cutting training model tooth of the present invention is made of only casein resin or only made of casein resin and white pigment.

  Next, the inventors of the present application examined a two-layer structure model tooth for cutting training. As a result, similar to natural teeth, the two-layered cutting training model tooth whose surface layer hardness is higher than the inner layer hardness gives a cutting feeling closer to natural teeth, and the two-layer structure is formed of casein resin. As a result, it has been found that safety to the human body can be secured. Accordingly, the inventors of the present application have made various studies and completed the present invention.

  That is, the model tooth for cutting training of the two-layer structure of the present invention includes a dentin portion mainly composed of the first casein resin and an enamel mainly composed of the second casein resin having a hardness higher than that of the first casein resin. Part.

  Here, in the model tooth for cutting training of the two-layer structure of the present invention, it is preferable that the shore hardness D of the dentin part is in the range of 55 to 73, and the shore hardness D of the enamel part is in the range of 74 to 86. It is preferable to be within. In this case, the hardness of the enamel portion of the surface layer can be matched with the hardness of the enamel of the natural tooth, and further the hardness of the dentin portion of the inner layer can be matched with the hardness of the dentin of the natural tooth. . Therefore, the cutting feeling of the two-layer structured cutting training model tooth can be made very close to the cutting feeling of the natural tooth, and a realistic cutting feeling like a natural tooth can be obtained.

  In the two-layer cutting training model tooth of the present invention, it is preferable that a white pigment is dispersed at least in the enamel portion. A real pigment that has a white-colored pigment dispersed in the enamel part, bringing the color of the enamel part of the surface layer of the model tooth for cutting training with a two-layer structure closer to that of natural teeth, and approximating the appearance to natural teeth Can be obtained. The white pigment may be dispersed not only in the enamel part but also in the dentin part.

Furthermore, in the two-layer structured cutting training tooth of the present invention, the white pigment is preferably titanium oxide (TiO ₂ ). Titanium oxide has no toxicity to the human body, and even if the powder is inhaled, it does not harm health. Therefore, the color of the tooth model for cutting training with a two-layer structure is made close to the color of the natural tooth, and the appearance of the model tooth for cutting training is realistic, but the safety of the cutting training model tooth to the human body is improved. It can be secured sufficiently.

  Further, in the model tooth for cutting training having a two-layer structure of the present invention, it is preferable that the white pigment is contained in an amount of 0.1 to 0.5% by weight. When white pigments are included in this range, combined with the ivory color of the cutting training model teeth when no white pigments are added, the appearance is more closely approximated to natural teeth, as it is very close to natural teeth. Can be very realistic.

  Here, the model tooth for cutting training of the two-layer structure of the present invention, it is preferable that the dentin portion is made of only the first casein resin, and the enamel portion is made of only the second casein resin, or It is preferable to consist only of the second casein resin and the white pigment.

  According to the cutting training model tooth of the present invention, even if a student or the like performing cutting training sucks powder scattered by cutting, it is safe without harming health and can give a cutting feeling close to natural teeth.

  Further, according to the model tooth for cutting practice of the two-layer structure of the present invention, it is safe without harming the health even if the student who performs the cutting practice sucks the powder scattered by the cutting, and the cutting feeling closer to the natural tooth. Can be given.

It is a figure which shows the relationship between the particle size of casein powder, and the hardness of the model tooth for cutting training. It is a figure which shows the influence on the hardness of the model tooth for cutting training by addition of a titanium oxide. It is a photograph of the model tooth for cutting training of the present invention. It is a photograph (cross section) of the model tooth for cutting training of the two-layer structure of the present invention.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.

<Model tooth for cutting training of single layer structure>
The single-layer cutting training model tooth according to the present invention is characterized by containing casein resin as a main component.

  By making the cutting training model teeth based on casein resin, the cutting training model teeth have a hardness close to that of natural teeth, and the cutting feeling of the cutting training model teeth is close to that of natural teeth. Can be. Moreover, casein is a kind of protein derived from milk, and is a substance that is harmless to the human body. Therefore, there is no risk of health damage due to powder scattered by cutting, and it is extremely safe.

  The method for producing the casein resin is not particularly limited, and a known or new method can be adopted. However, the casein powder is mixed with water, and the resulting molded product is crosslinked by heating and pressing. It is particularly preferred to process. In this case, the hardness of the casein resin can be controlled by adjusting the particle size of the casein powder. Therefore, the hardness of the cutting training model tooth can be controlled to be close to or match the hardness of the natural tooth, and the cutting feeling of the cutting training model tooth can be easily approximated to the cutting feeling of the natural tooth.

  For example, by setting the particle size of the casein powder to 50 μm to 1000 μm, preferably 70 μm to 800 μm, more preferably 100 μm to 600 μm, the hardness of the model teeth for cutting training is made to be the hardness of natural teeth (Shore hardness D55 to 86). It becomes easier to approach or match. In addition, if the particle size of the casein powder is increased, the hardness of the cutting training model teeth decreases. Conversely, if the particle size of the casein powder is reduced, the hardness of the cutting training model teeth increases.

  Here, by assuming that the Shore hardness D of the casein resin is in the range of 74 to 86, the hardness of the model tooth for cutting training is made to match the hardness of the enamel which is the surface layer of the natural tooth, for cutting training. The cutting feeling of the model tooth can be brought close to the cutting feeling of the surface layer of the natural tooth. Specifically, for example, the particle size of the casein powder may be a maximum of 355 μm, preferably 80 μm to 355 μm, more preferably a maximum of 100 μm, and even more preferably 80 μm to 100 μm.

  Further, by setting the Shore hardness D of the casein resin within the range of 55 to 73, the hardness of the cutting training model tooth is made to coincide with the hardness of the dentin which is the inner layer of the natural tooth, and the cutting training model The cutting feeling of the teeth can be brought close to the cutting feeling of the inner layer of the natural tooth. Specifically, for example, the minimum particle size of the casein powder is preferably more than 355 μm, more preferably 600 μm, and even more preferably more than 600 μm. The maximum particle size is preferably 1000 μm, and more preferably 800 μm.

  Here, it is preferable that white pigments such as white and milky white are dispersed in the cutting training model teeth. Since the casein resin is ivory color, the white pigment is dispersed in the cutting training model tooth, and in combination with the ivory color of the casein resin, the cutting training model tooth color is close to natural teeth. It can be adjusted to extremely realistic colors.

As the white pigment, known or novel various substances can be dispersed, but it is preferable to disperse a substance harmless to the human body. For example, an industrial white pigment can be dispersed, and in particular, titanium oxide (TiO ₂ ) can be suitably dispersed.

  If the amount of the white pigment is too large, the color of the cutting training model tooth will become too white and away from the color of the natural tooth, and the hardness of the cutting training model tooth will decrease and away from the cutting feeling of the natural tooth. May end up. If the amount is too small, the cutting training model teeth may not be as white as natural teeth. Therefore, the content of the white pigment in the casein resin may be, for example, 0.1 to 1.0% by weight, preferably 0.1 to 0.5% by weight.

In particular, casein produced from casein powder having a maximum particle size of 355 μm by setting the white pigment to titanium oxide (TiO ₂ ) and the content of the white pigment in the casein resin to 0.1 to 0.5% by weight. The effect of increasing the hardness of the resin to easily match the hardness of the enamel of the natural tooth is obtained.

  The cutting training model tooth of the present invention is essentially preferably made of casein resin or casein resin and a white pigment. That is, it is preferable that the casein resin alone or only the casein resin and the white pigment is included, but unintentional impurities are allowed to be mixed. In addition, other substances may be intentionally mixed within a range that does not impair the safety of the cutting training model teeth. For example, a substance other than the casein resin (for example, a resin other than the casein resin) may be intentionally mixed to adjust the hardness or may be colored.

  Hereinafter, although an example of the manufacturing method of the model tooth for cutting training of the single layer structure of this invention is demonstrated, the manufacturing method of the model tooth for cutting training of the single layer structure of this invention is not limited to the following method.

<Making method of model tooth for cutting training of single layer structure>
The single-layered cutting training model tooth can be produced by the following steps A1 to A4.
Step A1: A step of preparing a mixture mainly composed of casein powder and water,
Step A2: Packing the mixture in a tooth mold and heating and pressing to obtain a molded body,
Step A3: Step of crosslinking the molded body, and Step A4: Step of drying the molded body after the crosslinking treatment

  In step A1, a mixture mainly composed of casein powder and water is prepared.

  The particle size of the casein powder is adjusted as described above according to the desired hardness of the cutting training model teeth.

  If the amount of water added to the casein powder is too large, the dimensions are likely to change after molding due to the influence of sink marks. On the other hand, if the amount is too small, it is difficult to solidify and it is difficult to obtain a molded product. Therefore, for example, water may be added so that the water content of the casein powder is 17.5 wt% to 32.5 wt%, preferably 25 wt%.

  When the white pigment is dispersed in the casein resin, the white pigment is added to the casein powder in Step A1.

  In addition, it is preferable that the mixture prepared in process A1 consists essentially of casein powder and water or casein powder, water and a white pigment. That is, it is preferable to consist only of casein powder and water, or only casein powder and water and a white pigment, but unintentional mixing of impurities and the like is allowed. Moreover, you may make it mix intentionally with another substance in the range which does not impair the safety | security of the produced cutting training model tooth.

  Next, in step A2, the tooth mold is filled with the mixture obtained in step A1, and heated and pressurized to produce a molded body.

  As the tooth mold, one having a shape capable of pressurizing the mixture filled in the mold can be used as appropriate. For example, one having a shape capable of pressurizing from a portion not corresponding to the crown portion is used. it can. Moreover, as a material, the heat conductive material which can heat the filled mixture through a type | mold, for example, the thing made from prehardened steel (NAK55) can be used. Further, a split mold may be used. In this case, mold release becomes easy.

  The mixture filled in the mold may be heated by warming the mold to a desired heating temperature and then filling the mixture into the mold, or heating the mold after filling the mixture into the mold. Heating may be performed at a desired heating temperature.

  When the heating temperature of the mixture filled in the mold exceeds 100 ° C, casein itself is decomposed, and therefore, the heating temperature is preferably 100 ° C or less. On the other hand, if the heating temperature is too low, it will not harden and it will be difficult to form a compact. Therefore, for example, the mold may be heated at a temperature of 50 to 100 ° C., preferably 75 ° C.

  The heating time varies depending on the heating temperature, but may be about 3 minutes, for example.

If the applied pressure of the mixture filled in the mold is too low, air holes remain in the molded body and the hardness tends to decrease. When the applied pressure is too high, the molded body itself is not particularly affected, but energy used for pressurization is wasted. Thus, for ^{example, 200kg / cm 2 ~400kg / cm} 2, preferably may be set to 300 kg / cm ^2.

  The mixture filled in the mold may be heated before pressurization, may be performed during pressurization, or may be performed after pressurization. In order to shorten the length, it is preferable to heat during pressurization, and it is more preferable to heat before pressurization. In addition, it is preferable that the time required for producing the molded body can be further shortened by applying pressure after the mold is preheated and the mixture is packed in the mold.

  After the heating and pressurization are completed, the molded body is removed from the mold and used for the next step A3.

  In step A3, the molded body obtained in step A2 is subjected to crosslinking treatment.

  The crosslinking treatment is performed by immersing the molded body in a crosslinking solution. As the crosslinking liquid, a known or novel one capable of crosslinking casein can be appropriately used. For example, a formalin solution can be used, and a 5-7% by volume formalin solution can be suitably used.

  The time required for the crosslinking treatment is determined by the crosslinking treatment ability of the crosslinking solution. For example, when 5-7% by volume formalin solution is used, the cross-linking reaction of casein proceeds approximately 1 mm per day, so in the case of a model tooth for a cutting practice of a general size, the cross-linking process is completed in approximately one week. Will do. In some cases, heating the cross-linking liquid can accelerate the cross-linking reaction and reduce the time required for the cross-linking treatment.

  Next, in step A4, the molded body after the crosslinking treatment is dried.

  The time required for the drying process is determined by the drying temperature and the volatility of the crosslinking liquid. For example, when a 5-7% by volume formalin solution is used as a crosslinking solution, moisture and formalin components are sufficiently removed in a time substantially equal to the time required for the crosslinking treatment in a room temperature environment.

  Through the above process, a model tooth for cutting training having a single layer structure can be produced.

<Model tooth for cutting training of two-layer structure>
The model tooth for cutting training of the two-layer structure of the present invention includes a dentin part mainly composed of the first casein resin, and an enamel part mainly composed of the second casein resin having a hardness higher than that of the first casein resin. It is characterized by comprising.

  By making the cutting training model teeth into two layers of casein resin as the main component, the hardness of the cutting training model teeth is close to that of natural teeth, and the cutting feeling of the cutting training model teeth is cut by natural teeth. It can be close to the feeling. Moreover, casein is a kind of protein derived from milk, and is a substance that is harmless to the human body. Therefore, there is no risk of health damage due to powder scattered by cutting, and it is extremely safe.

  The method for preparing the casein resin is not particularly limited, and a known or new method can be adopted. However, as in the case of a model tooth for a cutting training with a single layer structure, the casein powder is mixed with water. It is particularly preferable to subject the molded product obtained by heating and pressurizing to crosslinking. In this case, the hardness of the casein resin can be controlled by adjusting the particle size of the casein powder. Therefore, the hardness of the cutting training model tooth can be controlled to be close to or match the hardness of the natural tooth, and the cutting feeling of the cutting training model tooth can be easily approximated to the cutting feeling of the natural tooth.

  For example, by setting the particle size of the casein powder to 50 μm to 1000 μm, preferably 70 μm to 800 μm, and more preferably 100 μm to 600 μm, the hardness of the cutting training model teeth can be made close to that of natural teeth or easily matched.

  And, as the particle size of the casein powder is reduced, the hardness of the casein resin is improved, so that the dentin portion made of the first casein resin has a casein powder having a particle size larger than that of the casein powder for producing the second casein resin. Use to make. Conversely, the enamel portion made of the second casein resin uses a casein powder having a particle size smaller than that of the casein powder for producing the first casein resin. Thereby, the hardness of the first casein resin becomes smaller than the hardness of the second casein resin, and the relationship between the hardness of the dentin portion and the enamel portion of the natural tooth can be simulated.

  Here, by assuming that the Shore hardness D of the enamel part is in the range of 74 to 86, the hardness of the surface layer of the cutting training model tooth is matched with the hardness of the enamel which is the surface layer of the natural tooth, The cutting feeling of the cutting training model teeth can be brought close to the cutting feeling of natural teeth. Specifically, for example, the particle size of the casein powder may be a maximum of 355 μm, preferably 80 μm to 355 μm, more preferably a maximum of 100 μm, and even more preferably 80 μm to 100 μm.

  Further, by setting the shore hardness D of the dentin portion within the range of 55 to 73, the hardness of the inner layer of the model tooth for cutting training is made to coincide with the hardness of the dentin which is the surface layer of the natural tooth. The cutting feeling of the model tooth for training can be brought close to the cutting feeling of natural teeth. Specifically, for example, the particle size of the casein powder is preferably greater than 355 μm, more preferably 600 μm, and even more preferably greater than 600 μm. The maximum particle size is preferably 1000 μm, and more preferably 800 μm.

  Here, it is preferable that white pigments such as white and milky white are dispersed at least in the enamel portion. Since the casein resin has an ivory color, the color of the cutting training model tooth can be adjusted to an extremely realistic hue close to that of a natural tooth by dispersing the white pigment therein. It is sufficient that the white pigment is dispersed only in the enamel portion that mainly contributes to the appearance of the cutting training model tooth, but the white pigment may be dispersed in the dentin portion.

As the white pigment, known or novel various substances can be dispersed, but it is preferable to disperse a substance harmless to the human body. For example, an industrial white pigment can be dispersed, and in particular, titanium oxide (TiO ₂ ) can be suitably dispersed.

  If the amount of the white pigment is too large, the color of the cutting training model tooth will become too white and away from the color of the natural tooth, and the hardness of the cutting training model tooth will decrease and away from the cutting feeling of the natural tooth. May end up. If the amount is too small, the cutting training model teeth may not be as white as natural teeth. Therefore, the content of the white pigment in the casein resin may be, for example, 0.1 to 1.0% by weight, preferably 0.1 to 0.5% by weight.

In particular, the white pigment is titanium oxide (TiO ₂ ), and the white pigment content in the second casein resin is 0.1 to 0.5% by weight. The effect of increasing the hardness of the second casein resin to easily match the hardness of the enamel of the natural tooth is obtained.

  The model tooth for cutting practice of the two-layer structure of the present invention essentially has a dentin portion made of a first casein resin and an enamel portion made of a second casein resin, or a second casein. It is preferable to consist of resin and a white pigment. That is, it is preferable that the dentin part is composed of only the first casein resin, and the enamel part is composed of only the second casein resin or only the second casein resin and the white pigment. Impurities that are not allowed to enter are allowed. In addition, other substances may be intentionally mixed within a range that does not impair the safety of the cutting training model teeth. For example, for example, a substance other than the casein resin (for example, a resin other than the casein resin) may be intentionally mixed to adjust the hardness or may be colored.

  Hereinafter, an example of a method for producing a two-layered cutting training model tooth of the present invention will be described. However, the method of manufacturing a two-layered cutting training model tooth of the present invention is not limited to the following method. Absent.

<Method for producing model tooth for cutting training of two-layer structure>
A two-layered cutting training model tooth can be produced by the following steps B1 to B5.
Step B1: A step of preparing a first mixture mainly composed of first casein powder and water,
Step B2: a step of preparing a second mixture mainly composed of a second casein powder having a particle size smaller than that of the first casein powder and water,
Step B3: Step of filling the tooth mold with the second mixture and the first mixture in order and heating and pressing to obtain a molded body,
Step B4: Step of crosslinking the molded body and Step B5: Step of drying the molded body after the crosslinking treatment

  In step B1, a first mixture containing a first casein powder and water as main components is prepared. In Step B2, a second mixture mainly composed of a second casein powder having a particle size smaller than that of the first casein powder and water is prepared.

  The particle size of the casein powder is adjusted as described above according to the desired hardness of the cutting training model teeth. That is, the particle size of the first casein powder is adjusted so that the inner layer made of the first casein resin has a desired hardness, and the particle size of the second casein powder is adjusted so that the surface layer made of the second casein resin has the desired hardness.

  The amount of water to be added to the first casein powder and the amount of water to be added to the second casein powder are the same as in step A1 in the manufacturing method of the model tooth for cutting training having a single layer structure, and the description thereof will be omitted.

  Here, when the enamel part is colored white, a white pigment is added to the second casein powder. Since the color of model teeth for cutting training using casein powder as the raw material is ivory, the color of the surface layer of the model teeth for cutting training is adjusted to an extremely realistic shade similar to natural teeth by adding a white pigment. can do. It is sufficient to add the white pigment only to the second casein powder that mainly contributes to the appearance of the cutting training model teeth, but the white pigment is added to the first casein powder to make the inner layer white. You may color.

  The type and amount of the white pigment are the same as those in the step A1 in the method for producing the one-layer cutting training model tooth, and the description thereof is omitted.

  In addition, it is preferable that the 1st mixture prepared in process B1 consists essentially of 1st casein powder and water or 1st casein powder, water, and a white pigment. That is, it is preferable to consist only of casein powder and water, or only casein powder and water and a white pigment, but unintentional mixing of impurities and the like is allowed. Moreover, you may make it mix intentionally with another substance in the range which does not impair the safety | security of the produced cutting training model tooth. The same applies to the second mixture prepared in step B2.

  Next, in step B3, the tooth mixture is filled with the first mixture obtained in step B1 and the second mixture obtained in step B2, and heated and pressurized to produce a molded body.

  As for the tooth shape, the same one as in step A2 in the method for producing a model tooth for cutting training having a single layer structure can be used. Further, the heating method, the heating temperature, the heating time, the applied pressure, and the heating timing are the same as those in the step A2 in the method for producing the model tooth for cutting training having a single layer structure, and the description thereof is omitted.

  In step B3, the order in which the first mixture and the second mixture are packed is important. That is, by filling the tooth mold with the second mixture and then filling the first mixture, the surface layer is constituted by the second mixture and the inner layer is constituted by the first mixture. Thereby, the hardness of the surface layer is higher than the hardness of the inner layer, and a two-layer structure simulating natural teeth can be obtained. Furthermore, by adjusting the particle size of the first casein powder and the particle size of the second casein powder as described above, the hardness of the inner layer and the surface layer of the model tooth for cutting training are set to the hardness of the dentin of the inner layer of the natural tooth and the surface layer, respectively. The cutting feeling of the cutting training model teeth can be made very close to that of natural teeth by approaching or matching the hardness of the enamel.

  In Step B3, the first mixture and the second mixture can be integrally formed. That is, a two-layer structure can be easily formed by one heating and pressurization. Moreover, the adhesion between the surface layer and the inner layer is very good, and the surface layer and the inner layer do not peel off. Therefore, the cutting training model teeth can be easily manufactured with high yield.

  The molded body obtained in step B3 is subjected to a crosslinking treatment in step B4. In addition, the bridge | crosslinking process in process B4 is the same as that of process A3 in the manufacturing method of the model tooth for cutting training of a single layer structure, and abbreviate | omits description.

  Next, in step A4, the molded body after the crosslinking treatment is dried. In addition, the bridge | crosslinking process in process B5 is the same as that of process A4 in the manufacturing method of the model tooth for cutting training of single layer structure, and description is abbreviate | omitted.

  Through the above steps, a two-layered cutting training model tooth can be produced. In addition, it has been confirmed by experiments by the inventors of the present application that the two-layered cutting training model tooth of the present invention shows a good bonding state without any cavities or the like being seen at the bonding portion between the surface layer and the inner layer. Yes. Therefore, when the cutting practice is performed, it is possible to experience the feel of transition from enamel to dentin.

  The single-layer cutting training model tooth and the two-layer cutting training model tooth of the present invention have a bottom for drilling or the like, and inserting, for example, E-Sert (registered trademark, also known as Helisart) or the like. Prepare a female screw and fix it by screwing it for use.

  The above-described embodiment is an example of a preferred embodiment of the present invention, but is not limited thereto, and various modifications can be made without departing from the gist of the present invention. For example, in the above-described embodiment, the E-sert hole is formed after the cutting training model tooth is produced, but the E-sert hole may be formed at the stage of the molded body. In this case, in the cross-linking treatment step, the cross-linking reaction proceeds from this hole, so that the cross-linking treatment time can be reduced.

  Further, in the above-described embodiment, the mixture is uniformly heated using a tooth mold made of a heat conductive material capable of heating the filled mixture through the mold. However, the mixture is brought into contact with the filled mixture. A part of the tooth mold is made of a material having a lower thermal conductivity than the heat conductive material that constitutes the tooth mold, or a material that does not have a thermal conductivity. May be lowered. In this case, this portion can be used as a pseudo caries portion, and a pseudo tooth-like model tooth for cutting training can be produced. Further, by coloring this pseudo-carious portion with, for example, a black pigment, it is possible to produce a pseudo-tooth-like cutting training model tooth with a more realistic appearance.

  Furthermore, in the above-described embodiment, the casein resin is prepared using the casein powder. For example, the casein precipitate obtained by adding acid to milk such as milk is heated and pressurized. It is good also as a model tooth for cutting training of this invention by producing casein resin by bridge | crosslinking the molded object obtained. In this case, it is possible to effectively use milk that is discarded due to reasons such as expiration of consumption or excessive milking.

  In the above-described embodiment, the dentin part which is the inner layer and the enamel part which is the surface layer are integrally formed, but the molded body of the dentin part which is the inner layer and the molded body of the enamel part which is the surface layer. May be integrated by bonding or the like to produce a two-layered cutting training model tooth.

  Furthermore, in the above-described embodiment, the hardness of the cutting training model tooth is made close to the natural tooth, but the hardness is not necessarily close to the natural tooth. For example, in cutting practice with a cutting practice model tooth simulating a tooth with thin enamel like an anterior tooth, it may be difficult to obtain a feeling of transition from enamel to dentin. Therefore, even in such a case, the hardness of the enamel is deliberately determined so that the practitioner can consciously recognize the difference in cutting feeling between enamel and dentin and the transition from enamel to dentin. It is good also as a model tooth for cutting training which raised the difference with the hardness of dentin higher than the hardness of normal enamel.

  Furthermore, another layer may be coated on a part or the whole of the cutting training model teeth of the above-described embodiment. For example, it may be a two-layered cutting training model tooth in which another layer is coated on the above-described one-layered cutting training model tooth, or another two-layered cutting training model tooth described above. It is good also as a model tooth for cutting training of the three-layer structure by which the layer was coated. In addition, in the case where the hardness of the enamel is dared to be higher than that of the normal enamel as described above, a hard material is coated on a part or the whole of the cutting training model tooth. You may be allowed to. The cutting training model tooth may be a cutting training model tooth whose surface is coated with a colorant or the like and close to the color of a natural tooth without being colored with a white pigment. Examples of the coating method include a method in which a substance to be coated (for example, resin or the like) is applied as a liquid to the surface of a cutting training model tooth, sprayed, or dipped. Moreover, you may make it affix on the model tooth for cutting training the substance processed beforehand into the film form.

  In the present invention, it is preferable to use only a safe material that does not harm health even if a student who performs cutting training inhales. A resin or the like may be used. In this case, although the melamine resin is contained in the cutting training model teeth, the amount of melamine resin powder scattered during cutting can be greatly reduced as compared with the conventional cutting training model teeth. Therefore, there is an advantage that the risk of harming the health of students and the like who perform cutting training can be greatly reduced as compared with the conventional case. For example, by adding melamine resin powder in the above-described step A1 or step B1, it is possible to adjust the hardness of the cutting training model tooth including the melamine resin, and the color of the melamine resin (white) ) May be used to bring the color of the cutting training model teeth closer to natural teeth. In addition, as a cutting training model tooth with a part or all of the surface coated with melamine resin, a two-layer structure as described above, or a layer with a high hardness on the surface of the cutting training model tooth Alternatively, the shade of the cutting training model tooth may be made closer to the natural tooth.

  Examples of the present invention will be described below, but the present invention is not limited to these examples.

Example 1
Pellets were produced from casein powder milled to various particle sizes, and the relationship between the particle size of casein powder and the Shore hardness of the pellets was examined.

First, casein powders having the following three particle sizes were prepared.
・ Minimum particle size> 600 μm ・ Maximum particle size 355 μm
・ Maximum particle size 100μm

  As the casein powder having a minimum particle size of more than 600 μm, casein (Nissei Kyoyoku Co., Ltd., Rennet Casein ALAREN786) was ground in a mortar, passed through a sieve having a diameter of 600 μm, and the powder that did not pass through this sieve was used.

  As the casein powder having a maximum particle size of 355 μm, casein (manufactured by Nissei Kyoyoku Co., Ltd., model number rennet casein ALAREN786) was ground in a mortar, passed through a sieve having a diameter of 355 μm, and passed through this sieve.

  Casein powder having a maximum particle size of 100 μm was prepared by grinding casein (manufactured by Nissei Kyoyoku Co., Ltd., model number rennet casein ALAREN786) with a mortar, passing it through a sieve with a diameter of 100 μm, and passing through this sieve.

  The pellet was produced by the following procedure.

To each casein powder, 0.5% by weight of titanium oxide (TiO ₂ ) was added as a pigment, and water was added in an amount such that the water content of casein was 25% by weight and mixed for 5 minutes to obtain a mixture.

The obtained mixture was packed in a pre-hardened steel (NAK55) mold (diameter: 19 mm, thickness: 15 mm) for producing pellets, which was heated to 75 ° C., and the mixture packed in the mold was applied with a pressure of 300 kg / cm ² . After pressurizing with, it was demolded. This series of processing took 7 minutes.

  Next, the solidified mixture was taken out from the mold, and this was immersed in a formalin solution (5 to 7% by volume) for 1 week for crosslinking treatment.

  The mixture after the crosslinking treatment was taken out of the formalin solution and dried for one week to obtain pellets.

  The Shore hardness of the obtained pellet was measured with a Shore hardness meter (scale: D type). The measurement was performed 10 times for each pellet.

  The results are shown in FIG.

  Here, the shore hardness D of natural teeth is 55-73 (Mohs hardness: 5-6) in dentin, and 74-86 (Mohs hardness: 6-7) in enamel. As is clear from FIG. 1 and Table 1, the shore hardness of the pellets is 61 to 84 in the range of the particle size of the casein powder that was tested, and it is clear that the hardness of dentin or enamel of natural teeth can be simulated. became.

  In particular, when the minimum particle size exceeds 600 μm, the average hardness becomes 70 (variations 61 to 77), and it has become clear that the hardness of dentin of natural teeth can be easily simulated.

  Further, when the maximum particle size is 355 μm, the average hardness is 78 (variations 73 to 81), and it is easy to simulate the hardness of the natural tooth enamel, and when the maximum particle size is 100 μm, the average hardness is 82 (variations 80 to 84). It became clear that the hardness of the tooth enamel could be simulated more easily. In addition, the tendency for dispersion | variation to fall was seen, so that the particle size became small.

  From the above, it has been clarified that by using casein powder, it is possible to produce a cutting training model tooth that is close to the hardness of the natural tooth and can provide a cutting feeling close to that of the natural tooth. In addition, it became clear that by adjusting the particle size of the casein powder, it is possible to produce a cutting training model tooth that simulates the hardness of a natural tooth and can obtain a realistic cutting feeling similar to that of a natural tooth.

(Example 2)
The effect of white pigment addition on the hardness of cutting training model teeth was investigated.

  The casein powder having the maximum particle size of 355 μm prepared in Example 1 was used, titanium oxide was used as the white pigment, and 0%, 0.1%, 0.5%, 1.6% of titanium oxide was added to the casein powder. % Or 4.5% by weight was added, and pellets were produced by the same procedure as in Example 1. About this pellet, Shore hardness was measured with the Shore hardness meter (scale: D type), and the relationship between the addition amount of a white pigment and Shore hardness was confirmed. The results are shown in FIG.

  When the addition amount of titanium oxide was 0.1% by weight and 0.5% by weight, the hardness tended to be higher than when titanium oxide was not added. On the other hand, when the addition amount of titanium oxide was 1.6% by weight and 4.5% by weight, the hardness tended to be lower than when no titanium oxide was added.

  In addition, as a result of the appearance observation of the prepared pellets, when the addition amount of titanium oxide is 1.6 wt% and 4.5 wt%, the pellet color becomes too white, and the color of the teeth Became unnatural. On the other hand, when the addition amount of titanium oxide is 0.1% by weight and 0.5% by weight, a color very close to that of natural teeth can be obtained in combination with the ivory color when no titanium oxide is added. It became clear.

  From the above results, it was revealed that the amount of white pigment added to casein powder is 0.1 to 1.0% by weight, preferably 0.1 to 0.5% by weight.

  In addition, when the amount of white pigment added to casein powder is 0.1 to 0.5% by weight, the hardness is increased to produce natural teeth for cutting training from casein powder having a maximum particle size of 355 μm. It was also confirmed that the effect of easily approaching the hardness of the tooth enamel can be obtained.

(Example 3)
A model tooth for cutting training with a single layer structure was prepared.

  Specifically, it was produced by the same procedure as the pellet production procedure of Example 1 except that a tooth mold was used instead of a pellet forming mold.

  The resulting single-layered cutting training model tooth is shown in FIG. It was confirmed that the structure of the crown part could be clearly reproduced according to the tooth type. It was also confirmed that the appearance was very close to that of natural teeth.

Example 4
A two-layered cutting training model tooth was prepared.

  Specifically, it was prepared in the same manner as in Example 3 except that two types of mixtures (first mixture and second mixture) were used, and the first mixture was stuffed after filling the second mixture into a tooth mold. did.

  The first mixture was prepared by using the casein powder of minimum 600 μm produced in Example 1 as the first casein powder and adding water so that the water content of the first casein powder was 25% by weight.

  In the second mixture, the casein powder having a maximum size of 355 μm prepared in Example 1 was used as the second casein powder, and water was added so that the water content of the second casein powder was 25% by weight. It was prepared by adding wt%.

  FIG. 4 shows the obtained two-layer model tooth for cutting training. Also in this case, it was confirmed that the structure of the crown portion could be clearly reproduced according to the tooth type. It was also confirmed that the appearance was very close to that of natural teeth.

  Further, it was revealed that no voids or the like were observed at the joint portion between the surface layer and the inner layer, and a good joined state was exhibited. Therefore, it was clarified that the feeling of transition from enamel to dentin can be experienced realistically during cutting training.

Claims (17)

Model tooth for cutting training, characterized by containing casein resin as a main component. The model tooth for cutting training according to claim 1, wherein the Shore hardness D is in the range of 74 to 86. The model tooth for cutting training according to claim 1, wherein the Shore hardness D is in the range of 55 to 73. The cutting training model tooth according to any one of claims 1 to 3, wherein a white pigment is dispersed. The model tooth for cutting training according to claim 4, wherein the white pigment is titanium oxide (TiO ₂ ). The cutting training model tooth according to claim 4 or 5, wherein the white pigment is contained in an amount of 0.1 to 0.5% by weight. The model tooth for cutting training according to any one of claims 1 to 3, comprising only the casein resin. The model tooth for cutting training according to any one of claims 4 to 6, comprising only the casein resin and the white pigment. A dentin portion mainly composed of a first casein resin;
An enamel part mainly composed of a second casein resin having a higher hardness than the first casein resin;
A model tooth for cutting training having a two-layer structure characterized by comprising: The double-layered cutting training model tooth according to claim 9, wherein the dentinal portion has a Shore hardness D in the range of 55 to 73, and the enamel portion has a shore hardness D in the range of 74 to 86. . The model tooth for cutting training with a two-layer structure according to claim 9 or 10, wherein a white pigment is dispersed at least in the enamel part. The white pigment titanium oxide (TiO ₂₎ a cutting training for tooth model having a two-layer structure of claim 11. The model tooth for cutting training with a two-layer structure according to claim 11 or 12, wherein the white pigment is contained in an amount of 0.1 to 0.5% by weight. The model tooth for cutting training with a two-layer structure according to claim 9 or 10, wherein the dentin portion is composed of only a first casein resin. The model tooth for cutting training having a two-layer structure according to any one of claims 9, 10, and 14, wherein the enamel portion is composed of only a second casein resin. The model tooth for cutting training with a two-layer structure according to any one of claims 11 to 13 , wherein the enamel portion is composed of only the second casein resin and the white pigment. The model tooth for cutting training with a two-layer structure according to claim 16, wherein the dentin portion is made of only the first casein resin.