CH428088A - Process for manufacturing a dental article and obtained by this process dental article - Google Patents

Description

  

  



  Process for manufacturing a dental article and obtained by this process dental article
 The present invention includes a method of manufacturing a dental article such as a dental prosthesis, an artificial tooth and its reinforcements, a crown, a filling cone, and a dental article obtained by this method.



   The material commonly used for this purpose is dental porcelain composed of a mixture of feldspar, silica and kaolin in various proportions with a small amount of a flux.



   Artificial teeth are normally made with porcelain exhibiting a high melting temperature, in the range of 1300 C, and platinum or gold fixation pegs are normally hot-mounted or welded into the backs of the teeth to form organs. fixing at the base of the teeth.



   Porcelain jacket crowns are formed on platinum matrices using a porcelain powder pigmented in the desired shade and which is usually bound with distilled water to facilitate molding.



  The platinum matrix with the hand-cast crown are kiln fired, ground to the desired shape and annealed to achieve a luster similar to that of healthy tooth enamel. Dental filling cones are made in a similar fashion using a platinum matrix or a refractory mold.



   Dental porcelain has the drawback of having limited mechanical strength. The resistance of this porcelain, which is generally measured by its modulus of rupture, is very low, of the order of 280 to 840 kg / cm 2.



  This low mechanical resistance makes porcelain unusable for areas of the mouth where the teeth are subjected to considerable stress. The brittle nature of commonly used dental porcelain is also manifested by a high percentage of fracture of artificial teeth in dentures when they accidentally meet hard surfaces and by fractures that occur in dental crowns subjected to notable forces when the subject bites. in some foods.



   Attempts have been made to improve the strength of dental porcelain by firing the water-bound powder in a vacuum to remove air bubbles trapped in the fired porcelain. Other techniques for strengthening this porcelain involve the use of an alloy of platinum, palladium and gold with a melting point between 1150 to 1175 C to form a core or a reinforced support on which is fired. dental porcelain with a similar coefficient of thermal expansion. This technique has been used to form permanently cemented dental crowns and bridges on healthy teeth.



   The process which the present invention comprises is characterized in that a refractory oxide comprising at least 60% by weight of alumina, titanium oxide, zirconium oxide or a mixture is molded to the required shape. of these bodies, the balance being mainly silica and in that the oxide is fired at a temperature of 1300 to 1750 C to ensure sintering and recrystallization of the oxide without appreciable melting of the latter.



   The appended drawing represents, by way of example, some embodiments of dental articles obtained by the method, object of the invention:
 Fig. 1 is a section of an artificial tooth mold.



   Fig. 2 is a section of another artificial tooth mold.



   Fig. 3 is a section through a pivot crown.



   Fig. 4 is a cross section of a jacket crown, and
 fig. 5 is a section through a front covering for a bridge.



   Impurities other than refractory oxides are not present in amounts such as to significantly weaken the physical properties of the recrystallized oxide. The allowable proportion of these impurities varies with their nature, but in general the refractory oxides of commerce for the manufacture of ceramic articles have been found to be satisfactory.



   Although the exact nature of the sintering and recrystallization process is not fully determined, it appears that the following stages occur during firing. Firstly, a solder effect occurs at the points of contact between adjacent oxide particles, giving rise to the formation of a magnifying glass as occurs in sintering processes.



  A migration of atoms then occurs from one particle to another causing a displacement of the boundaries of the particles or a recrystallization p. During the latter, the shifting of the grain boundaries leads to the formation of a tightly interwoven crystal structure and considerable mechanical strength, the improved agglomeration of the particles producing a contraction of the mass of the oxide. The resulting recrystallized oxide exhibits mechanical properties much superior to those of dental porcelain which are limited by the inferior mechanical characteristics of the glass phase.



   Although the preferred refractory oxide is alumina, titanium dioxide, zirconia and mixed oxides of alumina and silica can also be used.



   The cooking temperature required will vary depending on the oxide used and, to some extent, the cooking time. In the case of practically pure titanium dioxide, the firing temperature is of the order of 1400 C. Pure alumina requires a firing temperature of 1750 -C, but - by slightly reducing the purity of the alumina-- the temperature required for recrystallization can be lowered.

   Such an alumina with a lower degree of purity can be used advantageously with the corresponding reduction in the firing temperature required; for example, using an alumina with a purity of 85 It) / o, the balance being mainly silica, the recrystallization is carried out at about 1500 C, while a-mixture comprising-60 '/ o d The alumina and the balance of silica mainly can be fired at 1300 ° C. It is thus possible to use simpler and more economical ovens for the firing.



   After cooking, the oxide has a smooth surface impermeable to fluids in the mouth. This surface can still be vitrified and pigmented by any known means.



   Refractory oxides can be used in the process described for the following applications: 1) molding material intended to be cured in order to manufacture dental crowns; 2) material for producing preformed reinforcements based on recrystallized oxide for dental porcelain or alumina porcelain, a) as support material on which dental porcelain can be fired to form crowns, b) as bridge preformed onto which a porcelain coating can be fired, and c) as a reinforcing core for artificial porcelain teeth; 3) molding material intended to be cured for the manufacture of complete dental bridges intended to be cemented on a healthy tooth;

   4) molding material intended to be cured for the manufacture of artificial teeth, molars, premolars and incisors; 5) molding material intended to be baked into preformed shapes (dental fillings) intended to be cemented in healthy individual teeth; 6) coating material intended to be baked on metal pillars to support reinforcements, for example made of molybdenum.



   It will be understood that the cost of the recrystallized oxide as reinforcement material is considerably lower than that of the precious metals commonly used for the same purpose.



   Some examples of implementation of the method described are given below. Although these examples relate to the use of alumina, it should be understood that other oxides can be substituted for the alumina with the appropriate adjustment of the firing temperatures.



   In these examples, the alumina is molded by any known means into the required shape before firing.



  A binder is used to give cohesion to the mass of alumina during molding. The binder should normally leave no residue after firing and binders of this type are well known in the dental art.



  In the examples given, methylcellulose is used.



   Example 1
 A mixture of 10% by weight of methylcellulose and the balance of water is prepared as follows: The methylcellulose is mixed with half the required amount and heated at 800 C for five to ten minutes with continuous stirring, until 'it is wet; the mixture cools to 20O C when the rest of the water is added gradually until the dispersion of the methylcellulose is complete. the alumina and the methylcellulose gel prepared can then be mixed in various proportions depending on the nature of the alumina, to obtain a mass capable of being molded.

   In this example, 200 g of alumina was mixed with 30 g of methylcellulose gel.



  To facilitate removal from the mold and improve molding characteristics, agents well known in the art may be added to the mixture, for example at the rate of 30 ml of such an agent per 200 g of alumina. The mixture is then molded into the required shape. After removal from the mold, the molded alumina is first dried slowly in an oven at 2000 C, then heated to the required baking temperature.



   This process was carried out twice, first with alumina of a purity of 95% and then with an alumina of a purity of 85%.



   Articles molded from alumina with a purity of 95 ID / o, the. Impurities being mainly silica with minor amounts of titanium oxide, iron oxide and fluxes such as alkali or alkaline earth silicates, are heated for two hours at 1650 C.



  The comparative properties of the material thus obtained and of the dental porcelain are given in the following table.



  Reelblade reSSsee physical properties
 ¯: recrystallized - tensile strength kg / cm2. 1204 350 compressive strength
   kg / cm2. 22120 3500 Young's modulus kg / cm2 ... 3227.106 modulus of rupture-kg / cm2 .. 3850 259-840 coefficient of expansion
   0 to-2000 C 10-6 / C ... 6, 2 6, 4 to 7.8
Physical properties reaSée Foals
   0 to 4000 C 10-6 / o C ... 6.7
   0 to 600 C10-6 / C ... 7.1
   0 to 800 C 10-6 / C ... 7.5
 0 to 10,000 C 10-6 / o C ... 7.9 thermal conductivity
   100 C joule-cm / cm2 / sec / C 0.162 0.010 water absorption .....

   zero 0 to 2/0 Moh scale hardness ... 9 Rockwell scale hardness C 72 42 Vickers scale at one load
 10 kg VPN ...... 1200 430
 The coefficient of expansion of a human tooth is in the order of 11.4 10-s / C.



   Articles molded from alumina has a purity of 85 / o, the impurities being mainly silica with minor amounts of titanium oxide, iron oxide and fluxes such as alkali or silicates alkaline-earth, are baked for two hours at 15000 C and show physical properties slightly inferior only to those of recrystallized alumina at 95O / o and given in the previous table.



   The process is repeated using a mixture of oxides comprising approximately 60% alumina and 40% silica with low proportions of impurities such as titanium oxide, iron oxide and fluxes. The mixture of oxides is heated for two at 13,000 C.



   Example 2
 The recrystallized alumina can be nickel-plated by impregnating the surface of the recrystallized alumina component with a molybdenum paint, by baking the paint on the surface of the α-alumina. a temperature r passing 1600 ° C., the nickel plating of the surface being carried out by standard nickel plating methods, and then by welding gold supports to the nickel plating, also by known methods.



   Example 3
 Alumina cores obtained by the method described are manufactured in the shape required according to the tooth to be manufactured with a layer of alumina porcelain or with a dental porcelain having practically the same coefficient of expansion, and are vitrified with a coating of feldspar enamel. The method of forming teeth in this way is illustrated in fig. 1. A metal mold comprises two sections 1 and 2, the latter comprising a pin 3 projecting into the mold cavity. A core 4 of recrystallized alumina with a thickness of 1.5 to 2.5 mm, depending on the size of the tooth, is slipped over the pin 3. The core should fit on the pin with a tolerance of about 0.25 mm. A feldspar enamel coating is first applied to the inner surface of the mold cavity.

   A dental porcelain or alumina porcelain containing a stable pigment and mixed, if necessary with an inorganic binder, is then loaded into the mold to form a layer preferably having a thickness of 0.7 to 1.0 mm around the body. alumina core.



  The two halves of the mold are then sealed in a heat press and the complete tooth is fired and completed by standard dental fabrication methods which include the application of an enamel coating 6. This method is particularly suitable for fabrication. of posterior teeth.



   Fig. 2 illustrates a similar process suitable for the fabrication of anterior teeth.



   The process described in this example is particularly useful when it is desired to use pigments which are not stable at temperatures of 1500 ° C. and above and which consequently cannot be incorporated directly into the recrystallized alumina components. The teeth produced by this process can be used for bridges or dentures.



   Example 4
 Recrystallized alumina can also be used for the manufacture of pivot rings (fig. 3). A 1 to 1.5 mm diameter stainless steel swivel 10 is fitted into the root canal 11 of a healthy tooth and a tube 12 of recrystallized alumina is ground to fit over the exposed portion. 13 of the pivot 10. The pivot 10 and tube 12 may have various dimensions, but the tube must fit exactly over the pivot. An impression is taken by any known method of the root surface 14 while only the pivot is in place. A copper or silver matrix is made from the impression and a platinum matrix is fitted to the root surface 14. A dental crown is formed by firing a body of alumina porcelain on the alumina tube. 12 in the matrix.

   A dental enamel with fledspath 16 is applied during a second firing.



  The alumina tube 12 provides a reinforcement of the porcelain 15 and eliminates the need to cast a gold core for the crown.



   Example S
 A reinforced porcelain jacket crown containing a preformed support of recrystallized alumina can be manufactured by forming a silver model of the crown and by forming a platinum matrix using this model. A thin coating of pigmented alumina porcelain is then applied to the palatal face of the platinum matrix and a preformed alumina support is placed by vibration. A body is built over the rest of the die with alumina porcelain and the whole thing is then fired to produce the crown. A feldspar enamel is then applied to the appropriate surfaces of the crown and the whole is baked again.

   The resulting crown is shown in fig. 4 in the position it occupies on a healthy tooth 20, the crown comprising a layer 21 of pigmented alumina porcelain which rested against the palatal face of the platinum matrix, the preformed alumina support 22, the porcelain pigmented alumina 23 and feldspar enamel 24. This crown has the advantage of reinforcing the palatal surface 25 which is the most common site of fracture during chewing.



   Example 6
 Due to the refractory nature of recrystallized alumina, it has been found that it is possible to cast dental gold directly onto this material. Bridges are constructed using recrystallized alumina cores covered with alumina porcelain with a firing temperature exceeding 1100 C. Wax is fitted to the palatal retention areas of the preformed alumina core and gold is cast by a standard dental process using wax impressions. This technique can be used to construct a one-piece bridge in which the abutment fillings and the alumina bridge can be joined with a gold casting obtained by the wax process.



   Example 7
 An interior covering for a bridge can be made in the manner illustrated in FIG. 5. An alumina support 30 has a dovetail 31 through which it can be fixed to the bridge, and a layer 33 of pigmented alumina porcelain is cwte on its anterior surface 32, after which a coating 34 is coated. applied to alumina porcelain.



   Example 8
 Preformed ribbons of recrystallized alumina with a thickness of 0.6 mm are prepared in order to be fitted to the palatal face of a copper clad model prepared by a known method of manufacturing crowns. A dental porcelain with a firing temperature of 9800 C is then fired on the recrystallized aluminum support and a dental crown is constructed by the normal technique used in dental laboratories.



   The appearance of a natural tooth can thus be obtained by using an alumina support as a reinforcing material. The result is much superior in appearance to that obtained with the alloys of platinum and palladium which are normally used as reinforcement and which exhibit an opacifying effect.



   As already indicated, the alumina of the preceding examples can be replaced by other refractory oxides such as titanium oxide, zirconia and mixed oxides of alumina and silica.


 

Claims (1)

CLAIM I A method of manufacturing a dental article, characterized in that a refractory oxide comprising at least 60 ouzo by weight of alumina, titanium oxide, zirconium oxide or dia is molded into the required shape. 'a mixture of these bodies, the balance being mainly silica, and in that the molded oxide is fired at a temperature of 1300 to 1750 C to ensure the sintering and recldistalli6ation of the oxide without appreciable melting of the oxide. this last. SUB-CLAIMS 1. Method according to claim I, characterized in that the oxide contains a flux. 2. Method according to claim I, characterized in that the oxide contains at least 85 / o alumina. 3. Method according to sub-claim 2, characterized in that the oxide is baked at a temperature of 1500 to 17500 C. '4. A method according to claim I, characterized in that a binder is added to the unbaked oxide to facilitate molding. 5. Method according to claim I, characterized in that an unbaked oxide release agent is added before molding to facilitate the removal of the oxide from the mold. 6. A method according to claim 1, characterized in that a layer of dental porcelain is subsequently baked on the surface of the baked reoristallized oxide body. 7. A method according to claim I, characterized in that subsequently baked a layer of alumina porcelain on the surface of the baked recrystallized oxide body. 8. Method according to claim 6 or 7, characterized in that a layer of dental enamel or coating is baked on the surface of the porcelain. CLAIM II Dental article obtained by the process according to claim I, characterized in that it comprises an n core of a sintered and recrystallized refractory oxide, comprising at least 60 ouzo by weight of alumina, titanium oxide, d zirconium oxide or a mixture thereof, a layer of dental porcelain or fired alumina on the core, and a coating covering at least part of the porcelain layer.