JPH01277553A - Hard resin jacket crown and preparation thereof - Google Patents

Abstract

PURPOSE:To enhance hue, fittiness, strength, operability and impact resistance of the title jacket crown, by building up a hard resin layer on a matrix composed of a resin sheet. CONSTITUTION:A hard resin layer 5 is built up on the matrix 3 composed of a resin sheet mounted on a support tooth 2 through an adhesive 4. Said hard resin layer 5 consists of a thin opaque resin layer 5a, the dentine resin layer 5b built up thereon and the enamel resin layer 5c further built up on said resin layer 5b in order from the support tooth 2. This jacket crown 1 has a double structure wherein an outer hard part and an inner part rich in elasticity are bonded.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a hard resin used as a dental crown prosthesis material.
This concerns the jacket crown.

[Conventional technology]

There are three types of dental prosthetic materials currently used clinically: metal, ceramics, and resin.

Each is used in combination and alone.

Aesthetics is particularly important for front teeth, so crown-colored porcelain or resin is essential; however, for porcelain, in addition to conventional metal-baked porcelain crowns, jacket crowns made of new ceramic materials and special foils are also available. Now that the applied jacket crown is being applied, I feel that it has progressed a lot.

On the other hand, resin veneers are also made by bonding opaque resin to a metal frame (for example, Takuo Tanaka, Mitsuru Atsuta: 4-
Adhesion of gold alloys with META-based adhesives - theory and clinical applications - 1 Molar Review, 479.50-61° 1982, and Musll, R, and Tiler, H.
J: Diemelekulare Kopplung
der Kunstoff-Verbrandung
an die legierungsobarfl;1
che, Dental-1abor.

1155-1161.32 (10), 1984),
Considerable improvements are being made with the introduction of photopolymerizable hard resins. However, jacket crowns using only resin have a limited range of applications, and no research has been reported on their improvement.

In general, resin crowns give the impression that they are incomplete and undesirable, even if they are made of metal. In fact, there is no denying that there is a significant difference in aesthetics and durability compared to porcelain crowns.

When comparing a metal-baked porcelain crown and a hard resin veneer, there is a considerable difference in the material of the veneer, and although some can be judged as superior or inferior, a hard resin veneer is sufficient if the occlusion is restored with metal. However, in order to meet the aesthetic requirements for crowns of front teeth, it is necessary to apply continuous teeth and jacket crowns. However, conventional acrylic resins have poor wear resistance and are difficult to use for crowns. It is not suitable as a material.

However, in recent years, hard resins with excellent wear resistance have come into use, and it is true that improvements are being made.

Conventional resin jacket crowns manufactured in general dental laboratories and in-hospital laboratories include the following:

■ Shell method This method uses a ready-made resin shell, but the shell is ground down to match the abutment tooth, and the missing parts such as the lingual surface are filled with resin. This method was often used to make temporary crowns, but recently it has become possible to create hard resin jackets relatively easily by combining hard resin shells and photopolymerized resins. However, hard resin does not easily adhere to ready-made hard resin teeth, and if they are manufactured carelessly, the adhesion between the shell and the hard resin will be insufficient, leading to breakage.

■ Seedling pressure welding method This is a commonly used method in which foil is pressed onto the tooth mold and hard resin is built up on top of it. Tin foil is commonly used, but palladium foil with a thickness of 25 μm is also used to improve the fit. Since the foil is used, it is easy to separate it from the tooth impression, but on the other hand, it may take time to remove the foil from the inner surface of the jacket crown.

■ Direct build-up method using a mold release agent To save the effort of pressing the foil, a mold release agent is applied to the tooth mold.
There is a method of directly piling up hard resin on top of it, but if you do not choose the type of mold release agent, the separation will be poor and the tooth mold will easily break.With heat-polymerized hard resin, it is heated to nearly 130 degrees Celsius, so plaster teeth This poses a problem as the mold becomes brittle due to dehydration and is particularly prone to breakage. When a photopolymerizable hard resin is used, there is no need for heating, which is advantageous in this respect.

For this reason, a direct build-up method using photopolymerization has recently been widely used.

■Flasking method In this method, a flask is buried in the waxed-up pattern, and after waxing, a hard resin is filled and polymerized by heating. A paste-type hard resin is inserted, but a method has also been proposed in which a powder-liquid type is kneaded in advance, stored in a syringe, and then injected.

[Problem to be solved by the invention]

The following are the clinical problems with the conventional hard resin jacket crowns as described above.

■ Compatibility Even if it is a resin crown, it is still a crown, so good compatibility is desirable, but hard resin jacket crowns are generally a little tight. This is because after heating and polymerization, the material shrinks before returning to room temperature, and the shrinkage is also uneven, resulting in deformation. Compensation laws are also being considered for this purpose. In this regard, since the photopolymerizable type can be polymerized at room temperature, it is said that there is almost no shrinkage due to temperature changes. However, in the same way, the monomer changes into a polymer through polymerization, and the polymerization shrinkage of the resin itself that occurs during that process remains, so it cannot be said to be perfect in terms of compatibility.

■Strength The acrylic resin jacket crown used in the past has elasticity and does not easily break, but if you use hard resin, it will break more often. In addition to the above-mentioned compatibility problem, the unpleasant problem of breakage during trial use still occurs, which is evidence that the hard resin has become harder, but at the same time has less elasticity and has become brittle. Furthermore, regardless of whether thermal polymerization or photopolymerization is performed, if polymerization is incomplete, the strength will be extremely low. In any case, instructing patients not to chew on hard objects leaves a feeling of dissatisfaction.

■ Wear resistance Recent hard resins are said to have 2 to 5 times the wear resistance of conventional hard resins, and although improvements have been made, in the long term, the wear resistance of the hard resins is said to be 2 to 5 times higher than that of conventional hard resins. Attrition cannot be prevented, and it may cause protrusion of the gold tooth.

■Since the coefficients of thermal expansion of the fallen tooth and the resin are not equal, a gap is created due to temperature changes in the oral cavity, which makes it easier for the cement to melt and fall off. Naturally, this tendency becomes more pronounced in cases of poor fit. To prevent this.

Although it is recommended to use resin cement that adheres to the tooth structure, it cannot be applied in all cases due to its irritation and harmfulness.

■ Plaque adhesion The obvious difference compared to porcelain is that resin has water absorption properties, but it also absorbs water from saliva in the oral cavity, and at the same time adsorbs components such as proteins. It is inferred that adhesion also occurs more easily. It is known that this depends on the polishing condition of the surface, and it is necessary to polish the surface perfectly. Recent hard resins using organic composite fillers provide a fairly smooth surface and have good abrasion resistance, so they are expected to last for a long time, but there is no such thing as zero water absorption.
The problem remains.

The purpose of the present invention is to solve the above-mentioned problems and provide one color tone, compatibility,
It is an object of the present invention to propose a new hard resin jacket crown that is excellent in strength and operability, has improved impact resistance in particular, and can be manufactured by a simple method, and a method for manufacturing the same.

[Means for Solving the Problems] The present invention provides the following hard resin jacket crown and manufacturing method thereof.

(1) A hard resin jacket crown characterized by comprising a matrix made of a resin sheet attached to an abutment tooth, and a hard resin layer built up on this matrix.

(2) The hard resin jacket crown according to (1) above, wherein the resin sheet is an acrylic resin sheet or a polycarbonate resin sheet.

(3) A matrix is formed by press-contacting a resin sheet in a softened state to a tooth mold having a shape corresponding to the abutment tooth, and a hard resin layer is formed by building up hard resin on this matrix. How to make a hard resin jacket crown.

In the present invention, the material of the resin sheet forming the matrix is preferably a resin that is thermoplastic, has elasticity, and has good adhesion to the hard resin layer.

Examples of such resins include acrylic resins, polycarbonate resins, polyester resins such as polyethylene terephthalate and polyethylene terephthalate, polyether sulfone resins, and polyamide resins, with acrylic resins and polycarbonate resins being particularly preferred. .

Acrylic resins include homopolymers of esters of acrylic acid or methacrylic acid and lower alcohols having 1 to 5 carbon atoms, copolymers thereof, or copolymers of these with 50 mol% or less of other polymerizable heptamers. Examples include merging. Other polymerizable monomers include acrylic acid, methacrylic acid, acrylamide, methacrylamide, vinyl acetate, and styrene.

The resin sheet used in the present invention is formed by molding the above-mentioned resin into a sheet shape, and the original shape is not limited, but when it is attached to the abutment tooth after forming a matrix, it is molded into a shape. The thickness of the resin sheet is usually 0.1 to 10+am, preferably 0.2 to 0.5 .mu.m.

Next, as the hard resin used for building up in the present invention, conventionally used hard resins can be used. Such hard resins include those containing urethane dimethacrylate, triethylene glycol dimethacrylate, neopentyl glycol dimethacrylate, bisphenol A derivative dimethacrylate, etc., and those containing 1 to 3 of these are preferred. Depending on the type of catalyst, these hard resins can be used as room temperature polymerization type, heat polymerization type, photopolymerization type hard resins, etc., and photopolymerization type hard resins are particularly preferred.These hard resins contain fillers such as silica type. be able to.

It is preferable that an adhesive layer and an opaque resin layer are interposed between the matrix made of a resin sheet and the hard resin layer to be built up. The adhesive is preferably a mixture of an acrylate monomer and an acrylate polymer.

The tooth mold used in the hard resin jacket crown manufacturing method of the present invention is a model having a corresponding part for the abutment tooth,
It is preferable that the entire circumference of the base of the abutment tooth corresponding portion be a shoulder.

〔Example〕

The present invention will be explained below with reference to the drawings.

FIG. 1 is a partially cutaway perspective view showing the state in which the hard resin jacket crown of the embodiment is attached. In FIG. A hard resin layer 5 is built up on 3 with an adhesive layer 4 interposed therebetween. The hard resin layer 5 consists of a thin opaque resin layer 5a from the side of the abutment tooth 2, a dentine resin layer 5b built up thereon, and an enamel resin 15c built up further thereon.

In the embodiment, the jacket crown 1 includes a resin sheet 6 made of 0.3+s+a acrylic resin in a matrix 3.
A urethane dimethacrylate photopolymerizable hard resin layer 5 is built up on top of the matrix 3, and the structure is a double structure in which a hard outer part and a highly elastic inner part are combined. It has become.

The method for manufacturing the jacket crown 1 will be described below. 2 to 4 are cross-sectional views of the manufacturing process. As the tooth mold 7, a removable segmentable carbide plaster model was used. In the tooth pattern 7, an abutment tooth corresponding part 7b is formed at the tip of a support part 7a, and a shoulder portion C is formed around the entire circumference of the base thereof.

In the manufacturing method, first, a resin receipt 6 necessary for manufacturing a resin matrix is pressed against a tooth mold 7. This method is exactly the same as the conventional method of making copings and the like using plastic sheets. However, the conventional sheet is made of polystyrene and cannot be applied because it cannot be expected to adhere to the hard resin layer 5. However, the resin sheet 6 used in this pile is made of polymethyl methacrylate (
PMMA), and can be reliably bonded to the hard resin layer 5. This is softened by flame and changed from the state shown in Figure 2 to the third state.
As shown in the figure, the tooth mold 7 is pressed to form the matrix 3. Since PMMA is also a thermoplastic resin, pressure bonding can be performed in the same manner as polystyrene.

After welding, cool down, take out, and check the welding condition. Thereafter, the resin sheet 6 is cut according to the tooth pattern 7, but first a cut is made slightly outside the margin (x position) using a sharp object such as a heated cutter. Next, you can easily remove the excess by cutting with gold crown scissors. It is best to adjust the margins using carborundum points.Since the sheet 6 is transparent, adjustment can be easily performed while checking with the naked eye. The finished matrix 3 conforms reliably to the tooth profile 7.

As shown in FIG. 4, a hard resin layer 5 is built up on this matrix 3, and in order to achieve more reliable adhesion, an adhesive is applied to form an adhesive layer 4. This mixes PMMA into methyl methacrylate (MMA) monomer,
Since it is a syrup, it is necessary not to apply it too thickly. Next, an opaque resin is applied to form the opaque resin layer 5a, but a thermal polymerization type cannot be used because it deforms the sheet-like matrix 3, so a room temperature polymerization (chemical polymerization or photopolymerization) type is used. . After polymerizing the opaque resin layer 5a, the dentine resin layer 5
Build up layer b, and finally build up enamel resin layer 5c to complete the process.

Polishing can be done legally, but it feels a little more elastic than conventional ones, so you can do it with confidence. However, it is necessary to be especially careful when the margin part is thin. FIG. 4 shows the completed jacket crown 1, which has good aesthetics. After the jacket crown 1 manufactured in this way is released from the tooth mold 7, it is bonded to the abutment tooth 2 by cementation. Figure 1 shows the state in which it was installed in the oral cavity, and both the fit and color tone were satisfactory.

In order to examine the strength of the above-mentioned hard resin jacket crown, a repeated impact tester was used to compare the impact resistance with other hard resins. The samples used in the experiment were (A) a photopolymerizable hard resin made of urethane dimethacrylate and a silica filler (trade name: Metacolor, manufactured by Sun Medical Co., Ltd.), and (B) a conventional powder-liquid type heat-polymerizable hard resin. (Product name: Thermoresin, Menshisha), (C) The filling method also uses thermoresin, and (D) Metacolor is built up on a 0.3■■ resin sheet made of PMMA. .

The sample is 10mm x 10mm x 10. O in the shape of an ugly seal,
Five to six pieces of each were used. This sample was repeatedly attached to an impact tester with double-sided tape (0,85+++a), and a load of 200
The hammer was repeatedly hammered with a hemispherical steel rod with a diameter of 2 mm at the tip at a cycle of 120 times per minute at a drop distance of 2 cm and a falling distance of 2 mm.

The number of times it broke was read and used as the impact resistance value.

The results are shown in FIG. 5, and the weakest one was the sample (A) made only of photopolymerizable hard resin, and all of them broke after a few times. The impact resistance of the sample (B) using the heating polymerization filling method is around 100 times, but compared to these samples, the sample (D) using this method is significantly superior in impact resistance.
It was found that the sample did not break even after being hammered 10,000 times, but the sample after 10,000 times did not break, although indentations were observed. This is thought to be because the highly elastic plastic matrix 3 layer acts as a shock absorber against impact and helps prevent breakage.

Comparing this method with the conventional backing method for hard resin jacket crowns, we can see the difference as shown in Table 1.From the point of view of ease of producing zero tone, the filling method is superior. There seems to be some difficulty, but other than that there seems to be no problems.

Regarding compatibility, as mentioned above in the double pressure welding method,
In the 0-piece method, which causes problems if a foil of appropriate thickness is not selected, a good fit to the tooth mold can be obtained by using the legal method, so the crown should be able to fit as it is now. However, if the plastic matrix is not sufficiently pressed, it is natural that the fit will be poor, and the pressure welding should be performed with great care. At present, the matrix is transparent, so it is easy to confirm the pressure contact state.At zero strength, this method has excellent impact resistance as shown in the experimental results, but it is difficult to believe that this directly matches the conditions in the oral cavity. It is unthinkable and there must be a limit.

In any case, it goes without saying that the current hard resin jacket crowns are insufficient to withstand the harsh environment of the oral cavity, and that something with better properties is desired. do not have.

Finally, with regard to operability, no matter how good a product may be, it is not worth evaluating if it is not accepted by those who actually manufacture it.

The criterion for this is operability, and although the one-line method is simple, it is true that it takes more time to produce the plastic matrix.6 Compared to the method that uses a separating agent and completes the process with photopolymerized resin. .

Although it tends to feel a little complicated, the condition of the inner surface of the completed resin crown is very uniform, and there are no unpleasant problems such as unpolymerized parts remaining.

In addition, in the above embodiment, a colored plastic sheet can also be used as the resin sheet 6 in order to omit the step. Furthermore, if a resin sheet having an opaque color is used, it is possible to form a jacket crown by simply placing only the crown-colored hard resin on top.

〔Effect of the invention〕

As described above, according to the present invention, since the hard resin is built up using the resin sheet as a matrix, the hard resin jacket has excellent color tone, compatibility, strength, and operability, and has particularly improved impact resistance. You can easily get the crown.

[Brief explanation of the drawing]

Figure 1 is a partially cutaway perspective view showing how the hard resin jacket crown of the example is installed, Figures 2 to 4 are sectional views of the manufacturing process, and Figure 5 shows the test results of the example. It is a graph. In each figure, the same reference numerals indicate the same or equivalent parts, 1 is the jacket crown, 2 is the abutment tooth, 3 is the matrix, 4 is the adhesive layer, 5 is the hard resin layer, 6 is the resin sheet, and 7 is the tooth mold. , 7b is an abutment tooth corresponding part. Agent Patent Attorney Sei Yanagihara

Claims (3)

[Claims] (1) A hard resin jacket crown characterized by comprising a matrix made of a resin sheet attached to an abutment tooth, and a hard resin layer built up on this matrix. (2) The hard resin jacket crown according to claim 1, wherein the resin sheet is an acrylic resin sheet or a polycarbonate resin sheet. (3) A matrix is formed by press-contacting a resin sheet in a softened state to a tooth mold having a shape corresponding to the abutment tooth, and a hard resin layer is formed by building up a hard resin on this matrix. How to make a hard resin jacket crown.