CS268407B1 - Scanning dental replacement for the way it is made - Google Patents

Abstract

The invention relates to removable dental prostheses made of polymer resins, in which increased strength is achieved by polymerizing 1 to 4 layers of flat textile, e.g. woven, knitted, lace or laminated textile, preferably made of natural organic fibers with a textile weight of 25 to 250 g/m 2 .

Description

The invention ae relates to a removable dental prosthesis and to increased strength made of polymeric resins and to a polished armature of natural organic fiber fabrics.

Dental prostheses ae produce mainly from synthetic organic polymers, especially from acrylate resins, which are relatively brittle and easily cause defects in dentures. Therefore, several methods have been proposed for strengthening polyar restorations, especially the installation of so-called metal shafts or metal nets. Reinforcements made of simple metal screens and in practice did not work, because due to poor adhesion of acrylate resins to metal and different expansion during polymerization, the resin detached from the silk fibers, the cavities formed in the resin weakened the strength of the restoration and therefore resin under its tensile and bending stress. Cast metal stirrups, which use their tensile and flexural strength, have proved to be better. Even in them, however, ae exhibits poor adhesion of metal and resin, and detachment is observable as glossy surfaces of the polymerized yoke. 3e if the prosthesis is subjected to stress in such a weakened place, the resin breaks and the prosthesis is irreparable. Some shortcomings of these reinforcements have been solved by some authors by incorporating reinforcements made of polymers of excellent tensile and flexural strength. E.g. 1 in the Czechoslovak Socialist Republic, in the post-war period, already shaped silicas made of polyamides were supplied to strengthen acrylate substitutes. He soon abandoned their use for the given purpose in our country, because the practice of strengthening such reinforced prostheses did not confirm and, on the contrary, increased the number of irreparable defects. The main reasons for the increase in defects in polymer-reinforced prostheses were probably the following:

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The second reason why the strengthening of acrylate substitutes by other, less brittle polymers forming a chemical bond during polymerization was also a failure to disrupt the strength of the reinforcement. Therefore, various types of polyolefins have recently been proposed to reinforce prostheses, resp. their modifications, which should reduce some of the described shortcomings. While the use of polymers to reinforce acrylic animations of dental prostheses has not been successful, they have been shown to be useful in the form of knits for reinforcing the hydrogel plug of a soft floor defect obturator and attaching a hydrogel plug by gluing synthetic polymer knits to a polymer floor covering sheet. AO 174 296. In this case, however, ae is a reinforcement of the hydrogel plug. From the mentioned shortcomings of the reinforced polymer dental prostheses, it is clear that they did not fulfill the function of reinforcement of so-called armatures in the sense of functional, eg metal valves in concrete or in epoxy rubber resins, inorganic fibers in polyeaters, etc.

These disadvantages are solved by a high-strength removable dental prosthesis made of polymeric resins, characterized in that 1 to 4 gates of fabric, for example woven, knitted, lace or woven fabrics, preferably of natural organic fibers with a weight of fabric 25, are polymerized in the resin relaxation of the floor. up to 250 g / m ² .

Textile fittings made of natural organic fibers in animations of dental prostheses not only do not increase the weight of the prostheses, on the contrary, they reduce it, because they ensure their increased compressive, tensile and bending strength even when the polymer thickness is reduced. When the fabric is wetted by the polymerizing components of the resin in the liquid or semi-solid state, the polymerizing fabric chains penetrate the fibers of the textile armature, which increases its volume not only by comparable to perfectly reinforced concrete. Textile fittings made of natural organic fibers strengthen polymer dental prostheses - preferably in their marginal parts, where defects most often occur and keep them in their original shape, even if the polymer breaks, eg when the tooth falls

CS 268407 Bleaching of the restoration on a hard surface or in case of other · excessive stress on the restoration. X in this case proves the advantage of reinforcing the replacement area ·! textile·! made of natural organic fibers in a simpler repair. Because non-absorbent and water-repellent resins are used to make the dental prostheses, the fibers impregnated with them also become hydrophobic, even if the fabric used for arming has been dyed in an aqueous medium. Impregnated hydrophobic fibers polymerized inside the polyaernal prosthesis also cannot exhibit any adverse physiological effects. With regard to natural organic fiber fabrics, it is possible according to the invention to use 1 to 4 layers of fabrics, knits, laces or layered fabrics of ain weight for the reinforcement of dental prostheses. 25 g and max. 250 g per im ² fabrics of any density, the so-called delivery, enabling the impregnation of fibers with a polymerizing resin. The fabrics may be reinforced by stitching or other means before reinforcement. Of the natural organic fibers, vegetable fibers, e.g. flax, cotton, etc., are more suitable for fittings according to the invention, not only for their properties, but also because fabrics are cheaper and more affordable than, for example, wool, silk, etc. Create fittings directly of fibers e.g. made of cotton wool or yarn is suitable only in rare cases, such as twine. as a replacement for metal stirrups of lower dental prostheses. Installation of fittings made of natural organic fiber fabrics can be done by polymerizing it into the dental prosthesis at atmospheric or elevated pressure, at room or elevated temperature with event, using polymerization accelerators, stabilizers, dyes and other polymerization additives used in common practice. resins.

The invention can be used to increase the strength of polyacrylic methacrylic or other resins used in dental or other techniques.

Examples of fittings according to the invention:

Example i: ⁴

The total dental prosthesis was made in a generally known manner up to the stage of resin dough application, textile reinforcement from one layer of linen powder and one layer of cotton calico cut out to match the shape of the restoration board was used for reinforcement, but the size was did not exceed the margin of compensation. The polymethacrylate resin, which is no longer sticky, is applied in a layer about 0.5 mm thick to the insulating varnish of the cast gypsum working model, cotton reinforcement is applied and it is gradually pressed over the entire surface into the applied resin dough. Then the linen reinforcement is pressed against the dough penetrated by the cotton reinforcement with a gypsum form of the second part of the cuvette coated with a layer of resin dough about 0.5 mm thick. Proceeding with the generally known procedure. .

Example 2:

When making the lower partial dental prosthesis, the usual procedure was followed up to the stage of applying the resin dough. A still sticky resin dough will wet a strip of that opaque cotton lace long as! 5 ca and 3 cm wide so that the thickness of the fabric with resin is about 2 mm. As soon as the dough stops sticking, the fabric is rolled lengthwise and the roll is applied, instead of the commonly used metal yoke, to the insulating varnish of the cuvetteed working model and after applying the second part of the cuvette, the usual procedure is followed. .

Example 3:

The upper dental prosthesis was made as described in Example 1, except that the two canvas reinforcements were wetted with liquid monomer before reinforcement, then powdered with powdered resin, applied to a microlayer of resin dough on an insulated working model and after attaching the second part of the coated cuvette. also with the microlayer of resin dough, the replacement is completed in a generally known manner.

Claims (3)

OBJECT OF THE INVENTION 1. High-strength removable dental prosthesis made of polymer resins are characterized by ·! ee in that it is made of two to five layers of polymer resin, between which 1 to 4 layers of fabric are polymerized, for example woven, knitted, lace or layered fabrics of preferably natural organic fibers weighing 25-250 g / m ² . 2. A method of making a removable dental prosthesis with increased strength according to claim 1, characterized in that successive 2 to 5 layers of resin dough are applied to the insulated gypsum model of the prosthesis, between which 1 to 4 layers of fabric are inserted. 3. A method of making a high-strength removable dental prosthesis according to claim 1, characterized in that ae successively applies 1 to 4 layers of fabric soaked in a still viscous adhesive resin dough to the insulated gypsum model of the prosthesis.