RU2429798C1 - Method for making supragingival prosthesis support and supragingival prosthesis support - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: method for making a supragingival support consists in the fact that abutment crown teeth are prepared, and a working reproduction of jaw is made of plaster. A seat of the supragingival prosthesis support is marked on the reproduction. The supragingival support with a supragingival surface congruous to a surface of an alveolar process in the marking point is made. A wax reproduction of the support is scanned. Then the support is milled either of titanium, or of zirconium dioxide on a digitally program controlled machine. The supragingival prosthesis support comprises a crown with a permanently jointed shaped detail incorporating a supragingival prosthesis of adjustable pressing strength to a coupled mucosal surface of the alveolar process. The vertical section of the shaped detail represents two cups with the same bottom. One cup faces a supragingival surfaces, and the other one - an occlusal surface. The bottom is threaded for an adjusting screw driven in from the occlusal surface. The supragingival support is inserted into the cup and crank-fixed by a lock bolt. In an initial state, the supragingival support with its side facing the occlusal surface is tightly pressed to the cup bottom.

EFFECT: lower number of contra-indications to application, higher physiological characteristic and reliability.

5 cl, 3 dwg

Description

The group of inventions relates to medicine, namely to orthopedic dentistry, and can be used to treat patients with partial tooth loss.

Performed patent information search in relation to the proposed method of manufacturing a gingival support for prosthetics showed that the closest to the proposed method is the manufacture of a gingival support, in which the gingival support is made of glass brand ZX-27. In accordance with the known method, the abutment teeth are prepared under the crowns, then the working model of the jaw is made of gypsum. Glass blanks, which are of only two sizes: “L” for premolars and “S” for molars, make a gingival support with a gingival surface, a congruent surface of the alveolar ridge at the marking site on the working model. For this, one end of the glass preform is softened by heating and a surface impression of the alveolar ridge is obtained at the marking site on the working model. The opposite end of the gingival support is treated with burs to the shape of the tooth, prepared under the crown. After this, the gingival support is fixed temporarily on a marked place as an artificial tooth stump, and the frame of the future prosthesis is formed. A prosthesis is made with crowns for abutment teeth, artificial teeth and a crown for gingival support. The gingival support is permanently fixed in the corresponding crown. (“The new prosthetics system on glass supports ZX-27,” MD Arutyunov SD, MD, Karapetyan KL - see Appendix, Internet source).

The disadvantage of the method, first of all, is the presence of contraindications, which reduce its physiological properties, as they impose restrictions on its use and narrow the range of possible patients. Namely: contraindications to the use of glass supports determine very specific requirements for the morphometric characteristics of the alveolar ridge. Firstly, this is a limitation in the compliance of the mucous membrane on the alveolar process from 2 to 3 mm. This requirement for compliance of the mucous membrane was the result of the experience of using the known method and is optimal for ensuring reliable pressure of the glass gingival support made in a known manner to the mucous membrane of the alveolar process. Failure to comply with this requirement, for example, when using a support according to the known method as a supra-gingival support of a bridge in the presence of an end defect, increases the cantileverness of the entire prosthesis, and therefore, increases the likelihood of a fracture of the prosthesis near the abutment teeth. When using the gingival support made by the known method, as an additional support with a large length of the dentition defect, when the pressure density is weakened, the gingival support loses the main function for this case - a reduction in the masticatory load on artificial teeth, which leads to deformation or fracture of the prosthesis. As a result, the reliability and physiology of the method is reduced.

This also explains contraindications for the width of the alveolar process: it is not allowed to use the known method for narrow alveolar processes, as this reduces the reliability of the clamping of the supra-gingival support due to possible movements of the support in the transverse direction. It also increases the likelihood of fracture of the prosthesis, reduces the reliability and physiology of the method.

Moreover, since the stump of the supra-gingival support is fixed in one and the same crown, the pressure density to the mucous membrane of the alveolar process is determined, in fact, only by the morphometric characteristics of the mucous membrane of the alveolar process of this patient, which change over time and can differ significantly from the original. As a result of the mismatch of the morphometric characteristics of the alveolar ridge with the initial clamp density of the gingival support made by the known method, it deteriorates over time, which reduces the reliability of the method, since it increases the cantilever of the prosthesis or the load on artificial teeth (depending on the use of the gingival support made according to the known method, ) and can lead to a fracture of the prosthesis, and also reduces the physiological nature of the method, as it does not allow the patient to comfortably use the prosthesis with lennoy by a known method nadesnevoy support. Moreover, since the gingival support is fixed in one piece in the corresponding crown, as a result, the mismatch of the morphometric characteristics of the alveolar ridge with the initial one requires replacing the prosthesis, and this reduces the duration of use of the prosthesis with the known gingival support.

In addition, the prosthesis made with the well-known gingival support is securely fixed only on the abutment teeth, since the reliability of fixation of the distal end of the prosthesis (or the area with artificial teeth with the gingival support as an additional) is directly dependent on the morphometric characteristics of the mucous membrane of the alveolar process, which, as shown above, change over time. Since the stump of the support is fixed in the corresponding crown one-piece, this does not allow you to adjust the density of the clamp to the mucous membrane of the alveolar process and it is determined only by the morphometric characteristics of the mucous membrane of the alveolar process of this patient. This leads to an inevitable increase in the cantileverness of the prosthesis or an increase in the load on artificial teeth and, as a result, to a fracture of the prosthesis, shortens the duration of use of the prosthesis made using a gingival support made by a known method. In addition, an increase in the cantileverness of the prosthesis or an increase in the load on artificial teeth leads to loosening of the abutment teeth, which reduces the physiological nature of the method, and also reduces the duration of use of the prosthesis with a gingival support made according to the method

In addition, there are known cases when the glass support has cracked. This fact reduces the reliability of the method. Moreover, the glass itself is not physiological for the human body, which also reduces the physiological nature of the known method.

Thus, the method of manufacturing the gingival support revealed as a result of a patent search does not ensure the achievement of a technical result, which consists in reducing the number of contraindications to the use of the method, in increasing the physiology, in the possibility of lengthening the time of use of the prosthesis with the gingival support, in increasing reliability.

The performed patent information search in relation to the claimed gingival support used to implement the claimed method showed that the closest to the proposed is the gingival support, including a crown for an artificial tooth, in which the glass gingival support is permanently fixed, while the gingival surface of the support is congruent with the corresponding the surface of the alveolar bone (“The new prosthetics system on glass supports ZX-27”, MD Arutyunov SD, MD Karapetyan KL - see attached Ie, source of information INTERNET).

The disadvantage of the well-known gingival crown, first of all, is the presence of contraindications that reduce the physiology of the well-known gingival support, as they impose restrictions on its use and narrow the range of possible patients. Namely, contraindications to the use of glass supports determine very specific requirements for the morphometric characteristics of the alveolar process. Firstly, this is a limitation in the compliance of the mucous membrane on the alveolar process from 2 to 3 mm. This requirement for compliance of the mucous membrane was the result of the experience of using the known method and is optimal to ensure reliable pressure of the glass gingival support to the mucous membrane of the alveolar process. Failure to comply with this requirement, for example, when using a support as a gingival support of a bridge in the presence of an end defect, increases the cantileverness of the entire prosthesis, and therefore increases the likelihood of a fracture of the prosthesis near the abutment teeth. When using the gingival support as an additional support when the length of the dentition defect is large, when the pressure density is weakened, the gingival support loses the main function for this case - reducing the masticatory load on artificial teeth, which leads to deformation or fracture of the prosthesis. As a result, the reliability and physiology of the gingival support are reduced.

This also explains contraindications for the width of the alveolar ridge: it is not allowed to use the well-known gingival support for narrow alveolar processes, since this reduces the reliability of the clamping of the gingival support due to possible movements of the support in the transverse direction. It also increases the likelihood of a fracture of the prosthesis, reduces its reliability and physiology.

Moreover, since the stump of the supra-gingival support is fixed in one piece, the density of the clamp to the mucous membrane of the alveolar bone is determined, in fact, only by the morphometric characteristics of the mucous membrane of the alveolar bone of this patient, which change over time and can significantly differ from the original. As a result of the mismatch of the morphometric characteristics of the mucous membrane of the alveolar process with the initial clamp density of the gingival support, it deteriorates over time, which reduces its reliability because it increases the cantilever of the prosthesis or the load on artificial teeth (depending on the use of the gingival support made by a known method) and can lead to a fracture the prosthesis, as well as physiology, as it does not allow the patient to comfortably use the prosthesis with a known supra-gingival support. In addition, since the gingival support is fixed in one piece in the corresponding crown, as a result, the discrepancy between the morphometric characteristics of the mucous membrane of the alveolar process and the initial one requires replacing the prosthesis, and this reduces the duration of use of the prosthesis with a known gingival support.

In addition, the prosthesis made with the well-known gingival support is securely fixed only on the abutment teeth, since the reliability of fixation of the distal end of the prosthesis (or the area with artificial teeth with the gingival support as an additional) is directly dependent on the morphometric characteristics of the mucous membrane of the alveolar process, which, as shown above, change over time. Since the stump of the support is fixed in the corresponding crown one-piece, this does not allow you to adjust the density of the clamp to the mucous membrane of the alveolar process and it is determined only by the morphometric characteristics of the mucous membrane of the alveolar process of this patient. This leads to an inevitable increase in the cantileverness of the prosthesis or an increase in the load on artificial teeth and, as a result, to a fracture of the prosthesis, shortens the duration of use of the prosthesis made using the gingival support. In addition, an increase in the cantileverness of the prosthesis or an increase in the load on artificial teeth leads to loosening of the supporting teeth, which reduces the physiological nature of the gingival support, and also reduces the duration of use of the prosthesis made with the known gingival support.

In addition, there are known cases when the glass support has cracked. This fact reduces the reliability of the known gingival support. Moreover, glass in itself is not physiological for the human body, which also reduces the physiological nature of the known support.

Thus, the gingival support for prosthetics identified as a result of a patent search during implementation does not ensure the achievement of a technical result consisting in reducing the number of contraindications for use, in increasing physiology, in the possibility of lengthening the time of use of a prosthesis with a gingival support, in increasing reliability.

The present invention, a method of manufacturing a gingival support for prosthetics, solves the problem of creating an appropriate method, the implementation of which allows to achieve a technical result, which consists in reducing the number of contraindications to the use of the method, in increasing physiology, in the possibility of lengthening the time of use of the prosthesis with gingival support made by the method, increase reliability.

The essence of the claimed method consists in the fact that in the method of manufacturing the gingival support, according to which the supporting teeth are prepared for the crowns, then the working model of the jaw is made of gypsum, the place for installing the gingival support of the prosthesis is marked on the finished model, the gingival support is made with gingival surface congruent the surface of the alveolar ridge at the place of marking on the working model of the prosthesis, and the crown for the gingival support, then place the gingival support in the crown with the gingival surface outward, new It is said that the gingival support of the bridge is placed in the corresponding crown of the artificial tooth with the possibility of adjusting the force of pressing of its gingival surface to the mucous membrane of the alveolar process, and the gingival support of the bridge is made of either titanium or zirconia, and the gingival surface is first formed, congruent surface of the alveolar ridge at the place of marking on the working model of the prosthesis, and the shape of the gingival support by modeling from plastic dental of the material, then, according to the model, a computer scan is performed, after which the gingival support is made, for which they are milled from titanium or zirconia on a numerically controlled machine.

The technical result is achieved as follows. Features of the claims; “... prepare abutment teeth for crowns, then make a working model of the jaw of gypsum, mark on the finished model the installation site of the gingival support of the prosthesis, make the gingival support with the gingival surface, the congruent surface of the alveolar ridge at the marking place on the working model of the prosthesis, and the crown for the gingival support , then the supra-gingival support is placed in the crown with the gingival surface outward, ... ”are the signs ensuring the operability of the claimed method, and therefore, they provide up to tizhenie claimed technical result. Preparation of abutment teeth for crowns provides the possibility of manufacturing a working model of gypsum. Marking the installation site of the gingival support of the prosthesis on the finished model allows us to determine its future location, taking into account future replacement teeth, which ensures the physiological nature of the method. Due to the fact that a gingival support with a gingival surface, a congruent surface of the alveolar ridge at the marking place on the working model is made, using a gingival support made by the method, physiological uniform pressure of the gingival surface of the support against the surface of the mucous membrane of the alveolar ridge is ensured, which ensures the physiological nature of the method and reliability. Since the framework of the future prosthesis is formed with temporarily fixed on the working model in the place of marking the finished gingival support, this makes it possible to manufacture the crown of the required artificial tooth for the gingival support, which ensures the physiology of the known method.

The main difference between the claimed method and the prototype is that the gingival support of the bridge is placed in the corresponding crown of the artificial tooth with the possibility of adjusting the density of the clamp of its gingival surface to the mucous membrane of the alveolar process. This allows you to adjust any undesirable changes in the density of the gingival support clamp to the mucous membrane of the alveolar process, due to morphometric characteristics of the mucous membrane of the alveolar process that change over time, which eliminates the requirements for compliance of its mucous membrane. In addition, the claimed method allows, by adjusting the density of the gingival surface of the gingival support to the mucous membrane, to reduce the transverse movement of the prosthesis and reduce the likelihood of the prosthesis sliding off the alveolar process, which eliminates the requirement for the width of the alveolar process and allows you to use the claimed method of manufacturing the gingival support even for narrow alveolar processes processes. At the same time, the introduction of an adjustable density of the clamp of the gingival support to the mucous membrane increases the physiology and reliability of the claimed method, since it allows to reduce the cantileverness of the prosthesis with the gingival support made according to the claimed method, as well as to reduce the masticatory load on artificial teeth when using the gingival support made according to the claimed method , as an additional support with a large extent of a dentition defect. This reduces the likelihood of fracture of the prosthesis with gingival support and the likelihood of loosening of the supporting teeth. This increases the comfort of using both the gingival support made according to the claimed method and the prosthesis with this gingival support, which increases the physiological nature of the claimed method.

In addition, since the gingival support is fixed in the corresponding crown of an artificial tooth with the ability to adjust the force of the gingival support surface to the mucous membrane of the alveolar process, the claimed method allows you to repeatedly adjust the density of the gingival support to the mucous membrane, which allows multiple adaptation to the mucous membrane of the alveolar process, made by the method of gingival support. This, in turn, lengthens the time of use of the prosthesis with a gingival support made according to the claimed method. Moreover, since the mismatch of the morphometric characteristics of the alveolar process with the initial one that appears over time is simultaneously eliminated, this increases the physiological nature of the claimed method.

In addition, in contrast to the prototype, which is limited in width of the alveolar ridge, the claimed method allows to perform supragingival support with the gingival surface of any shape for any width of the alveolar ridge, since in the claimed method "... first form the gingival surface congruent to the surface of the alveolar ridge in the place of marking on the working model of the jaw, and the shape of the gingival support by modeling from plastic dental material, then a computer scan is performed according to the model then the gingival support is made, for which it is milled from titanium or zirconium dioxide on a numerically controlled machine. ”As a result, together with the possibility of adjusting the density of the gingival support to the mucous membrane of the alveolar ridge, the width of the alveolar bone is removed.

In the inventive method, the gingival support of the bridge is made of either titanium or zirconia.

Today, zirconium dioxide is one of the most advanced dental materials. Zirconia has important qualities such as biocompatibility; ease of construction; durability and ease of use; protection against caries under crowns; the absence of a negative reaction to heat and cold in the teeth; hypoallergenic materials used for the manufacture of prostheses, which allows the use of zirconia prosthetics for people suffering from allergic diseases; strength. The strength of zirconia significantly exceeds the strength of many metals used in dentistry. In addition, zirconia provides computer precision manufacturing and design (http://www.clinicalmeda.ru/spagels/365_koronki_dioksid_ceny.html).

With an increase in allergic reactions to various metals and metal alloys used in medicine and dentistry, titanium, like zirconium dioxide, is considered as a decisive alternative. Due to the remarkable biocompatibility and incredible stability of titanium, this metal has attracted the attention of medicine. High biocompatibility is due to the ability of titanium to form a protective oxide layer on its surface in a fraction of a second, due to which it does not corrode and does not give away free metal ions, which are capable of causing pathological processes at the sites of metal contact with living tissue.

Titanium is a pure chemical element, metal; serial number in the periodic system of elements 22.

In dental practice, pure titanium is used. Titanium has the ability, while in the body, to remain inert for a long time; the density of titanium is about four times lower than the density of gold; low thermal conductivity; biocompatibility, corrosion resistance; neutral taste does not cause unpleasant taste sensations; lack of metal taste in the mouth (http://www.rus4you.ru/mats/titan/).

Titanium, as well as zirconium dioxide, provides computer precision manufacturing and design.

From the foregoing, it follows that the implementation of supragingival support for prosthetics of titanium or zirconium dioxide reduces the number of contraindications to the use of the claimed method and increases its physiology.

In addition, the property of titanium and zirconia — ensuring computer precision in manufacturing and design — allows computer modeling of the gingival surface of the support and its shape as a whole and milling on numerically controlled machines (CNC) to produce a gingival support for prosthetics: “... gingival surface congruent with the surface of the alveolar ridge at the marking site on the working model of the prosthesis, and the shape of the gingival support by modeling from a plastic denture of biological material, then a computer scan is performed according to the model, after which the gingival support is made, for which it is milled from titanium or zirconia on a numerically controlled machine. ”This, in turn, allows to obtain high accuracy of the shape of the gingival surface of the gingival support made by the method, and therefore, high biocompatibility of its surface with the surface of the mucous membrane of the alveolar process, which increases the physiological nature of the method, increases the density of the clip, reduces the The salinity of the prosthesis with such a gingival support reduces loosening of the supporting teeth, and therefore ensures the achievement of a technical result consisting in reducing the number of contraindications to the use of the method, in increasing the physiology, in the possibility of lengthening the time of using the prosthesis with a gingival support made according to the method, in increasing reliability .

The use of computer modeling of orthopedic structures in modern orthopedic dentistry and its further manufacture by milling on CNC machines is well known. It is known to use this system for the manufacture of single crowns and short and long bridges, telescopic crowns, individual abutments for implants, to recreate the full anatomical shape for models of press ceramics applied to the frame (overpress), to create temporary crowns in full profile and for creating various injection molds. The system provides high accuracy and excellent biocompatibility. The material may be zirconium dioxide, titanium, cobalt-chromium alloy, wax, plastic ("Modern CAD-CAM - systems in dentistry", source - INTERNET).

However, the use of a computer simulation and milling system on CNC machines for the manufacture of a gingival support for prosthetics with the shape of its gingival surface congruent to the surface of the alveolar ridge is not known previously. This method of manufacturing a gingival support is proposed by the author of the invention and is used for the first time in the claimed method. At the same time, the possibility of using a computer simulation and milling system on CNC machines for the manufacture of a gingival support in the claimed invention is provided due to the fact that either titanium or zirconia are used for the support, which provide computer-aided manufacturing and design accuracy. The manufacture of titanium or zirconia epigastric support for prosthetics is not previously known. The manufacture of gingival support from these materials was first proposed by the inventor.

Thus, from the foregoing, it follows that the present invention is a method of manufacturing a gingival support for prosthetics, when implemented, it provides a technical result, which consists in reducing the number of contraindications to the use of the method, in increasing physiology, in the possibility of lengthening the time of use of the prosthesis with gingival support, in increase reliability.

The claimed gingival support for prosthetics, implementing the claimed method of manufacturing the gingival support for prosthetics, solves the problem of creating a gingival support for prosthetics, the implementation of which allows to achieve a technical result, which consists in reducing the number of contraindications for use, in increasing physiology, in the possibility of lengthening the time of use of the prosthesis with gingival pillar in improving reliability.

The essence of the claimed invention "Gingival support for prosthetics", carrying out a method of manufacturing a gingival support for prosthetics, lies in the fact that in the gingival support for prosthetics, including the crown of the artificial tooth and placed on it gum support, while the surface of the gingival support facing toward the gingival surface , congruent with the surface of the alveolar ridge that interacts with it, new is that the epigastric support is made of tatan or zirconia, and in the crown the support is placed inside, fixed in the crown, one-piece, hollow, curly, symmetrical in the vertical plane of the metal part, the cross section of which is either an equilateral polygon or a circle, and the vertical section has the form of two glasses rigidly connected to each other by a common bottom, one of which are directed towards the gingival and the other toward the occlusal surface, in the crown and in the bottom of the glasses are made coaxially through axial holes, while in the hole in the bottom of the glasses a thread is made and a screw is screwed into it from the side of the occlusal surface, while the gingival support is inserted into the glass facing the gingival surface, so that in the initial state it is pressed to the bottom of the glasses with the side facing the occlusal surface, and the other side is congruent the mucous membrane of the alveolar ridge that interacts with it, faces the gingival surface and protrudes out of the glass, while the part of the gingival support located inside the glass is congruent to its inner surface and.

In addition, in a symmetrical figured part, the size of the cross section of the glass facing the side of the occlusal surface is smaller than the size of the cross section of the glass facing the side of the gum surface, which, in addition, is equipped with a vertical cut. At the same time, a part of the gingival support placed inside the cup facing the gingival surface, in cross section, has a locking tongue corresponding to the place of cutting, and the shaped part, rigidly fixed in the crown, is made of titanium.

The technical result is achieved as follows.

The features of the claims: "The gingival support for prosthetics, including the crown of an artificial tooth and the gingival support placed in it, while the surface of the gingival support, facing the gingival surface, is congruent with the surface of the alveolar bone interacting with it ..." are the signs that ensure the operability of the declared gingival supports for prosthetics, and therefore, they ensure the achievement of the claimed technical result.

Introduction to the design of the gingival support for prosthetics, which is rigidly fixed in the crown for the gingival support, of a hollow, figured part, provides the possibility of non-rigid fixing of the gingival support in the crown. The implementation of the curved part symmetrical with a vertical section in the form of two glasses rigidly connected to each other by a common bottom, one of which is facing the gingival side, and the other to the side of the occlusal surface, made it possible to form two cavities coaxial in the vertical plane, one of which is facing towards the gingival, and the other toward the occlusal surface.

A rigid connection between them by a common bottom provided the possibility of performing a common axial hole for both cavities, which ensured the communication of the cavities, and the execution of a thread in the axial hole made it possible to place a screw in it. Since the gingival support is inserted into the glass, facing the gingival surface, so that in the initial state it is with the side facing the occlusal surface tightly pressed to the bottom of the glasses, while the part of the gingival support inside the glass is congruent to its inner surface, then As a result, the screw is provided with non-gingival support. Moreover, the interaction of the screw with the gingival support is provided starting from the extreme upper position of the support, which allows you to adjust the pressure density of the gingival surface of the support already at the initial stages of changing the morphometric characteristics of the mucous membrane of the alveolar process, compared with the initial ones, which increases the physiology of the declared non-gingival support for prosthetics.

Performing coaxially with the through hole in the bottom of the glasses of the through axial hole in the crown, as well as the screw being screwed in from the side of the occlusal surface, provides the ability to manipulate the screw: screwing in and out of the screw when using the gingival support in the prosthesis fixed on the supporting teeth. Moreover, since the gingival support is inserted, in the glass facing the gingival surface and, in addition, in the initial state, with the side facing the occlusal surface, it is firmly pressed to the bottom of the glasses, and its other side, congruent with the mucous membrane of the alveolar process, facing toward the gingival surface and protrudes out of the glass outward, the translational movement of the screw leads to the translational movement of the supra-gingival support, which allows you to adjust the density of the clamp support to izistoy shell alveolar bone that provides achievement of the claimed technical result. Moreover, since the part of the gingival support located inside the cup is congruent to its inner surface, this provides a tight hold of the side surface of the support to the surface of the inner wall of the cup, which in turn ensures smooth adjustment and reliable preservation of the achieved position of the gingival support in the figured part, and therefore, the achievement of the claimed technical result.

Since the glass facing the gingival surface is provided with a vertical cut, and the part of the gingival support located inside the glass facing the gingival surface has a stop tab in cross section corresponding to the place of cutting, this eliminates the turning of the gingival support during translational movement of the screw, which eliminates injury to the mucous membrane, ensures the physiological design of the prosthesis, and also increases reliability.

Due to the fact that the gingival surface of the gingival support is congruent with the corresponding surface of the alveolar process, a physiological uniform clamping of the gingival support to the surface of the mucous membrane of the alveolar process is ensured, which ensures its physiology.

The execution of the curly part increases the adhesion surface of the material of the crown with the part, which ensures the adhesion of the material of the crown to the surface of the part and ensures its permanent fixation in the crown, ensures the operability of the structure and, therefore, ensures the achievement of the claimed technical result. The performance of the metal part ensures the strength of the structure, and the execution of titanium ensures the strength of the structure, reduces the weight of the curly part and facilitates the adjustment of the density of the clamp of the gingival support to the mucous membrane of the alveolar bone, thereby increasing its physiology.

Due to the fact that the figured part, symmetrical in the vertical plane, while in the cross section of the part is either an equilateral polygon, or a circle, and the fact that the figured symmetrical part in the vertical section has the form of two glasses connected by a common bottom, the load is distributed evenly support as a result of chewing efforts, which ensures uniformity of the pressure density of the support against the mucous membrane, increases physiology, increases the reliability of the structure. In addition, since the part is symmetrical in the vertical plane, the screw is screwed into the axial hole of the bottom of the glasses, and the part of the gingival support located inside the cup is congruent to its inner surface, then with the translational movement of the screw, uniform pressure is applied to the gingival support, which ensures uniform pressure density of the gingival surface support to the mucous membrane of the alveolar process.

From the foregoing, it follows that the main difference between the claimed gingival support for prosthetics and the prototype is that in the crown the gingival support is placed inside, fixed in the crown, one-piece, hollow, curly, symmetrical in the vertical plane of the metal part, the cross-section of which is an equilateral polygon, or a circle, and the vertical section is in the form of two glasses, rigidly interconnected by a common bottom, one of which is facing the gingival side, and the other is facing the occlus zion surface. The presence of two coaxial cavities in the curved part made it possible to introduce an adjustment element - a screw for changing the density of the gingival surface of the gingival support against the mucous membrane of the alveolar ridge, placing it in the cavity facing the occlusal surface, and placing the gingival support in the cavity facing the gingival surface . As a result, the translational movement of the screw in the figured part leads to the translational movement of the support, which allows you to adjust the density of the support of the support to the mucous membrane of the alveolar process and ensures the achievement of the claimed technical result.

Thus, in the claimed supra-gingival support for prosthetics by translating the screw interacting with the supra-gingival support, it is possible to adjust the density of the gingival surface of the gingival support against the mucous membrane of the alveolar process. This allows you to adjust any undesirable changes in the density of the gingival support clamp to the mucous membrane of the alveolar process, due to morphometric characteristics of the mucous membrane of the alveolar process that change over time, which eliminates the requirements for compliance of its mucous membrane. In addition, the claimed supra-gingival support for prosthetics allows, by adjusting the pressure density of the contact surface of the supra-gingival support to the mucous membrane, to minimize its own transverse movement, and therefore the transverse movement of the prosthesis that uses it, and to reduce the likelihood of the prosthesis sliding off the alveolar process, which increases its physiology and reliability. In addition, providing the required pressure density reduces the cantileverness of the prosthesis with the gingival support, and this reduces the likelihood of a fracture of the prosthesis and loosening of the supporting teeth. This increases the comfort of using both the gingival support and the prosthesis with its use, which also increases the physiology of the declared gingival support.

In addition, since the gingival support has the ability to adjust the density of the gingival surface to the mucous membrane of the alveolar process, this allows you to adjust the density of the grip of the support repeatedly, which allows multiple adaptation to the mucous membrane of the alveolar process of the supragingival support without replacement and extends the time of use of the prosthesis with the gingival support. At the same time, the inconsistencies in the morphometric characteristics of the alveolar process with the initial ones that appear over time are eliminated, which increases the physiological nature of the declared supra-gingival support for prosthetics.

In addition, unlike the prototype, which has limitations on the width of the alveolar ridge, the claimed prosthesis, due to the property of titanium and zirconium dioxide: ensuring computer precision in manufacturing and design, allows using computer technology to produce a supragingival support with a gingival surface of any shape for any the width of the alveolar process, which, combined with the ability to adjust the density of the clamp of the supra-gingival support to the mucous membrane of the alveolar process, removes restrictions on the width alveolar bone.

In the claimed invention, the gingival support is made of titanium or zirconia.

Today, zirconium dioxide is one of the most advanced dental materials. Zirconia has important qualities such as biocompatibility; ease of construction; durability and ease of use; protection against caries under crowns; the absence of a negative reaction to heat and cold in the teeth; hypoallergenic materials used for the manufacture of prostheses, which allows the use of zirconia prosthetics for people suffering from allergic diseases; strength. The strength of zirconia significantly exceeds the strength of many metals used in dentistry. In addition, zirconia provides computer precision manufacturing and design (http://www.clinicalmeda.ru/spagels/365_koronki_dioksid_ceny.html).

With an increase in allergic reactions to various metals and metal alloys used in medicine and dentistry, titanium, like zirconium dioxide, is considered as a decisive alternative. Due to the remarkable biocompatibility and incredible stability of titanium, this metal has attracted the attention of medicine. High biocompatibility is due to the ability of titanium to form a protective oxide layer on its surface in a fraction of a second, due to which it does not corrode and does not give away free metal ions, which are capable of causing pathological processes at the sites of metal contact with living tissue.

Titanium is a pure chemical element, metal; serial number in the periodic system of elements 22.

In dental practice, pure titanium is used. Titanium has the ability, while in the body, to remain inert for a long time; the density of titanium is about four times lower than the density of gold; low thermal conductivity; biocompatibility, corrosion resistance; neutral taste does not cause unpleasant taste sensations; lack of metal taste in the mouth (http://www.ras4you.ru/mats/titan/).

Titanium, as well as zirconium dioxide, provides computer precision manufacturing and construction.

From the above it follows that the implementation of the gingival support of titanium or zirconium dioxide reduces the number of contraindications to the use of the claimed gingival support for prosthetics and increases its physiology.

The implementation of the epigastric support of titanium or zirconium dioxide is not previously known. The implementation of the gingival support of titanium or zirconium dioxide is proposed for the first time by the inventor.

In addition, the property of titanium and zirconia — ensuring computer precision in manufacturing and design — allows computer modeling of the contact surface of the gingival support and its milling on numerically controlled machines (CNC) for manufacturing the gingival support. This, in turn, allows to obtain high accuracy of the shape of the gingival surface of the gingival support, and therefore, to obtain high biocompatibility of its surface with the surface of the mucous membrane of the alveolar process, which increases the pressure density, and therefore, the physiology and reliability of the declared gingival support for prosthetics.

Thus, from the foregoing, it follows that the claimed gingival support for prosthetics, implementing the inventive method for manufacturing the gingival support for prosthetics, when implemented, ensures the achievement of a technical result consisting in reducing the number of contraindications for use, in increasing physiology, in the possibility of lengthening the time of use of the prosthesis with the gingival pillar in improving reliability.

On figa shows a fixed bridge for replacing a dentition with an end defect; figb depicts a fixed bridge for replacing the dentition with suprametal support as an additional support; figure 2 - nasal support for prosthetics, carrying out the claimed method of manufacturing a nasal support for prosthetics, a vertical section.

A fixed bridge for replacing a dentition with an end defect (Fig. 1) and a fixed bridge for replacing a dentition with a gingival support as an additional support (Fig. 2) contains crowns 1 ₁ (1 ₂ ) for supporting teeth , artificial teeth 2 ₁ (2 ₂ ) and placed in the distal part of the prosthesis corresponding to the end defect (Fig. 1a), or in the interval between the artificial teeth (Fig. 1b), the crown 3, in which the gingival support 4 of the bridge is placed. The surface of the gingival support 4, facing the gingival surface, is congruent with the surface of the alveolar process interacting with it. The gingival support 4 is made of titanium or zirconia. In the crown 3, the gingival support 4 is placed inside the integral part of the metal part 5. The figure 5 is made of titanium. The cross section of part 5 is either an equilateral polygon or a circle, and the vertical section has the form of two glasses 6 and 7, rigidly interconnected by a common bottom 8, one of which 6 is facing the gingival, and the other is towards the occlusal surface. In the crown 3 and in the bottom 8 of the glasses 6, 7 are made coaxially through axial holes 9 and 10, respectively. At the same time, a thread is made in the hole 9 in the bottom of the 8 glasses and a screw 11 is screwed into it from the side of the occlusal surface. At the same time, the gingival support 4 is inserted into the glass 6, facing the gingival surface in such a way that in the initial state it is firmly pressed to the bottom of the 8 occlusal surface by 8 glasses 6 and 7, and its other side congruent with the mucous membrane interacting with it the membrane of the alveolar ridge, facing the gingival surface and protrudes out of the glass 6. At the same time, the part of the gingival support 4 located inside the glass 6 is congruent to its inner surface.

In the curly symmetrical part 5, the size of the cross section of the cup 7 facing the occlusal surface is smaller than the size of the cross section of the cup 6 facing the gingival surface, which, in addition, is equipped with a vertical cut 12.

Part of the gingival support 4, placed inside the cup 6, facing the gingival surface, has a locking tab 13 in cross section (FIG. 2, view BB), corresponding to the place of cut 10.

In the exemplary embodiment, the curly symmetrical part 5 in a vertical section has the form of two U-shaped glasses. The vertical and transverse dimensions of the figured part 5 are determined by the shape and size of the tooth crown, which replaces the crown 3 of the artificial tooth of the gingival support 4. In this case, the outer dimensions of the figured part 5 are close to the size of the stump of the tooth turned under the crown and depend on the tooth (canine, premolar, molar) and methods of turning the tooth under the crown, characteristic of a particular orthopedic doctor. So, in our case, for canine, premolar and molars, these sizes fluctuated within the following limits: cup diameter 6 - from 5 to 7 mm (depending on the width of the tooth); the height of the part 5 is from 4 to 5 mm (depending on the height of the tooth); cup diameter 7 - from 2 to 2.5 mm (determined by the ability to obtain the desired shape of the upper part of the crown); step height from 2 to 2.5 mm (determined by the adhesion to the crown material and the possibility of obtaining the desired tooth shape).

The inner diameter of the cup 7 is determined by the diameter of the screw head 11 selected for adjustment. The inner diameter of the glass 6 is determined by the width of the alveolar process. Choose its size less than the width of the alveolar ridge from the condition of ensuring a stable position of the supra-gingival support 4 on the alveolar ridge and the possibility of obtaining a saddle-shaped gingival surface of the gingival support 4.

In the present invention, part 5 can be made standardized with average parameters. Item 5 can be milled from titanium.

A method of manufacturing a gingival support for prosthetics is as follows. The abutment teeth are prepared for the crowns, then the working model of the jaw is made of gypsum, the place for the installation of the gingival support of the prosthesis is marked on the finished model, the gingival support with the gingival surface, the congruent surface of the alveolar ridge at the marking place on the working model of the prosthesis is made, and the crown for the gingival support, then the gingival support is placed in the gingival surface outward into the corresponding crown of an artificial tooth with the possibility of adjusting the force of pressing of its gingival surface to the mucous membrane chke of the alveolar process. Moreover, the gingival support of the bridge is made of either titanium or zirconium dioxide. In this case, first, by modeling from plastic dental material, the shape of the gingival support and its gingival surface, the congruent surface of the alveolar ridge at the marking site on the working model are formed. Then, a computer scan is performed on the model. After that, the gingival support is made, for which they are milled from titanium or zirconium dioxide on a numerically controlled machine.

For the manufacture of a gingival support by computer scanning the shape of the gingival support and its gingival surface and its milling on numerically controlled machines, for example, CAD / CAM equipment composed of products from Wieland, Germany (Modern CAD / CAM systems for dentistry can be used). Source - INTERNET.)

As a plastic dental material, wax may be used. The wax model of the gingival support is scanned using a scanner, which converts the information about the appearance of the wax model into a computer file. Then, using a special computer simulation program, a gingival support is constructed. The program offers a design, and a technician can change it with a computer “mouse” in much the same way that a wax composition is made using an electric spatula on a plaster model. In addition, the design can always be viewed from any angle, “removed” from the model, considered any section, etc. The result is an optimal design of the gingival support.

After modeling, the file with the design of the gingival support is fed to the control unit of the milling machine. As a result, the material (from titanium or zirconium dioxide) embodies a three-dimensional model of the gingival support of the prosthesis, created in advance on a computer.

The gingival support for prosthetics is made and used as follows.

The gingival support for prosthetics is made in accordance with the claimed method. Prepare abutment teeth for crowns 1 ₁ (figa) or 1 ₂ (fig.1b). Then make a working model of the jaw of gypsum. On the finished model mark the installation site of the supra-gingival support 4 of the prosthesis. Then, a gingival support 4 is made with a gingival surface, a congruent surface of the alveolar process at the marking site on the working model. To do this, take the curly part 5 and densely fill with wax the glass of part 5, facing the gingival side. Take wax so much that it protrudes out of the glass of part 5 and, upon receipt of the impression, forms a collar slightly covering the olveolar process (saddle-shaped form of the gingival surface of the support). Otherwise, the gingival support may rub the mucous surface. At the same time, it is ensured that the wax well fills the cut 10. To obtain an impression, part 5 is pressed tightly with wax to the installation site of the gingival support of the prosthesis, marked on the finished plaster model of the jaw. The resulting print has the shape of the gingival surface of the gingival support, congruent to the surface of the alveolar ridge at the marking site on the working model. The outer edge of the gingival support 4 extending from the cup 6 is drawn. Then the wax model is removed from the cup 6 of the part 5, make sure that the part of the gingival support 4 inside the cup 4 is completely congruent to its inner surface and the locking tab 13 is formed (view B -B). If necessary, make appropriate amendments, simulating the desired shape. Then, according to the wax model of the gingival support 4, computer scanning is performed. After that, the gingival support 4 is made, for which it is milled from titanium or zirconia on a numerically controlled machine.

Then, the finished supra-gingival support 4 is inserted into the part 5 in the glass 6, facing the gingival side, so that in the initial state it is firmly pressed to the bottom of the 8 glasses with the side facing the occlusal surface, and its other side congruent to interacting with her mucous membrane of the alveolar process, facing the gingival surface and protruded from the glass 6 out. In this case, the locking tongue 13 is fixed in the cut of the glass. After that, the part 5 in the assembly with the gingival support 4 is temporarily fixed on the working model in the place of marking and in the traditional way: the frame of the future prosthesis is formed, according to which the prosthesis is made with crowns 1 for abutment teeth, with artificial teeth 2 and crown 3 of an artificial tooth for gingival support 4. After making the prosthesis, part 5 is permanently glued to the crown of the artificial tooth 3 for the gingival support 4. After that, the gingival support 4 is inserted into the part 5 in the above manner. Then the prosthesis is placed on the prosthetic bed and fixed on the abutment teeth. After that, visually evaluate the density of the clamp of the gingival support 4 to the mucous membrane of the alveolar process and, if necessary, the prosthesis is fixed in the place of fixation of the gingival support 4, changing the density of the clamp of the gingival support to the mucous membrane of the alveolar process by translational movement of the screw 11, thereby informing the support 4 of the downward movement and increasing the density of the clip. The achievement of the nominal pressure density of the gingival surface of the support to the mucous membrane of the alveolar process can be judged by a change in the color of the mucous membrane: it should be slightly paler than neighboring areas.

After obtaining the desired result, the hole 10 in the crown 3 of the gingival support 4 and the glass 7, facing the occlusal surface, are stained with dental material.

After time, if necessary, increase the pressing force, the hole 10 and the glass 7 with the screw 11 are opened and the operation of increasing the density of the gingival surface of the gingival support 4 to the surface of the mucous membrane of the alveolar process is repeated.

Claims (5)

1. A method of manufacturing a gingival support for prosthetics, according to which the supporting teeth are prepared for crowns, then a working model of the jaw is made of gypsum, on the finished model, the installation site of the gingival support of the prosthesis is marked, a gingival support with a gingival surface, congruent surface of the alveolar process in place markings on the working model of the prosthesis, and the crown of the artificial tooth for the gingival support, then place the gingival support in the crown with the gingival surface outward, which differs m, that the gingival support is placed in the corresponding crown of the artificial tooth with the possibility of adjusting the pressure force of its gingival surface against the mucous membrane of the alveolar process, and the gingival support of the bridge is made of either titanium or zirconia, while first they are formed from plastic dental material by modeling the shape of the gingival support and its gingival surface, the congruent surface of the alveolar ridge at the marking site on the working model of the jaw, and then ate operate computer scanning, and then made nadesnevuyu support, which is milled from a titanium or zirconium dioxide on a machine with numerical control. 2. A gingival support for prosthetics, including the crown of an artificial tooth and a gingival support located therein, while the surface of the gingival support facing the gingival surface is congruent with the surface of the alveolar bone interacting with it, characterized in that the gingival support is made of titanium or dioxide zirconium, and in the crown, the gingival support is placed inside the metal part fixedly fixed in the crown, hollow, curly, symmetrical in the vertical plane, the cross section of which d is either an equilateral polygon or a circle, and the vertical section has the form of two glasses rigidly connected to each other by a common bottom, one of which is facing the gingival side, and the other is towards the occlusal surface, in the crown and in the bottom of the glasses are made coaxially through axial holes, while in the hole in the bottom of the glasses a thread is made and a screw is screwed into it from the side of the occlusal surface, while the gingival support is inserted into the glass, facing the gingival surface, so that in the initial state, it is firmly pressed to the bottom of the glasses with the side facing the occlusal surface, and its other side, congruent to the mucous membrane of the alveolar process interacting with it, faces the gingival surface and protrudes out of the glass, while part of the gingival support located inside the glass congruent to its inner surface. 3. The gingival support for prosthetics according to claim 2, characterized in that in the curly symmetrical part, the size of the cross section of the cup facing the occlusal surface is smaller than the size of the cross section of the cup facing the gingival surface, which is also provided with a vertical cut . 4. The gingival support for prosthetics according to claim 3, characterized in that the part of the gingival support located inside the glass facing the gingival surface, in cross section, has a locking tab corresponding to the place of cut. 5. The plumbing support for prosthetics according to claim 3, characterized in that the shaped part, rigidly fixed in the crown, is made of titanium.

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