RU110974U1 - RADIATED SUPPORT FOR PROSTHETICS WITH AN ADJUSTABLE CLIP TO THE MALAYOUS ALVEOLAR PROJECT - Google Patents

Abstract

 1. The gingival support for prosthetics with an adjustable clamp to the mucous membrane of the alveolar ridge, including the crown of an artificial tooth and a gingival support made of metal, inserted into the crown with the possibility of movement in the vertical plane, while the surface of the gingival support facing the gingival surface is made saddle-shaped the shape and congruence of the surface of the alveolar process interacting with it, characterized in that the surface of the gingival support interacting with the inner surface the crown crown is made in the form of a dome, in the center of which a protrusion in the form of a vertical column is made along the common axial line, in addition, a pusher is additionally introduced, while a through hole is made in the body of the artificial tooth crown along the common axial line with the gingival support and its column, in which the pusher is located, made with the possibility of interaction with the gingival support by reciprocating movement, while the pusher is fixedly attached to the crown, in addition, the inner surface of the crown sstvennogo tooth congruent surface interacting with it nadesnevoy support and pusher surface and a vertical support column nadesnevoy inserted into the bit firmly. ! 2. The plumbing support for prosthetics according to claim 1, characterized in that the pusher comprises an extended body with a through axial hole provided with a thread and a screw screwed into the pusher body along an axial line from the side of the chewing surface of the crown. ! 3. The plumbing support for prosthetics according to claim 2, characterized in that the end of the pusher body facing �

Description

The utility model relates to medicine, namely to orthopedic dentistry, and can be used to treat patients with partial tooth loss.

Closest to the proposed epigastric support for prosthetics with an adjustable clamp to the mucous membrane of the alveolar process is the epigastric support described in the utility model of the Russian Federation, No. 93671, А61С 13/00, А61С 13/225, 01/25/2010, which contains the crown of an artificial tooth and a gingival support 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 circle, and the vertical section it has the form of two glasses, rigidly interconnected by a common bottom. One of the glasses faces 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. A thread was made in the hole in the bottom of the glasses and a screw was screwed into it from the side of the occlusal surface. 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, is turned to the side gingival surface and protrudes from the glass outward. At the same time, the part of the gingival support located inside the glass is congruent to its inner surface. The gingival support is made of titanium or zirconium dioxide, and the shaped part, rigidly fixed in the crown, is made of titanium.

Thus, in the well-known supra-gingival support for prosthetics, a special structural unit that has a complex configuration and is technically difficult to perform is used to secure the supra-gingival support in the crown of an artificial tooth. As a result, the disadvantage of the known supra-gingival support for prosthetics with an adjustable clamp to the mucous membrane of the alveolar process is the complexity of the design.

The proposed gingival support for prosthetics with an adjustable clamp to the mucous membrane of the alveolar process solves the problem of creating an appropriate device, the implementation of which allows to achieve a technical result, which consists in simplifying the design.

The essence of the utility model lies in the fact that in the claimed gingival support for prosthetics with an adjustable clamp to the mucous membrane of the alveolar ridge, including the crown of an artificial tooth and a gingival support made of metal, inserted into the crown with the ability to move in a vertical plane, while the surface of the gingival support, facing the gingival surface is made saddle-shaped and congruent to the surface of the alveolar process interacting with it, the new is that the surface the spine of the gingival support interacting with the inner surface of the crown is made in the form of a dome, in the center of which a protrusion in the form of a vertical column is made along the common axial line, in addition, a pusher is additionally introduced, while in the body of the artificial tooth crown along the common axial line with the gingival support and its column has a through hole in which the pusher is placed, made with the possibility of interaction with the gingival support by reciprocating movement, while the pusher is fixed in the crown one-piece, in addition, the inner surface of the crown of the artificial tooth is congruent with the surface of the gingival support and the surface of the pusher interacting with it, and the vertical column of the gingival support is inserted into the crown with effort. At the same time, the pusher comprises an extended body with a through axial hole provided with a thread and a screw screwed into the pusher body along an axial line from the side of the chewing surface of the crown. In addition, the end of the pusher body, facing the side of the gingival support, is provided with a shoulder made in the shape of a polygon.

The technical result is achieved as follows. The features of the utility model formula "..., including the crown of an artificial tooth and a gingival support made of metal, inserted into the crown with the ability to move in a vertical plane, while the surface of the gingival support facing the gingival surface is made saddle-shaped and congruent to the surface of the alveolar bone interacting with it , ... "are signs that ensure the operability of the claimed device, and, therefore, they ensure the achievement of the claimed technical result ultat.

The implementation of the gingival support of metal ensures the strength and safety of its use. Due to the fact that the gingival support is inserted into the crown with the ability to move in the vertical plane, it is possible to control the density of the support clamp to the mucous membrane of the alveolar process by changing the pressure on it in the vertical plane, which ensures the physiological design.

Since a gingival support of a saddle shape with a gingival surface, congruent to the surface of the alveolar process, congruent with it, is made, this ensures reliable fixation of the support on the alveolar process when it is used (the likelihood of the gingival support slipping from the alveolar process is minimized), and a physiological physiological surface is also provided to the surface of the mucous membrane of the alveolar process.

In the claimed gingival support, the pusher is placed in the hole made in the body of the artificial tooth crown along a common axial line with the gingival support and its vertical column. In this case, the hole is through. As a result, the cavities for accommodating the gingival support and for accommodating the pusher are interconnected. Since the pusher is capable of interacting with the gingival support by reciprocating movement, this allows the pusher to control the density of the gingival surface of the support against the mucous membrane of the alveolar process, which, in turn, ensures reliable fixation of the gingival support on the alveolar process and its physiology. The inseparable fastening of the pusher in the body of the crown excludes the possibility of its rotation in the process of adjusting the density of the support clamp to the mucous membrane of the alveolar process. In addition, the end of the pusher body, facing the side of the gingival support, is provided with a shoulder made in the shape of a polygon. All this ensures reliable fixation of the pusher in the crown, eliminates the possibility of its rotation in the through hole during rotation of the screw and ensures accurate control of the required pressure density.

The execution of the body of the pusher extended provides the possibility of its installation in the through hole in the body of the crown of an artificial tooth vertically along a common longitudinal line of symmetry with a gingival support. Since the pusher screw is screwed into its body along the axial line from the side of the chewing surface of the crown, it is possible to control the clamp of the supra-gingival support in the finished prosthesis through the through hole in the crown. As a result, the executive body of the pusher - a screw screwed into the body of the pusher, allows the pusher to interact with the surface of the gingival support facing it by means of vertical reciprocating movement. In addition, the implementation of the common axial cavities for the vertical column of the gingival support and pusher, as well as the congruence of the surface of these cavities of the crown to the surfaces of the vertical column of the gingival support and pusher, excludes the possibility of sliding of the actuator of the pusher from the surface of the column. In this case, the pressure force on the surface of the gingival support is directed along a common axial line. As a result, uniform pressure of the executive body of the pusher on the surface of the gingival support is provided in the process of adjusting the density of the clip, and, consequently, uniform density of pressing it to the surface of the alveolar process. At the same time, the physiological nature of the declared gingival support to the mucous membrane of the alveolar process is ensured.

In addition, the presence in the form of execution of the gingival support of a vertical column provides reliable fixation in the crown of the finished metal support, not only in a stationary state, but also when adjusting the pressure density, and the implementation of the support in the form of a dome ensures uniform distribution of pressure on the support, and, therefore, and uniform clamping of the gingival surface of the support to the mucous membrane of the alveolar process. This is because in the claimed design, the movement of the support in the tooth crown is reported by the pusher screw by moving the vertical column of the support in its corresponding cavity, which, in view of the congruence of the surfaces of the tooth crown and the vertical column, is a fairly narrow channel. The vertical column of the gingival support is inserted into the crown with effort. As a result, the movement of the vertical column, and, consequently, of the entire gingival support is carried out with effort. At the same time, the verticality of the column determines the movement of the gingival support in the tooth crown in a strictly vertical plane, which excludes the possibility of lateral displacements of the support on the alveolar process when adjusting the density of its clamp, ensures its stability on the alveolar process, eliminates the possibility of gum injury. In addition, due to the fact that the movement of the vertical column, and, consequently, of the entire gingival support is carried out with effort, i.e. the movement of the support is slower, it is possible to eliminate even a slight weakening of the density of the clamp of the gingival support to the mucous membrane of the alveolar process. This also eliminates the possibility of gum injury and ensures the physiological nature of the declared supra-gingival support.

It follows from the foregoing that the claimed gingival support for prosthetics with an adjustable clamp to the mucous membrane of the alveolar process, similarly to the prototype, allows you to adjust any undesirable changes in the density of the clamp of the gingival support to the mucous membrane of the alveolar process, due to morphometric characteristics of the mucous membrane of the alveolar process changing with time. In addition, the ability to adjust the pressure density of the gingival surface of the support to the mucous membrane of the alveolar process allows to reduce the transverse movement of the prosthesis and to reduce the likelihood of the prosthesis slipping off the alveolar process, which eliminates the requirement for the width of the alveolar process and allows the claimed supra gingival support to be used even for narrow alveolar processes. Using the claimed gingival support as an additional support with a large length of the dentition defect, as in the prototype, reduces the cantileverness of the prosthesis and the masticatory load on artificial teeth, which, in turn, reduces the likelihood of a fracture of the prosthesis with the gingival support and the likelihood of loosening of the supporting teeth. At the same time, the ability to control the density of the clamp provides the implementation of multiple adaptation of the epigastric support according to the claimed method to the mucous membrane of the alveolar process, thereby prolonging the life of the prosthesis.

As a result, the proposed implementation of the claimed supra-gingival support for prosthetics with an adjustable clamp to the mucous membrane of the alveolar process allows you to save all the positive qualities of the supra-gingival support, which is closest to the proposed one. Moreover, in comparison with the closest to the proposed, the design of the declared gingival support is simple: a gingival support made of metal, a pusher and an artificial tooth crown with communicating cavities for a gingival support and a pusher. The figured metal part, difficult to manufacture, was excluded from the design, which was permanently fixed in the crown and intended for placement of the gingival support in it. This greatly simplified the claimed supra-gingival support. In addition, at the same time, the shape of the gingival support placed in the crown of an artificial tooth was also simplified.

Thus, from the foregoing, it follows that the claimed supra-gingival support for prosthetics with an adjustable clamp to the mucous membrane of the alveolar ridge, when implemented, ensures the achievement of a technical result, which consists in its simplification.

Figure 1 shows the epigastric support for prosthetics with an adjustable clamp to the mucous membrane of the alveolar process, a vertical section along AA; figure 2 - pusher; figure 3 - pusher, view B; figure 4 - fixed bridge for replacing the dentition with an end defect; 5 is a fixed bridge for replacing the dentition with gingival support as an additional support.

Figures 1 and 2 are shown without oblique hatching so as not to obscure the drawing.

A gingival support for prosthetics with an adjustable clamp to the mucous membrane of the alveolar bone contains a gingival support 1 made of metal, for example, titanium or zirconia, made in the form of a dome, in the center of which a protrusion in the form of a vertical column 2 is made in the center line; artificial tooth crown 3 for gingival support 1; the pusher 4. The spring support 1 is inserted into the crown 3 with the possibility of movement in the vertical plane. For reliable fixation of the gingival support in the crown, the vertical column can be made with an oval section. The surface of the gingival support 1, facing the gingival surface, is made saddle-shaped. The inner surface of the crown 3 of the artificial tooth is congruent to the surface of the gingival support 1 located inside it: the surface of the gingival support 1 and the surface of the follower 4. In the body of the crown 3 of the artificial tooth, a through hole 5 is made along the common axial line with the gingival support 1 and its column 2, which placed the pusher 4, made with the possibility of interaction with the surface of the supra-gingival support 1 facing him by vertical reciprocating movement.

The pusher 4 comprises an extended housing 6, for example in the form of a cylinder or a polyhedron, with a through axial hole provided with a thread and a screw 7 screwed into the pusher body along an axial line from the side of the chewing surface of the crown, which allows the pusher 4 to interact with the surface facing it supragingival support 1 by vertical reciprocating movement. The housing 6 of the pusher 4 is fixed in the crown 3 one-piece. For a more reliable fixation of the pusher 4 in the tooth crown 3, the end of the pusher body 4 facing the gingival support is equipped with a shoulder 8 made in the example of a rectangular shape.

A fixed bridge for replacing a dentition with an end defect (Fig. 4) and a fixed bridge for replacing a dentition with a gingival support as an additional support (Fig. 5) contain crowns 9 ₁ (9 ₂ ) for supporting teeth, artificial teeth 10 ₁ (10 ₂ ) and a crown 3 with a gingival support located in the distal part of the prosthesis corresponding to the end defect (Fig. 4), and in the interval between the artificial tooth 10 ₂ and the crown 9 ₂ (Fig. 5). The gingival support 1 is applied to the mucous membrane of the alveolar process 11.

The claimed supra-gingival support for prosthetics with an adjustable clamp to the mucous membrane of the alveolar process is made as follows. Prepare abutment teeth for crowns 9 ₁ (9 ₂ ). A working model of the jaw is made of gypsum. On the working model mark the installation site of the gingival support 1 in the prosthesis. The gingival support 1 is made of metal according to a previously made model of plastic dental material. The gingival support 1 is modeled directly on the working model of the jaw at the place of its installation. For modeling, wax may be used as a plastic dental material. The gingival support 1 on the side of the gingival surface of the alveolar process 11 is modeled with a surface that is congruent to the alveolar process 11, of a saddle shape, forming for this a flange slightly covering the alveolar process 11. The surface interacting with the inner surface of the crown 3 is modeled in the shape of a dome, in the center which along the common centerline perform a protrusion in the form of a vertical column 2.

A gingival support 1 made of metal is temporarily fixed on the working model of the jaw in a marked place. On the column 2, along the common axial line along the common axial line with the gingival support and the column, the pusher 4 is temporarily fixed. The resulting structural unit is used as an artificial tooth stump. Then, a frame of the future prosthesis is made, according to which a prosthesis is made, including the crown 3 of the artificial tooth for the gingival support 1. Since the construction site of the gingival support 1 and the pusher 4 mounted on it was used as the stump of the artificial tooth, two corresponding communicating cavities were formed in the body of the crown . At the same time, a cavity is formed for fixing a rectangular shoulder 8 of the body 6 of the pusher 4. The inner surface of the crown 3 of the artificial tooth is congruent with the surface of the gingival support 1 and the surface of the body 6 of the pusher 4. The cavity for the body 6 of the pusher 4 is made through. To do this, from the chewing surface of the crown 3 along the axial line of the pusher 4, a through hole 5 is made, which is simultaneously adjustable. In this case, the vertical column 2 is performed with a cross-section that provides free passage of the shoulder 8 of the pusher 4 in the body of the crown 3 through the cavity of the vertical column during assembly of the supra-gingival support made according to the claimed method.

The assembly of the declared gingival support is as follows. If the housing 6 of the pusher 4 is provided with a shoulder 8, the pusher 4 is first inserted into the crown 3 from the gingival surface until the shoulder 8 is fixed. After that, the pusher 4 is fixed in the crown, for example, using dental glue. Then, the supra-gingival support 1 is inserted into the crown 3 with the gingival surface outward, advancing the vertical column 2 in the corresponding cavity in the tooth crown 3 until it stops with the pusher 4.

A gingival support 1 is performed for prosthetics from titanium or zirconium dioxide, which reduces the number of contraindications to the use of the claimed gingival support and ensures its physiology.

Today, zirconium dioxide is one of the most advanced dental materials. Zirconium dioxide has such important qualities 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; hypoallergenicity. The strength of zirconia significantly exceeds the strength of many metals used in dentistry. In addition, zirconium dioxide provides computer precision manufacturing and 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. 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 in the places of metal contact with living tissue (http://www.rus4you.ru / mats / titan /).

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

In addition, the property of titanium and zirconium dioxide, which provides computer precision manufacturing and design, allows the use of computer simulation of the gingival surface of the support and its shape as a whole and milling on numerically controlled machines (CNC) for the manufacture of gingival support for prosthetics:

A gingival support 1 is made by computer scanning the resulting model, followed by milling on numerically controlled machines. For this purpose, for example, CAD / CAM equipment made up of products from Wieland, Germany (Modern CAD / CAM - systems for dentistry. Source - INTERNET.) Can be used.

Use the gingival support 1 as follows. In the initial state, the vertical column 2 of the gingival support 1 is fully inserted into the crown 3 and the gingival support 1 is tightly pressed to the inner surface of the crown 3. The finished prosthesis (Figs. 4, 5) is placed on the prosthetic bed and fixed on the supporting teeth (crowns 9 ₁ (9 ₂ )). After that, visually evaluate the density of the clamp of the gingival support 1 to the mucous membrane of the alveolar process 11 and, if necessary, the density of the clamp of the gingival support 1 to the mucous membrane of the alveolar process 11 by translational movement of the screw 7 of the pusher 4, thereby informing the vertical column 2, and therefore, the gingival support 1, translational movement in the direction of the alveolar process 11 and increasing the density of the clamp support 1 to its surface. As a result, the reliability of prosthesis fixation is increased. The achievement of the nominal pressure density of the gingival surface of the support 1 to the mucous membrane of the alveolar process 2 can be judged by a change in the color of the mucous membrane: it should be slightly paler than the neighboring areas.

After obtaining the desired result, the hole 5 in the crown 3 of the gingival support 1 is bricked up with dental material.

After time, in the presence of a weakened fixation of the prosthesis, increase the clamping force of the gingival support 1. To do this, open the hole 5 and the operation of increasing the density of the clamping of the gingival support 1 to the surface of the mucous membrane of the alveolar bone 11 is repeated.

Claims (3)

1. The gingival support for prosthetics with an adjustable clamp to the mucous membrane of the alveolar ridge, including the crown of an artificial tooth and a gingival support made of metal, inserted into the crown with the possibility of movement in the vertical plane, while the surface of the gingival support facing the gingival surface is made saddle-shaped the shape and congruence of the surface of the alveolar process interacting with it, characterized in that the surface of the gingival support interacting with the inner surface the crown crown is made in the form of a dome, in the center of which a protrusion in the form of a vertical column is made along the common axial line, in addition, a pusher is additionally introduced, while a through hole is made in the body of the artificial tooth crown along the common axial line with the gingival support and its column, in which the pusher is located, made with the possibility of interaction with the gingival support by reciprocating movement, while the pusher is fixedly attached to the crown, in addition, the inner surface of the crown sstvennogo tooth congruent surface interacting with it nadesnevoy support and pusher surface and a vertical support column nadesnevoy inserted into the bit firmly. 2. The plumbing support for prosthetics according to claim 1, characterized in that the pusher comprises an extended body with a through axial hole provided with a thread and a screw screwed into the pusher body along an axial line from the side of the chewing surface of the crown. 3. The gingival support for prosthetics according to claim 2, characterized in that the end of the pusher body facing toward the gingival support is provided with a shoulder made in the form of a polygon.