RU2329004C1 - Method of foreteeth reconstruction preventing crown angle defects not lower than neck third of its height with application of reinforcing grid contour cage - Google Patents

Abstract

FIELD: medicine; stomatology.

SUBSTANCE: defect surface is cleaned from demineralised tissues. Retention points are formed on palatal (oral) and vestibular surfaces on coronal part. Coronal part contour is formed. Shaped contour cavity has depth 0.5 mm, indented 1-2 mm from palatal (oral) surface borders of reconstructed coronal part. Reinforcing cage made of dental gilt metal grid is fixed within contour cavity. Cage is fixed in contour cavity by means of macrofiled composite material. Anatomical form of coronal part is finally reconstructed within contour cavity.

EFFECT: method allows increasing of reliability and durability of reconstructed tooth.

Description

The invention relates to the field of reinforcing dentistry, in particular to methods for eliminating defects in the angle of the crown of the anterior teeth using composite materials and a reinforcing dental gilded metal mesh.

The invention is aimed at restoring the anatomical shape and function of the anterior teeth with defects of the mesial or distal angle with a length not lower than the cervical third of the crown height.

A common method for restoring fractures of the crown of the front teeth is the manufacture of artificial crowns.

However, the use of composite materials in dentistry has become a serious alternative to this method of orthopedic treatment, because, unlike prosthetics with artificial crowns, tooth restoration with composite materials does not require significant preparation of hard tooth tissues.

The method of restoration of the anterior teeth for traumatic fractures of the angle of the coronal part is described in the book. A.V. Borisenko, V.P. Nespryadko “Composite filling and facing materials in dentistry”, Kiev, Book-plus, 2001, pp. 110-112. The method of composite restoration includes cleaning teeth with special preventive pastes, determining the color of future restoration, anesthesia, and then sparing the preparation of hard tooth tissues, in which, in contrast to the traditional method of preparing a tooth for an artificial crown, only a small layer of hard tissue is removed on the cleaved surface. On the periphery of the cleavage (on the vestibular, palatine and contact surfaces), an enamel bevel is formed in the form of a fold. The preparation is carried out approximately 1 mm cervically from the break line to a depth of approximately half the thickness of the existing enamel.

This is followed by acid etching and application of an adhesive system. Then, using composite materials of opaque shades, lost dentin is restored. In subsequent portions of selected enamel shades, the palatal surface is restored. The following is a layered overlay of the composite material from the vestibular side. After restoration of the anatomical shape of the crown part with composite materials, the restoration is processed, occlusion checked and polished.

A significant drawback of the known composite restoration technique is the technologically complex and laborious enamel mowing operation.

Ideally, the bevel should be formed over the entire thickness of the enamel, as soon as possible without exposing the dentin to allow the maximum amount of composite material to overlap the tooth structure. In this case, special requirements are imposed on the shape of the surface of the bevel. The recess should not be too flat, otherwise an unwanted halo is possible around the restoration. The surface of the bevel should have a slightly concave appearance, which allows for the final restoration to mask the transition line “composite-enamel” using composite material. A complex bevel configuration is formed in order to ensure the maximum possible contact of the marginal enamel layer and the composite material to prevent repeated marginal fractures of the composite restoration.

The enamel mowing operation is very laborious, requiring an individual approach and high skill from the doctor, as noted in the book by S.K. Surzhansky et al. “Restoration materials and the basics of endodontics practice”, Kiev, Book-plus, 2004, p. 71.

However, the expected effect of retention of the composite material may not be achieved in this case, since the mandatory etching of the bevel surface of the enamel leads to demineralization of its tissues, which negatively affects the adhesion of the composite material to the surface of the bevel. Etched areas of enamel are a zone of weakness in restoration technologies (see Prince A.K. Nikolishin “Restoration (restoration) and filling of teeth with modern materials and technologies”, 2001, p. 89).

When eliminating the defect by a known method, separation of the restoration of the angle of the crown part is also probable due to the insufficient strength of the composite material.

The application of the known method to eliminate the defect of the mesial and / or distal angle of the crown not lower than the cervical third of its height is not shown, because of the extent of the defect (the defect extends to the cutting edge, middle third and cervical third of the crown), due to the uneven distribution of the mass of the composite material along the length of the defect, as well as due to a decrease in the thickness of the enamel in the direction of the cervical third of the crown, the likelihood of spallation of the composite restoration increases.

The claimed invention was developed with the aim of simplifying the technology of eliminating the crown defect when the crown angle is destroyed not lower than the cervical third of its height, and also to ensure the strength and durability of the restoration.

The technical result achieved by the implementation of the invention consists in hardening the composite restoration of the crown angle, as well as in the formation of additional efforts to hold the composite restoration on the surface of the defect of the crown part.

The technical result is ensured by a certain sequence of operations of the proposed method, as well as by reinforcing the composite material in the area of the defect and hard tissues of the preserved crown part from the palatine (oral) surface.

As in the known method, when implementing the claimed invention, the crown angle defect is eliminated using composite materials.

Moreover, in order to increase the durability of the restoration and ensure its strength, the inventive method uses a reinforcing mesh contour frame. The reinforcing mesh contour framework fixed from the palatine (oral) surface of the restored crown part provides additional mechanical connection between the composite restoration material and the hard tissues of the crown part. The additional holding force of the composite restoration of the angle is determined by the strength and elasticity of the metal mesh from which the reinforcing contour frame is made, as well as the contact area of the frame and hard tissues of the crown of the tooth.

Reinforcing the angle of the crown using a mesh contour framework increases the strength of the composite restoration material, eliminating its chipping under the influence of the functional load.

A significant difference of the claimed method consists in a certain sequence of crown restoration operations. When implementing the inventive method, at first, the anatomical shape of the crown part is completely restored using composite materials, and then the fully restored crown part is reinforced using a mesh contour frame. For its manufacture, a dental gilded metal mesh 0.4 mm thick is used. The mesh is pre-flattened, reducing its thickness from 0.4 mm to 0.2 mm. As a result of flattening, the interwoven mesh wires lose their relative mobility. While maintaining the cellular structure, the grid acquires flexibility and strength similar to a thin metal plate. The reinforcing contour frame formed from such a mesh retains a given shape and size. Due to the reduction of the thickness of the mesh to a size of 0.2 mm, the contour frame fits snugly to the bottom surface of the contour cavity, which is formed from the palatine (oral) surface of the coronal part. The shape of the reinforcing mesh contour frame repeats the natural relief of the oral (palatal) surface of the coronal part.

As follows from practical dentistry, the disadvantages of composite restorations of the front teeth include spallations of the composite material in the incisal region. In this area, the teeth are significantly affected by the functional load, which neither the strength of the composite material itself, nor the strength of its adhesion to hard tooth tissues can adequately resist it.

The claimed sequence of operations of the method provides accurate reinforcement of the contour of the crown part, including the contour of the cutting edge, due to the placement and fixation of the mesh contour frame in relation to the fully restored crown part.

Thus, the use of a reinforcing mesh contour framework strengthens the composite restoration material along the perimeter of the crown part contour, preventing chipping and spalling of the restoration.

SUMMARY OF THE INVENTION

The claimed method is intended to eliminate a defect in the angle of the crown not lower than the cervical third of its height (that is, in the case of a defect spreading to the region of the cutting edge, the middle third and the cervical third of the crown part).

Mechanically, toothbrushes using toothpastes clean the surface of the teeth that are next to the defect and determine their color according to the generally accepted VITA scale.

Atraumatic preparation is carried out, removing only demineralized tissues from the surface of the defect of the crown of the tooth.

At the same time, retention points are formed on the palatine (oral) and vestibular surfaces of the tooth with the help of a spherical boron.

The surface of the defect is subjected to acid etching. After 15 seconds, the etched surface is thoroughly washed off with water while the saliva ejector is running and dried with air. An adhesive is applied to the etched surface, slightly blown with air for even distribution, polymerized by the standard method according to the instructions.

Prepared for composite restoration, the front tooth is carefully isolated from the oral fluid (preferably with a cofferdam). Then they proceed directly to eliminate the defect in the angle of the crown part with the help of a composite material.

From the palatine (oral) surface, an artificial enamel layer is formed from macrophilic composite material, restoring the contours of the crown of the restored tooth. An artificial enamel layer is formed to the level of occlusal contact with the antagonist. Perform occlusal editing.

Then, artificial dentin is formed in the area of the defect within its topographic boundary. For the formation of artificial dentin using microfilament composite material. Carry out the polymerization.

On the side of the vestibular surface, an artificial enamel layer is formed from a macro profiled composite material. Polymerization of the completely restored contour of the crown of the tooth is carried out.

Thus, the coronal part is restored taking into account the anatomical structure of the front tooth.

After complete restoration of the crown part of the tooth with composite material, they begin to reinforce its palatine (oral) surface.

To do this, from the palatine (oral) surface of the restored tooth, a contour cavity is formed for placement and fixation of the mesh contour reinforcing element.

By contour cavity is meant a cavity formed on the palatine (oral) surface of the tooth, the borders of which are 1-2 mm apart from the borders of the contour of the palatine (oral) surface of the crown part. The cavity is formed with a depth of 0.5 mm. Moreover, the shape of the surface of the bottom of the contour cavity repeats the natural relief of the palatine (oral) surface of the restored crown part of the front tooth.

After the formation of the contour cavity, they begin to reinforce the crown of the tooth with the help of a reinforcing mesh contour frame.

The reinforcing contour frame is formed from a dental gilded mesh 0.4 mm thick.

Dental gilded metal mesh flatten, reducing its thickness to 0.2 mm. The flattening operation eliminates the mutual mobility of the interwoven mesh wires. A flexural network, after being flattened, acquires elasticity and flexibility similar to a thin metal plate. At the same time, its cellular structure is preserved to improve the retention of the composite restoration material.

A reinforcing contour frame formed from such a mesh retains a given shape and size, and due to a decrease in the thickness of the mesh to a size of 0.2 mm, it more closely adheres to the bottom surface of the formed contour cavity, ensuring its uniform reinforcement.

A contour reinforcing element is cut from a flattened mesh in accordance with the dimensions of the contour cavity. Carry out its fitting, placing the reinforcing element without tension in the contour cavity. If necessary, adjust its size and re-try.

An adhesive is applied to the bottom of the contour cavity, slightly blown with air for even distribution. Within 10 seconds, polymerized by the standard method.

Then the bottom of the contour cavity is covered with a layer of macro-profiled composite material and at the same time a mesh contour reinforcing element is installed, tightly pressing it to the bottom surface of the contour cavity. As a result of pressing through the mesh cells, excess composite material is removed, a dense uniform fit of the mesh contour reinforcing element over the entire bottom surface is ensured. Conducted directional polymerization.

In a fixed form, the reinforcing mesh contour element takes the form of a frame, the surface of which completely repeats the relief of the surface of the bottom of the contour cavity.

After fixing the reinforcing mesh contour framework, the anatomical shape of the crown part of the tooth is again restored from the side of the oral (palatal) surface.

On the surface of the fixed reinforcing mesh contour frame, a macrophilic composite material is applied, with which the artificial enamel layer is restored in the area of the contour cavity, the palatal (oral) surface of the restored tooth is finally restored. Carry out the polymerization.

Before polishing and control polymerization, occlusal editing is performed. Grinding and polishing is carried out on the 2nd day after polymerization. This method allows for one visit to eliminate the defect in the angle of the crown of the front tooth by the method of reinforcement, taking into account the characteristics of the dentition, to achieve the accuracy of the restoration, increase its strength and durability.

Complications after eliminating the defect in the angle of the crown part of the claimed method was not detected.

Claims (1)

The method of restoration of the front teeth with crown angle defects not lower than the cervical third of its height using a reinforcing mesh contour framework, including the removal of demineralized tissues from the defect surface, the formation of retention points on the palatal (oral) and vestibular surfaces of the crown part, acid etching and adhesive treatment of the defect surface with subsequent restoration of the contour of the crown part by forming from the palatine (oral) surface an artificial enamel layer, forms artificial dentin and then forming an artificial enamel layer on the side of the vestibular surface, and reinforcing the fully restored crown part by means of a contour reinforcing frame formed from a dental gilded metal mesh 0.4 mm thick, which is further flattened to a thickness of 0.2 mm, while reinforcing the mesh contour frame is placed in the contour cavity, which is formed with a depth of 0.5 mm, retreating 1-2 mm from the borders of the contour of the palatine (oral) surface o the restored crown part, and is fixed in the contour cavity using macrophilic composite material, while the reinforcing mesh contour frame repeats the relief of the bottom of the contour cavity, and then the artificial enamel layer is again formed, finally restoring the anatomical shape of the crown part in the region of the contour cavity, while the artificial enamel a layer is formed from a macrophilic composite material, and artificial dentin is formed from a microfiled composite material.