RU2331384C1 - Method of restoration of tooth crown in case of wedge-shaped defects using reinforcing framework contour element - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to stomatology and can be used to restore tooth crown in case of wedge-shaped defects. Around defect contour C-shaped slot is formed at the of distance 0.3 mm from the border of contour of crown vestibular surface, height and width of C-shaped section of the slot being not more than 1-1.5 mm, respectively. Cavity of wedge-shaped defect and C-shaped slot are filled at the level of its lower borderline with microfilled composite material. Contour reinforcing element made of stomatological gilded metal framework is fixed in cavity of C-shaped slot. Macrofilled composite material is applied on the surface of fixed reinforcing framework contour element, which finally restores anatomical form of crown in region of wedge-shaped defect.

EFFECT: enhanced resistance to functional loading, improved cosmetic properties when restoring tooth crown.

Description

The invention relates to the field of reinforcing dentistry, in particular to methods for eliminating non-carious lesions of teeth using composite materials and a dental metal gilded mesh.

Wedge-shaped defects occur in individuals with impaired endocrine system, central nervous system, gastrointestinal tract under the influence of factors of mechanical and chemical effects, are often observed with periodontal disease. Defects are funnel-shaped (cup-shaped) depressions in the cervical part of molars and premolars, in the frontal group of teeth (see AK Nikolishin. Restoration (restoration) and filling of teeth with modern materials and technologies. Poltava, 2001). The lesion sites pass directly into healthy tooth tissue.

Unlike caries and its complications with non-carious lesions of the coronal part, demineralization and softening of hard tissues of the teeth are practically not observed. The surface of the defect is dense, painless.

The restoration of wedge-shaped defects is described in the book by A.V. Borisenko, V.P. Nespryadko, “Composite filling and facing materials in dentistry”, Kiev, “Book-plus”, 2001, p. 122.

Under anesthesia, a gentle preparation of a non-carious defect is performed, in which only the external mineralized (prism-free layer) of enamel and dentin are usually removed in order to create better conditions for the adhesion of the composite material. Compared to the non-prepared mineralized surface of the enamel, in such prepared tissues, pores are enlarged as a result of acid etching, which contributes to a deeper penetration of the composite material into the structure of the hard tissues of the crown part.

Carry out the isolation of the teeth with a rubber dam, carry out acid etching and treat the surface of the defect with an adhesive system.

Then, a composite material of the selected transparency and color is applied in layers to the treated surface.

Fixation of the shape of the material and its polymerization is carried out according to the rules of layer-by-layer application of a composite material. An existing defect is filled with some excess material. After complete polymerization of the composite material, the final processing, grinding and polishing of the restoration are carried out.

Significant disadvantages of the known method include separation of the restoration material from the hard tissues of the surface of the defect, as well as the occurrence of imbalances in color shades along the line of transition enamel - composite.

Separation of the composite restoration material from the hard tissues of the tooth is due to a violation of the technology of applying the composite material, improper polymerization. Tearing of the material may occur during the final processing of the restoration. A crown fracture is likely in the weakened cervical defect under the influence of the horizontal component of the functional load.

Chipped composite material can be triggered by the structural features of enamel and dentin in the cervical part of the tooth. Enamel in this part is aprismatic, thinner, therefore its etching from the point of view of creating better conditions for the adhesion of composite materials is ineffective. Dentin in the cervical part is more fragile due to the significant amount of near-tubular substances in its structure (see Prince Marek Tomashkevich “Modern Composite Materials in Dental Practice”, “GalDent”, 2001, p. 62).

The listed disadvantages of the known method of eliminating a wedge-shaped defect adversely affect the long-term restoration and reduce its cosmetic effect.

The claimed invention was created with the aim of increasing the durability and aesthetics of the restoration of the crown of the teeth while eliminating wedge-shaped defects.

As in the known method, when eliminating a wedge-shaped defect by the claimed method, a composite material is used.

In this case, the task of hardening directly the composite restoration material, as well as increasing the life of the restored tooth, is achieved by reinforcing the defect area and hard tooth tissues around the defect area using a contour element made of gilded dental metal mesh.

To manufacture a reinforcing contour element, a dental gold-plated metal mesh 0.4 mm thick is flattened, reducing its thickness to 0.2 mm. Since the damage surface of the crown part with wedge-shaped defects is small, it is impossible to form the corresponding reinforcing contour element without additional flattening of the mesh. Without additional flattening, the contour reinforcing element will not maintain a given shape and size due to the mutual mobility of the interwoven mesh wires.

After flattening, the interwoven wire mesh lose their relative mobility, the reinforcing contour element formed from such a mesh maintains a stable shape and size. A flattened mesh, while maintaining a cellular structure, becomes flexible and elastic like a thin plate, which greatly simplifies the operation of fixing the reinforcing contour element when reinforcing the defect area.

The mesh contour reinforcing element is fixed in an annular C-shaped groove, which is formed around the defect contour, deviating from the boundaries of the contour of the vestibular surface of the crown part at a distance of 0.3 mm deep into the defect cavity.

Reducing the thickness of the mesh to 0.2 mm provides a gentle preparation of hard tooth tissues around the wedge-shaped defect in the formation of a C-shaped groove. When forming a groove, the enamel layer is prepared to a depth and a width of 1-1.5 mm. The C-shaped cross-section of the groove has corresponding dimensions. The mesh contour reinforcing element is fixed at the level of the lower boundary of the C-shaped groove.

A fixed contour reinforcing element forms solid tooth tissues at the border — the composite — an additional mechanical bond holding the composite material with which the cavity of the wedge-shaped defect was previously filled within the defect contour.

The mesh contour reinforcing element compensates for the effect of the functional load aimed at tearing or pushing the composite material out of the defect cavity. A mesh contour reinforcing element fixed in a C-shaped groove strengthens the weakened enamel layer around the contour of the wedge-shaped defect.

Thus, the fixed mesh contour reinforcing element, like a matrix, provides contouring of the surface of the crown part at the level of the lower boundary of the C-shaped groove and simultaneously reinforces the restoration surface and the enamel layer of the crown part.

The masking properties of the grid exclude the transillumination of the boundaries of the contour of the wedge-shaped defect.

The technical result achieved by the implementation of the claimed method is to increase the durability, strength and aesthetics of the restoration of the crown of the tooth while eliminating the wedge-shaped defect.

SUMMARY OF THE INVENTION

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. Under infiltration anesthesia, after gum retraction, a gentle preparation of the surface of the cavity of the wedge-shaped defect is carried out according to the generally accepted method.

Using a spherical boron with a diameter of 0.5 mm, retreating a distance of 0.3 mm from the boundaries of the contour of the vestibular surface of the coronal part into the defect, an annular C-shaped groove is formed along the defect contour. When forming a groove, the enamel layer is prepared to a depth and a width of 1-1.5 mm. The C-shaped cross-section of the groove has corresponding dimensions.

Then, from the dental gilded metal mesh 0.4 mm thick, a mesh contour reinforcing element is made.

The dental gold-plated metal mesh is pre-flattened, reducing its thickness from 0.4 mm to 0.2 mm. The flattening operation eliminates the mutual mobility of interwoven wires. The flexural network, after being flattened, gains elasticity and flexibility like a thin metal plate. At the same time, its cellular structure is preserved to improve the retention of the composite restoration material.

A contour reinforcing element is cut from a flattened mesh, the shape and size of which provide free placement and fixation inside a C-shaped contour groove.

The formed mesh contour reinforcing element is placed in a C-shaped groove and, if necessary, its dimensions are adjusted. After fitting and correction, the mesh contour reinforcing element is removed from the groove.

Then proceed to eliminate the wedge-shaped defect with the use of composite materials and a mesh contour reinforcing element. To create a microrelief, acid etching of the surface of the wedge-shaped defect and the inner surface of the C-shaped groove is carried out. The acid is washed off with a stream of water while the saliva ejector is working. The etched surface is dried with air, adhesive is applied, lightly blown with air for even distribution. Polymerized by a standard method according to the instructions. Microphilic composite material is used to fill the cavity of the wedge-shaped defect and the cavity of the C-shaped groove at the level of its lower boundary. Mesh contour reinforcing element is placed in the cavity of the C-shaped groove. Then the mesh contour reinforcing element is pressed in the area of the defect to remove excess microfiled composite material through the mesh cells and to ensure uniform adherence of the mesh to the microfiled composite material. Polymerized by the standard method.

A mesh contour element fixed in this way reinforces, at the level of the lower boundary of the C-shaped groove, a microfilament composite material with which the cavity of the wedge-shaped defect was previously filled and hard tooth tissues (enamel layer) at a distance of 1-1.5 mm around the contour of the wedge-shaped defect. The fixed mesh contour reinforcing element prevents the tearing of the composite material from the hard tissues of the tooth. As an additional mechanical link included in the “hard fabrics - composite” system, the mesh contour reinforcing element holds the mass of microfilated composite material with which the cavity of the wedge-shaped defect is filled within the boundaries of this cavity.

A mesh contour reinforcing element strengthens the acid-etched enamel layer around the contour of the wedge-shaped defect.

On the surface of the fixed mesh contour reinforcing element, a macro-profiled composite material is applied, with the help of which the anatomical shape of the crown of the tooth is finally restored in the area of the wedge-shaped defect. Carry out the polymerization.

As a result, the mesh contour reinforcing element is walled between two composite materials: a microfiled composite material that fills the cavity of the wedge-shaped defect, and macrophilic composite material, with which the anatomical shape of the crown part in the area of the wedge-shaped defect is restored.

The use of a mesh contour reinforcing element eliminates the negative consequences of the use of composite materials with various strength characteristics.

The final restoration of the wedge-shaped defect is carried out using a macro profiled composite corresponding to the color of the cervical surface of the tooth.

Before polishing and control polymerization, occlusal editing is performed. Grinding and polishing is carried out on the 2nd day after polymerization. This method allows one visit to eliminate the wedge-shaped defect by the reinforcement method, taking into account the anatomical structure of the tooth, to achieve increased strength, durability and aesthetics.

Complications in eliminating a wedge-shaped defect by the claimed method were not identified.

Claims (1)

The method of restoration of the crown of teeth with wedge-shaped defects using a reinforcing mesh contour element, characterized in that mineralized tissues are removed from the surface of the wedge-shaped defect, a C-shaped groove is formed around the defect at a distance of 0.3 mm from the boundaries of the contour of the vestibular surface of the crown, the width and height of the C-shaped section of this groove, respectively, no more than 1-1.5 mm, fill the cavity of the wedge-shaped defect and the C-shaped groove at the level of its lower boundary microfilmed with a composite material, a contour reinforcing element pre-made from a 0.4 mm thick gold-plated metal mesh, which is additionally flattened, reducing its thickness to 0.2 mm, is placed and fixed in the cavity of the C-shaped groove, then applied to the surface of the fixed reinforcing mesh contour element macrophilic composite material, with which finally restore the anatomical shape of the crown in the area of the wedge-shaped defect.