RU2339338C2 - Dental post - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: dental post is made as a fiberglass rod damped with connecting agent, having narrow cylindrical part and a flattered cone part, located on the one end of the narrow cylindrical part. The post additionally contains wide cylindrical part diameter of section of which is 2-5 times higher than the diameter of section of the narrow cylindrical part connected with it by a conical adapter.

EFFECT: facilitates clinical practice, ensures reliable fixation of post in duct and enables creation of high-test stump of the restored tooth.

3 cl, 2 dwg

Description

The claimed invention relates to dentistry, namely to intra-root pins used to strengthen the crown of damaged teeth.

The intra-root pins are used for significant tooth decay during their filling and restoration, including if the restored tooth will be used as a support for prosthetics. In this case, a particularly high stump strength is required, which is provided by the intra-root pin.

Traditionally [see, for example, GB 396973, 1933] metal pins are still used that are screwed into the root of the tooth or passively fixed in the canal using cement. However, metal pins of various configurations have a number of common disadvantages for them. For example: the modulus of elasticity (elasticity) of the root dentin and metal are different, because of which high stress points are possible during loading. If root dentin is not thick enough, these loads can lead to a longitudinal root fracture. Inside the channel, the metal pin is usually strengthened without the use of adhesive technology, but only with cement. This technique does not combine the walls and the pin into a single whole, but weakens the tooth. In addition, an opaque metal pin gives a shadow during restoration of the front teeth with non-metal structures. Aesthetic restorations of the front teeth suffer from this. The negative point of the metal pin is also the difficulty of its extraction during retreatment of the channel.

Glass fiber pins, similar in elastic properties to tooth characteristics, are devoid of these drawbacks. They are fixed inside the channel with the help of special polymer adhesives and composite cements, which generally strengthens the tooth. In this case, strong adhesion occurs between the root walls, polymer cement and the pin, which prevents the appearance of excessive local stresses during chewing. Optionally, the fiberglass pins can be easily removed from the channel by drilling. However, when using fiberglass pins to achieve the optimal result, their geometric shape and internal structure become significant. Known dental pin made in the form of a cylinder with a working end in the form of a truncated cone [US 5797748, M.cl. A61C 5/08, 08/25/1998]. It is made of fiberglass immersed in polymerized resin. The pin consists of a core made of one bundle of fiber and a case consisting of at least one layer of the same fiber wrapped around the core at an angle α to the axis of the pin. In this case, the core is 50% of the volume of the pin. Preferably, the outer case consists of fibers wound crosswise around the core, or in the form of non-touching strands parallel to each other.

However, practice shows that in the case of complex interweaving of glass fiber, it is unevenly impregnated with a binder resin, which, with an overall high bending strength, leads to local dislocations and possible fragility at the place of dislocation.

A dental pin in the form of a cylinder or similar with a conical end is also known [EP 1319375, M.cl. A61C 8/00, 06/18/2003]. This pin is made of fiber, for example, glass, located along the axis of the pin, completely surrounded by interweaving of threads. The fibers are impregnated with epoxy resin. The pins according to EP 1319375 can have different cross-sections: round, in the shape of a rhombus, a pentagon or a hexagon, and be bent along the axis. The pin may be fitted with a nozzle, which is later used to form the stump and place the crown.

This pin, due to the loose and complex interlaced structure of the core winding, has the same drawback as the pin according to US 5797748.

The closest to the claimed pin on the set of essential features is a dental pin made in the form of a fiberglass rod having a thin cylindrical part and a part in the shape of a truncated cone [RU utility model No. 51485, M.cl. A61C 13/30, 02.27.2006]. The cylindrical part of the pin is characterized as periosteal, and the conical part as intraosseous, and the cone angle is 12-15 ° relative to the cylinder guide. Glass fiber is impregnated with a binder, comprising 30-35 wt.h. by 65-70- parts by weight fiberglass.

The specified pin has the disadvantage inherent in the pins according to US 5797748 and EP 1319375, namely its periosteal part is made in the form of a fairly thin cylindrical pin. With this design, the periosteal part of the stump of the restored tooth cannot have high mechanical strength, especially with significant destruction of the crown of the tooth. The thin part of such a pin does not provide high resistance to chewing loads, and the stump restored by such a pin cannot be used under the support of the bridge. In addition, after processing the canal, the zone in the area of the tooth mouth often has the shape of a funnel, which leads here to a large gap between the cylindrical pin of a small diameter and the walls of the root canal. Shrinkage of composite fixing cements in this area can lead to a general weakening of the adhesion strength of the pin and increase the risk of cementation.

The technical result to which the claimed invention is directed is to increase the reliability of fixing the pin in the canal and create a high-strength stump superstructure of the tooth, and in addition, to facilitate the clinical use of the pin.

The specified technical result is achieved by the fact that a dental pin made of fiberglass impregnated with a binder and having a thin cylindrical part and a truncated conical part located at one end of the cylindrical part further includes a wider cylindrical part with a diameter 2-5 times the diameter a narrow part, placed at the other end of the thin cylindrical part and connected to it through a conical transition.

The claimed pin can be made bilateral, that is, the wide cylindrical part can have at the other end a second thin cylindrical part connected to the wide cylindrical part through a conical transition and having a truncated cone-shaped part at the other end.

Shallow circular notches with a pitch of 1.0 ± 0.1 mm can be applied on the wide part of the pin to improve retention of the reducing materials.

The claimed pin is presented in figure 1-2.

Figure 1.1 presents a view of the inventive pin.

In Fig.1.2. presented its appearance, in the manufacture of its two-sided.

Figure 2 schematically shows the placement of the inventive pin in the root canal and the final formation of the stump of the tooth.

As shown in figure 1.1, the inventive pin includes a thin cylindrical part (1), which on one side ends with a truncated cone (2), and the other end of the thin cylindrical part passes through a conical extension (3) into a cylindrical part of a larger diameter (4). Shallow circular notches with a pitch of 1.0 ± 0.1 mm were applied on the cylindrical part of a larger diameter to improve the retention of restoration materials around the circumference (5).

In the case when the inventive pin is made bilateral (see Fig. 1.2), the wider cylindrical part (4) at the other end is connected through the conical transition (3 ') to the second thin cylindrical part (1') having the end (2 ' ) in the form of a truncated cone.

The geometric dimensions of the claimed pin may be different. The diameter of the thin cylindrical part can be from 0.7 mm to 1.4 mm, and the cylindrical part of a larger diameter can be from 1.5 mm to 3.5 mm. The length of the thin cylindrical part can be from 8 mm to 16 mm, and the length of the wide cylindrical part can be from 7 mm to 14 mm. When calibrating and adjusting this pin, you can use a cutting rotating diamond tool that easily cuts the inventive pin to achieve the required dimensions.

For the manufacture of the pin, glass roving of the brand RBN-16-4800-US is used, TEKS - 16 g / km. The binder used is epoxy resin of the ED-20 brand. The ratio of glass fibers and binder resin by weight is on average 70%: 30%. The degree of resin conversion in the finished pin is not less than 96% when extracting chips in the Soxhlet apparatus according to STP 1-595-43-324. In the manufacture of the pin, the fiber is parallel and stretched with a force of 1-2 tons (when pulled through the die), and then impregnated with resin. This tension ensures that the pin is completely and uniformly impregnated with resin.

The finished pin has the following physical and mechanical characteristics:

- modulus of elasticity (GOST 25604-80) not less than 12 GPa;

- bending strength not less than 0.8 GPa;

- ultimate strength in compression of more than 560 MPa;

- fracture resistance of about 150 kg;

- the transmittance in the wavelength range of 450-600 nm is not less than 15%.

The advantages of the claimed fiberglass pin include the fact that it does not give an opaque shadow in the area of the tooth crown during aesthetic restoration, and notches on the wide cylindrical part facilitate marking when fitting the pin in the channel. In addition, this pin is more radiopaque than its fiberglass counterparts.

The claimed pin is installed in the tooth as follows. A pin of a suitable size is selected depending on the diameter of the calibrated channel. Typically, the middle and lower part of the channel during processing is not widely developed, so the thin cylindrical part of the pin can be placed in a calibrated channel with the smallest gap (see figure 2). The conical expansion should be at the mouth of the channel, which during processing usually opens more widely and has a funnel shape (figure 2). If the original pin is too long, it can be shortened with a diamond bur or disc. Placing the transitional conical part of the pin at the mouth of the channel reduces the clearance and increases the overall strength of the superstructure. The cylindrical part of the large diameter of the pin is located directly in the crown of the tooth (figure 2) and is well resistant to chewing load, especially with significant destruction of the crown. The cylindrical part of a large diameter is cut along the length with a diamond rotating tool so that the protruding end does not interfere with the closure with antagonist teeth.

The pin is fixed using a special adhesive technique.

To do this, the surface of the pin is roughened by sandblasting with alumina powder with a fineness of 50 microns. Then the pin is degreased with 96% ethanol and dried. A special polymer dental adhesive is applied to the pin and polymerizes under the influence of light.

The walls of the root of the tooth are etched with dental etching based on 32-38% phosphoric acid for 15 seconds and washed with water. After that, they are dried and covered with the same dental adhesive. For reliable bonding of the adhesive-coated pin and the channel walls, a special composite polymer cement of double or chemical curing is used. After fixing the pin using composite cement, the supragingival superstructure can be made using special material for stump superstructures (Fig. 2). The restored tooth can be processed under the crown or restored by any therapeutic method. The proposed shape of the pin allows you to create a solid and reliable superstructure of the tooth. The thin cylindrical part of the pin does not have a flare effect on the root walls, which ensures the strength of the root walls under load. In addition, the small gap between the pin and the walls of the channel provides high retention of the entire pin in the tooth. The conical expansion placed at the mouth of the channel also gives a small gap, which reduces the effect of shrink stress during the polymerization of the composite fixing cement. The wide cylindrical part is located directly in the crown part of the tooth, significantly enhancing the entire stump superstructure. Such a stump can be used both for direct restoration and for support under a bridge.

In the manufacture of the pin bilateral (Fig.1.2) there are options for a more universal and economical fitting of the pin in length.

The advantages of the proposed pin make it easy to use it in both therapeutic and orthopedic dentistry.

Claims (3)

1. A dental pin made in the form of a fiberglass impregnated with a binder rod having a thin cylindrical part and a section in the shape of a truncated cone located at one end of the thin cylindrical part, characterized in that it further includes a wide cylindrical part with a cross-sectional diameter of 2-5 times the diameter of the cross section of the thin cylindrical part, placed on the other end of the thin cylindrical part and connected to it through a conical transition. 2. The dental pin according to claim 1, characterized in that the free end of the wide cylindrical part is connected through a conical transition to a second thin cylindrical part having a truncated cone-shaped part at the end. 3. The dental pin according to claim 1, characterized in that it has circular notches on a wide cylindrical part with a pitch of 1.0 ± 0.1 mm.

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