RU2489987C1 - Itraosteal cylindrical implant for prosthetics of upper and lower jaws - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medical equipment, namely to intraosteal cylindrical implants for upper and lower jaw prosthetics. Intraosteal cylindrical implant for prosthetics of upper and lower jaw teeth contains metal conic crown part with neck, connected with cylindrical intrasoteal part, made in form of disassemblable construction. Intraosteal part consists of three cylindrical parts of equal diameter with possibility of thread connection of their adjacent butt end surfaces. Central non-metal part, connected with lower metal part, provided with diametrical grooves is additionally connected to upper near neck metal part, which has longitudinal grooves.

EFFECT: ensuring better conditions of efficient functioning of implant in jaw bone by implant construction under action of chewing loads.

2 dwg, 3 cl

Description

The invention relates to medical equipment, namely to intraosseous cylindrical implants, and can be used in dentistry for implantation of artificial teeth roots of the upper and lower jaws.

When developing and using intraosseous dental implants, it is necessary to take into account the functioning conditions of natural teeth under the action of chewing loads. Normal biomechanical conditions for the functioning of teeth are characterized by their ability to effectively absorb axial, bending and twisting loads, as well as provide a shock-absorbing effect when chewing to reduce pressure on bone tissue. Therefore, intraosseous dental implants, which are artificial roots of teeth and serve as a supporting support for fixed dentures, must have the same functional features as natural teeth. This can be achieved by performing implants with structural parts and elements that provide resistance to axial displacement and rotation, as well as elastic micromotion during chewing.

Known dental implant with a rotation lock containing an integral conical crown and cylindrical intraosseous parts, between which there is a neck, while on the intraosseous part there are two external longitudinal protrusions, beveled in the direction from the cervical zone to the apical zone and located in one diametrical plane [Patent RF №96481. Publ. 08/10/2010]. This design ensures the implant is fixed in the bone in compliance with the conditions of resistance to its rotation (rotation) during operation, however, the design drawback is the lack of structural elements in its composition that ensure the implant's resistance to axial displacement and its elastic micromotion under the action of chewing loads.

A known dental implant made in the form of a cylinder with a neck, a hemispherical apical base and having structural elements on the intraosseous surface in the form of recesses and protrusions formed by the intersection of two helical grooves in the opposite direction and a triangular profile with the same interturn distance of 0.7-1.0 mm, and a groove width of 0.45-0.75 mm, as well as blind holes in the middle of the protrusions with a diameter and depth equal to the width of the screw grooves [RF Patent No. 2372875. Publ. November 20, 2009]. This design provides a strong osseointegration fixation of the implant in the bone, subject to the conditions of resistance to its axial displacements and rotation, however, a significant drawback of the design is the lack of technical ability to ensure elastic micromotion of the implant during chewing loads.

The closest in technical essence of the invention is the design of the intraosseous dental implant, comprising an integral conical coronal and cylindrical intraosseous parts, between which the neck is located, while on the intraosseous part there are structural elements for resistance to rotation in the form of longitudinal protrusions, beveled in the direction from the cervical to the apical zone, and structural elements for resistance to axial displacement in the form of transverse grooves located between the longitudinal protrusions [RF Patent No. 95502. Publ. 07/10/2010].

A significant drawback of this design is that it does not have the technical ability to provide elastic micromotion of the implant under the action of chewing loads.

The objective of the invention is the creation of an intraosseous cylindrical implant with constructive parts and elements providing resistance to axial displacement and rotation, as well as elastic micromotion at chewing loads.

The technical result of the invention is to provide the implant design with the best conditions for its effective functioning in the jaw bone under the action of chewing loads.

The problem is achieved in that in the proposed intraosseous cylindrical implant for prosthetics of the upper and lower jaws, containing a metal conical crown part with a neck connected to a cylindrical intraosseous part made with structural elements for resistance to axial displacement and rotation, the cylindrical intraosseous part is made in the form collapsible design, consisting of three cylindrical parts of the same diameter with the possibility of threaded connection of their mating aemyh end surfaces, wherein the upper cervical metal part having longitudinal grooves, further attached central metallic portion connected to the lower metal portion having a transverse groove.

In this case, blind threaded holes are made on the end surfaces of the upper and lower metal parts directed to the central non-metal part, and threaded protrusions are made on the ends of the central non-metal part.

The height of the Central non-metallic part is selected from the ratio:

1 / 2B≥A≥1 / 3B,

where A is the height of the Central non-metallic part,

B - the height of the upper cervical and lower metal parts.

The invention is illustrated by images, in which Fig. 1 shows the construction of the implant in a collapsible form, Fig. 2 shows the construction of the implant in the assembly, where the positions indicated: 1 - the upper metal part; 2 - lower metal part; 3 - central non-metallic part; 4 - conical crown part; 5 - neck; 6 - cervical intraosseous cylindrical part; 7 - longitudinal grooves of the cervical intraosseous part; 8 - blind threaded hole of the upper metal part; 9 - hemispherical apical base of the lower metal part; 10 - transverse grooves of the lower metal part; 11 - a blind threaded hole in the lower metal part; 12 - threaded protrusions of the Central non-metallic part.

The invention consists in the following. To provide resistance to axial displacement, resistance to rotation and elastic micromotion during chewing loads with an intraosseous cylindrical implant, the design is collapsible with parts and elements that create technical capabilities that provide the best conditions for the implant to function in the jaw bone.

An intraosseous cylindrical implant for prosthetics of the upper and lower jaws consists of three separate parts connected during assembly to a single medical and technical structure and includes the upper metal part 1, the lower metal part 2 and the central non-metal part 3.

The upper metal part 1 consists of a conical coronal part 4 and the cervical intraosseous part 6 in the form of a cylinder, which are inseparably connected to each other by the neck 5. On the surface of the cervical intraosseous part 6, longitudinal grooves 7 are made, which are structural elements that provide resistance to the rotation of the implant during germination in them bone tissue. From the end directed towards the central part 3, there is a blind threaded hole 8 for connection with the central part by screwing into the hole 8 of the threaded protrusion 12 of the central part 3 (Fig. 1).

The lower metal intraosseous part 2 is made in the form of a cylinder with a hemispherical apical base 9 and has transverse grooves 10 on the surface, which are structural elements that provide resistance to axial displacement of the implant when bone tissue grows in them. From the end directed towards the central part 3, there is a blind threaded hole 11 for connection with the central part by screwing into the hole 11 of the threaded protrusion 12 of the Central part 3 (Fig.1).

The central non-metallic part 3 is made in the form of a cylinder, at the ends of which there are threaded protrusions 12, designed to connect with the blind threaded holes 8 and 11 of the upper 1 and lower 2 parts and to combine them into a single structure (figure 2). This part is made of a biocompatible polymer material with high elastoplastic properties to enable elastic micromotion of the upper part 1 of the implant under the action of chewing loads.

The diameters of the upper metal part 1, the lower metal part 2 and the central non-metallic part 3 are the same, and the height of the central non-metallic part 3 is at least 1/3 of the height of the upper cervical intraosseous part 6 and the height of the lower part 2, but not more than 1 / 2 the height of the upper cervical intraosseous part 6 and the height of the lower part 2, i.e. with the ratio:

1 / 2B≥A≥1 / 3B,

where A is the height of the Central non-metallic part,

B - the height of the upper cervical and lower metal parts.

The indicated ratio of the height of the central part 3 to the height of the cervical intraosseous part 6 and to the height of the lower part 2 is selected based on the conditions for ensuring the required elastic micro-deformation of the central part 3 during chewing loads. The implementation of the central part 3 with a height ratio of less than 1/3 of the height of the cervical intraosseous part 6 and the height of the lower part 2 does not allow for sufficient elastic micromotion of the upper metal part 1 of the implant under loads, and the execution of the central part 3 with a height ratio of more than 1/2 the height of the cervical intraosseous part 6 and the height of the lower part 2 leads to unacceptable macro-mobility of the upper metal part 1 under loads, as well as loosening of the implant with the risk of irritation of surrounding tissues and subsequent rejection.

The width of the longitudinal grooves 7 of the cervical intraosseous part 6 and the transverse grooves 10 of the lower part 2, as well as the pitch of their location, are selected based on the conditions for ensuring effective resistance to axial displacement and rotation of the implant after germination of the bone into the grooves, and are values within: width 0.45 0.75 mm, pitch 0.7-1.0 mm. Deviation from these limits does not allow high resistance to axial displacement and rotation of the implant under the action of chewing loads.

The proposed intraosseous cylindrical implant for prosthetics of the teeth of the upper and lower jaws is used as follows.

To install the implant in the jaw bone, a cylindrical bed is made. Before installing the implant, it is assembled, in which, by means of a threaded connection, the upper metal part 1 and the lower metal part 2 are fixed to the central non-metal part 3, combining them into a single structure. The assembled cylindrical implant is immersed in the formed bed to the level of the neck 5. In the process of engraftment and osseointegration of the implant, the surrounding bone tissue grows in the longitudinal grooves 7 of the cervical intraosseous part by transverse grooves 10 of the lower metal part 2 of the structure. Due to the fact that the bone tissue fills the existing longitudinal grooves 7, a high resistance to rotation of the implant is created during chewing loads, and due to the fact that the bone tissue fills the existing transverse grooves 10, a high resistance to axial displacement of the implant is created. Due to the implementation of the Central part 3 of a polymer biocompatible material with high elastic-plastic properties, elastic (shock-absorbing) micromotion of the upper metal part 1 of the implant is ensured under the action of chewing loads, which reduces pressure on the bone tissue and creates biomechanical conditions as close as possible to the functioning conditions of natural teeth.

Thus, due to the proposed design of the implant, its resistance to axial displacement and rotation, as well as elastic micromotion during chewing loads are ensured, which allows creating the best biomechanical conditions for the effective functioning of the implant in the jaw bone.

Claims (3)

1. An intraosseous cylindrical implant for prosthetics of the upper and lower jaws, containing a metal conical crown part with a neck connected to a cylindrical intraosseous part made with structural elements for resistance to axial displacement and rotation, characterized in that the cylindrical intraosseous part is made in the form of a collapsible design consisting of three cylindrical parts of the same diameter with the possibility of threaded connection of their mating end surfaces, where cervical upper metal portion having a longitudinal groove, further attached central metallic portion connected to the lower metal portion having a transverse groove. 2. The intraosseous cylindrical implant for prosthetics of the teeth of the upper and lower jaws according to claim 1, characterized in that blind ends are made on the end surfaces of the upper and lower metal parts directed to the central non-metallic part, and threaded protrusions are made on the ends of the central non-metallic part . 3. The intraosseous cylindrical implant for prosthetics of the upper and lower jaw according to claim 1, characterized in that the height of the Central non-metallic part is selected from the ratio
1 / 2B≥A≥1 / 3B,
where A is the height of the central non-metallic part;
B - the height of the upper cervical and lower metal parts.

Images