RU2026030C1 - Dental implant - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: dental implant has longitudinal cuts 4 with formation of petals 5; crown parts 6 with fitting head 7, spacer 8 with rounded distal end 9. Made along axis of intraosteal part 2 is canal 10 which accommodates spacer 8 for axial displacement. Distal end 9 of spacer 8 is made for interaction with petals 5 of intraosteal part 5. Installed inside canal 10 is screw 11 connecting crown part 6 with intraosteal part 2. Spacer 8 is made in form of screw and thread 12 is made in canal 10 to provide for axial displacement of spacer 8 and connecting screw 11. EFFECT: higher efficiency. 15 cl, 17 dwg

Description

 The invention relates to medical equipment, in particular to dentistry.

 Similar devices are known. So, in US patent N 4220712, 433-173, CL. A61C8 / 00, 1980, an implant device is presented that has a curly end part, which, under the action of the longitudinal element, after the implant is installed in the bone, is deformed in such a way that it penetrates the bone tissue with its pointed part, fixing the implant in it.

 The disadvantages of this device are the presence of a stress concentrator in the bone that occurs during the introduction of the pointed part of the implant into the bone tissue, the inability to eliminate the gap that occurs between the implant and the bone during the operation of the implant, the complexity of the implant design, and the low-tech form.

 Japanese Patent Application No. 61-39056, A61CB / 00, 1986, describes the design of an implant comprising a body and a longitudinal element. A figured hole is made in the housing into which a longitudinal element is inserted.

 The disadvantages of this device are the impossibility of eliminating the backlash that occurs in the bone during the operation of the implant, the difficulties associated with the elimination, prevention of possible septic phenomena due to the presence of a longitudinal element protruding above the gum, the imperfection of the implant design due to the operational loads acting on the denture of the tooth are transmitted directly to the element that provides the implant in the bone tissue.

 The closest to the claimed in fact is a device (US patent N4588381, 433-173, class A61C8 / 00, 1986), which is a universal pin for an oral implant prosthesis. The pin has a first element that is inserted into the hole in the bone of the patient. The skeleton of the first element has an elongated cylindrical shape. Along the longitudinal axis of the core passes axial drilling. The first part of the drilling has an inner and outer inclined walls, as a result of which a conical inner space is formed, facing up. The central cylindrical part has parallel inner and outer walls, and the lower part, which is attached externally to a cylindrical and inside conical configuration, is provided with at least two axial grooves dividing it into at least two parts that can be separated from each other . The second pin element has a lower part for insertion into the drilling of the first element, and an upper part for insertion into the prosthesis. The lower part of the second element contains three sections corresponding to the three parts of the drilling. The outer surface of the upper section has the configuration of a truncated cone, and the dimensions and shape of this section provide the possibility of its exact comparison with the corresponding part of the drilling. The central cylindrical section has such dimensions and configuration that provide the possibility of its exact comparison with the Central part of the drilling. The lower section has dimensions and shape, providing the possibility of connection with the inner conical surface of the drilling and impact on the walls of the latter.

The disadvantages of this device are:
the inability to eliminate the backlash that occurs in the bone tissue during the operation of the pin;
imperfection of the implant design, due to the fact that the operating loads acting on the denture of the tooth are transferred directly to the element that provides the implant in the bone tissue;
great efforts that need to be developed for breeding in the direction of the cut end elements of the first element of the pin;
difficulties associated with the elimination of possible septic phenomena due to the presence of the protruding above the gingival part of the second element of the pin;
the inability to regulate the initial clearance between the pin and bone tissue;
a limited range of possible use of the pin, depending on the structural features of the oral cavity of patients.

 To improve operational characteristics, increase the reliability and durability of the implant by separating the functions performed by its parts, and to create the possibility of strengthening the implant in the bone during operation in a dental implant containing an intraosseous part, the free end of which has longitudinal sections with the formation of petals, a crown part with a landing a head and a spacer element with a rounded distal end, while a channel is made along the axis of the intraosseous part, in which it is axially arranged movement of the expander member, the distal end of which is adapted to cooperate with petals intraosseous portion mounted connecting screw extending along the axis of the implant and the intraosseous portion of the channel is threaded to the expansible element formed as a screw.

 The crown part of the implant additionally has a figured base rigidly connected with the landing head. In this case, the size of the landing head of the shaped base in the transverse direction is less than the maximum transverse size of the adjacent part of the implant (shaped base or intraosseous part) so that an annular supporting surface is formed on the latter.

 To prevent mutual rotation of the coronal and intraosseous parts, the curly base of the coronal part is made with the possibility of interaction with the counter surface of the intraosseous part.

 A through threaded channel is made in the mounting head of the crown part, and a connecting screw is located in the threaded channel of the crown part with the possibility of axial movement.

 To simplify the design of the implant, the connecting screw can be rigidly connected to the landing head of the crown part.

 The spacer and connecting screws of the implant can be made in one piece.

 In the landing head of the crown part, a through smooth-walled channel can be made. In this case, the connecting screw interacts with the threaded part of the intraosseous part and has a head with a seating surface interacting with the end part of the head of the crown part.

 To prevent possible septic effects in the process of implant engraftment, it is equipped with a sealing stopper located at the end of the intraosseous part, interacting with the figured base of the crown part.

 To simplify the design of the implant, the coronal and intraosseous parts can be made monolithically interconnected.

 To ensure regulation of the magnitude of the opening of the lobes of the intraosseous part, the distal end of the spacer screw is made in the form of a figured body. In this case, its maximum transverse dimension is not greater than the diameter of the spacer screw, and the mating surface of the lobes of the intraosseous part is conjugated with it.

 The minimum transverse dimension of the figured body of the distal end of the expansion screw may be no less than the diameter of the expansion screw.

 The landing head of the crown of the implant can be located at an angle to the longitudinal axis of the intraosseous part.

 To increase the reliability of interaction with the prosthesis, the crown head of the crown part from the side of the free end has longitudinal sections or recesses.

 On the outer surface of the implant, annular grooves or notches can be made, preferably at an angle to the longitudinal axis.

 Figure 1 and 2 shows a General view of the implant; figure 3 - sequence of assembly of the implant; figure 4-7 - the landing head of the crown part and several options for its possible performance; on Fig - intraosseous part of the implant with a sealing tube; figure 9 - implant with a smooth-walled central channel in the crown part and a connecting screw having a head; figure 10 - implant with a crown part, combined with a connecting screw; figure 11 is an implant in which the intraosseous part is combined with the crown; in Fig.12 - an implant having, in contrast to the implant shown in Fig.1, another design of the distal end of the spacer screw; on Fig and 14 is a variant of a possible implementation of the landing head of the crown part, located at an angle to the longitudinal axis of the implant; on Fig and 16 is a variant of a possible implementation of the implant having longitudinal sections or grooves; on Fig - implant with annular grooves and notches on the outer surface, including having an annular groove at the base of the landing head.

 The dental implant 1 (Fig. 1) includes an intraosseous part 2, the free end 3 of which has longitudinal sections 4 with the formation of petals 5, the crown part 6 with the landing head 7, the spacer element 8 with a rounded distal end 9. On the axis of the intraosseous part 2 a channel 10 is made, in which the spacer element 8 is located with the possibility of axial movement. The distal end 9 of the spacer element 8 is configured to interact with the lobes 5 of the intraosseous part 2 of the implant 1. Inside the channel 10 of the implant 1 is also connected an integral screw 11 connecting the crown part 6 with the intraosseous part 2. The spacer element 8 is made in the form of a screw, and thread 12 is made to provide axial movement of the spacer 8 and connecting 11 screws in the implant channel 10.

 Figure 2 shows a cross section of the petals 5 and the distal end 9 of the spacer element (screw) 8.

 Figure 3 presents the assembly of the implant 1: the intraosseous part 2, the spacer screw 8, the sealing tube 13, the crown part 6, the connecting screw 11.

 In Fig. 4, the crown part 6 is separately shown, and in Figs. 5-7, several possible embodiments of the seating head 7 of the crown portion 6. So in Fig. 5, the landing head 7 has the shape of a circular cone, in Fig. 6 - an elliptical cone, in FIG. 7 - pyramids. You can give many other examples of the possible design of the landing head 7, the purpose of which is to ensure a secure fit on the head 7 of the tooth prosthesis and to prevent axial rotation of the prosthesis relative to the landing head 7.

 The crown part 6 (FIGS. 1, 4) additionally has a figured base 14, rigidly connected with the landing head 7. Moreover, the transverse dimension 15 of the landing head 7 of the figured base 14 is less than the maximum size of the adjacent part of the implant (figured base of FIGS. 1 and 4 ) so that an annular bearing surface 16 is formed on the seating head 7.

 To prevent mutual rotation of the coronal 6 and intraosseous 2 parts, the curly base 14 of the coronal part 6 is configured to interact with the mating surface 17 of the intraosseous part 2. For example, the lower part of the curved base 14 can be made in the form of a tetrahedral prism. Thus in the intraosseous part 2 should be made a recess having a similar shape.

 On Fig shows the intraosseous part 2 with a sealing tube 13.

 In FIG. 9 shows an implant 1, in the crown part 6 of which a smooth-walled central channel 10 is made. The connecting screw 11 has a head 18 with a seating surface 19 that interacts with the end part of the landing head 7 of the crown part 6. Possible variants of the mounting head 7 are possible when the head 18 of the connecting screw 11 is completely recessed in the seating head 7. The connecting screw 11 in these embodiments with its threaded part only interacts with the threaded channel 20 of the intraosseous part 2.

 Possible options for the implementation of the crown part 6, combined with a connecting screw 11 (11, pos.21). In this case, the implant design is simplified.

 Figure 11 shows the design of the implant, in which the intraosseous part 2 is combined with the coronal part 6. Such an implementation of the implant simplifies its manufacturing technology, but leads to the protrusion of the landing head 7 above the gum, which may cause undesirable effects in some patients.

 Figure 1 presents the implant 1, in which the distal end 9 of the spacer element (screw) 8 is made in the form of a figured body. Moreover, its maximum transverse dimension is not greater than the diameter of the spacer screw 8, and the mating surface of the lobes 5 of the intraosseous part 2 is associated with it. In the simplest embodiment, the distal end 9 has the shape of a conical blunted sphere. But there are other possible embodiments of the figured body of the distal end 9 in the form, for example, came to life, a paraboloid, and other geometric bodies. The choice of the shape of the distal end 9 of the spacer screw 8 is determined by the required value of the mutual dilution of the petals 5 of the intraosseous part 2.

 In FIG. 12 shows an implant 1, in which the distal end 9 of the spacer screw 8 is made in the form of a figured body, the minimum transverse dimension of which is not less than the diameter of the spacer screw 8. In this embodiment, the implant is mutually diluted with the petals 5 when the spacer screw 8 moves into the intraosseous part 2, in contrast to the embodiment shown in FIG. 1, where a similar procedure is carried out when extending the spacer screw 8 from the intraosseous part 2.

 To ensure the installation of the tooth prosthesis at an angle to the longitudinal axis of the implant 1, the device design is shown in Figs. 13 and 14. Here, the landing head 7 can be made in the form of indirect, for example, a cone, a cylinder, a truncated pyramid, a prism, etc. Or in the form of straight lines, but set at an angle, obliquely of the same geometric bodies.

 The device shown in FIGS. 15 and 16 can serve the same purpose. Here, the landing head 7 of the crown part 6 has longitudinal cuts 25 or recesses from the free end side, which allow bending individual elements 26 of the landing head 7 cut into parts, and thereby create the necessary angle of dentures. Individual elements 27 of the landing head 7 may have dimensions different from other similar elements 26. When installing a tooth prosthesis, all of these elements 26, 27 can act as reinforcing elements in, for example, cement mortar, on which the tooth prosthesis is installed.

 For the inclined installation of the tooth prosthesis, the above-described options for constructive implementation of implants can also be used if they have an annular groove 28 at the base of the landing head 7 (Fig. 17), which facilitates bending to the necessary angle of the landing head 7 relative to the intraosseous part 2 before installing the implant 1 to the patient .

 A similar annular groove 29 at the base of the petals 5 of the intraosseous part 2 (Fig. 17) reduces the force required for the mutual dilution of the petals 5 during the installation of the implant to the patient.

 To ensure a more reliable adhesion of the landing head 7 with the prosthesis of the tooth, the body of the intraosseous part 2 and its lobes 5 with the bone tissue 22 (Fig. 17), annular grooves 23 and notches 24 are provided mainly at an angle to the longitudinal axis of the implant 1.

 It should also be noted that in the device shown in Fig. 10, an annular abutment surface for a tooth prosthesis is formed at the end of the intraosseous part 2 due to the difference in the transverse dimensions of the coronal and intraosseous parts, in contrast to the above example, when a similar surface 16 is formed in the figured base 14 of the landing head 7.

 The device operates as follows. A hole is drilled in the jawbone, the diameter of which is equal to the diameter of the cylindrical part of the intraosseous part 2. Intraosseous part 2 is inserted into this hole, into which the spacer screw 8 is pre-screwed. Holding the intraosseous part 2 with a special key, move the spacer screw 8 from (Fig. 1) or in (Fig. 12) the intraosseous part 2 using a special screwdriver until the petals 5, overcoming the resistance of the elastic forces of the material of the petals and intraosseous tissue 22, squeezing slightly the latter, do not occupy the working position ( ig.1 and 12), fixing the intraosseous portion of bone 22.

 After installing the intraosseous part 2, a sealing plug 13 is inserted into it (Fig. 8) and the gum 30 is sutured over the sealing plug 13, providing optimal conditions for implant engraftment (minimum septic effects).

 After the implantation of the intraosseous part 2 of the implant 1 in the bone and the end of inflammatory processes, if they nevertheless occur, the gum 30 is opened with a cylindrical knife, the sealing plug 13 is removed and the crown part 6 is installed in its place (Fig. 3), into which the connecting screw is previously screwed 11. The latter, the coronal part 6 is rigidly associated with the intraosseous part 2.

 Then some time is given for the final healing of the gums. During this time, an impression is taken for the tooth prosthesis or the landing part of the bridge, the entire bridge or the jaw prosthesis are prepared. After healing of the gums, the prosthesis is worn on the landing head 7.

 The presence of the annular landing surface 16 allows the prosthetist to feel the moment the prosthesis is fully planted on the landing head 7 and eliminates trauma to the gums.

The supporting surface of the device during the operation of the implant is formed by the end supporting surfaces of the petals 5 and the end surface of the spacer 8. The approximate total supporting surface of the implant can be determined by the formula S _op = π R ² , where R is the minimum radius by which the petals 5 radially diverge (taking into account the thickness of the petals). In general, the support surface of the implant can be considered equal to the support surface of a conventional tooth or even slightly exceeding it.

 In order to increase the effective abutment surface and improve the adhesion of the petals 5 to the surrounding bone tissue 29, annular grooves or notches are made on the outer surface of the intraosseous part 2, including the petals 5 (Fig. 17), which are gradually overgrown with bone tissue.

 The described embodiment of the device is interesting in that for patients who have an increased sensitivity to irritation of the oral mucosa and inflammatory processes, the option guarantees almost ideal conditions for implant engraftment and the complete absence of extraneous irritants in the oral cavity. In addition, the placement of the implant at the initial stage under the gum guarantees a minimum of septic effects.

 However, other implant embodiments are also possible, as described above.

 It should be noted here that if the intraosseous part 2 is combined with the coronal part 6 after the implant is installed, the latter will act as its landing head 7 in the oral cavity for the entire period of engraftment, which causes some patients with increased sensitivity to external stimuli, unpleasant sensations. Therefore, it is recommended to place such implants in patients less sensitive to external stimuli.

 But such implants are easier to manufacture and require less production costs.

 It should be noted the important role assigned to the shape and design of the landing head 7 of the crown part 6, since its characteristics determine the bond strength of the prosthesis with the implant, i.e. operational characteristics of the prosthesis. The choice of one or another shape of the head is determined by the specific characteristics of the prosthesis (single tooth, bridge, jaw), the angle of its installation and is made by the doctor in each case. It is desirable to have a set of such crown parts 6. In this case, the execution of the crown parts 6 separately from the intraosseous part 2 is preferred.

 Finally, it should also be noted that the presence of two screws in the implant allows you to separate the functions of the screws. The first one is necessary for installing the implant in the bone, the second - for connecting the coronal 6 and intraosseous 2 parts.

 During operation, in case of implant loosening, it is possible to remove the prosthesis and unscrew the connecting screw 11, tighten the petals 5 with the spacer screw 8, eliminate the play, fixing the intraosseous part 2 in the bone tissue, and then installing the crown part and prosthesis to ensure the patient can quickly eliminate the defect.

 Thus, the proposed implant design provides improved performance, increased reliability and durability of the implant, the prevention of possible septic effects in the process of implant engraftment.

 The implant design allows you to vary the magnitude of the opening of the petals 5 of the intraosseous part 2. The variety of possible embodiments of the device with a minimum nomenclature of incoming elements allows you to meet the requirements of patients with strictly individual characteristics of the structure of the jaw and sensitivity to external stimuli.

 Currently, prototypes of the device have been manufactured, medical experiments are being conducted with them, preparations are underway for the mass production of implants.

Claims (15)

 1. DENTAL IMPLANT, containing an intraosseous part, the free end of which has longitudinal sections with the formation of petals, a crown part with a seating head and a spacer element with a rounded distal end, while a channel is made along the axis of the intraosseous part, in which the spacer element is axially movable the distal end of which is configured to interact with the lobes of the intraosseous part, characterized in that it is provided with a connecting screw passing along the axis of the implant, and into the canal A thread was made for the intraosseous part for a spacer element made in the form of a screw.  2. The implant according to claim 1, characterized in that the crown part further has a figured base rigidly connected to the landing head, while the transverse size of the landing head at the figured base is less than the maximum transverse size of the adjacent part of the implant so that an annular supporting surface is formed on the latter .  3. The implant according to claim 2, characterized in that to prevent mutual rotation of the coronal and intraosseous parts, the curly base of the coronal part is configured to interact with the mating surface of the intraosseous part.  4. The implant according to claim 1, characterized in that in the landing head of the crown part, a through threaded channel is made.  5. The implant according to claim 1, characterized in that the connecting screw is located in the threaded channel of the crown part with the possibility of axial movement.  6. The implant according to claim 1, characterized in that the connecting screw is rigidly connected with the landing head of the crown part.  7. The implant according to claim 1, characterized in that the spacer and connecting screws are made in one piece.  8. The implant according to claim 1, characterized in that the through-head smooth-walled channel is made in the landing head of the crown part, and the connecting screw interacts with the thread of the intraosseous part and has a head with a landing surface interacting with the end face of the crown part head.  9. The implant according to claim 1, characterized in that it is equipped with a sealing tube located at the end of the intraosseous part, interacting with the figured base of the crown part.  10. The implant according to claim 1, characterized in that the coronal and intraosseous parts are made integrally linked.  11. The implant according to claim 1, characterized in that to ensure regulation of the opening size of the lobes of the intraosseous part, the distal end of the spacer screw is made in the form of a figured body, while its maximum transverse dimension is not greater than the diameter of the spacer screw, and the mating surface of the lobes of the intraosseous part is associated with him.  12. The implant according to claim 11, characterized in that the minimum transverse size of the figured body is not less than the diameter of the spacer screw.  13. The implant according to claim 1, characterized in that the landing head of the coronal part is located at an angle to the longitudinal axis of the intraosseous part.  14. The implant according to claim 1, characterized in that in order to increase the reliability of interaction with the prosthesis, the crown head of the crown part from the side of the free end has longitudinal sections or recesses.  15. The implant according to claim 1, characterized in that annular grooves or notches are made on its outer surface, preferably at an angle to the longitudinal axis.

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