WO2011071419A2 - Dental implant - Google Patents

Abstract

The invention relates to medicine and, more specifically, to surgical and orthopedic dentistry. According to the present invention, a dental implant is proposed that comprises a rod-shaped main part and at least one anchoring rib, which is formed on the main part and is intended to interact with the bone tissue when the implant is installed. The direction of the position of the anchoring rib substantially coincides with the direction of the axis of the main part. Using this type of implant makes it possible to reduce implantation time and lower the likelihood of rejection of the implant.

Description

 Dental implant

The present invention relates to medicine, namely to surgical and orthopedic dentistry in dental implantation.

 An implant is an artificial tooth root, most often made of medical pure titanium (BT 1-00). Through surgery, the implant is implanted in the jawbone. After implantation, the implant is used as the main support to restore lost chewing function.

 The implant is inserted into the jawbone, both by open access, that is, by folding the mucosal-periosteal flap, and by closed access, using a mucotome, form an opening on the mucous membrane of the alveolar bone corresponding to the diameter of the implant.

 At the next stage, using a special tool, a bed is formed in the jawbone for implant placement.

 After the installation of a dental implant, bone tissue forms on its surface, that is, the process of osseointegration. A necessary condition for achieving the predicted result during dental implantation is the condition of the soft tissues surrounding the implant.

 Success in dental implantation is considered when there is a direct connection between the implant and bone tissue, and this connection is not broken under the influence of functional loads. As a result of restoration, bone tissue is attached to the implant and fixes it securely.

 Implantation takes a long time, on average, from three to six months.

 After implantation, an orthopedic design is installed on it.

The dental implant has intraosseous and supragingival parts. The intraosseous part is implanted in the patient’s jaw bone. Gingival part protrudes from the jawbone and gums and is designed to attach an orthopedic structure.

 From the prior art corresponding to the claimed invention it is known to use in dental practice plate, cylindrical conical helical and cylindrical helical implants.

 With significant atrophy of the bone tissue, plate implants are used.

 A plate implant is an implant, the intraosseous part of which is in the form of a plate. One embodiment of a plate implant is described in patent RU 2139010.

 A plate implant may have several through holes. In the process of implantation of a plate implant, bone tissue is restored and fixes the implant. In addition, during restoration, bone tissue grows through the through holes in the implant, thereby providing additional fixation of the implant.

Cylindrical root implants are implants of the intraosseous part of which has the shape of a cylinder. In the process of implantation of a cylindrical implant, bone tissue is restored and fixes the implant.

 One of the options for a cylindrical implant is described in patent SU 1806686.

 A cylindrical implant may also have several openings. During restoration, bone tissue grows through the through holes in the implant, thereby providing additional fixation of the implant.

 An example of such an implant is disclosed in PCT / CH95 / 00304 (WO96 / 19947).

The disadvantage of plate implants is the increased invasiveness of surgical interventions. In addition, when using plate implants, it is necessary to connect the implant with intact teeth. An additional disadvantage of lamellar and cylindrical implants having through holes is that if it is necessary to remove the implant after restoration of the bone tissue of the jaw, traumatic removal of bone tissue together with the implant will be required. Removing one implant without surrounding bone tissue is not possible.

 A cylindrical implant that does not have through holes and any means of preventing rotation can rotate about its axis when using early functional loads. This is also a disadvantage.

Root-shaped implants of helical form are implants of the intraosseous part of which has the shape of a cylinder and is equipped with an external thread.

 In FIG. 1 is a schematic illustration of the intraosseous portion of a screw implant.

 The screw implant 1 contains an external thread 2.

 To install a screw implant 1 in the bone 3 of the jaw, a hole is drilled corresponding to the cylindrical part 4 of the screw implant 1. The size of the hole in the bone 3 of the jaw is smaller than the external size of the thread 2 of the implant 1. The screw implant 1 is installed by screwing it into the bone tissue.

 Thus, when installing the screw implant 1, the cylindrical part 4 is freely placed inside the hole in the bone tissue, and the external thread 2 is in contact with the inner surface of the hole, namely, it cuts into the bone tissue.

 The result is the fixation of the screw implant 1 inside the bone tissue 3 of the jaw at the time of installation of the implant.

Also, a screw implant can be equipped with anti-rotation grooves 5. In the process of bone tissue restoration, bone tissue grows into anti-rotation grooves 5. After implantation 1 has been implanted and an orthopedic structure is installed, the bone tissue sprouted into anti-rotation recesses 5, prevents the rotation of the implant 1 under the influence of forces applied to the dental prosthesis.

Screw implants provide fixation of the implant from the moment of installation. This ensures the primary stability of the implant.

In those cases when the inflammatory process develops around the implant (reimplant), the extraction of a screw implant is easier than the extraction of plate and cylindrical implants equipped with through holes.

The disadvantages of screw implants include the following.

 In the process of installing a screw implant 1, the external thread 2 interacts with the bone tissue, namely, cuts into it and forms a mating internal thread on the inner surface of the hole in the bone tissue of the jaw.

 In the process of the interaction of external thread 2 with bone tissue when installing a screw implant 1 part, compression of the bone tissue adjacent to the surface of the implant 1 (external thread 2) occurs, that is, necrosis of part of the bone tissue occurs.

 Figure 1 shows the area 6 of bone tissue undergoing necrosis.

 Subjected to necrosis of the area 6 of bone tissue impede the process of restoration of bone tissue and, accordingly, the process of implantation of the implant. Thus, the implantation period is increased.

 In addition, due to the presence of necrosis areas 6 of the bone tissue during the implantation period, the implant 1 can be shifted relative to its original position.

 Thus, the use of screw implants solves the problem of the exact location of the implant partially.

Due to necrosis of part of the bone tissue, the implantation time of the screw implant is increased and the likelihood of rejection is increased. In addition, the range of application of screw implants is limited. Screw implants are not used for dental prosthetics in narrow places of the jaw and atrophied places of the jaw. This restriction is caused by the possibility of destruction of the jaw bone when installing a screw implant as a result of external threading.

Currently, most implants are performed in one-stage or two-stage form.

One-stage implants are implants in which the intraosseous part and the supragingival part are made as a whole, that is, as a single product.

 After implantation of such an implant, an orthopedic design is installed on it and, thereby, the patient's treatment time is reduced.

 However, after implant placement, the supragingival part of the implant is exposed to external forces that are transmitted to the intraosseous part. As a result, during implantation, the implant may move relative to its original position.

 In the case of a screw implant, due to the presence of bone necrosis around the external thread, the position of the one-stage screw implant can also be changed. In addition, any effect on the tissue that has undergone necrosis complicates and increases the period of restoration of bone tissue and, accordingly, the period of implantation, and also increases the likelihood of rejection of the implant.

Two-stage implants are implants in which the intraosseous part and the supragingival part are made separately, that is, in the form of two products.

 In most cases, the intraosseous part and the supragingival part of the two-stage implant are connected using a threaded connection.

Only the intraosseous part of the implant is installed in the bone tissue of the jaw. The supragingival part of the implant is attached to the intraosseous only after implantation of the intraosseous part of the implant, that is, after complete restoration of the bone tissue of the jaw.

 Next, the healing abutment is set for 10 days. Subsequently, the gingiva former is changed to an abutment. After fixing the crown on the abutment, prosthetics is considered complete.

Thus, the use of the two-stage method of dental implants stretches the period from primary surgery to final prosthetics for a period of several months to one year. Expectant tactics are not always welcomed by patients.

 Also, the disadvantage of two-stage implants is a greater number of surgical interventions, and the high cost of prosthetics.

The present invention is based on the task of eliminating the above disadvantages of implants corresponding to the prior art. Namely, the task of the exact location of the implant in the jaw bone, reducing the likelihood of displacement of the implant during implantation and reducing the likelihood of rejection of the implant.

 The problem is solved by using a dental implant, the intraosseous part of which contains the main part of the rod shape and at least one fixation rib, made on the main part and designed to interact with bone tissue when installing the implant, while the direction of fixation rib is essentially coincides with the direction of the axis of the main part.

 A dental implant according to the invention may contain one, two or more fixation ribs.

The dental implant can be made in the form of a one-stage and two-stage implant. The supragingival part of the implant may comprise means for fixing the implant in the implant placement means. For example, made in the form of recesses on the surface of the supragingival part of the implant.

 Additionally, the surface of the main part of the implant can be made textured.

 In addition, at least a portion of the surface of the implant may have a coating containing titanium dioxide.

The following is a description of the best embodiments of the present invention with reference to the drawings, in which:

 figure 1 depicts the intraosseous part of the screw implant, according to the prior art;

 figure 2 is a General view of the intraosseous part of the implant according to the present invention;

 fig.Z is a top view in section of a bone implant according to the present invention;

 4 is an embodiment of an implant fixation rib according to the present invention;

 5 is an embodiment of an implant fixation rib according to the present invention;

 6 is an embodiment of an implant comprising three fixation ribs according to the present invention;

 7 is an implant containing two fixation ribs located in the atrophied jaw bone;

 Fig is a General view of a one-stage implant according to the present invention;

 Fig.9 is a top view of the implant according to the present invention, from the supragingival part;

 figure 10 is a General view in partial section of a two-stage implant according to the present invention.

As shown in FIG. 2, the implant 10 comprises fixation ribs 11. To install the implant 10 in the jaw bone, a hole is drilled corresponding to the main part 12 of the implant 10. In this case, the hole size is smaller than the external size of the fixation ribs 11 of the implant 10.

 Thus, when installing the implant 1, a tight fit of the entire surface of the implant 10 to the bone tissue is ensured, and due to the corresponding fixation ribs 11, the implant is securely fixed in the bone tissue, which makes it possible to use the early functional load method. The fixation ribs 11 also prevent the implant 10 from turning during and after implantation, which is an important factor in the early functional load.

 The direction of the fixation ribs 11 substantially coincides with the axis of the implant body 12.

On Fig.3 shows a top view in section of an implant 10 mounted in bone tissue.

 In the process of interaction of the fixation ribs 11 with the bone tissue when installing the implant 10, the part of the bone tissue adjacent to the fixation ribs 11 undergoes compression, as in the case of screw implants.

 Fig. 3 shows areas 13 of bone tissue that underwent compression and, accordingly, necrosis.

 Subjected to necrosis of the area 13 of the bone tissue impede the process of restoration of bone tissue and, accordingly, the process of implantation of the implant.

When using the proposed implant structure, the volume of the areas 13 of the bone compression undergone is significantly lower than the volume of the bone tissue compressed in the case of using a screw implant of a similar size, since the surface area of the external thread of the screw implant is much larger than the surface area of the fixation ribs 11 and, accordingly, significantly larger total contact area of external thread with bone tissue. As a result, due to the lower volume of the bone tissue subjected to compression, the trophism of bone tissue is not impaired, and therefore, the implantation of the implant 10 is faster than the implantation of a similar screw implant. Accordingly, the likelihood of rejection of the implant is reduced.

As shown in FIG. 3, the locking ribs 11 are triangular in shape. However, the locking ribs 11 may be rectangular in shape, as shown in FIG. 4; trapezoidal, as shown in FIG. 5; or any other form.

As shown in FIG. 3, the implant 10 comprises four fixation ribs 11. However, the implant 10 may comprise any number of fixation ribs 11.

 As shown in FIG. 6, the implant 10 comprises three fixation ribs 11.

 The use of an implant 10 with three or less fixation ribs 11 is advisable for dental prosthetics in places with brittle or atrophied bones.

7 shows the location of the implant 10 in the atrophied narrow bone of the jaw. The implant 10 has two fixation ribs 11. The implant 10 is located to ensure the integrity of the jaw bone.

 In this case, using a screw implant, the atrophied bone would be destroyed.

Fig. 8 shows a general view of a one-stage implant 10 according to the present invention.

As shown in FIG. 8, the implant portion 10 is the intraosseous portion 14 and is intended to be located inside the jaw bone. The other part of the implant 10 is the supragingival part 15, which extends beyond the gums 16 of the patient and is intended for the installation of a dental structure. On the supra-gingival part 15, several recesses 17 are made. The recesses 17 are designed to accommodate the response elements of the implant installation means.

 Thus, before installation, the supragingival part 15 is installed in the installation tool and held therein by the recesses 17. Next, the implant 10 is inserted into the opening in the jaw of the patient. After installation, the installation tool is disconnected from the supragingival part 15 of the implant.

 As shown in Fig. 9, an additional fixation hole 18 can be made on the supragingival part 15 of the implant 18. The fixation hole 18 is also designed to accommodate the implant means mating element therein and provides additional implant stability during installation.

 The fixation hole may be of any shape, for example, round or square.

 Figure 10 presents a General view in partial section of a two-stage implant 10, in accordance with the present invention. Unlike a one-stage implant, the intraosseous part 14 and the supragingival part 15 of the two-stage implant are made in the form of two products and are interconnected by any known method, for example, by means of a threaded connection 19.

 In the case of using a two-stage implant 10, after installation, the supragingival part 15 is separated from the intraosseous part 14. Instead of the supragingival part 15, a temporary plug is installed. After restoration of bone tissue, a permanent supragingival part is mounted instead of a temporary plug on which the dental structure is mounted.

 Additionally, the surface of the implant body 12 may be textured. The textured surface enhances the adhesion of bone tissue and implant 10 after implantation.

Also, the surface of the implant 10 may have a coating containing titanium dioxide TU ₂ . Titanium dioxide TiO ₂ reduces the likelihood of rejection of the implant 10.

Claims

CLAIM 1. A dental implant, the intraosseous part of which contains the main part of the rod shape and at least one fixation rib made on the main part and intended to interact with the bone tissue when installing the implant, while the direction of the fixation rib coincides essentially with the direction of the axis the main part.  2. The dental implant according to claim 1, characterized in that it contains two fixation ribs.  3. The dental implant according to claim 1, characterized in that it contains three fixation ribs.  4. The dental implant according to claim 1, characterized in that it contains four fixation ribs.  5. The dental implant according to any one of paragraphs 1-4, characterized in that it is a one-stage implant.  6. The dental implant according to claim 5, characterized in that the supragingival part of the implant contains at least one means of fixing the implant in the implant installation tool.  7. The dental implant according to claim 6, characterized in that the fixation means is a recess made on the surface of the supragingival part of the implant.  8. The dental implant according to any one of paragraphs 1-4, characterized in that it is a two-stage implant.  9. The dental implant according to claim 1, characterized in that the surface of the main part is made textured.  10. Dental implant according to any one of paragraphs 1 or 9, characterized in that at least part of the surface of the implant has a coating containing titanium dioxide.