RU2323698C2 - Dental implant - Google Patents

Abstract

FIELD: MEDICINE, PROSTHETICS.

SUBSTANCE: dental implant has cylinder-shaped head with straight generating line, its prismatic part or, preferably, hexagonal jut projects outside. Dental implant has blind hole with inner screw thread and rod with external screw thread that has a head in shape of truncated cone with screw thread and in turn, accomplished with another end in the shape of truncated cone. Height of hexagonal jut is 0.65 to 1.5 mm. Height of cylinder head is 0.7 to 5 mm. Cone end, which accomplishes a part of rod that has screw thread and shape of truncated cone, has an angle of approximately 120 degrees and is accomplished by flat skewed round-shaped face with diameter making 15 to 25% from diameter of part of rod supplied with screw thread. At base of cutting edge, lengthway grooves have curved outside concave rounded parts from which another curved outside convex rounded parts start, which go towards cutting edges of adjacent area.

EFFECT: decreases diameter of self-tapping part when installed into upper edge of narrow alveolar process, as well as friction during screw thread cutting.

2 cl, 15 dwg

Description

The present invention relates to a dental implant of the type used by dental surgeons to insert the jaws of patients into the bone so that it acts as a solid base on which artificial teeth or dentures are placed.

The general methodology for using such implants was proposed more than twenty years ago by the Swedish professor Dr. Branemarck, and there are a large number of options based on it aimed at improving or trying to improve the characteristics of implants in order to increase their effectiveness.

In general terms, a dental implant is a part that is placed in the patient’s jaw bone, attaching well to the bone until the upper part or crown remains. In this part, the implant is equipped with a means for firmly fixing the artificial tooth. In order to perforate a bone, it is first pierced at least so as to obtain a cylindrical internal cavity with a smooth surface, into which then screw threads are cut with another tool, for example a tap, in order to obtain an internal cavity with a screw thread in which it could be well the implant is fixed.

This last thread cutting operation in a hole with a smooth surface made in the bone is usually carried out by the implants themselves and is called self-cutting, which has been known for many years, and this method is based on the already mentioned tapping system.

US-A-2388482 discloses a surgical tool for making holes in patient bones, which is provided with a part with a screw thread terminated by a part with four longitudinal grooves, which, in turn, ends with its characteristic apical end.

In addition, from the publication US-A-2472103 it is also known the existence of a tool for cutting a screw thread, which has a cylindrical part with a screw thread, terminated by another tapered end part, on which the specified screw thread continues and which is provided with longitudinal grooves or grooves that facilitate insertion of the tool .

A conical implant with a screw thread and with many longitudinal grooves that extend radially along its outer periphery is also known from US-A-2609604.

From US-A-3435526, an implant is known having a polygonal head, for example with a hexagonal cross-section, which can be used during attachment of the implant to the bone and which is followed by another smooth cylindrical part turning into another cylindrical part of a smaller diameter with a threaded screw thread and with through holes. The end of this implant has the shape of a truncated cone and is provided with longitudinal grooves extending from this end.

A conical shape implant is also known from US-A-3,672,058, which has a screw thread with a large pitch and is also provided with longitudinal grooves. This implant is self-tapping and has an internal or apical conical end with an angle of approximately 10 degrees to facilitate its insertion.

The cutting teeth and threads have, starting from the conical apical head, a progressive increase both in the radius of the head and in the radius of the base, which makes the base of the implant completely conical.

A conical implant is also known from FR-A-2395738, which is provided with helical teeth and grooves, both straight longitudinal and inclined.

US-A-4324550 describes an implant also with a conical shape and with cutting teeth and threads, which also has longitudinal grooves, which, in turn, have cutting edges, which helps to screw the implant into the bone.

From the German publication Run um die werkzeugmaschine, published in Spain with the right to reprint in 1957 in Editoreal Reverté, SA, taps with a cylindrical body ending at the end with a truncated cone part are also known, both of which are provided with helical teeth and threads and longitudinal grooves having cutting edges.

US-A-4406623 discloses an implant that has a conical shape and is provided with helical teeth located throughout its body to the apical end, which can end with a cone with an angle of approximately 90 degrees. A group of grooves in a spiral direction interrupts the teeth and is equipped with cutting edges that facilitate the insertion of the implant, which is self-tapping.

Some of the mentioned implants on their head have a blind hole made in the axial direction and used to screw in a screw, which later enters the artificial tooth. This hole, starting from the polygonal end, passes through the adjacent smooth cylindrical part and a significant segment of the screw-threaded implant part, so that this screw-threaded part must have a significant diameter to ensure its proper strength.

In many cases, this is a significant inconvenience or disadvantage, since it is extremely difficult to position the implant in narrow bony alveolar processes due to the diameter of the part provided with a screw thread.

On the other hand, as is very well known in dentistry, the implant is better attached to the patient’s bones when it reaches the cortical bone layer, so there is a tendency to prefer screwing the implants into the specified cortical bone layer, which is much harder than the part of the medullary bone .

In addition, there is an alveolar nerve problem in the posterior region of the jaw, so it is important not to disturb it with an implant in order to avoid the very serious problems that this causes.

In this regard, implant insertion operations usually begin, as mentioned earlier, with the bone being pierced in order to form a cylindrical cavity with smooth surfaces until the self-tapping implant, which acts as a tap, is inserted.

In drilling operations, specialists drill until they reach the smallest possible distance from the alveolar nerve. During these operations, the drills make a large number of revolutions, and after the hole is made, they begin processing with a self-tapping implant operating at a very low peripheral speed.

This common practice is undesirable, and lower risks would be if the nature of the treatment changed, i.e. when the hole is pierced to a greater distance from the alveolar nerve, since at a high working speed there is less control and inaccuracy in processing.

Therefore, the final operation with a self-tapping implant at a low peripheral speed would provide perfectly controlled penetration of the implant until it is close to the alveolar nerve, which creates a lower risk for the patient.

On the other hand, all these implants have a common feature such that when cutting internal screw threads in a previously drilled hole in the bone, a certain amount of chips in the form of flakes or films is formed, while the cut chips do not in any way contribute to the subsequent formation of bone mass that binds the implant .

An object of the present invention is to provide a dental implant, which makes it possible to reduce the diameter of its self-cutting part in the opening of the jaw of a patient in order to facilitate insertion of the implant into the upper edge of very narrow alveolar processes.

Another object of the invention is a dental implant, which is configured to be bicorticalized, thus providing better attachment in the cortical bone layer.

Another object of the invention is a dental implant, which facilitates both its insertion and the formation of screw threads in the patient’s bones, which makes it possible to position the implant with a lower risk near the alveolar nerve by changing the way the hole is made.

Another objective of the invention is a dental implant, which reduces friction during threading, while at the same time facilitating crushing and grinding of the bone for better implant implantation.

Another object of the invention is a dental implant, which provides a more centered placement of the implant in a previously made hole.

To solve these problems, an implant is used, which has the following features already known from the prior art:

- essentially a cylindrical head, which at the outer end has a hexagonal protrusion, for example, having a theoretical outer diameter that is smaller than the cross-sectional diameter of the specified cylindrical head,

- a blind axial hole starting from the end of the specified outer end and serving for the subsequent reception of the supporting screw for the artificial tooth,

- a cylindrical rod equipped with helical teeth or thread ending in a truncated cone end, on which the teeth or thread continue along its entire lateral surface,

- some longitudinal grooves or grooves of different numbers, which extend from the free apical end of the implant and are provided with at least one cutting edge.

With these features, the implant according to the invention is characterized in that the straight cylindrical part of its head, from which the hexagonal part starts, has a significantly larger generatrix than conventional implants compared to this size, so that the front blind axial hole with a screw thread that runs along the axis the implant does not extend beyond the end plane of the indicated cylindrical part.

Therefore, a screw-threaded rod that starts from the cylindrical part has an integral cross section and may be smaller in diameter. This reduction in the diameter of the shaft means in practice that it is easier to use the implant in narrow alveolar processes without any loss or deterioration of its strength.

Based on the studies and experiments, it was found that good practical results are achieved with a dental implant in cases where the height or size of the straight cylindrical part forming it is between 0.7 and 5 millimeters, the total height of a blind axial hole with a screw thread is in between 3 and 5 millimeters, and the diameter of the rod is between 2.5 and 6 millimeters.

Using these values and combining them accordingly, it is possible to prepare the implant well in accordance with any alveolar process in the patient's jaw, while, as described above, any change in its correct direction and centering is excluded and its strength does not deteriorate.

Therefore, the head is wider and makes it possible to place a screw to hold the prosthesis without loosening the implant head at the place of mowing, which prevents it from tearing off. Consequently, the use of implants with a smaller diameter than conventional implants is also facilitated.

Thus, the hexagonal protrusion is characterized in that it has a size between 0.65 and 1 millimeter.

Thus, the implant according to the invention also differs in the apical end of a substantially conical shape, according to which the angle at this end is 120 degrees. This part ends with a screwed end of the implant shaft, having the shape of a truncated cone and equipped with incisive longitudinal grooves, which make it possible to pierce a hole in the bone at a high number of revolutions and with interruption at a safe distance from the alveolar nerve when work is carried out on the tooth in the posterior region of the jaw.

In particular, the free end of this apical conical part is made flat so that it does not have sharp edges during its penetration. The diameter of this cut-off part is from 15 to 25% of the diameter of the cross-section of the implant, which is one of the claimed distinguishing features of the implant.

In the implant screw-in operation according to the invention, the tapered apical end cone makes it possible to approach the alveolar nerve without great risks due to the low rotation speed during the screw-in operation and, therefore, reliable control by a specialist.

On the other hand, the conical part of the apical end contributes to the achievement of the cortical part of the bone, which thus makes it possible to install the implant in this part, which is harder, and increase the guarantee of its immobility.

Thus, when the apical end of the implant is sharp, it moves a smaller amount to the weaker cortical part of the bone.

As is well known, with respect to two cortical parts, in the section of either of the two jaws, the lingual or palatine part is usually wider and more similar to the ivory than the vestibular part, and does not become centered, as was originally expected.

For this reason, since the implant is a self-centering working end, it can go deeper into the previously created bed. If necessary, it will be accurately inserted into the space formed by the piercing tool, since the apical part of the implant has a shape similar to the shape of the piercing tool, and no segment of the implant is spent uselessly and there are no empty holes in the bone.

A part of a truncated cone-shaped self-cutting implant equipped with a screw thread and, in addition, with longitudinal grooves with cutting edges, usually in the amount of four or six, has a special cross-section, due to which it rotates with less friction during insertion of the implant into a previously machined hole, and, in addition, better crushing and grinding of the bone is ensured for its subsequent integration with the implant itself after it is inserted.

All this is carried out through the special geometry of the bases of the longitudinal grooves, which are located between the protrusions provided with external cutting edges of the thread. Therefore, starting from the cutting end farther from the center of the implant, each cutting edge extends a certain length in the radial direction to the point where it makes an outwardly curved concave rotation that is continuously connected to the other outwardly curved portion that reaches the cutting end of an adjacent protrusion with screw thread.

All these and other features of the invention will be described in more detail and more accurately with reference to the accompanying drawings, in which, without limiting meaning of any kind, the following is presented:

figure 1 is a vertical view of the implant according to the invention,

figure 2 - narrow alveolar bone of the patient

figure 3 is a view in section of a bone showing the cortical part,

4 is a sectional view of the back of the jaw showing the alveolar nerve,

5 is a sectional view of a perforation or hole according to the invention near the alveolar nerve,

6 and 7 are two views that show different positions, respectively normal and displaced, relative to the palatine and lingual and vestibular cortical parts,

Fig - position of the implant according to the invention in a previously machined hole in the bone,

Fig.9 is a method of action of a conventional implant,

figure 10 is a bottom view of the apical part of the implant according to the invention,

11 is an embodiment of the apical end of the implant according to the invention,

Fig.12 is a top view of the implant shown in Fig.1,

Fig - an embodiment of the apical end of the implant according to the invention,

Fig.14 is a vertical view of the apical end of the implant according to the embodiment of the invention shown in Fig.13,

Fig - another embodiment of the apical end of the implant according to the invention.

Figure 1 shows an implant (1) equipped with a part (2) with a screw thread, a head or a neck (4) and a hexagonal protrusion (3), spaced from the upper base (5) of the specified head.

Part (2) is provided with teeth or screw thread (18 ′) along its entire length, except for its lower or apical end, on which longitudinal grooves (19) can be seen, also equipped with longitudinal cutouts.

In the same way, the lower end of the implant is shaped like truncated cones (8, 9), in which part (9) has an angle of 120 degrees.

This part (9), in turn, ends with a chamfer (9A), which has a circular cross section with a diameter equal to about 15-25% of the diameter of the threaded portion of the implant shaft.

The head (4) has a size (A) of its generatrix, which according to the invention is from 0.7 to 5 millimeters.

Size (B), which is the sum of the height of the forming head (4) and the height of the protrusion or, in other words, the total depth of the blind axial hole (6) with a screw thread according to the invention is from 1.4 to 6.5 millimeters.

In turn, the diameter of the screwed portion (18 ′) of the implant shaft (18) will be from 2.5 to 6 millimeters, which is much smaller than the usual diameter indicated by dashed lines (7).

Figure 2 shows the usual narrow alveolar bone (11) of the bone (12), which usually makes it difficult for a large diameter rod to penetrate, while the rod described in accordance with the invention can easily penetrate it.

Figure 3 shows the preferred prior art method for piercing holes (15) or a bed for an implant in the tooth (12), passed from the upper end (13) of the tooth, and in order to better fix the implant, it must successfully reach the cortical layer (14) bones.

In Figs. 4 and 5, one can see the bone (12 ′) corresponding to the posterior part of the jaw and having the alveolar nerve (16) passing through this place. Since it is necessary to avoid this nerve, it is clear that according to the prior art, the piercing of the hole (15) in the bone (12 ′) would be interrupted at a distance (17) from the nerve, and this distance provides the necessary guarantee that the specified nerve would not affected.

After x-ray control, if necessary, the implant could be inserted at a small number of revolutions, for example 15 or 20, until it was as close as possible to the nerve passage site.

6 and 7 depict two options, which show the lingual or palatine (14A) and vestibular (14B) cortical parts of the jaw. Often when piercing a hole in the bone and due to the greater hardness of the cortical part (14A), various punched holes (15A, 15B, 15C) turn out to be displaced to the vestibular cortical part (14B), sometimes even reaching such a point that this vestibular cortical part breaks through.

Figure 6 shows the ideal penetration, carried out in a centered and correct manner, in which the implant according to the invention with its apical end has a minimal tendency to move towards the weaker cortical part, which provides a more reliable fit of the specified implant.

Figures 8 and 9 show the behavior of a conventional implant (2 ′ - in Fig. 9), which with its usual cut or flat end (9B) leaves space in the bone (15D) (9C, 15D), which is not its advantage.

In Fig. 8 according to the invention, the space (9C, 15D) is fully occupied by the end of the implant, while its apical end precisely adapts to the shape of the specified bone due to the fact that it has a shape similar to the shape of the milling head.

Figure 11 shows the practical implementation of the apical end of the implant on its part (2), at the end of which longitudinal grooves or grooves (21) are cut. This end ends with a conical part (23) with an angle of approximately 120 degrees, the tip of which has a cut surface or a chamfered surface (9A) to avoid any sharp edges.

The specified surface of the chamfer (9A) has a size equal to from 15 to 25% of the size of the average cross section of the rod (2) of the implant.

Figure 10 shows the special geometry of the apical end of the implant with grooves or grooves (21) defined by longitudinal recesses in which cutting surfaces and edges can be seen (25, 26). The geometry of these grooves (21) is determined by the outwardly curved concave parts (28), followed by other outwardly curved convex parts (27) that form the base of these grooves.

In the embodiment of FIG. 10, there are four grooves at the end, which technically corresponds to the embodiment of FIG. 13, in which there are six grooves (29) with curved concave (31) and curved convex (30) parts.

FIG. 14 is a side view of this embodiment, which technically corresponds to the embodiment shown in FIG. 11.

In all of these figures 10, 11, 13 and 14, you can see the slice or chamfer (9A) of the end, which ends the apical end of the implant according to the invention.

On Fig shows a hexagonal protrusion (3) of the implant, protruding from the upper base (5) of the cylindrical head (4), together with the image (24) corresponding to the blind axial hole (6) in figure 1.

Finally, FIG. 15 shows another practical embodiment of the implant with its apical end having longitudinal grooves (33), a conical end (34, 35) and a chamfer (9A). In this case, the implant is provided with openings (32) filled with bone after implant insertion.

In addition, it should be noted that, as is known from US-A-4826434, the implant for the corresponding purposes can be treated by etching its surface using methods that are known in other technical fields.

Concentrated acids are usually used for this, since treatment with these acids significantly increases the surface of the implant.

Claims (3)

1. A dental implant having a head (4) of cylindrical shape and a direct generatrix, from which the prismatic part or protrusion (3) protrudes outward, preferably of a hexagonal shape, and which has a blind axial hole (6) with an internal screw thread, and also having a shaft ( 18) with an external screw thread, which at its apical end ends with part (8) in the form of a truncated cone, also having a screw thread and, in turn, terminated by the other end (9) in the form of a truncated cone, provided with longitudinal grooves (19) with cutting edges and having a sector with a screw thread between them, characterized in that the height of the protrusion (3) of the hexagonal shape is from 0.65 to 1.5 mm ³ , the height of the cylindrical head is from 0.7 to 5 mm ³ , the conical end ( 9), which completes the part (8) of the rod (18) having a screw thread and a truncated cone shape, has an angle of approximately 120 ° and ends with a flat beveled surface of a round bevel, whose diameter is from 15 to 25% of the diameter of the part of the rod equipped with a screw threaded, longitudinal grooves (19) at the base of its cutting edges IOC are curved outwards, concave rounded part, which departs from the other curved outward, convex rounded portions that extend towards the cutting edges of the adjacent sector. 2. A dental implant according to claim 1, characterized in that the blind axial hole (6) with an internal screw thread has a length from its outer side that does not extend beyond the lower plane (10) of the cylindrical head (4), comprising from 3 to 5 mm ³ , and the diameter of the cylindrical rod (18) with a screw thread, which starts from the aforementioned cylindrical head (4), is from 2.5 to 6 mm. 3. The dental implant according to claim 1, characterized in that when the implant has a diameter of more than 3 mm, a blind axial hole extends beyond the lower plane of the cylindrical head.

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