KR101182806B1 - Membrane for bone-repair - Google Patents

Abstract

The present invention relates to a membrane for alveolar bone regeneration, and more particularly, in a membrane for regenerating alveolar bone to induce bone regeneration by covering an implant filling a bone defect, a central hole through which an implant insert inserted into the alveolar bone may pass. A coupling portion formed and coupled to the implant insert; A side bent portion that is bent downwardly from the coupling portion to form a curved shape as a whole and has a plurality of first holes; A side cover portion which protrudes from both edges of the side bent portion and is bent and bent toward an alveolar bone defect; And a bottom bent portion protruding from the bottom of the side bent portion and disposed adjacent to the side cover portion and bendable independently of the side cover portion, wherein the side bent portion and the side cover portion are regenerated. The present invention relates to a membrane for alveolar bone regeneration, which is preformed three-dimensionally according to the final shape of the alveolar bone.

Description

Membrane for bone-repair

The present invention is directed to a membrane for alveolar bone regeneration that is disposed on the bone defect area to cover the implant to induce bone regeneration, and more specifically, there is no need for extra trimming and bending, so there is no locally excessive protrusion, thereby shortening the procedure time. It is about the membrane for alveolar bone regeneration that is easy to manufacture and increase the success rate.

Conventional Guided Bone Regeneration (GBR), that is, a product in which a hole is formed in a rectangular titanium plate among non-absorbable products has been generally used for osteoinduction regeneration.

The operator recognizes the shape of the location where the bone defect has occurred, trims it to the desired shape by using a rectangular membrane, and then bends it again in three dimensions to cover the defect area. And finally secured using a separate screw to secure the membrane.

However, the prior art had to recognize the shape of the bone defect and trim it to the required shape, and by bending it again, it was difficult to cover the bone defect more completely, and the procedure time was increased, and the excessive crying during the bending process In other words, the excessively protruding bending area was a major cause of failure of bone regeneration due to infection from the outside through the gingival during bone regeneration induction period. In addition, in order to remove the screw fastened to fix the membrane, a wider gingival incision is required, which not only increases the procedure time but also causes swelling due to bleeding, which causes pain to the patient. There was a burden.

Republic of Korea Patent Publication No. 10-2009-0111671

The present invention relates to a customized alveolar bone regeneration membrane which is trimmed in three dimensions and simultaneously bent at the same time in order to predict the bone defect shape in the above problem, specifically, the procedure time is shortened, and the production is convenient. In addition, it aims to provide a membrane for alveolar bone regeneration that can increase the success rate of the procedure and reduce swelling and pain to the patient.

Alveolar bone regeneration membrane of the present invention for achieving the above object, Alveolar bone regeneration membrane to induce bone regeneration covering the implant filling the bone defect site,

A coupling portion formed with a central hole through which an implant insert inserted into the alveolar bone may pass, and coupled to the implant insert;

A side bent portion that is bent downwardly from the coupling portion to form a curved shape as a whole and has a plurality of first holes;

A side cover portion which protrudes from both edges of the side bent portion and is bent and bent toward an alveolar bone defect; And

Is formed to protrude from the bottom of the side bent portion and is disposed adjacent to the side cover portion and comprises a bottom bent portion that can be bent independently of the side cover portion,

The side bent portion and the side cover portion are preformed three-dimensionally to match the final shape of the alveolar bone to be regenerated.

In the membrane for regenerating alveolar bone, the lower bent portion may be provided with an independent portion cut toward the side bent portion so as to be independent of the side cover portion.

In the membrane for alveolar bone regeneration, the independent part may have a “U” or “V” shape.

In the membrane for alveolar bone regeneration, the lower bent portion may be preformed three-dimensionally in accordance with the shape of the alveolar bone to be regenerated.

In the membrane for alveolar bone regeneration, the side cover portion may be easier to bend than the side bent portion.

In the membrane for alveolar bone regeneration, the side cover portion may be formed in a single shape over the entire side surface of the side bent portion.

In the membrane for regenerating the alveolar bone, the side bent portion may include a first bent portion bent outwardly toward the lower side and a second bent portion connected to the first bent portion and bent inwardly toward the lower side.

In the membrane for alveolar bone regeneration, the first hole may be formed only in the first bent portion.

In the membrane for alveolar bone regeneration, the first hole at the lowermost end of the first bent portion may be aligned in a concave dish shape.

In the membrane for alveolar bone regeneration, the lower bent portion may be symmetrically disposed with respect to the center of the side bent portion.

In the membrane for regenerating the alveolar bone, a coupling side portion protruding from the side edge of the coupling portion and bent to surround the implant may be provided.

In the membrane for alveolar bone regeneration, a coupling upper portion protruding from the upper end of the coupling portion and bent to surround the implant may be provided.

In the membrane for alveolar bone regeneration, the coupling upper portion, at least two or more may be spaced at equal intervals.

In the membrane for alveolar bone regeneration, the coupling upper portion may be symmetrically disposed with respect to the center of the coupling portion.

In the membrane for alveolar bone regeneration, the joining upper part may be preformed in three dimensions in accordance with the final shape of the alveolar bone to be regenerated.

In the alveolar bone regeneration membrane, a titanium nitride (TiN) coating layer or an anodizing coating layer may be formed on a surface thereof.

In the case of alveolar bone regeneration membrane according to the present invention, by suggesting a pre-molded alveolar bone regeneration membrane that has been three-dimensionally customized to the treatment environment when the bone regeneration induction is required, the operator can easily and quickly perform the procedure clinically. The success rate can be increased, and the patient can reduce edema by shortening the procedure time, as well as reducing the time burden on the procedure, thereby giving satisfaction to both the operator and the patient.

In particular, by suggesting a 3D molded alveolar bone regeneration membrane customized to cope with various shapes of bone defects compared to existing products, it minimizes additional work such as trimming and bending, and minimizes local protrusion phenomenon due to bending. This will increase the effectiveness of the procedure.

1 is a two-dimensional plan view of the membrane for alveolar bone regeneration according to an embodiment of the present invention.
2 and 3 are views showing the three-dimensional form of Figure 1;
4 is a view showing a state in which the membrane for alveolar bone regeneration of FIGS.
5 is a two-dimensional plan view of the membrane for alveolar bone regeneration according to another embodiment of the present invention.
6 and 7 are views showing the three-dimensional form of FIG.
8 to 17 is a two-windowed plan view of the membrane for alveolar bone regeneration according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings the alveolar bone regeneration membrane according to an embodiment of the present invention will be described in detail.

The membrane 10 for alveolar bone regeneration according to an embodiment of the present invention is to induce the alveolar bone regeneration at the alveolar bone defect by wrapping the open wall of the alveolar bone defect. The two-dimensional plan view of the membrane 10 for alveolar bone regeneration is as shown in Figure 1 and the shape is shown to be trimmed according to the pre-classified bone defects. The two-dimensional bone regeneration membrane, which has been trimmed in advance, is bent in three dimensions by a predetermined bending mechanism, as shown in FIGS. 2 and 3.

As described above, the membrane 10 for alveolar bone regeneration according to the present embodiment is not immediately trimmed and bent to the shape of the patient by the operator immediately before the procedure, but is trimmed and bent in advance using a predetermined bending machine in three dimensions. It is produced by performing, characterized in that pre-formed in three-dimensional curved shape in the alveolar bone direction to match the shape of the alveolar bone to be reproduced.

The alveolar bone regeneration membrane 10, the coupling portion 20, coupling side portion 30, coupling upper portion 40, side bent portion 50, side cover portion 60 and the lower bent portion 70 It is prepared.

The coupling part 20 is to form a central hole 21 through which the implant insert 80 inserted into the alveolar bone 81 is formed, and is coupled to the implant insert 80. This coupling portion 20 is a bone defect, and covers the upper side of the site where the implant 82 is stacked is made of a substantially flat form. The central hole 21 is formed in the central portion of the coupling portion 20, a plurality of fourth in the radial shape around the central hole 21 around the central hole 21 The hole 22 is formed. The fourth hole 22 has a smaller size than the central hole 21 but may be 0.8 mm to 2.0 mm. The fourth hole 22 is a physiological reaction between the implant 82 filling the bone defect and the blood of the surrounding bone tissue is activated to allow the implant 82 to be firmly and stably fused with the surrounding bone tissue, It is desirable to have a size suitable for bone fusion.

The engaging side portion 30 is bent inward to surround the implant 82 as protruding from the side edge of the engaging portion 20. The coupling side portion 30 may be formed to protrude from a portion of the side edge of the coupling portion 20 and accordingly may be easily bent. Specifically, the side coupling portion 20 is provided to cover the upper medial or distal of the alveolar bone 81.

A plurality of fifth holes 31 are formed in the engaging side portion 30. The fifth hole 31 has a smaller diameter than the fourth hole 22 so that more holes can be formed in a narrow space. As such many holes are formed, there is an advantage that the overall flexibility can be increased and the bending can be facilitated.

The coupling upper portion 40 is bent inward to surround the implant 82 as disposed on the upper end of the coupling portion 20. The engaging upper portion 40 is preformed in three dimensions to match the final shape of the alveolar bone 81 to be regenerated.

On the other hand, the coupling upper portion 40 is formed with a plurality of sixth holes 44, the blood through the sixth hole 44 can be promoted bone fusion. In addition, the coupling upper portion 40 is preformed in three dimensions in accordance with the final shape of the alveolar bone 81 to be regenerated.

The side bent portion 50, the implant 82 is provided therein and is bent downward from the fixed coupling portion 20, the overall curved surface shape. A plurality of first holes 53 having a predetermined size are formed in the side bent portion 50.

As described above, the first hole 53 is used as a passage through which blood can communicate.

The side bent portion 50 includes a first bent portion 51 bent in a direction away from the coupling portion 20 and a second bent portion 52 bent in a direction approaching the coupling portion 20. . In this case, the first hole of the first bent portion 51 may be 0.8 to 2.0 mm, and the first hole of the second bent portion 52 may have a diameter of 0.1 to 0.7 mm. At this time, the first hole 53 at the lowermost end of the first bent portion 51 is aligned in a concave dish shape. In other words, the lowermost end of the first hole 53 is aligned along the concave line lr. The reason for the concave dish shape is to form a bending line naturally so that there is no local protrusion in some sections during bending. In addition, the reason for the small size of the hole of the second bent portion 52 is to maximize flexibility in the bending process so that the flexible bend can be bent even when the radius of curvature is large.

The side cover part 60 is provided with a graft material 82 therein and protrudes from both side edges of the side bent portion 50 and is bent and bent toward the graft material 82 to provide a plurality of second holes 61. ) Is formed. The side cover portion 60 wraps around the buccal side of the bone defect, and the distance from the side bend portion 50 gradually increases from the top to the bottom, and the shape remains constant after the middle. To have. The side cover portion 60 is formed in a single shape over the entire side of the side bent portion 50 so that it can be easily removed when pulling out from the bone defect site after bone fusion, as well as a large amount of bone graft material It can be covered. The side cover portion 60 is formed with a plurality of second holes 61, the diameter of the second hole 61 is preferably smaller than the diameter of the first hole (53). For example, the diameter of the second hole may be 0.1 to 0.7 mm. In addition, the second hole 61 is arranged more densely than the first hole 53 so that a large number of holes can be formed in the side cover part 60 in contrast to the same area. That is, the total area of the holes per unit area of the second hole 61 of the side cover part 60 is preferably larger than the total area of the holes per unit area of the first hole 53 of the side bent part 50. As the second hole 61 is densely arranged in a small size as described above, the flexibility of the overall side cover part 60 is increased and can be easily removed without damaging the surroundings in the process of removing it from the alveolar bone 81 later. Make sure In addition, as the side cover portion 60 is flexible, bending can be easily performed.

The lower bent part 70 is formed at the lower end of the side bent part 50 and is bent inwardly. A plurality of third holes 73 are formed in the lower bent portion 70. At this time, the diameter of the third hole 73 may be smaller than the first hole 53, thereby ensuring sufficient flexibility and can be easily removed from the alveolar bone 81 after the bone fusion later. Meanwhile, the lower bent part 70 may include an independent part 77 cut or concavely recessed toward the side bent part 50 such that the side cover part 60 may be bent independently from each other. Can be. The independent part 77 is to prevent bending with the side cover part 60 when the lower bent part 70 is bent, and the lower bent part 70 is provided as the independent part 77 is provided. Or facilitate the bending of the side cover portion 60, of course, in the process of bending the lower bent portion 70 is locally protruded between the side cover portion 60 so as not to cry. The independent portion 77 may have a “U” or “V” shape, but is not limited thereto.

Meanwhile, a tin coating layer or an anodizing coating layer may be formed on the surface of the membrane 10 for alveolar bone regeneration. In the case where such a coating layer is formed, there is an advantage that the overall appearance of the membrane may cause aesthetics as it appears black.

Alveolar bone regeneration membrane 10 according to an embodiment of the present invention has the following effects.

First, before attaching the membrane 10 for alveolar bone regeneration, the implant insert 80 is inserted into the alveolar bone 81 and the implant 82 is filled in the bone defect site. Subsequently, the membrane 10 for alveolar bone regeneration formed by forming a three-dimensional shape in advance with respect to the implant insert 80 is coupled to the implant insert 80. Specifically, the implant insert 80 is fitted into the central hole 21 of the coupling portion 20 to be coupled. As described above, after the alveolar bone regeneration membrane 10 is fixedly bonded, after the predetermined time passes after the gingival bone regeneration membrane 10 is fused in the interior of the alveolar bone regeneration membrane 10, the alveolar bone regeneration membrane 10 is fused. ) Is removed from the bone defect.

Since the membrane 10 for alveolar bone regeneration of the present invention is customized and preformed in three dimensions, the operator can perform the procedure with minimal trimming and bending at the procedure site or without the trimming or bending. Has the advantage.

In particular, since the membrane 10 for alveolar bone regeneration has a pre-customized shape, there is an advantage in that a part of the protruding portion of the alveolar bone regeneration process can be prevented from being squeezed, and the implant insert 80 is locked. Can be eliminated when a separate fastening screw is required.

In addition, by varying the size of the hole for each part to be able to bend a lot to be able to increase the flexibility to maximize the ease of bending. Accordingly, even when local bending is required at the procedure site, field workability can be increased.

In addition, as the entire curved surface is made suitable for bone defects and the separate crying phenomenon is eliminated, the membrane 10 for alveolar bone regeneration can be completely adhered to the implant 82, which is an implant during regeneration induction period, and serves as a stable guide. As a result, the risk of exposing the membrane 10 out of the gingival can be minimized.

In addition, the side cover portion 60 is configured to be highly flexible, so that in addition to the ease of bending, it can be easily removed later from the implant.

Alveolar bone regeneration membrane 10 according to an embodiment of the present invention may be modified as follows.

First, as shown in FIGS. 5 to 7, two coupling upper portions 40 are provided in the membrane 10 for alveolar bone regeneration, and are symmetrical based on the concave groove 43 formed in the center of the coupling portion 20. It can be arranged as an enemy. Specifically, the coupling upper portion 40 is preferably shaped so that the bending line can be two or more. For example, a first bending line l1 in which all the coupling upper parts 40 can be bent in a batch, and a second bending line l2 in which each coupling upper part 40 can be bent individually are formed. It is desirable to be shaped so that it can be. To this end, the coupling upper portion 40 includes a first upper portion 41 including all the coupling upper portions 40 together with a second upper portion 42 that protrudes from the first upper portion 41 separately. But the concave groove 43 is formed between the second upper portion 42. Accordingly, during bending, the second bending line l2, which is the lower end of the second upper part 42, is bent primarily around the first bending line l1, which is the lower end of the first upper part 41. It can be bent secondarily around the center. As the second bending is performed as described above, the overall bending curve may be smoothly prevented from locally protruding from the bending start portion.

In addition, the lower bent portion 70 is a pair is arranged at equal intervals, each lower bent portion 70 is arranged symmetrically with respect to the center of the side bent portion (50). The lower bent portion 70 is preformed three-dimensionally in accordance with the shape of the alveolar bone 81 to be regenerated. In addition, the lower bent part 70 is made of a first lower bent part 71 and a second lower bent part 72 similar to the coupling upper part 40, and the first lower bent part 71. Is configured to include all the lower bent portion 70, the second lower bent portion 72 is configured to protrude from the first lower bent portion 71 can be bent individually. As such, since the first lower bent portion 71 and the second lower bent portion 72 are divided, the bending line is generally smoothed, and local protrusion may be prevented. That is, the third bending line l3 centering on the first lower bent portion 71 and the fourth bending line l4 centering on the second lower bending portion 72 may be formed.

In addition, as shown in FIG. 8, in the configuration of FIG. 5, it is also possible that no additional holes are formed in the second bent portion 52 and the lower bent portion 70. As described above, since no separate holes are formed in the second bent portion 52 and the lower bent portion 70, there is an advantage in that the membrane 10 for alveolar bone regeneration is removed. For example, if a separate hole is not formed in the second bent portion 52 and the lower bent portion 70, there is no place for blood to pass through and thus the second bent portion 52 and the lower bent portion 70 are formed. The connective tissue is not provided due to the communication of blood, which is convenient when the membrane 10 for alveolar bone regeneration is removed from the implant.

In addition, as shown in FIG. 9, in the configuration of FIG. 1, it is also possible that no additional holes are formed in the second bent portion 52 and the lower bent portion 70. As such, since there are no separate holes formed in the second bent portion 52 and the lower bent portion 70, there is an advantage that it is convenient when removing the membrane 10 for alveolar bone regeneration.

In addition, as shown in FIG. 10, in the configuration of FIG. 5, it is possible that a separate coupling upper portion 40 is not provided. As such, the structure in which the separate coupling upper portion 40 is not provided can be adopted when there is no defect in the side where the tongue is located and the defect portion is provided in the lip side and the surrounding teeth.

In addition, as shown in FIG. 11, in the configuration of FIG. 10, it is also possible that a separate hole is not formed in the second bent portion 52 and the lower bent portion 70. As such, when the hole is not formed at a specific site, a separate connective tissue is not formed at the corresponding site, which is advantageous when the membrane 10 for alveolar bone regeneration is removed.

In addition, as shown in FIG. 12, in the configuration of FIG. 1, it is possible that a separate coupling upper portion 40 is not provided. As such, the structure in which the separate coupling upper portion 40 is not provided can be adopted when there is no defect in the side where the tongue is located and the defect portion is provided in the lip side and the surrounding teeth.

In addition, as shown in FIG. 13, in the configuration of FIG. 12, it is also possible that a separate hole is not formed in the second bent portion 52 and the lower bent portion 70. As such, when the hole is not formed at a specific site, a separate connective tissue is not formed at the corresponding site, which is advantageous when the membrane 10 for alveolar bone regeneration is removed.

In addition, as illustrated in FIG. 14, the coupling side portion 30 and the coupling upper portion 40 may be removed in the configuration of FIG. 5. The structure in which the engaging side portion 30 and the engaging upper portion 40 are not provided in this way can be employed when the defect portion is formed only on the lip side without the defect portion being formed on the tongue side and the surrounding tooth side. .

In addition, as shown in FIG. 15, it is also possible that a separate hole is not formed in the second bent portion 52 and the lower bent portion 70 in the configuration of FIG. 14. As such, when the hole is not formed at a specific site, a separate connective tissue is not formed at the corresponding site, which is advantageous when the membrane 10 for alveolar bone regeneration is removed.

In addition, as shown in FIG. 16, in the configuration of FIG. 14, the lower bent portion 70 may be configured in a single form. As such, when the lower bent portion 70 is configured in a single shape, the area that can be covered may be increased.

In addition, as shown in FIG. 17, in the configuration of FIG. 16, it is also possible that a separate hole is not formed in the second bent portion 52 and the lower bent portion 70. As such, when the hole is not formed at a specific site, a separate connective tissue is not formed at the corresponding site, which is advantageous when the membrane 10 for alveolar bone regeneration is removed.

The present invention is not limited to this, but the scope of the claims can be broadly interpreted as long as it can reasonably be interpreted by the claims of the present invention.

10 Membrane for alveolar bone regeneration
21 ... the central hole 22 ... the fourth hole
30 ... engage side 31 ... 5th hole
40 ... Upper coupling part 41 ... First upper part
42 second upper part 43 recessed groove
44 ... 6th hole 50 ... side bend
51 ... the first bend 52 ... the second bend
53 1st hole 60 Side cover
61 second hole 70 bottom bend
71 First lower bend 72 Second lower bend
73 3rd hole 80 Insert for implant
81 Alveolar bone 82

Claims (16)

In the membrane for alveolar bone regeneration to induce bone regeneration by covering the implant filling the bone defects,
A coupling portion formed with a central hole through which an implant insert inserted into the alveolar bone may pass, and coupled to the implant insert;
A side bent portion that is bent downwardly from the coupling portion to form a curved shape as a whole and has a plurality of first holes;
A side cover portion which protrudes from both edges of the side bent portion and is bent and bent toward an alveolar bone defect; And
Is formed to protrude from the bottom of the side bent portion and is disposed adjacent to the side cover portion and comprises a bottom bent portion that can be bent independently of the side cover portion,
The side bent portion and the side cover portion is a membrane for alveolar bone regeneration, characterized in that pre-formed in three dimensions to match the final shape of the alveolar bone to be regenerated. The method of claim 1,
The lower bent portion, the membrane for alveolar bone regeneration is provided with an independent portion cut toward the side bent portion so that the side cover portion and the independent bending can be made. The method of claim 2,
The independent portion, the membrane for alveolar bone regeneration, characterized in that having a "U" or "V" shape. The method of claim 1,
The lower bent portion of the alveolar bone regeneration membrane, characterized in that pre-formed in three dimensions in accordance with the shape of the alveolar bone to be regenerated. The method of claim 1,
The side cover portion is a membrane for alveolar bone regeneration, characterized in that easier bending than the side bent portion. The method of claim 1,
The side cover portion is a membrane for alveolar bone regeneration, characterized in that formed in a single shape over the entire side of the side bent portion. The method of claim 1,
The side bent portion, the first bent portion that is bent outwards toward the lower side, and the second bent portion of the membrane for alveolar bone regeneration characterized in that it is connected to the first bent portion and bent inwardly toward the lower side. The method of claim 7, wherein
Alveolar bone regeneration membrane, characterized in that the first hole is formed only in the first bent portion. The method of claim 8,
Membrane for alveolar bone regeneration, characterized in that the first hole of the lowermost end of the first bent portion is aligned in the shape of a concave dish. The method of claim 1,
Membrane for alveolar bone regeneration, characterized in that the lower bent portion is disposed symmetrically with respect to the center of the side bent portion. The method of claim 1,
Membrane for alveolar bone regeneration, characterized in that the coupling side portion protruding from the side edge of the coupling portion is bent to surround the implant. The method of claim 1,
Membrane for alveolar bone regeneration, characterized in that the upper portion is provided to protrude from the upper end of the coupling portion is bent to surround the implant. The method of claim 12,
The coupling upper side, at least two or more membranes for alveolar bone regeneration, characterized in that arranged at equal intervals. The method of claim 12,
The coupling upper side is alveolar bone regeneration membrane, characterized in that disposed symmetrically with respect to the center of the coupling. The method of claim 12,
The coupling upper side, alveolar bone regeneration membrane, characterized in that pre-formed in three dimensions to match the final shape of the alveolar bone to be regenerated. The method of claim 1,
Membrane for alveolar bone regeneration, characterized in that the titanium nitride (TiN) coating layer or anodizing coating layer is formed on the surface.

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