KR20200120320A - Connector to induce Biotissue - Google Patents

Abstract

The present invention provides a connector comprising, in a bone body having a fixing part formed on one side thereof where a biological tissue (Achilles tendon or plantar muscle) is fixed to a corresponding region, a fixing cap that is coupled to the corresponding region to which the biological tissue is to be fixed, a connecting part extending from the fixing cap toward the biological tissue and receiving the biological tissue by introducing the same inside through an opening at an end thereof, and a fastening means that is fastened to the biological tissue received in the connecting part and fixes the biological tissue to the connecting part, so that the fixing part to which the biological tissue is fixed is formed on the bone body, and the fixing cap connected with the biological tissue is covered on the bone body having the fixing part. The biological tissue is simply and firmly fixed to the bone body, and a contact area with the biological tissue is increased by the connecting part extending from the fixing cap, thereby reducing the tensile force per unit area, and avoiding damage to the biological tissue due to tensile stress. Also, as the biological tissues are brought into close contact with the bone body by the fixing cap and the connecting part, engraftment of the biological tissue cells is promoted and induced. Therefore, the connector excellent in fixation of biological tissue can induce the engraftment of the biological tissue.

Description

Connector to induce biotissue

The present invention relates to a connector that induces engraftment of biological tissues in bone (bone), and more particularly, the biological tissue (muscle (muscle), tendon (tendon) or ligament) is firmly fixed to the bone body, and biological It relates to a connector that safely induces engraftment of living tissue cells and induces engraftment of living tissues with excellent fixation power.

In general, 3D printing technology is expected to present new treatments for many areas that cannot be solved by current medical technologies. Among them, bones that are no longer in use due to fractures or arthritis are duplicated in their original shape by 3D printing. Therefore, the technique of removing damaged bones and replacing them with replicas is in the limelight as a very innovative treatment because it can avoid joint fusion or cutting.

And in the case of avascular necrosis of the talus, the current technique is to remove the necrotic bone, transplant the allogeneic bone, and fix it together with the upper and lower bones. In this case, the joint is fixed and the joint motor function is lost. .

Accordingly, a technology to duplicate and replace the talus by 3D printing has already been introduced and has been successfully applied to the human body, but in this case, due to the characteristics of the talus, there are few attachments of tendons or ligaments, so the results were limited to simple replacement of the replica. .

A ligament is attached between the bone and the bone to stabilize the joint, and a tendon (tendon) is attached between the muscle and the bone to transmit the force induced by the muscle to the bone to cause movement. ) Is attached in place to relax the muscle, the muscle naturally contracts, causing pain and contracture, and loss of function.The current technology for this is to make a hole in a 3D-printed bone restoration product to make a tendon (tendon) or ligament. However, this method of suturing depends only on the force of the suture, so it was difficult to expect a proper function due to weak tensile strength and susceptibility to fatigue.

In addition, the direct fixation method using such a suture may not be able to maintain a solid fixation state in the case of a doctor who is not highly skilled, and it took a long time to form a knot of the suture, which was the cause of low surgical convenience and increased operation time. .

In view of the above problem, Patent Publication No. 10-2016-0053389 (2016.05.13) provided a fixing device for bonding a tendon and ligaments and bones, the fixing device being formed at the head part and both ends of the head part, At least one of a tendon and a ligament and a leg portion penetrating the dense bone of the bone, the leg portion penetrating at least one of the tendon and ligament and the dense bone of the bone, and the head portion pressurizes at least one of the tendon and ligament And fixed.

However, since the tendon (tendon) or ligament tissue, which is a living tissue, is a living tissue, but the bone replica is an object made of metal (or composite synthetic resin), it is difficult to induce the living tissue to engraft onto a metal object or to be strongly connected.

Therefore, there is a need to develop a technology that induces the tendon (tendon) or ligament, which is a living tissue, to be sturdily engrafted on the bone body.

The present invention is to form a fixed portion to be fixed to the biological tissue (Achilles tendon or plantar muscle) to the bone (bone) body, and cover the fixed cap to which the biological tissue is connected to the bone body in which the fixed portion is formed, wherein the biological tissue is the bone body It is easily and firmly fixed to the body, and it is possible to avoid damage to the living body tissue due to tensile stress as the tensile force per unit area is reduced by increasing the contact area with the living tissue by the connection part extended from the fixing cap, and the fixing cap and the connection part It is an object of the present invention to provide a connector that promotes engraftment of biological tissue cells as the biological tissue is brought into close contact with the bone body, thereby inducing the engraftment of the biological tissue with excellent fixation of the biological tissue.

The connector for inducing the engraftment of the living tissue according to the present invention includes a fixing cap that is coupled to a corresponding region to which the living tissue is to be fixed among bone bodies formed on one side of the fixing part to which the living tissue is fixed to the corresponding region, and a biological tissue in the fixed cap. It extends toward and includes a connecting portion for an interview with the end of the biological tissue, and a fastening means that is fastened to the biological tissue accommodated in the connecting portion, and fixes the biological tissue to the connecting portion.

At this time, the connection part according to the present invention may enter the living tissue through the opening at the end of the living body, so as to surround the living tissue for an interview, or the connection part may be embedded between the inside of the living tissue for an interview.

And it is preferable that the fixing cap and the connection part according to the present invention are made of a mesh shape.

In addition, it is formed around a corresponding portion of the bone body to which the fixing cap is coupled according to the present invention, and may include a fixing means for fixing the end of the fixing cap to the bone body.

In addition, a coupling groove is formed in a corresponding portion of the bone body to which the biological tissue is fixed according to the present invention, and a coupling portion coupled to the coupling groove may be formed inside the fixing cap.

The biological tissue according to the present invention is an Achilles tendon or plantar muscle.

The connector for inducing engraftment of living tissue according to the present invention has the following effects.

First, by forming a fixing part to which the biological tissue (Achilles tendon or plantar muscle) is fixed to the bone (bone) body, and putting a fixing cap connected to the biological tissue to the bone body where the fixing part is formed, the living tissue is attached to the bone body. It can be fixed simply and firmly.

Second, by increasing the contact area with the living tissue by the connection part extended from the fixing cap, the tensile force per unit area is reduced, so that damage to the living body tissue due to tensile stress can be avoided.

Third, as the living tissue is brought into close contact with the bone body by the fixing cap and the connection part, the engraftment of the living tissue cells is promoted and thus the fixation of the living tissue has an excellent effect.

1 is an exemplary view showing a connector for inducing engraftment of a living tissue according to an embodiment of the present invention.
2 is an exemplary view showing a state in which an Achilles tendon is fixed to a bone body by a fixing cap according to an embodiment of the present invention.
3 is an exemplary view showing a connector for inducing engraftment of living tissue according to another embodiment of the present invention.
4 is an exemplary view showing a fixed state in which the plantar muscle is fixed to the bone body by a fixing cap according to another embodiment of the present invention.
5 is an exemplary view showing a connector for inducing engraftment of living tissue according to another embodiment of the present invention.
6 is an exemplary view showing a state in which the Achilles tendon is fixed to the bone body by a fixing cap according to another embodiment of the present invention.
7 is an exemplary view showing a connector having a coupling part formed inside a fixing cap according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventors appropriately explain the concept of terms in order to explain their own invention in the best way. Based on the principle that it can be defined, it should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, and at the time of the present application, they are equivalent to It should be understood that there may be variations.

The present invention relates to a connector for inducing the engraftment of the living tissue (Achilles tendon or plantar muscle) is firmly fixed to the bone body, and biologically and safely engraftment of the living tissue cells is induced, and the drawing Looking in more detail with reference to the following.

First, the bone body according to the embodiment of the present invention with reference to FIGS. 1 to 7 is manufactured by 3D printing according to the shape of the bone to be transplanted, and the biological tissue (Achilles tendon or plantar muscle) among the bone body 110 is fixed. A fixing part (unsigned) is formed at the corresponding part, and a fixing cap 200 is mounted on the bone body 110 on which the fixing part (unsigned) is formed.

At this time, the fixing cap 200 forms a pocket so that the bones (bones) of the corresponding part of the bone body 110 to be fixed are covered and hooked, and a connection part 210 is extended to one side thereof.

The connection part 210 is formed extending from the fixing cap 200 toward a living tissue (Achilles tendon or plantar muscle), and is connected by interviewing the living tissue at the end, wherein the connection part 210 has an opening formed at the end. The biological tissue may be introduced into the interior through the biological tissue and connected through an interview, or the connection part 210 may be interposed between the interior of the biological tissue and connected by an interview with a core.

Here, the fixing cap 200 and the connection part 210 are made of a mesh to induce engraftment of biological tissue cells, and the fixing cap 200 is selectively expanded by elasticity, and the bone body 110 A composition for inducing engraftment of cells may be applied to the fixing part, the fixing cap 200 and the connection part 210, and the living body tissue is connected to the connection part 210 by a fastening means 220 fastened to the connection part 210. Is fixed to

At this time, the fastening means 220 is preferably in the form of a bolt or pin having a head, but may be composed of a suture that sutures the connection portion 210 in which the Achilles tendon or plantar muscle is accommodated.

Therefore, the connector for inducing engraftment of living tissue according to an embodiment of the present invention has a shape corresponding to the bone (bone) to be bone transplanted, and the bone body 110 is manufactured by 3D printing, and the connection part 210 ), a fixed cap 200 to which a biological tissue (Achilles tendon or plantar muscle) is fixed is covered and coupled to a portion of the bone body 110 that needs to be connected to the biological tissue, so that the biological tissue is in close contact with the bone body 110 While being fixed.

At this time, since the fixing cap 200 is attached to a corresponding portion of the bone body 110 to which the biological tissue is to be fixed, the biological tissue can be conveniently and firmly fixed to the bone body.

In addition, as the tensile force per unit area is reduced by increasing the contact area with the living tissue by the connection part 210 extending from the fixing cap 200, damage to the living body tissue due to tensile stress can be avoided, and the fixing cap 200 As the biological tissue is brought into close contact with the bone body by the connection part 210, the engraftment of the biological tissue cells is promoted, and thus the fixation of the biological tissue is excellent.

Herein, in the present invention, the bone body 110 is described as being limited to that manufactured by 3D printing, but the bone (bone) of the human body may be used as it is without being limited thereto.

In addition, the connector for inducing the engraftment of the biological tissue having the above-described configuration can be applied in various ways, which will be described as follows.

Looking at an embodiment of connecting the Achilles tendon to the heel bone using a connector for inducing engraftment of living tissue according to an embodiment of the present invention with reference to FIGS. 1 and 2, the bone body corresponding to the shape of the heel bone is 3D Manufactured by printing.

The fixed cap 200 for inducing the generation of engraftment cells is made in a mesh shape so that the Achilles tendon is firmly connected to the bone body 110 and has elasticity, and extends from the fixed cap 200 in the direction of the Achilles tendon The formed connecting portion 210 is formed to extend in a tubular shape having a hollow with one side open, and the end of the Achilles tendon is inserted through the hollow opening to accommodate the Achilles tendon in the connecting portion 210.

At this time, the connection part 210 and the Achilles tendon are sealed with a suture which is a fastening means 220, and the Achilles tendon is fixed to the connection part 210 by the fastening means 220.

The fixing cap 200 fixed to the connection part 210 of the Achilles tendon through the above process is covered on the corresponding part of the bone body 110 to which the Achilles tendon is fixed, so that the fixing cap 200 is in the bone body 110 The Achilles tendon is coupled as if surrounding the region to be connected, so that the Achilles tendon is connected to the bone body 110.

The Achilles tendon connected in this way is more rigidly connected to the bone body 110 by the fixing cap 200, and the contact area with the Achilles tendon is increased by a connection part 210 extending from the fixing cap 200. As the tensile force per area decreases, damage to the Achilles tendon due to tensile stress can be avoided, and the engraftment of Achilles tendon cells is promoted as the Achilles tendon is in close contact with the bone body 110 by the fixing cap 200 and the connection part 210 Induction, excellent fixation of the Achilles tendon is maintained and the fixed state is protected.

And looking at an embodiment of connecting the plantar muscle to the heel bone using a connector for inducing engraftment of living tissue according to an embodiment of the present invention with reference to FIGS. 3 and 4, a bone body corresponding to the shape of the heel bone Manufactured by 3D printing.

The fixation cap 200 for inducing the generation of engraftment cells is made in a mesh shape so that the plantar muscle is firmly connected to the bone body 110 and has elasticity, and from the fixation cap 200 to the plantar muscle direction The extended connecting portion 210 is formed to extend in a tubular shape having a hollow with one side open, and the end of the plantar muscle is inserted through the hollow opening to accommodate the plantar muscle in the connecting portion 210.

At this time, the connection part 210 and the plantar muscle are sutured to each other with a suture which is a fastening means 220, and the Achilles tendon is fixed to the connection part 210 by the fastening means 220.

The fixation cap 200 in which the plantar muscle is fixed to the connection part 210 by the above-described process is covered on a corresponding part of the bone body 110 to which the plantar muscle is to be fixed, so that the fixation cap 200 is applied to the bone body 110 ), the plantar muscle is connected to the bone body 110 so that the plantar muscle is connected to the bone body 110.

The plantar muscle connected in this way is more firmly connected to the bone body 110 by the fixation cap 200, increasing the contact area between the plantar muscle and the bone body 110 to decrease the tensile force per unit area, thereby reducing tensile stress. It avoids damage to the plantar muscle caused by the plantar muscle, promotes the production of engraftment cells in the plantar muscle, and keeps the fixed state protected.

Therefore, since the fixing cap 200 is attached to a corresponding portion of the bone body 110 to which the plantar muscle is to be fixed, the plantar muscle can be conveniently and firmly fixed to the bone body.

In addition, as the tensile force per unit area is reduced by increasing the contact area with the plantar muscle with the connecting portion 210 extended from the fixing cap 200, damage to the plantar muscle due to tensile stress can be avoided, and the fixing cap 200 And as the plantar muscle is in close contact with the bone body 110 by the connection part 210, the engraftment of the plantar muscle cells is promoted and induced, so that the fixation of the plantar muscle is excellent and the fixed state is protected and maintained.

In addition, the connector for inducing engraftment of living tissue according to the embodiment of the present invention with reference to FIGS. 5 and 6 includes a connection part 210 extending from the fixing cap 200 to the Achilles tendon between the Achilles tendon. Is connected to the core.

The connection part 210 has elasticity in a plate shape made of a mesh, is built inside the end side of the Achilles tendon fixed to the connection part 210, and is connected to the Achilles tendon.

The fixing cap 200 fixed to the connection part 210 of the Achilles tendon through the above process is covered on the corresponding part of the bone body 110 to which the Achilles tendon is fixed, so that the fixing cap 200 is in the bone body 110 The Achilles tendon is coupled as if surrounding the region to be connected, so that the Achilles tendon is connected to the bone body 110.

In addition, the connector for inducing the engraftment of living tissue according to an embodiment of the present invention is formed with a fixing means 111 capable of fixing the fixing cap 200 around the bone body 110, the fixing means ( 111) may be operated in the form of a bolt, a pin, or a ring, and a plurality of the bone bodies 110 are disposed at regular intervals in the region to which the fixing cap 200 is coupled, and are coupled to the bone body 110 By fixing the periphery of the fixed cap 200 to the bone body 110, it is not separated and can be firmly coupled.

Therefore, with the above-described configuration, the fixing cap 200 is attached to the corresponding portion of the bone body 110 to which the Achilles tendon is to be fixed, so that the Achilles tendon can be conveniently and firmly fixed to the bone body.

In addition, damage to the Achilles tendon due to tensile stress can be avoided by increasing the contact area with the Achilles tendon by increasing the contact area with the Achilles tendon with the connecting portion 210 extended from the fixing cap 200, thereby reducing the tensile force per unit area, and the fixing cap 200 and the connection As the Achilles tendon is brought into close contact with the bone body 110 by 210, the engraftment of Achilles tendon cells is promoted and induced, so that the fixation of the Achilles tendon is excellent and the fixed state is protected and maintained.

In addition, the fixing cap 200 may be manufactured together with the bone body 110 when manufacturing the bone body 110 by 3D printing, and may be integrally formed with the bone body 110.

In addition, another embodiment of the connector for inducing the engraftment of the biological tissue according to the present invention with reference to FIG. 7 is that one side is inserted and fixed to the bone body 110, and the biological tissue (Achilles) of the bone body 110 A coupling groove 114 is formed in a corresponding portion to which the tendon or plantar muscle) is to be fixed, and a coupling portion 230 formed inside the fixing cap 200 may be inserted into the coupling groove 114.

At this time, the coupling groove 114 is formed as a groove recessed into the bone body 110, and the coupling end portion 230 of the fixing cap 200 to which the biological tissue is connected is inserted into the coupling groove 114 Thus, a living tissue (Achilles tendon or plantar muscle) is fixed to the bone body 110.

The fixing cap 200 has a connection part 210 and a connection part 230 formed therein. The fixing cap 200 and the connection part 210 are formed in a mesh shape to have elasticity, and one side of the connection part 210 is It is a tubular shape having an open hollow, and the living tissue (Achilles tendon or plantar muscle) is inserted and connected through the hollow, and a coupling part 230 is formed on the other side facing the connection part 210.

Here, the coupling part 230 of the fixing cap 200 is formed to protrude into the pocket of the fixing cap 200 and is made of a hard material that is harder than the body of the fixing cap 200, and the bone body 110 It is coupled to the coupling groove 114, is fixed and does not fall out.

For example, the coupling groove 114 has a length in the lateral direction of the bone body 110 in a shape of a rhombus in a vertical cross-sectional shape of the coupling groove 114 so that the coupling portion 230 is coupled by sliding in the lateral direction. Formed as a sliding groove having a, and the coupling portion 230 coupled to the coupling groove 114 can also be formed in a vertical cross-sectional shape of a rhombus, the coupling groove 114 is a process of fixing the coupling portion 230 Looking at, first, the fixing cap 200 is folded toward the connection part 210 to expose the coupling part 230 formed inside the fixing cap 200 to the outside, and then the coupling part 230 is inserted into the coupling groove ( 114) by sliding in the lateral direction.

And when the coupling of the coupling part 230 to the coupling groove 114 is completed, the fixing cap 200 is written back toward the bone body 110, and the corresponding part where the living tissue (Achilles tendon or plantar muscle) is fixed Wrap it around.

As the biological tissue (Achilles tendon or plantar muscle) is fixed to the coupling groove 114 of the bone body 110 is coupled, even if the force acts in the front, rear, up and down directions The coupling part 230 does not fall out of the coupling groove 114 and maintains the coupled state continuously.

Therefore, while the biological tissue (Achilles tendon or plantar muscle) is more firmly fixed to the coupling groove 114 by the fixing cap 200 having the coupling part 230 formed, the biological tissue and the bone body 110 By increasing the contact area and decreasing the tensile force per unit area, damage to living tissues due to tensile stress is avoided, the generation of engraftment cells of the living tissue is promoted, and the fixed state is maintained and protected.

Here, the coupling groove 114 of the bone body 110 and the coupling portion 230 of the fixing cap 200 are not limited to any one shape, and various shapes may be applied, and the coupling of the fixing cap 200 A separate fixing means may be further provided so that the part 230 is maintained in a fixed state in the coupling groove 114 of the bone body 110.

The present invention has been described with reference to the embodiments shown in the drawings, but these are only exemplary, and those of ordinary skill in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

110: bone body
111: fixing means
200: fixed cap
210: connection
220: fastening means
230: coupling portion

Claims (7)

In the bone body formed on one side of the fixing part to which the biological tissue is fixed to the corresponding site,
A fixed cap coupled to a corresponding portion of the bone body to which the biological tissue is to be fixed;
A connecting portion extending from the fixed cap toward the living tissue and for an interview with the end of the living tissue; And
A connector for inducing engraftment of a living tissue comprising a; fastening means fastened to the living tissue accommodated in the connecting part and fixing the living tissue in the connecting part.
The method according to claim 1,
The connection part
A connector for inducing engraftment of a biological tissue for an interview by enclosing the biological tissue by entering the living tissue through an opening at the end.
The method according to claim 1,
The connection part
A connector for inducing engraftment of the biological tissue to be interviewed by being built into the interior of the biological tissue.
The method according to claim 1,
The fixing cap and the connection part
Connector for inducing engraftment of living tissue, characterized in that made in a mesh form.
The method according to claim 1,
A connector for inducing engraftment of a biological tissue comprising a fixing means for fixing an end of the fixing cap to the bone body, formed around a corresponding portion of the bone body to which the fixing cap is coupled.
The method according to claim 1,
A connector for inducing engraftment of a biological tissue formed in a portion of the bone body to which the biological tissue is fixed, and a coupling portion coupled to the coupling groove is formed inside the fixing cap.
The method according to claim 1,
The biological tissue is
A connector that induces engraftment of living tissue, such as the Achilles tendon or plantar muscle.

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