KR102155644B1 - sleeve anchor with biodegradable barb - Google Patents

Abstract

The present invention relates to a sleeve anchor provided with biodegradable barbs.
The sleeve anchor provided with biodegradable barbs of the present invention comprises an anchor body 10 made of fibrous material and a suture 20 fastened to the anchor body 10 to fix the soft tissue to the bone. In the sleeve anchor that is transformed and fixed in shape after being inserted into the perforated bone, the barbs 70 made of biodegradable material are formed in either or both of the anchor body 10 or the suture 20 To do.
According to the present invention, barbs are formed on the anchor body or suture, so that they are not easily loosened during binding of soft tissues, and even if the knot is unwound, they are not easily separated due to the shape of the barbs. It maintains the shape protruding from and naturally disassembles after a certain period of time, so that when the anchor is separated, it can be easily separated.

Description

Sleeve anchor with biodegradable barb

The present invention relates to a sleeve anchor in which shape is transformed after being inserted into the bone to fix soft tissues such as tendons, ligaments and muscles to the bone, and biodegradable barbs are formed in the suture or anchor body, so that the It is excellently fixed to the soft tissue, and is naturally decomposed after a certain period of time to be easily removed, it relates to a sleeve anchor provided with biodegradable barbs.

In general, when damage (rupture) occurs in soft tissues such as tendons, ligaments, and muscles, or when the soft tissue is broken, a surgical method is used in which the soft tissue of the damaged part is attached to and fixed to the bone.

For example, when a rotator cuff is diagnosed as a rupture of a rotator cuff according to an increase in the sports or leisure population and undergoes surgery, the damaged part is removed and a normal rotator cuff is fixed to the bone for treatment.

At this time, in order to fix soft tissues such as rotator cuffs to the bone, an anchor is inserted by drilling a hole in the bone, and a suture connected to the anchor is tied to the soft tissue so that the soft tissue can be attached and fixed to the bone.

For example, conventionally, as introduced in Korean Patent Publication No. 2015-0136707 and Korean Patent Publication No. 2015-0126855, a method of bolting a bolt-shaped anchor with a screw thread to a bone was used.

Therefore, the screw thread formed in the bone and the thread formed in the anchor do not exactly match according to the difference in bone density, etc., and as time passes, the anchor becomes loose, and the suture also becomes loose, causing a problem in that the soft tissue cannot be held firmly.

In addition, it is difficult to form a screw hole in the bone using a surgical drill, a doctor feels a sense of rejection while bolting the anchor with a surgical driver, and the patient's point of view also has a problem of feeling a sense of disparity due to inserting a metal anchor. have.

Accordingly, in the'Omega Notebook Sleeve Anchor' (Korean Patent Publication No. 10-1634796, Patent Document 1), the suture is fastened to pass through the through holes formed at both ends of the anchor body, and the anchor body is inserted into the bone and then the suture is held. It has been pulled and anchored by shape deformation.

However, such a configuration has a problem in that when the complete omega shape cannot be achieved, it is anchored in the bone for a long time or when the suture is pulled with a force of a certain amount or more, it is separated.

As a technology for solving this problem, the "flat-type sleeve anchor" (Korean Patent Publication No. 10-1849682, Patent Document 2) has a fibrous anchor body through which a suture is passed through several times, so that the shape of the anchor is uniform. To achieve.

It seems that Patent Document 2 has solved the problem occurring in Patent Document 1 to some extent.

However, the structure in which the suture penetrates between the various tension holes between the inlet hole and the outlet hole has a problem that the force held by the tension hole is distributed around the inlet hole and the outlet hole, so that the anchoring force is not high. .

Due to this, the suture is strongly pulled during the procedure, which leads to a problem in which the suture is broken.

In particular, after the anchor body is inserted into the bone, the anchor body is tied to the soft tissue using a suture to be bound. If the suture is incorrectly bound, the anchor may be separated.

KR 10-1634796 (2016.06.23) KR 10-1849682 (2018.04.11)

The sleeve anchor provided with biodegradable barbs of the present invention is to solve the problems occurring in the prior art as described above, and the barbs are formed on the anchor body or suture, so that it is difficult to loosen when binding the soft tissue, and even if the knot is loose, the barb shape This is to make sure it does not deviate well.

In addition, the barb is formed of a biodegradable raw material to maintain the shape protruding from the surface of the suture only for a certain period of time, and naturally decomposes after a certain period of time, so that when the anchor is separated, it can be easily separated.

At this time, the barbs are integrated with the suture using a mold, but a small amount of the surface of the suture is peeled off before installing the mold to form grooves and peeling pieces, so that the contact area of the polymer supplied to the inside of the mold increases through the grooves and peeling pieces, so that the barbs become suture robters. This is to prevent easy separation.

The suture is composed of a plurality of sutures, one inlet hole and one outlet hole, and the number of tension holes in each row in succession between them is formed differently so that the anchor body is held as much as possible in the tension ball, and the force to be held in the tension ball This inlet hole and withdrawal hole are brought together to minimize the distribution of force, so that the anchoring force of the anchor can be improved when the anchor is fixed to the bone.

The sleeve anchor provided with biodegradable barbs of the present invention comprises an anchor body 10 made of fibrous material and a suture 20 fastened to the anchor body 10 in order to solve the above problems. In the sleeve anchor that is shaped and fixed after being inserted into the perforated bone to fix the bone to the bone, the barb made of a biodegradable material on either or both of the anchor body 10 or the suture 20 70) is characterized in that it is formed.

In the above configuration, the suture 20 is made of ultra high strength yarn (UPE), and the barbs 70 are characterized in that the PDO polymer.

In addition, the anchor body 10 is made of a hollow tube shape with both ends open, a lead-in hole 30 is formed on one outer circumferential surface of the anchor body 10, and a withdrawal hole 40 is formed on the other outer circumferential surface. The suture 20 has a main suture 23 penetrating both ends of the hollow tube, and a first suture 21 that is inserted at one side into the inlet hole 30 and the other side is drawn out through the withdrawal hole 40 ), and the barb 70 is formed on the main suture 23 and the first suture 21, and is formed only on a portion protruding outside the anchor body 10.

In addition, the barbs 70 are molded by extruding a PDO polymer into the mold 71, and the mold 71 is installed on the surface of the suture 20, and the surface of the suture 20 is formed with a knife (N). The groove 25 and the peeling piece 24 protruding by scraping off are formed, and the mold 71 is installed at the location where the groove 25 and the peeling piece 24 are formed. It is filled in the groove 25, and wrapped around the peeling piece 24, characterized in that the PDO polymer is firmly integrated with the suture 20.

In addition, the suture 20 is configured to further include a second suture 22, and the first suture 21 and the second suture 22 have one inlet hole 30 and a lead-out hole 40 Penetrating through, a plurality of tension holes 50 are formed between the lead-in hole 30 and the lead-out hole 40, but the tension hole 50 is continuous with the lead-in hole 30 and the lead-out hole 40 Consisting of an outer tension hole 51 positioned so as to be, and an inner tension hole 52 positioned between the outer tension holes 51, the outer tension hole 51 is a direction perpendicular to the longitudinal direction of the anchor body 10 The number corresponding to the number of sutures 20 is formed to be spaced apart from each other, and the inner tension hole 52 is the number of the outer tension hole 51 in a direction orthogonal to the longitudinal direction of the anchor body 10 It is formed in a smaller number, and a plurality of sutures (20) that have penetrated each outer tension hole (51) alone pass through the inner tension hole (52), and the suture (20) between the outer tension holes (51) on both sides It is characterized in that they form a shape that intersects with each other.

According to the present invention, barbs are formed on the anchor body or suture, so that when soft tissue is bound, it is difficult to loosen, and even if the knot is released, it is not easily separated by the barb shape.

In addition, the barb is formed of a biodegradable raw material and maintains a shape protruding from the surface of the suture only for a certain period of time, and naturally decomposes after a certain period, so that when the anchor is separated, it can be easily separated.

At this time, the barbs are integrated with the suture using a mold, but a small amount of the surface of the suture is peeled off before installing the mold to form grooves and peeling pieces, so that the contact area of the polymer supplied to the inside of the mold increases through the grooves and peeling pieces, so that the barbs become suture robters. It is not easily separated.

The suture is composed of a plurality of sutures, one inlet hole and one outlet hole, and the number of tension holes in each row in succession between them is formed differently so that the anchor body is held as much as possible in the tension ball, and the force to be held in the tension ball The inlet hole and the outlet hole are brought together to minimize the distribution of force, so that the anchoring force of the anchor can be improved when the anchor is fixed to the bone.

1 to 6 is a front view showing an embodiment of the sleeve anchor provided with biodegradable barbs of the present invention.
Figure 7 schematically shows a method of forming barbs in the present invention.
Figure 8 is a front view showing an example provided with a tension ball in the present invention.
9 is a view showing an example of use when the tension hole of FIG. 8 is formed.

Hereinafter, a sleeve anchor with biodegradable barbs of the present invention will be described in detail through the accompanying drawings.

The sleeve anchor of the present invention is largely composed of an anchor body 10, a suture 20, and a barb 70.

In the embodiment of FIGS. 1 to 6, the anchor body 10 has a hollow tube shape with both ends open, and an example in which the main suture 23 passes through the hollow tube is shown.

However, in the present invention, the anchor body 10 is not limited to a hollow tube shape, and a case of a flat type is also applicable.

At this time, the anchor body 10 is preferably made of a material having elasticity in the case of a tubular shape, and preferably made of a fiber material having flexibility in the case of a flat type.

Specifically, the material of the anchor body 10 includes various types of polyethylene (PE) such as well-known ultra-high molecular weight PE (UHMWPE), and fiber yarns such as polyethylene terephthalate (PET), nylon, and polypropylene (PP). Materials can be applied.

In the embodiment of FIG. 1, the main suture 23 penetrates both ends of the anchor body 10 in the form of a hollow tube, while the inlet hole 30 is formed on the outer circumferential surface of one side of the anchor body 10, and is formed on the outer circumferential surface of the other side. The withdrawal hole 40 is formed so that the first suture 21 is inserted into the hollow interior toward the inlet hole 30, and then the other side comes out toward the withdrawal hole 40.

In addition, the barbs 70 are formed on the outer peripheral surface of the anchor body 10.

At this time, since the anchor body 10 is folded in half with respect to the center during surgery using a tool, the barbs 70 are symmetrical with each other obliquely toward both ends with respect to the center of the anchor body 10.

The barbs 70 may be formed in a direction opposite to the illustrated example.

However, as shown in the drawing, when the anchor body 10 is formed inclined toward the center of the anchor body 10, the anchor body 10 is inserted into the bone in the inclined direction of the barb 70 during the procedure, and after the insertion, the barb 70 is It is desirable to have a shape that is caught in the bone tissue and cannot be easily pulled out.

The embodiment of FIG. 2 is made in the same manner as in FIG. 1, but the second suture 22 is fitted in addition to the first suture 21 in the inlet hole 30 and the outlet hole 40.

In this case, since two sutures are inserted inside the hollow, it is possible to prevent the suture from breaking during the pulling process.

On the other hand, the embodiment of Figure 3 is an example in which the barb 70 is formed on the suture 20, not the anchor body 10.

Specifically, the main suture 23 and the first suture 21 have barbs 70 formed in portions protruding outside the anchor body 10.

In this case, as in the example of FIG. 1, since the inclined direction of the barb 70 is toward the center of the anchor body 10, the insertion in the direction of entering the bone by using a tool becomes easy. It will not be possible.

In the case of FIG. 4, as in FIG. 2, in addition to the first suture 21, the second suture 22 is inserted into the inlet hole 30 and the outlet hole 40.

When the barbs are formed in the suture 20 as shown in FIGS. 3 and 4, the anchor body 10 may also be formed in a portion entering the interior.

In this case, when the suture 20 is inserted into the anchor body 10 and a pulling force is applied, it is not easily removed from the inside of the anchor body 10.

In the case of the example of Figs. 3 and 4 in which the barbs 70 are formed on the suture 20, the knot is excellent when the suture 20 is fixed to the soft tissue, and the suture 20 is firmly attached to the soft tissue even when the knot is not made. Can be fixed.

5 and 6 is an example in which barbs 70 are formed on both the outer circumferential surface of the anchor body 10 and the suture 20.

In this case, the anchor body 10 is firmly fixed to the bone, and the suture 20 can be held firmly fixed to the soft tissue.

In the above-described embodiment, when the suture 20 is non-degradable, it is difficult to separate the anchor body 10 and the suture 20.

Therefore, the barbs 70 described above are preferably made of biodegradable raw materials.

Among them, the barb 70 is preferably made of a PDO (Polydioxanone) polymer.

In addition, the suture 20 is preferably made of ultra-high tenacity yarn made of ultrahigh molecular weight polyethylene (UPE) material.

This is because ultra-high-strength yarns do not break easily, and when PDO polymers are extruded, adhesion becomes excellent.

7 is a simplified schematic of the process of forming the barbs 70 to implement the configuration as described above.

In (A) of FIG. 7, a mold 71 is installed on the surface of the suture 20 or the anchor body 10, and then a PDO polymer is injected into the mold 71 to perform extrusion molding.

At this time, the extrusion-molded PDO polymer may be integrated in the same manner as shown in FIG. 7B in order to maintain the state firmly fixed to the suture.

An example of the drawing is that the surface of the suture 20 is scraped off with a knife N to form a groove 25 dug on the surface and a peeling piece 24 protruding by scraping, and the groove 25 and the peeling piece 24 By installing the mold 71 at the position where) is formed, the polymer is filled in the groove 25 during extrusion, and the PDO polymer is firmly integrated with the suture 20 by wrapping the peeling piece 24.

That is, not only increases the surface area, but also acts as a root of the PDO from which the peeling piece 24 is extruded, thereby enabling solid integration.

Meanwhile, in FIGS. 8 and 9, a configuration in which the tension hole 50 is located between the inlet hole 30 and the lead hole 40 is shown.

At this time, the anchor body 10 may be formed in the above-described hollow tube shape, or may be formed in a flat type.

In the case of a flat type, the main suture 23 is adhesively fixed to both ends of the anchor body 10.

Figure 8 (A) shows one outer peripheral surface of the main body 10, (B) shows the inner peripheral surface, in the case of the flat type, Figure 8 (A) shows the front surface of the main body 10, (B) Means the back side.

In the example of FIG. 8, the main suture 23 is connected to the end of the anchor body 10 or passes through the end.

In addition, the lead-in hole 30 and the lead-out hole 40 are each composed of one, so that the first suture 21 and the second suture 22 pass through one inlet hole 30 and the outlet hole 40. On the other hand, the inlet hole 30 and the outlet hole 40 and the adjacent outer tension hole 50 are composed of two, and each suture 20 is configured to penetrate each outer tension hole 50.

In this case, the outer tension hole 51 in the drawing is composed of two first outer tension holes 51a and two second outer tension holes 51b that are separated from each other in the longitudinal direction of the anchor body 10, and the Between the first outer tension hole 51a and the second outer tension hole 51b, the suture 20 is configured to cross and penetrate in a "X" shape.

That is, as can be seen from the state of Fig. 1, in the state of being installed on the surgical tool (T), each branched into the first outer tension hole (51a) based on the one inlet hole (30) and the withdrawal hole (40). After that, when it reaches the second outer tension hole 51b, it crosses in the shape of an "X" and passes through, and it can be seen that the inner tension hole 52 merges into one again.

In addition, the inner tension hole 52 is located in succession with one first inner tension hole 52a through which all of the plurality of sutures 20 penetrate, and the first inner tension hole 52a. It is composed of one second inner tension hole 52b through which all the sutures 20 penetrating through (52a) pass through, which has a straight shape while the sutures 20 are in close contact with each other at the part where the anchor body 10 is folded. Get drunk.

When the anchor body 10 is made of a hollow shape, some of the sutures passing through the continuous tension holes 50 protrude into the hollow interior and some of the suture outside the hollow.

If the anchor body 10 is of a flat type, some of the sutures passing through the tension holes 50 protrude to the rear and some to the front.

In addition, FIGS. 8 and 9 illustrate a configuration in which a reinforcing part 60 is formed on the anchor body 10.

Specifically, between the inlet hole 30 from one end of the anchor body 10, the inlet hole 30 and the first outer tension hole (51a), the first outer tension hole (51a) and the second outer tension hole (51b) ), between the second outer tension hole (51b) and the first inner tension hole (52a), between the withdrawal hole (40) and the other end of the anchor body (10), the portion of the front and rear surface where the suture (20) does not pass The reinforcement part 60 is formed along the longitudinal direction.

In the drawing, the reinforcing portion 60 has a rectangular shape and is formed to protrude further forward or rearward than the other surfaces of the anchor body 10.

This configuration serves to reinforce the anchor body 10 by being located opposite the surface through which the suture thread 20 passes when used by being installed on the surgical tool (T).

This is because the sutures 20 pass through the tension holes 50 in an intersecting form, so when the sutures 20 are pulled, the sutures 20 penetrated in the crossing form try to move in a straight line, and the anchor body 10 is torn. You can suppress the phenomena you are trying to do.

If, when the tension balls are in a straight line, there is a problem that the force held by the tension balls is dispersed when exiting into the inlet and outlet holes, whereas in the case of the above configuration, the force held by the tension balls 50 is one inlet. Since they are collected by the balls 30 and the withdrawal holes 40, the teeth are not dispersed, so that when fixing the anchor to the bone, the fixing force of the anchor body 10 can be improved.

Moreover, between the continuous first outer tension hole (51a) and the second outer tension hole (51b), the sutures cross each other in an "X" shape, and this structure is applied to the anchor body 10 The strength and distribution of the losing force can be increased.

Due to this, it is possible to suppress the phenomenon that the suture is about to break due to high tension being applied only to the suture.

According to the above configuration, when the anchor body 10 is folded in half and inserted into the bone so as to be approximately'U' shape, and pulling the suture thread 20 in that state, the shape of the anchor body 10 is deformed and formed in the bone. The volume (or cross-sectional area) becomes larger than the insertion hole, and the anchor body 10 is fixed (ie, anchored) inside the bone, and the soft tissue is tied and fixed with a suture 20 fixed to the bone through the anchor body 10 By doing so, soft tissues such as damaged tendons, ligaments and muscles are treated.

At this time, the barb 70 strengthens the anchoring function of the anchor body 10 and strengthens the soft tissue fixation of the suture 20, and is naturally decomposed after a certain period of time.

The present invention is applied to surgery in which soft tissues such as tendons, ligaments, and muscles are damaged by attaching and fixing the soft tissue of the damaged part to the bone to make a hole in the bone during treatment to drive an anchor and tie the suture connected to the anchor to the soft tissue.

10: anchor body 20: suture
21: first suture 22: second suture
23: main suture 24: peeling piece
25: groove 30: entrance hole
40: withdrawal hole 50: tension hole
51: outer tension hole 51a: first outer tension hole
51b: second outer tension hole 52: inner tension hole
52a: first inner tension hole 52b: second inner tension hole
60: reinforcement part 70: barb
71: mold T: surgical tool
N: knife

Claims (5)

delete delete In a sleeve anchor that is configured to include an anchor body 10 and a suture 20 fastened to the anchor body 10 and is inserted into the perforated bone to fix the soft tissue to the bone, the shape is transformed and fixed ,
Barbs 70 made of a biodegradable material are formed on either or both of the anchor body 10 or the suture 20,

The suture 20 is made of ultra-high strength yarn made of ultrahigh molecular weight polyethylene (UPE) material,
The barb 70 is made of a PDO (Polydioxanone) polymer material,

The anchor body 10 has a hollow tube shape with both ends open, a lead-in hole 30 is formed on one outer circumferential surface of the anchor body 10, and a lead-out hole 40 is formed on the outer circumferential surface of the other side. ,
The suture 20 is composed of a main suture 23 penetrating both ends of the hollow tube, and a first suture 21 which is inserted into the inlet hole 30 and the other side is drawn out through the drawing hole 40 And
The barb 70 is formed on the main suture 23 and the first suture 21, characterized in that it is formed only in a portion protruding outside the anchor body 10,
Sleeve anchor with biodegradable barbs.
The method of claim 3,
The barbs 70 are molded by extruding a PDO polymer into the mold 71, and a mold 71 is installed on the surface of the suture 20,
The surface of the suture 20 is scraped off with a knife (N) to form a groove 25 dug in the surface and a peeling piece 24 protruding by scraping, and the groove 25 and the peeling piece 24 are formed. By installing the mold 71 at the position, the polymer is filled in the groove 25 during extrusion, and the PDO polymer is firmly integrated into the suture 20 by wrapping the peeling piece 24,
Sleeve anchor with biodegradable barbs.
The method according to any one of claims 3 to 4,
The suture 20 is configured to further include a second suture 22,
The first suture 21 and the second suture 22 penetrate through the one inlet hole 30 and the outlet hole 40,
A plurality of tension holes 50 are formed between the inlet hole 30 and the withdrawal hole 40,
The tension holes 50 are composed of an outer tension hole 51 positioned to be continuous with the inlet hole 30 and the withdrawal hole 40, and an inner tension hole 52 positioned between the outer tension holes 51 Become,
The outer tension holes 51 are formed by being spaced apart from each other in a number corresponding to the number of sutures 20 in a direction perpendicular to the longitudinal direction of the anchor body 10,
The inner tension holes 52 are formed in a number less than the number of the outer tension holes 51 in a direction orthogonal to the longitudinal direction of the anchor body 10,
A plurality of sutures 20 that have penetrated each outer tension hole 51 alone pass through the inner tension hole 52 to form a shape in which the sutures 20 cross each other between the outer tension holes 51 on both sides. Characterized in that,
Sleeve anchor with biodegradable barbs.

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