KR101297509B1 - Apparatus and method for processing surface of medical member for insertion into in-vivo and the medical member for insertion into in-vivo using the same - Google Patents

Abstract

PURPOSE: A surface processing apparatus of a component for organism insertion, a method thereof, and a component for organism insertion thereof are provided to form a specific form of projections uniformly on the surface of a component for organism insertion by using wire. CONSTITUTION: A surface processing apparatus (100) of a component (10) for organism insertion comprises: a component supplying part (20a) capable of providing the component consecutively; a component collecting part (20b); more than one supporting parts (31, 32) supporting the component; a wire module (40) cutting a part of the surface of the component on the surface of the component; and more than one rotating member (50a, 50b) provided to a location between the component supplying part and supporting part, or a location between the supporting part and component collecting part, which rotates the component. [Reference numerals] (20a) Component supplying part for organism insertion; (20b) Component collecting part for organism insertion; (60) Controller

Description

Apparatus and method for processing surface of medical member for insertion into in-vivo and the medical member for insertion into in-vivo using the same}

The present invention relates to an apparatus and method for processing a surface of a member for inserting a living body, and to a member for inserting a living body manufactured using the same, and more specifically, processing such that a protrusion having a specific shape is formed on a surface of the member for inserting a living body using a wire. The present invention relates to a surface processing apparatus and a method which can be used, and to a living body insert manufactured using the same.

In particular, the present invention relates to a member for inserting a living body and a device for processing the surface of the member for inserting a living body which can be used for extending and maintaining a living soft tissue in cosmetic surgery, dermatological surgery, cosmetic surgery and general surgery. It is about a method.

With the development of modern medicine, there is a rapid development of the cosmetic surgery field where the help of medicine can be used to shape a part of the body that one has and to feel confident or satisfied.

In particular, the nose located in the center of the face of the part of the body depends on the first impression, the nose molding to raise the nose can be said to be a typical field in cosmetic molding. In this case, various methods are used to naturally raise or shape the nose (eg, using silicone implants or Gore-Tex, autologous cartilage, autologous fat, etc.).

Among them, silicone implants on the nose and filling the ear cartilage and nose cartilage obtained from the patient's body at the tip of the nose are the most common and stable surgical methods with few reported side effects.

However, the method of using autologous tissues has relatively various advantages, but it is necessary to bear the separate procedure of taking a part of one's body, and the disadvantage that the physical characteristics and absorption rate are not uniformly predicted. exist.

Moreover, when cartilage is not sufficient and about five years after surgery, the shaped nose is deformed (because the cartilage can move easily and the thread holding the cartilage can be loosened and the cartilage position can change). Since many cases have been reported to perform reoperation, this is not an ideal cosmetic method. In addition, there is a lot of swelling after the operation and the treatment period takes at least a week, so there is a lot of obstacles in daily life, there is a disadvantage that there are many restrictions.

In order to solve the problems with the existing nose molding method, various nose molding methods or tools have been invented and developed. In particular, Korean Patent No. 10-0761921 (name of the invention: a thread for inserting a living body and a tool for inserting it into a living body for use in anti-compression multifibroadhesion for bio soft tissue extension) is a thread for inserting a living body for nose molding. Initiate.

1 is a view showing a state in a conventional insert chamber for nose molding.

Referring to FIG. 1, Korean Patent No. 10-0761921 is a thread 10 for inserting a human body having a directional protrusion that is used for extending a part of a human body, and the protrusion 12 has a wedge shape that is separated from the actual axis. Consists of a wing 12b and a groove 12a, the projection 12 is composed of two sections (10A, 10B) holding each other back and the like in the tapered end direction of the wing with respect to one reference point (P) on the solid axis Inserted into the living body by a needle, and the tissue is stretched in the bioinserted state so that the protrusions do not interfere with it and the tissue is stretched, and removing the pulling force, the living body is configured to resist the force retracted by tissue elasticity Disclosed is a bioinsertion thread for use in an anti-compression multi-fiber adhesion closure method for soft tissue extension.

In the case of such a bio-insertable thread, using the existing suture structure (structure having protrusions in both directions of the thread, disclosed in US Publication No. 2005/0267532 (named Surgical thread) of the invention), This method has significance in that it is used for anti-apb multifiber adhesion closure for soft tissue extension.

However, in order to manufacture the seal for inserting the living body described in the above Patent No. 10-0761921 (iii) the thickness of the wing and the groove, the length and the degree of protrusion of the wing and the groove is not constant because the projections made of the wing and the groove by hand There is a problem that (ii) it is not possible to manufacture a plurality of bio-insertion yarns in a short time, (i) the procedure results in the case of the tip of the nose because the thickness and length of the wings and grooves is not constant The disadvantage was that it was not satisfactory.

Thus, in order to solve the above-described problems in manufacturing the seal for living body insertion, the present inventors can use a wire to process a certain form of protrusions on the surface of the living body insertion member, thereby manufacturing time and The present invention has been made to invent an apparatus and method for processing a surface of a member for inserting a living body capable of improving satisfaction of a procedure, and a member for living body insert manufactured using the same.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a surface processing apparatus and method which can be processed so that a certain type of protrusion is formed on the surface of a member for biological insertion using wire. To provide.

In particular, the present invention provides a surface processing apparatus and method capable of processing a surface of a plurality of living body insertion members more quickly and accurately by automating a surface processing process using a wire cut.

In addition, an object of the present invention, by designing to adjust the cutting angle (direction), cutting length and cutting depth of the wire, the projection angle, the thickness and the length of the projections formed on the member for insertion of the living body to suit the type of procedure used It is to provide a surface processing apparatus and method which can be easily controlled and manufactured.

It is also an object of the present invention to provide a biological insertion member in which the shape of the protrusion (ie, the protrusion angle, thickness and length of the protrusion, etc.) is formed in accordance with the user's intention using the above-described surface processing apparatus and method.

In particular, the present invention provides a member for inserting a living body that can be effectively used for extending and maintaining living tissue in plastic surgery or cosmetic surgery.

The present invention relates to an apparatus for processing a surface of a member for inserting a living body, and the present invention provides a member for supplying a living body insert and a member for recovering a living body insert capable of continuously providing the living body insertion member; At least one support for supporting the biological insertion member between the biological insertion member supply portion and the biological insertion member recovery portion; A wire module for cutting a part of the surface of the bio-insertable member such that a protrusion having a predetermined shape is formed on the surface of the bio-insertable member; And at least one rotating member provided between at least one of the biological insert member and the support and between the support and the biological insert recovering member to rotate the biological insert. do.

Preferably, the wire module, the wire is located in the vertical direction on the upper side of the biological insert member to cut a part of the surface of the biological insert member; And a wire moving unit capable of moving the wire in X and Y axis directions with respect to the central axis of the wire.

Preferably, the at least one support portion is characterized in that for moving the biological insertion member in the longitudinal direction of the biological insertion member.

Preferably, said at least one support is a roller.

Preferably, the at least one rotating member is characterized in that to rotate the biological insertion member within a 360 ° range along the circumferential direction of the biological insertion member.

Preferably, the surface processing apparatus of the said biological insertion member is a movement direction of the said wire by the said wire moving means, the moving speed of the said biological insertion member by the said at least 1 support part, and said said by the said at least one rotating member. It further comprises a control unit for controlling any one or more of the degree of rotation of the biological insertion member.

Moreover, this invention relates to the method of processing the surface of a biological insertion member using the surface processing apparatus of the above-mentioned biological insertion member.

Specifically, the present invention comprises the steps of: a) providing the biological inserting member by using the biological inserting member supply unit and the biological inserting member recovering unit capable of continuously or intermittently providing the biological inserting member; b) cutting a part of the surface of the biological inserting member using a wire module to form a protrusion having a predetermined shape on the surface of the biological inserting member; c) rotating the biological inserting member using at least one rotating member; And d) cutting a part of the surface of the non-cut member of the bio-insertable member using the wire module to form a protrusion having a predetermined shape on the surface of the bio-insertable member.

Preferably, (e) moving the member for inserting the living body using at least one support; characterized in that it further comprises.

Preferably, in the steps b) and d), the wire module is a wire located in the vertical direction on the upper side of the member for inserting the living body and the wire in the X-axis and Y-axis directions relative to the central axis of the wire It is characterized in that for cutting the surface of the biological insert member using a wire moving means capable of moving.

Preferably, in the steps b) and d), the wire movement means is characterized in that to cut the surface of the biological insert member by changing the cutting angle of the wire two or more times.

Preferably, in the step (c), the at least one rotating member is characterized in that for rotating the biological insertion member in the 360 ° range along the circumferential direction of the biological insertion member.

Preferably, in the steps b) and d), the movement direction of the wire by the wire moving means, the moving speed of the biological insertion member by the at least one support part, and the living body by the at least one rotating member. It is characterized by controlling the form of the projection by using a control unit for controlling any one or more of the degree of rotation of the insertion member.

The present invention also relates to a living body insertion member processed using the surface processing method of the aforementioned living body insertion member.

Preferably, the biological inserting member, the body portion made of a yarn shape or cylindrical; A protrusion formed in a predetermined shape along an outer circumferential surface of the body portion; And a cutting part formed by cutting the wire and having a space formed therein.

Preferably, the cutting portion is characterized in that it is formed to have a two-stage inclined surface based on the longitudinal direction of the body portion.

Preferably, the bio-insertable member may be configured to stretch the tissue when a force is applied to the biological tissue in a bio-insertion state, and when the force is removed, the protrusion structure may resist the force to return the tissue to its original state. Characterized in that the tissue is configured to remain in an extended state.

Preferably, the bio-insertion member is characterized in that it comprises silicon.

Preferably, the bio-insertion member is nylon, polypropylene, polydioxanon, polycarprolacton, poly-L-lactic acid (PLLA), polyglycolic acid (PGA), poly-lactic-glyolic acid (PLGA), cat gut, gold (Au ), An alloy containing Au, platinum (Pt), an alloy containing platinum, Titanium (Ti) and is characterized by consisting of any one material of the alloy containing titanium.

Preferably, the bio-insertion member is characterized in that it is used in any one or more of plastic surgery, dermatological surgery, cosmetic surgery and general surgery.

Preferably, the biological insertion member is a body portion made of a cylindrical; A protrusion formed in a predetermined shape along an outer circumferential surface of the body portion; And a cutting part formed by a wire and formed with a space, wherein the biological insertion member is inserted into the biological soft tissue by an injection needle, and when the force is applied to the biological soft tissue in the biological insertion state, the tissue is extended. The protruding portion and the cutting structure are configured to remain in the extended state in response to the force that the tissue is intended to return to when the force is extended and maintained and the force applied to the biological soft tissue is removed, And at least one of the one end and both ends of the body portion is provided with a concave-convex portion is configured to prevent the projecting member is protruded to the outside in the state inserted into the living body, and the at least one projection is present, the body portion It is characterized by being formed at regular intervals spirally along the longitudinal direction.

According to the present invention, it is possible to process such that a certain type of projection is formed on the surface of the member for biological insertion used in plastic surgery and cosmetic surgery.

In addition, by using a wire cut to automate the machining process, the effect of the surface of a plurality of biological insert members can be processed more quickly and accurately.

In addition, by adjusting the cutting angle (direction), the cutting length, and the cutting depth of the wire, there is also an effect that the protrusion angle, the thickness, the length, and the like of the protrusions formed on the biological insertion member can be easily controlled.

In addition, there is an effect that can be controlled according to the user's intention up to the number and the degree of separation of the protrusions formed on the member for biological insertion.

In addition, according to the present invention, it is possible to provide a member for inserting a living body in which the shape of the protrusion (that is, the protrusion angle, the thickness and the length of the protrusion, etc.) is formed uniformly by using the above-described surface processing apparatus and method.

Therefore, it can be effectively used for extending and maintaining the soft tissue of the living body in plastic surgery or cosmetic surgery, and in particular, unlike the conventional bio-insertion thread, the thickness and length of the wing and the groove are constant, so the procedure is performed at the tip of the nose. In this case, the effect of satisfactory procedure occurs.

1 is a view showing a state in a conventional insert chamber for nose molding.
2 is a view schematically showing a surface processing apparatus 100 of a member for biological insertion according to an embodiment of the present invention.
3 is a view showing step by step of the surface processing step of the biological insertion member 10 processed by the surface processing apparatus 100 of the biological insertion member according to an embodiment of the present invention.
Figure 4 is a flow chart schematically showing a method for processing the surface of the biological insert member 10 according to an embodiment of the present invention.
5 is a cross-sectional view of a part of the surface of the biological inserting member 10 manufactured by the method for processing the surface of the biological inserting member according to an embodiment of the present invention.
6 is a perspective view of the bio-insertion member 10 manufactured by the method for processing the surface of the bio-insertion member according to an embodiment of the present invention.

With reference to the accompanying drawings, a preferred embodiment of the surface processing apparatus and method for a biological insertion member and a biological insertion member manufactured using the same according to the present invention. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to the intention or convention of a user or an operator. Therefore, the definitions of these terms should be described based on the contents throughout this specification.

2 is a view schematically showing the surface processing apparatus 100 of the biological insertion member according to an embodiment of the present invention, Figure 3 is a surface processing apparatus of the biological insertion member according to an embodiment of the present invention ( It is a figure which shows step-by-step the surface processing step of the biological insertion member 10 processed by 100).

2 and 3, the surface processing apparatus 100 of the living body insertion member according to an embodiment of the present invention will be described in detail.

2 and 3, the surface processing apparatus 100 of the biological insertion member according to an embodiment of the present invention may include a biological insertion member supply part 20a, a biological insertion member recovery part 20b, and one or more components. The support portions 31 and 32, the wire module 40 and one or more rotating members 50a and 50b may be included. In addition, the control unit 60 may further include a control unit for components such as the wire module 40.

On the other hand, the surface processing apparatus 100 according to an embodiment of the present invention, controls the driving of the biological insertion member supply unit 20a, the biological insertion member recovery unit 20b to enable intermittent or continuous surface processing A feeder or various control modules; And various current devices used when performing wirecuts; It may further include components such as, but the detailed description thereof will be omitted unless the corresponding technical elements of the present invention.

The biological insertion member supply unit 20a and the biological insertion member recovery unit 20b serve to provide the biological insertion member 10 so that the biological insertion member 10 may uniformly move in one direction.

The biological insertion member supply unit 20a and the biological insertion member recovery unit 20b are characterized in that they are provided so that the biological insertion member 10 can be constantly cut by the wire module 40 to be described later. Note that is not limited.

Here, the living body insertion member 10 is preferably made of a silicon material. The reason for this is that the silicone material is used in various ways for medical purposes, and in particular, the flexibility or the supporting force is better than that of the suture material, and thus, the silicone material has an excellent effect of supporting the tissue extended in the state in which the biological inserting member 10 is inserted in the living body.

In addition, the member 10 for inserting the living body may use a variety of materials to enhance the supporting force while increasing adhesion and elasticity with human tissue, specifically, nylon, polypropylene, polydioxanon, polycarprolacton, poly-L-lactic acid ( PLLA), polyglycolic acid (PGA), poly-lactic-glyolic acid (PLGA), cat gut, gold (Au), alloys containing Au, platinum (Pt), alloys containing platinum, Titanium (Ti) and Titanium Note that the material may be made of an alloy or the like.

The at least one support part 31 and 32 serves to support the biological inserting member 10 between the biological inserting member supply part 20a and the biological inserting member recovery part 20b. It also serves to move 10) in the longitudinal direction.

Note that one or more of these supports 31, 32 may generally be in the form of a roller, but the shape is not particularly limited as long as it performs the above-described role.

Meanwhile, a plate part 33 may be additionally provided between the at least one support part 31 and 32 to perform a process of processing a part of the surface of the biological insert member 10 by the wire module 40 to be described later. .

Note that this plate portion 33 can be omitted and used by the process needs.

The wire module 40 serves to cut a part of the surface of the bio-insertable member 10 so that protrusions 12a and 12b (see FIG. 5) having a predetermined shape are formed on the surface of the bio-insertable member 10. .

Specifically, the wire module 40 may include: a wire 41 positioned vertically on an upper portion of the biological inserting member 10 to cut (ie, wire cut) a part of the surface of the biological inserting member 10; And wire moving means 42a and 42b capable of freely moving the wire 41 in the X and Y axis directions with respect to the central axis of the wire 41.

According to the wire module 40, the wire moving means (42a, 42b) is to move the wire 41 up and down in consideration of the desired cutting angle (direction), cutting length, cutting depth, etc. with respect to the biological insert member 10 It can be moved in the front-rear direction.

As a result, as shown in FIG. 5, the surface processing apparatus 100 according to the present invention may form protrusions 12a and 12b having a predetermined shape on the surface of the biological insertion member 10. For example, the wire moving means 42a in consideration of the primary cutting angle θ 'and the secondary cutting angle θ ″, the secondary cutting length a, the total cutting depth c, and the like of the wire 41. When 42b moves the wire 41, the user may form a protrusion having a desired shape.

One or more rotating members 50a and 50b may be provided between at least one of the biological insertion member supply part 20a and the support part 31 and between the support part 32 and the biological insertion member recovery part 20b. It serves to rotate the member 10.

At this time, it is preferable that the one or more rotation members 50a and 50b rotate the biological insertion member 10 within a 360 ° range along the circumferential direction of the biological insertion member 10.

According to such rotating members 50a and 50b, after the part of the surface of the biological inserting member 10 is cut by the wire 41, the biological inserting member 10 is rotated by the rotating members 50a and 50b. In this case, the wire 41 can cut a part of the surface of the biological insert member 10 with respect to the uncut surface.

As a result, as illustrated in FIG. 6, protrusions may be formed at various positions along the circumferential surface of the biological insertion member 10.

The controller 60 controls the support parts 31 and 32, the wire moving means 42a and 42b, and the rotating members 50a and 50b.

Specifically, the control unit 60 adjusts the moving speed of the living body insertion member 10 by controlling the one or more support units 31 and 32, and moves the wire 41 by controlling the wire moving means 42a and 42b. Direction (i.e., X-axis and Y-axis directions), and by controlling the rotational members 50a, 50b to adjust the rotation angle and the degree of rotation of the biological insertion member 10 by the rotational members 50a, 50b. do.

That is, the surface processing step of the biological inserting member 10 processed by the surface processing apparatus 100 of the biological inserting member 100 according to the embodiment of the present invention having such a configuration will be described as follows.

The biological insertion member 10 is provided by the biological insertion member supply part 20a and the biological insertion member recovery part 20b, and the wire 41 is positioned above the biological insertion member 10 ( (A) of FIG. 3).

Next, in consideration of the cutting angle (direction), the cutting length, the cutting depth, and the like, the wire 41 cuts a part of the surface of the bio-insertable member 10 by the wire moving means 42a and 42b to form a protrusion of a specific shape. To form (see FIG. 3 (b)). Then, the wire 41 is returned to its original state by the wire moving means 42a and 42b (see FIG. 3C).

Next, the biological inserting member 10 is rotated by a predetermined angle by the rotating members 50a and 50b (see FIG. 3D).

Next, the wire 41 cuts a part of the surface (part of the uncut surface) of the biological insertion member 10 by the wire moving means 42a and 42b to form a protrusion of a specific shape (Fig. 3). (e)).

Then, the living body insertion member 10 is moved forward by the support portions 31 and 32, and the non-cut surface portion of the living body insertion member 10 is positioned at the lower side of the wire 41.

Due to this principle, according to the surface processing apparatus 100 of the member for biological insertion according to an embodiment of the present invention, a projection of a particular shape on the surface of the biological insertion member 10 used for molding and cosmetic surgery It can be processed to be formed uniformly, by using a wire cut to automate the processing process it is possible to process the surface of the plurality of biological insert member 10 more quickly and accurately.

In particular, by adjusting elements such as the cutting angle (direction), the cutting length, and the cutting depth of the wire 41, the protrusion angle, the thickness, and the length of the protrusions formed on the biological insertion member 10 can be easily controlled. There is also an effect.

Figure 4 is a flow chart schematically showing a method for processing the surface of the member for biological insertion according to an embodiment of the present invention. Referring to Figure 4, it will be described in detail the method for processing the surface of the member for insertion of a living body according to an embodiment of the present invention.

Referring to FIG. 4, the method for processing a surface of a member for inserting a living body may include (a) providing a member 10 for inserting a living body (S01); (b) cutting the surface of the biological inserting member 10 using the wire module 40 (S02); (c) rotating the biological inserting member 10 (S03); (d) wire module Cutting the surface of the biological insertion member 10 by using the 40 (S04) and (e) moving the biological insertion member 10 forward by using the supporting parts 31 and 32 (S05). ).

Specifically, it is as follows.

Step (a) is a step of providing the living body insertion member 10 continuously or intermittently using the living body insertion member supply unit 20a and the living body insertion member recovery unit 20b.

In the step (b), the wire module 40 is used to cut a part of the surface of the biological insertion member 10 to form a protrusion having a predetermined shape on the surface of the biological insertion member 10.

Here, the wire module 40 may include a wire 41 positioned vertically on the upper portion of the bioinsertion member 10 to cut (ie, wire cut) a part of the surface of the bioinsertion member 10; And cutting the surface of the biological insertion member 10 by using wire moving means 42a and 42b that can freely move the wire 41 in the X and Y axis directions with respect to the central axis of the wire 41. It is characterized by.

Step (c) is to rotate the biological inserting member 10 by using one or more rotating members 50a and 50b.

Here, the at least one rotation member (50a, 50b) is characterized in that to rotate the biological insertion member 10 in the 360 ° range in the circumferential direction of the biological insertion member 10.

Step (d) is to cut a part of the surface of the non-cut biological insert member 10 using the wire module 40 to form a protrusion having a predetermined shape on the biological insert member 10.

Step (e) is a step of moving the living body insertion member 10 forward by using the support parts 31 and 32.

At this time, in steps (b), (c) and (d), the movement direction of the wire 41 by the wire moving means 42a and 42b, and the member 10 for insertion of the living body by the support parts 31 and 32 The shape of the projection (protrusion angle, thickness and length, etc.) of the projection through a control unit controlling any one or more of the moving speed of) and the degree of rotation of the biological insertion member 10 by the one or more rotating members 50a and 50b. Note that it may further include controlling the.

5 is a cross-sectional view of a part of the surface of the biological inserting member manufactured by the method for processing the surface of the biological inserting member according to an embodiment of the present invention, and FIG. 6 is a biological inserting member according to an embodiment of the present invention. It is a perspective view of the member for biological insertion manufactured by the surface processing method of this.

5, the living body insertion member 10 according to the present invention basically comprises a body portion 11 made of a yarn shape or a cylinder; Protruding portion 12 protruding in a predetermined form along the outer peripheral surface of the body portion 11; And a cutting part 13 formed by cutting the wire 41 to form a predetermined space.

In this case, the protrusion 12 may be composed of a first protrusion 12a and a second protrusion 12b. Accordingly, the cutting portion 13 may also have a two-stage inclined surface 14 based on the length direction of the body portion 11. (The first inclined surface 14a and the second inclined surface 14b).

This is because, when the wire 41 cuts the biological inserting member 10, the cutting member is set in two stages to cut the biological inserting member 10. FIG. Specifically, since the primary cutting angle θ 'and the secondary cutting angle θ ″ are different, the inclinations of the first inclined surface 14a and the second inclined surface 14b are different, and accordingly, the first protrusions ( 12a) and the protruding shapes of the second protrusion 12b are also formed differently.

On the other hand, the secondary cutting length a, the primary cutting angle θ 'and the secondary cutting angle θ "and the whole according to the moving direction of the wire moving means 42a and 42b under the control of the control unit 60. Elements such as the cutting depth c may be set and formed in a shape desired by a user.

6, it can be seen that one or more protrusions 12 are formed at regular intervals along the longitudinal direction of the body portion 11. That is, the protrusion 12 is characterized in that formed at regular intervals in a spiral along the longitudinal direction of the body portion (11). At this time, it is noted that the spacing of the protrusions 12 may be variously set according to the degree of rotation of the rotating members 50a and 50b as described above. For example, it is noted that the one or more protrusions 12 may be formed at 180 degree intervals or at 90 degree intervals.

As described above, according to the present invention, not only the shape of the protrusions (that is, the thickness, the length and the fine angle of the wing and the groove, etc.) using the surface processing apparatus 100 and the method, but also the number and distance of the protrusions are intended by the user. Can be controlled according to.

Therefore, the bioinsertion member 10 according to the present invention can be effectively used for extending and maintaining the soft tissues of the living body in plastic surgery or cosmetic surgery, and in particular, since the thickness and length of the wings and the grooves are constant, the tip of the nose When the procedure is performed, the effect of the procedure result is satisfactory.

On the other hand, it is preferable that the above-described secondary cutting length a is 0.6 mm to 0.8 mm, and the primary cutting angle θ 'and the secondary cutting angle θ ″ are about 25 ° to 40 °. The total depth of cut (c) is preferably about 0.18 to about 0.25 mm, and the diameter of the body is preferably about 0.4 mm to 0.6 mm, however, the above ranges may be variously applied according to the user's intention. And may be changed.

That is, due to such a configuration, when the biological insertion member 10 is applied to the biological tissue in a state where the biological insertion member 10 is inserted into the living body, the tissue increases without resistance, and the protrusion is removed when the force applied to the biological tissue is removed. And since the cutting structure is resistant to the force to return the biological soft tissue to the original state it is possible to continuously maintain the stretched state for a long time.

In addition, although not shown, one end or both ends of the biological insertion member 10 may be provided with a rough surface such as an uneven portion, a protrusion, and a curved portion at a cross section thereof.

Note that such a rough surface may be naturally formed in the process of cutting to use the biological insert 10, or may be formed in advance in the process of manufacturing the biological insert 10, if necessary.

When such a rough surface is provided at one end or both ends of the bioinsertion member 10, the surface area is increased to improve tissue adhesion, and the pressure applied to both ends of the bioinsertion member 10 is reduced to insert the living body. It is possible to prevent the dragon member 10 from protruding out of the skin (outwardly).

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the present invention can be changed.

100: surface processing device
10: member for biological insertion
20a: member for inserting a living body
20b: member recovery part for living body insertion
31, 32: support portion
40: wire module
41: wire
42a, 42b: wire transfer means
50a, 50b: rotating member
60:

Claims (16)

A biological insertion member supply part and a biological insertion member recovery part capable of continuously providing the biological insertion member;
At least one support for supporting the biological insertion member between the biological insertion member supply portion and the biological insertion member recovery portion;
A wire module for cutting a part of the surface of the bio-insertable member such that a protrusion having a predetermined shape is formed on the surface of the bio-insertable member; And
And at least one rotating member provided between at least one of the biological insert member and the support and between the support and the biological insert recovering member to rotate the biological insert. ,
Surface processing apparatus of a member for biological insertion.
The method of claim 1,
The wire module,
A wire positioned perpendicularly to an upper portion of the biological inserting member to cut a portion of the surface of the biological inserting member; And
Further comprising: a wire moving means for moving the wire in the X-axis and Y-axis direction relative to the central axis of the wire,
Surface processing apparatus of a member for biological insertion.
The method of claim 2,
The one or more supports,
It characterized in that for moving the biological insertion member in the longitudinal direction of the biological insertion member,
Surface processing apparatus of a member for biological insertion.
The method of claim 1,
The one or more rotating members,
Characterized in that in the circumferential direction of the member for inserting the living body, the member for inserting the living body is rotated within a 360 ° range,
Surface processing apparatus of a member for biological insertion.
The method of claim 1,
The surface processing apparatus of the said member for living body insertion,
Control unit for controlling any one or more of the direction of movement of the wire by the wire moving means, the moving speed of the biological insertion member by the at least one support portion, and the degree of rotation of the biological insertion member by the at least one rotating member. Characterized in that it further comprises,
Surface processing apparatus of a member for biological insertion.
The surface processing method of the member for biological insertion using the surface processing apparatus of the member for biological insertion as described in any one of Claims 1-5.
a) providing the biological insertion member by using the biological insertion member supply part and the biological insertion member recovery part capable of continuously or intermittently providing the biological insertion member;
b) cutting a part of the surface of the biological inserting member using a wire module to form a protrusion having a predetermined shape on the surface of the biological inserting member;
c) rotating the biological inserting member using at least one rotating member; And
and d) cutting a portion of the surface of the bio-insertable member not cut using the wire module to form a protrusion having a predetermined shape on the surface of the bio-insertable member.
The surface processing method of the member for biological insertion.
The method of claim 7, wherein
(e) moving the member for inserting the living body using at least one support; further comprising:
The surface processing method of the member for biological insertion.
The method of claim 7, wherein
In the steps b) and d), the wire module can move the wire and the wire located in the vertical direction on the upper portion of the biological insert member in the X-axis and Y-axis direction with respect to the center axis of the wire. Characterized in that for cutting the surface of the biological insert member using a wire moving means,
The surface processing method of the member for biological insertion.
The method of claim 7, wherein
In steps b) and d),
The wire moving means is characterized in that for cutting the surface of the member for insertion of the living body by changing the cutting angle of the wire two or more times,
The surface processing method of the member for biological insertion.
The method of claim 7, wherein
In the step (c), the at least one rotating member is characterized in that for rotating the biological insertion member within a 360 ° range along the circumferential direction of the biological insertion member,
The surface processing method of the member for biological insertion.
10. The method of claim 9,
In steps b) and d),
Control unit for controlling any one or more of the direction of movement of the wire by the wire moving means, the moving speed of the biological insertion member by the at least one support portion, and the degree of rotation of the biological insertion member by the at least one rotating member. It characterized in that for controlling the shape of the projection using,
The surface processing method of the member for biological insertion.
The member for biological insertion processed using the surface processing method in any one of Claims 7-12.
The method of claim 13,
The living body insertion member,
A body portion formed of a yarn shape or a cylinder;
A protrusion formed in a predetermined shape along an outer circumferential surface of the body portion; And
Characterized in that it comprises a; cutting portion formed by the wire to form a space,
Biometric insertion member.
15. The method of claim 14,
The cutting unit is characterized in that it is formed to have a two-stage inclined surface based on the longitudinal direction of the body portion,
Biometric insertion member.
In the member for biological insertion,
A body portion formed of a cylindrical shape;
A protrusion formed in a predetermined shape along an outer circumferential surface of the body portion; And
It includes; cutting portion formed by cutting the wire space;
The biological insertion member is inserted into the biological soft tissue by a needle, and when the biological soft tissue is extended by applying force to the biological soft tissue, the tissue is extended and maintained, and the force applied to the biological soft tissue is removed. Wherein the protrusion and cutting structure is configured to maintain the biological soft tissue in an extended state in response to a force of the tissue to return to its original state, and
Any one or more of one end and both ends of the body portion is provided with an uneven portion is configured to prevent the protruding member from protruding outside in the state inserted into the living body, and
At least one protrusion is present, characterized in that formed in a predetermined interval in a spiral along the longitudinal direction of the body portion,
Biometric insertion member.

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