KR101465946B1 - apparatus for inserting the member for insertion into in-vivo - Google Patents

Abstract

The present invention relates to an insertion device capable of injecting a member for insertion into a living body, and more particularly, to a method for injecting a living body insertion member into a living body more easily by injecting a living body insertion member into a living body while rotating and pressing To an inserting device.

Description

[0001] The present invention relates to an insertion device for inserting a member for insertion into a living body,

The present invention relates to an insertion device capable of injecting a member for insertion into a living body, and more particularly, to a method for injecting a living body insertion member into a living body more easily by injecting a living body insertion member into a living body while rotating and pressing To an inserting device.

As modern medicine develops, the field of cosmetic surgery is rapidly developing, with the help of medicine, to form a part of the body that it possesses and to feel confident or to feel the satisfaction of oneself.

Particularly, in the case of the nose located in the center of the face among the parts of the body, the nose for increasing the nose is a typical field in cosmetic molding because it affects the first impression. In this case, various methods (e.g., methods using silicone implants or gore-tex, autologous cartilage, autologous fat, etc.) are used to naturally raise or shape the nose.

Among them, silicone implants are inserted into the nasal bridge, and the ear cartilage obtained from the patient's nose at the tip of the nose and the nasal cartilage are filled with the most common method, and there is little side effect reported.

However, the method of using the self-organization has relatively various advantages. However, it should be considered that a separate operation for collecting a part of the body should be performed, and there is a disadvantage that the physical characteristics and the absorption rate are not uniformly predicted exist.

Moreover, if cartilage retrieval is not sufficient and about 5 years after surgery, the formed nose shape is deformed (because the cartilage can easily move and the cartilage fixation thread may loosen and the cartilage position may change) There is a lot of cases in which reoperation is performed. Therefore, it is not an ideal molding method. In addition, there is a disadvantage that there is a lot of limitations in daily life because it causes swelling after surgery and the treatment period lasts at least a week.

Various nose forming methods and tools have been invented and developed to overcome the problems of the conventional nose forming method. In particular, Patent No. 10-0761921 entitled " Bioinjection Seal for Use in Anti-Press Multi-Fiber Adhesive Sealing Method for Biomechanical Stretching and a Tool for Inserting it into a Living Body " .

1 is a view showing a state in a living body insertion chamber for conventional nose formation.

Referring to FIG. 1, the patent document 10-0761921 discloses a human body insertion chamber 10 having a directional protrusion used for extending a part of a human body. The protrusion 12 has a wedge- And the protrusions 12 are formed of two sections 10A and 10B which are opposite to each other with respect to a reference point P on the seal axis, The biopsy device is inserted into the living body by the injection needle, and when the biopsied tissue is pulled out, the protrusion does not interfere with the tissue, and the tissue is stretched. When the pulling force is removed, the bioreactor resists the force Discloses a biocompatible thread for use in an anti-compression multifilament adhesion suturing method for soft tissue lengthening.

In the case of such a biotissue thread, the existing suture structure (a structure in which protrusions exist in both directions of the thread, disclosed in U.S. Publication No. 2005/0267532 (Surgical thread) This is significant in that it was used for the interbody abdominal multifilament adhesion suture for biomechanical extension.

In addition, various needles and injection tools have been developed and used as a tool for injecting the above-described biotooling chamber into a living body. Specifically, Japanese Patent No. 10-1178871 (entitled "Injection Needle for Injection Molding with Surgical Yarn") discloses an injection needle and a device for inserting a surgical knife in vivo.

2 is a view showing a needle for inserting a conventional surgical thread into a living body. Referring to Fig. 2, the injection needle 10 "includes a hollow cylindrical injection section 12 " in which a surgical thread 20" is received and injected into a living body, An insertion portion 14 "for transferring pressure so as to be able to be inserted into the living body, and a tip portion 16" At this time, the surgical knitting yarn 20 "includes a plurality of directional protrusions 22", and the end of the protrusion 22 "is configured to face the opposite direction of the distal end portion 16" do. On the other hand, the push pin 30 "penetrates through the insertion portion 14" and is inserted into the injection needle 10 ", and pushes the surgical knife 20" located inside thereof.

However, in the case of using the needle and the injection tool described in the above-mentioned Japanese Patent No. 10-1178871, (i) the suture such as the surgical suture is very thin and the supporting force of the material itself is weak. Therefore, (Ii) there is a possibility that the direction to be inserted is not constant and it is warped, (iii) because of the simple structure of the needle and the injection tool, (Iv) the injection needle and the instrument itself must be simple and unstable, and (v) because of the need to use a biotissue thread The procedure itself is very difficult for specialists as well as the patient's satisfaction with it It is possible dots.

The inventor of the present invention invented a biomechanical member having a new configuration and applied for a patent, and in order to solve various problems that arise while actually using the above-mentioned needles and tools, The insertion member can be more effectively injected into the living body by injecting the living body insertion member into the living body.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-described problems, and an object of the present invention is to provide an insertion device capable of more effectively injecting a living body insertion member into a living body by injecting a living body insertion member into a living body while rotating and pressing the living body insertion member spirally. .

It is also an object of the present invention to provide a rotatable core member that rotates the biplane member in both directions or makes it movable forward and backward so that when the biplane insertion member is not inserted in the correct position, The present invention provides an inserting device that can be inserted into a patient's body.

It is also an object of the present invention to provide an insertion device which can more easily grasp to what extent a biopsy insertion member is inserted by providing a transparent material or a display window.

It is also an object of the present invention to provide an insertion device which can be operated more accurately and safely even in an untrained state because the insertion device itself is manufactured in the form of a needle as well as a tool and a tool.

The present invention relates to an insertion device capable of injecting a living body insertion member into a living body. The living body insertion member insertion device according to the present invention comprises: a tubular needle having a hollow portion communicating with one end and the other end; A biotissue insertion member positioned in the needle; And a rotating core member capable of pressing the biomechanical member while rotating to inject the biomedical member into the living body.

Preferably, the biotissue-use member includes a body portion formed of a thread or a cylinder; A protrusion formed to extend spirally along an outer circumferential surface of the body portion; And a toothed groove structure or convexo-concave structure formed on the protrusion.

Advantageously, the inserter comprises an insertion device distal end configured to receive the tubular needle and the rotating core member therein and to allow a portion of the needle to be inserted into a living body; And an insertion device body connected to the distal end of the insertion device and configured in a shape of a gun so that a user can mount the insertion device.

Preferably, the distal end of the insertion device is made of a transparent material so that the movement of the biomedical insertion member can be seen from the outside, or a display window is provided on one side.

Preferably, a groove is provided at one end of the rotating core member and is engaged with the end of the biotissue insertion member.

Preferably, the insertion device body part houses a gear module for rotating and moving the rotary core member according to the operation of the user.

Preferably, the gear module converts a linear motion according to a user's operation into a rotational motion.

Preferably, the gear module rotates and moves the rotating core member by receiving the force of the user when the user presses a lever provided on the insertion device body part, Or the like.

Preferably, the insertion device body further includes a rotation direction switching unit connected to the rotating core member and the gear module, and capable of selectively controlling a rotation and a moving direction of the rotating core member.

Preferably, the insertion device body includes: a motor for rotationally driving the gear module; And a battery capable of supplying power to the motor.

According to the present invention, the biotissue member can be injected into the living body more effectively by injecting the biotissue member into the living body while spirally rotating and pressing the member.

According to the present invention, there is also provided a rotating core member that rotates the biomechanical member in both directions or makes it movable forward and backward, thereby making it possible to more easily retrieve the member when the biomechanical insertion member is not inserted at the correct position .

Therefore, it is possible to perform an accurate procedure, and the procedure can be easily performed even if the patient is not an expert.

Further, according to the present invention, by providing a transparent material or a display window at the distal end portion of the insertion device, it is possible to more easily grasp to what extent the biopsy insertion member is inserted.

Further, according to the present invention, since the insertion device itself is manufactured in the form of a gun as well as a needle and a tool, it can be operated more accurately and safely even in an untrained state.

That is, by using the inserting device according to the present invention, it is possible to more effectively perform plastic surgery, dermatological surgery, cosmetic molding, general surgery, and the like, thereby improving the patient's satisfaction.

1 is a view showing a state in a living body insertion chamber for conventional nose formation,
2 is a view showing a needle for inserting a conventional surgical thread into a living body,
FIG. 3 is a view schematically showing a member insertion device for a living body according to the present invention,
4 is a view schematically showing a member for insertion of a living body used in a member insertion apparatus for a living body according to the present invention,
5 is a view schematically showing an auxiliary tool for inserting a member 100 for insertion of a living body into a tubular needle 200 of an inserting device according to the present invention,
6 is a view showing a tubular needle 200 configured to be easily inserted into a tubular needle 200 of the insertion device according to the present invention,
7 is a view schematically showing a device for inserting a member for insertion according to another embodiment of the present invention,
FIG. 8 is a schematic view of a biplane insertion device according to another embodiment of the present invention.

A preferred embodiment of an insertion device capable of injecting a living body insertion member according to the present invention into a living body will be described with reference to the accompanying drawings. 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, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, the definitions of these terms should be described based on the contents throughout this specification.

< Example  1 - Insertion device in the form of a syringe>

3 is a view schematically showing a device for inserting a member for insertion according to the present invention. 4 is a view schematically showing a member 100 for insertion of a living body used in a member insertion apparatus for a living body according to the present invention.

3, the insertion device according to the present invention basically includes a member 100 for insertion of a living body, a tubular needle 200, and a rotating core member 220.

The biopsy member 100 may be composed of various kinds of sutures or silicon materials. When the biopsy member 100 is inserted into the living body and the tissue is extended, the biopsy member 100 resists the tissue elasticity to return to the original state, And to maintain the state.

The body-insertable member 100 includes a body 110 formed in a cylindrical shape or a cylindrical shape; A protrusion 120 spirally extending along an outer circumferential surface of the body portion; And a toothed groove structure or concave-convex structure 130 formed on the protrusions.

Here, the protrusion 120 helps the biopsy member 100 to be more easily injected into the living body, and the biotissue, which is artificially elongated, As shown in FIG. Note that the projected size, width, spiral angle, spacing distance, and the like are not particularly limited as long as the protrusion 120 can perform the above-described functions.

The tooth groove or concavoconvex structure 130 is configured to increase the biocompatibility and surface area of the biopsy member 100 to increase the surface area in contact with the biopsy member 100 and (i) (Ii) effectively resist forces that are to be pulled back by tissue elasticity, thereby (iii) maintaining the tissue more effectively in an extended state.

Preferably, such a body-insertable member 100 is made of a silicone material. The reason for this is that silicone material is widely used for medical use and particularly since the flexibility and the supporting force are better than the suture material described above and the biopsy member 100 is inserted into the living body, to be.

The tubular needle 200 has a structure in which a hollow portion communicating with one end and the other end is internally formed. A living body insertion member 100 is positioned inside the tubular needle 200 and a part of the living body insertion member 100 is inserted into the living body, As shown in FIG.

At this time, it is preferable that the tubular needle 200 use a needle of 21 gauge or less without scarring in view of characteristics to be practiced for cosmetic purposes.

The tubular needle 200 has a tip portion 202 having a pointed end so as to be injected into a living body; A hollow cylindrical injection section 204 in which a member for insertion 100 is accommodated and a certain portion is injected into the living body; And an insertion portion 206 capable of transmitting pressure so that the member for biopsy 100 can be inserted into the living body.

The rotating core member 220 penetrates through the insertion portion 206 and is inserted into the tubular needle 200, and serves to push and push the biomedical insertion member 100 positioned inside thereof.

It is preferable that the rotating core member 220 is configured so that the rotating core member 220 also rotates so that the biopsy member 100 is inserted into the living body while rotating spirally. It is more preferable that a groove is provided at one end of the rotating core member 220 so as to be engaged with the end portion or the helical protrusion of the living body insertion member 100.

Due to such a configuration, the user can inject the living body insertion member 100 into the living body while rotating and pressing the living body insertion member 100 in a spiral manner, so that the living body insertion member can be more effectively injected into the living body.

5 is a schematic view of an auxiliary tool for inserting a member 100 for insertion of a living body into a tubular needle 200 of an inserting device according to the present invention, 200 for easily inserting a member 100 for insertion of a biomedical device into a living body.

5, the auxiliary tool 300 has threads corresponding to the helical protrusions 310 so that one end of the auxiliary tool 300 is inserted into the hub of the tubular needle 200 and the helical protrusion 120 is easily inserted into the other end of the auxiliary tool 300 ) Is formed.

Due to such a constitution, the body-insertable member 100 can be easily inserted into the tubular needle 200 by rotating the helical protruding portion 120 by screwing the threaded body 310 with no tool .

It should be noted that although not shown, the auxiliary tool 300 may also have a structure in which a taper is formed such that the center portion starts to have the same diameter as the diameter of the needle and becomes larger toward the outer portion.

Referring to FIG. 6, a dedicated tubular needle 200 for inserting a member 100 for in-vivo insertion in vivo is shown, which is configured to more easily fit a member 100 for insertion for a living being formed with a spiral protrusion.

For this purpose, a hole having an inner diameter for accommodating a member 100 for insertion of a living body, in which a spiral protrusion is formed, is formed at the center thereof. The other end of the needle has a thread 210 corresponding to the spiral protrusion so that the spiral protrusion 120 can be inserted easily.

Due to such a constitution, the biotissue member 100 according to the present invention can rotate the biotissue member 100 more easily by rotating the helical protrusion 120 on the thread 210 without any additional tool, (Not shown).

As described above, by forming the threads 310 and 210 in the auxiliary tool 300 for insertion and the tubular needle 200, the biotissue insertion member 100 is naturally inserted into the tubular needle 200 without any tool It is possible to shorten the time required for inserting the member 100 for insertion into the needle in a number of procedures, thereby significantly shortening the procedure time.

< Example  2 - Inserting device of scanning gun type>

FIGS. 7 and 8 are views schematically showing a device for inserting a member for insertion according to another embodiment of the present invention. 7 and 8, the inserting device in the form of a scanning gun has a structure in which the insertion member 100, the tubular needle 200 and the rotating core member 220 Note that the configuration including the rotation core member 220 is the same but a configuration for more easily performing rotation and movement of the rotating core member 220 is added. Therefore, a detailed description of the same configuration will be omitted below.

Insertion device 500 in the form of a scan gun comprises an insertion device tip 460 and an insertion device body 400 and is configured in a known "dry" configuration.

The above-described insertion member 100, the aforementioned tubular needle 200 and the rotating core member 220 are received in the insertion device distal end portion 460, and a portion thereof is configured to be inserted into the living body.

A needle connection part 461 may be additionally provided at the distal end of the insertion device 460 to be coupled with the needle 200 so that the disposable tubing needle 200 can be used as needed. In such a configuration, since the user can use the disposable tube needle 200 every time the operation is performed, the user can use the disposable tube needle 200 for the sanitary operation.

It should be noted that although not shown, the tubular needle 200 may be used as a non-disposable needle. In this case, it is noted that the needle 200 and the needle connection portion 461 may be integrally formed.

It is noted that the insertion device distal end portion 460 may be made of a transparent material so that the movement of the biometrical insertion member 100 can be seen from the outside, or the display window 462 may be formed on one side portion. With this configuration, the practitioner can more easily grasp the degree of insertion of the member for biomechanics insertion, thereby enabling more accurate operation.

The insertion device body 400 is connected to the insertion device distal end 460 and is configured in a gun shape so that the user can mount the insertion device. The insertion device body 400 may include a lever 410, a handle 420, a gear module 430, a rotation direction switching unit 440, a battery 450, and the like, as described later.

The lever 410 and the handle 420 help the user to insert the bioprocessing member 100 at a correct position in the living body by placing the insertion device 500 according to the present invention in a stable state. Specifically, the user can stably insert the insertion device 500 by placing the index finger on the lever 410, which will be described below, as if shooting a gun, and holding the finger 420 with the remaining fingers while gripping the finger. Here, the lever 410 is configured to be interlocked with the gear module 430, which will be described later.

The gear module 420 is positioned inside the inserter 500 and is configured to be mechanically interlocked with the lever 410 and the rotational direction switching unit 430 to be described later. The gear module 420 serves to rotate and move the rotating core member 220 by converting linear motion according to a user's operation into rotational motion.

Specifically, when the user presses the lever 410, the gear module 430 receives the force of the user (that is, the force generated by the linear motion of the user due to the operation of pulling the lever). At this time, the gear module 430 converts the linear motion corresponding to the pressure of the user into rotational motion, and rotates the rotary core member 220 and moves it forward. Accordingly, the rotatable core member 220 can be effectively inserted into the living body by moving the biotissue insertion member 100 which is engaged and rotated while rotating forward.

Meanwhile, the insertion device 500 according to the present invention may further include a rotation direction switching unit 440. The rotation direction switching unit 440 is mechanically interlocked with the rotating core member 220 and the gear module 430 and is configured to selectively control the rotation and movement direction of the rotating core member 220.

For example, if the user presses the lever 410 while the rotation direction switching unit 440 is positioned at "+ ", the rotating core member 220 is rotated in the rightward direction and simultaneously moved forward, If the user presses the lever 410 while the switching unit 440 is positioned at "-", the rotating core member 220 may be configured to rotate in the leftward direction and simultaneously move backward.

According to such a configuration, when the member 100 for biometrical insertion is not inserted at the correct position, the member 100 for biometrical insertion can be more easily recovered. Therefore, it is possible to perform an accurate procedure, and the procedure can be easily performed even if the patient is not an expert. However, the rotation direction switching unit 440 described above is constructed using known components, and a detailed description thereof will be omitted.

The inserter 500 according to the present invention may further include a motor (not shown) and a battery 450. These components are applied when the inserting device according to the present invention is driven by an electric force such as, for example, an electric driver.

At this time, the motor can rotate and drive the gear module, and the battery 450 plays a role of supplying power to the motor. That is, when the motor and the battery 450 are applied, the operator can rotate and move the rotating core member 220 only by a slight force acting on the lever 410, thereby causing friction with surrounding tissues It is possible to insert the member 100 for biometrics more easily into the living body.

INDUSTRIAL APPLICABILITY As described above, according to the present invention, the biotissue member can be more effectively injected into the living body by injecting the biotissue member into the living body while spirally rotating and pressing the member. As a result, it is possible to effectively solve the various problems of the previously known "MISCO molding" and "HAICO molding &quot;, thereby providing a cosmetic molding method and member that are more efficient and highly satisfactory to the operator and patient .

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: member for biomechanical insertion
200: Needle
220: rotating core member
300: Auxiliary tool for insertion
400: insertion device body part
410: lever
420: Handle portion
430: Gear module
440: rotation direction switching unit
450: Battery
460: insertion device distal end
500: insertion device

Claims (10)

An insertion device capable of injecting a living body insertion member into a living body,
A tubular needle in which a hollow portion communicating one end and the other end is formed;
A biotissue insertion member positioned in the needle; And
And a rotating core member capable of pressing the biomechanical member while rotating to inject the biomedical member into the living body, and
And a rotation direction switching unit connected to the rotary core member and a gear module for converting a linear motion according to a user's operation into a rotary motion and selectively controlling a rotation and a moving direction of the rotary core member As a result,
A member insertion device for in vivo insertion.
The method according to claim 1,
Wherein the biotissue-
A body portion made of a thread or a cylinder;
A protrusion formed to extend spirally along an outer circumferential surface of the body portion; And
And a tooth groove structure or a concavo-convex structure formed on the protruding portion.
A member insertion device for in vivo insertion.
3. The method according to claim 1 or 2,
The inserting device includes:
An insertion device distal end configured to receive the tubular needle and the rotating core member therein and to insert a portion of the needle into a living body; And
And an insertion device body connected to the distal end of the insertion device and configured in a shape of a gun so that a user can mount the insertion device.
A member insertion device for in vivo insertion.
The method of claim 3,
Characterized in that the distal end of the insertion device is made of a transparent material or the display window is provided on one side so that the movement of the bi-
A member insertion device for in vivo insertion.
The method of claim 3,
Wherein one end of the rotating core member is provided with a groove to engage with an end of the biotissue insertion member.
A member insertion device for in vivo insertion.
The method of claim 3,
The insertion device body part
And a gear module which rotates and moves the rotating core member according to an operation of the user,
A member insertion device for in vivo insertion.
delete The method according to claim 6,
The gear module includes:
When the user presses the lever provided on the insertion device body part, the rotation member is rotated and moved to receive the force of the user, thereby inserting or removing the biplacing member in the living body As a result,
A member insertion device for in vivo insertion.
delete The method according to claim 6,
The insertion device body part
A motor for rotationally driving the gear module; And
And a battery capable of supplying power to the motor.
A member insertion device for in vivo insertion.

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