KR20210019887A - Micro-needle bullet injection apparaus for endoscope - Google Patents

Abstract

According to the present invention, a micro-needle bullet injection device for an endoscope includes: a hollow body part which can be inserted into the endoscope channel and has a movable space therein; a microneedle bullet which contains a chemical solution which can penetrate into skin and can be loaded at the tip of the body based on the direction of penetration; and a control unit which penetrates the loaded microneedle bullets into the skin using elastic force provided in the movable space of the main body. According to this configuration, it is possible to permeate a predetermined amount of the chemical solution through mucosal skin into a tissue to be treated through a simple operation, thereby contributing to the improvement of treatment reliability.

Description

Microneedle bullet injection device for endoscope {MICRO-NEEDLE BULLET INJECTION APPARAUS FOR ENDOSCOPE}

The present invention relates to a microneedle bullet injection device for an endoscope, and more specifically, it is mounted on an endoscope channel to enable delivery of a drug through mucosal skin to a tissue in need of treatment, thereby improving the accuracy of penetration into the mucous skin and quantitatively It relates to a microneedle bullet injection device for an endoscope capable of delivery.

During gastric, large intestine, and bladder endoscopy, various treatments such as polyp removal, mucosal and submucosal resection, dilatation, and stent insertion may be performed for the purpose of diagnosis as well as treatment. In the case of injecting a drug such as Botox into the stomach or bladder muscle, the procedure is as follows.

First of all, in the case of bladder system disease, an overactive bladder (Urgency) with urinary urgency in which urinary urgency is unbearable due to a sudden contraction of the bladder muscle, even though the bladder is not sufficiently filled with urine (Micturition desire). Overactive Bladder) or neurogenic detrusor overactivity disease in which the nervous system controlling the lower urinary tract is damaged may occur. As a treatment for such overactive bladder or neurotic detrusor hyperactive disease, it is common to take drugs along with lifestyle correction therapy. However, along with side effects such as dry mouth and constipation that may be caused by drugs for the treatment of such bladder diseases, there is a problem that continuous treatment is difficult.

In order to improve the drug treatment problem of bladder system diseases, in recent years, Botox is injected into the bladder muscle to block the secretion of neurotransmitters, thereby inhibiting unnecessary contraction of the bladder muscle, thereby improving immediate overactive bladder symptoms.

In addition, when Botox is injected into the muscles of the stomach using a gastrointestinal endoscope, it is possible to prolong the digestion time of food and maintain a feeling of fullness by lowering the gastrointestinal muscle movement, which is effective in treating obesity.

As described above, in recent years, as Botox treatment using an endoscopic procedure is applied in various ways, various studies are continuously being conducted to improve the accuracy and stability of the procedure at the time of drug injection.

Republic of Korea Patent Publication No. 10-2018-0081550

An object of the present invention is to provide an endoscopic microneedle bullet injection device that is mounted on an endoscopic channel to improve penetration accuracy of drug delivery through mucosal skin to tissues requiring treatment, and capable of delivering a quantitative drug.

Another object of the present invention is to provide an endoscopy microneedle bullet injection device capable of penetrating the microneedle bullet to a desired position and depth, thereby improving treatment safety and reliability.

The microneedle bullet injection device for an endoscope according to the present invention for achieving the above object, can be inserted into an endoscope channel, a hollow body portion provided with a movable space therein, a chemical solution that can penetrate into the skin, and the direction of penetration As a reference, a microneedle bullet that can be loaded at the front end of the body portion, and a manipulation unit provided in the movable space of the body portion and penetrating the loaded microneedle bullet into the skin using an elastic force.

In addition, the main body may include a catheter that extends in a longitudinal direction in a penetration direction into which the microneedle bullet penetrates, and in which the movable space is provided parallel to the penetration direction.

In addition, the operation unit has a shape extending in a longitudinal direction to the penetration direction into which the microneedle bullet penetrates and is inserted into the body portion, the operation body movable in the penetration direction, the operation body based on the penetration direction A shaft extending from the tip of the microneedle bullet to selectively interfere with the microneedle bullet, an elastic member for elastically supporting the shaft, and provided in an exposed hole penetrating through one side of the main body to prevent movement of the operation body. It may include an interfering trigger and a trigger cover provided to be movable along an outer surface of the main body and selectively exposing the trigger according to a movement posture.

In addition, the front end of the operating body is connected to the shaft by a connecting member, the rear end is connected to a cap fixed to close the open rear end of the main body, and the elastic member is interposed on the outer circumferential surface of the operating body, The elastic member may include a coil spring positioned between the connection member and the cap and compressible according to the movement of the connection member.

In addition, the trigger is provided to be rotatable around a hinge, and when the trigger cover is moved in a direction opposite to the penetration direction, when the trigger is exposed and an external force is applied, the trigger is rotated around the hinge Interference with the shaft can be canceled.

In addition, the trigger cover may be provided with a stepped interference jaw on at least a portion of a surface facing the trigger, and a movement range in the penetration direction may be limited by interference between the interference jaw and the trigger.

Further, a hollow penetration guider is connected to the front end of the control body to extend in the penetration direction, and the shaft may be movable inside the penetration guider.

In addition, the penetration guider may be flexibly provided with multiple twists.

In addition, a hollow chemical guider into which the microneedle bullet is loaded is coaxially connected to the penetration guider at the tip of the penetration guider based on the penetration direction, and the microneedle bullet is at the tip of the chemical guider based on the penetration direction. A shielding film that can be torn by the penetration force of is provided, and the microneedle bullet loaded in the chemical guider can be protected from the outside.

In addition, the chemical liquid guider may receive the microneedle bullet from a charging unit having the microneedle bullet.

In addition, when the microneedle bullet is mounted on the body, the trigger compresses the elastic member by pressing the elastic member in a direction opposite to the penetration, and an interference force between the trigger and the elastic member is caused by the movement of the trigger. When released, the shaft presses the microneedle bullet by the elastic restoring force of the elastic member and discharges it to the outside of the main body.

In addition, the microneedle bullet may have at least one of a tip shape, an arrowhead shape, a multistage shape, a screw shape, and a groove shape with a pointed tip based on the penetration direction penetrating into the skin.

In addition, the microneedle bullet may be prepared by solidifying the chemical liquid containing at least a portion of Botox, and may be made of a material that can be absorbed into the body after penetrating the skin and releasing the chemical liquid.

In addition, the microneedle bullet is provided such that a stopper for limiting the penetration depth into the skin can be folded or unfolded at the rear end based on the penetration direction, and the stopper of the microneedle bullet is in a folded state when loaded in the body, As it is discharged from the main body, it can be spread by elasticity.

The microneedle bullet injection device for an endoscope according to a preferred embodiment of the present invention is an endoscopic microneedle bullet injection device for injecting a microneedle bullet formed by solidifying a chemical solution that penetrates and dissolves into the skin. In the endoscope channel, it includes a hollow body portion to which the microneedle bullet is mounted at a distal end portion, and a manipulation portion provided to be movable inside the body portion to discharge the microneedle bullet to the skin.

In addition, the main body may include a catheter extending parallel to the penetration direction, and in which a movable space in which the manipulation unit is inserted and movable is provided parallel to the penetration direction.

In addition, the operation unit has a shape extending parallel to the penetration direction and is inserted into the body portion, the operation body movable in the penetration direction, the microneedle bullet from the tip of the operation body based on the penetration direction A shaft extending toward and interlocking with the movement of the operating body to selectively interfere with the microneedle bullet, and elastically supporting a connecting member connecting the operating body and the shaft to provide a penetration force to the operating body A member, a trigger provided in an exposed hole formed penetrating through one side of the body part, to selectively compress the elastic member by interfering with the movement of the operation body, and a trigger provided to be movable along the outer surface of the body part, according to the movement posture It may include a trigger cover that selectively exposes.

In addition, a hollow penetration guider in which the shaft is inserted and movable at the front end of the body part based on the penetration direction and a hollow chemical guider in which the microneedle bullet is mounted are coaxially provided to be connected to the penetration guider. It is connected, and a cap for sealing the inside is mounted at a rear end of the main body, and an operation space in which the operation body is movable may be provided inside the cap.

In addition, the penetration guider may be flexibly provided with multiple twists.

In addition, the elastic member is interposed on the outer peripheral surface of the operation body, the elastic member may include a coil spring that is located between the connection member and the cap, compressible according to the movement of the connection member.

In addition, the trigger is provided to be rotatable around a hinge, and when the trigger cover is moved in the penetration direction or in a direction opposite to the penetration to expose the trigger, the trigger is rotated by an external force to interfere with the elastic member. Can be released.

In addition, when the microneedle bullet is mounted on the main body, the trigger compresses the elastic member by pressing the connection member in a direction opposite to the penetration, and the trigger is exposed by the movement of the trigger cover to cause external force. When this is applied, the shaft presses the microneedle bullet in association with the movement of the manipulation body in the penetration direction by the elastic restoring force of the elastic member, thereby discharging it to the outside of the body part.

In addition, the chemical solution of the microneedle bullet contains at least a part of Botox, and is provided with a material absorbable into the body after penetrating into the skin and releasing the chemical solution, and the microneedle bullet has a pointed tip based on the penetration direction. It may have at least one shape among a tip shape, an arrowhead shape, a multistage shape, a screw shape, and a groove shape.

In addition, the microneedle bullet is provided such that a stopper for limiting the penetration depth into the skin is foldable or unfoldable at the rear end based on the penetration direction, and the stopper of the microneedle bullet is in a folded state when loaded in the main body. In connection with being discharged from the main body, it may be unfolded by elasticity.

In addition, a shielding film that can be torn by the penetrating force of the microneedle bullet is provided at the tip of the chemical liquid guider based on the penetration direction to protect the microneedle bullet loaded in the chemical liquid guider from the outside, and the chemical liquid guider comprises the The microneedle bullet may be provided from a charging unit having a microneedle bullet.

According to the present invention having the above configuration, first, by loading a microneedle bullet, it is possible to accurately penetrate the chemical solution through the mucosal skin into a target tissue requiring treatment, thereby contributing to improvement of treatment accuracy according to the penetration accuracy. do.

Second, due to the simple operation of loading and penetrating the microneedle bullet using the elastic force, it is possible to contribute to the improvement of ease of use.

Third, by limiting the depth at which the microneedle bullet penetrates the skin, the microneedle bullet containing the solidified chemical solution can be dissolved in the body for a sufficient time, thereby providing a quantitative solution.

Fourth, even if the microneedle bullet penetrates the skin with a strong force, it does not penetrate the skin, so safety is excellent.

Fifth, it is possible to accurately penetrate the chemical liquid into the mucous membrane tissue of the skin, which has many wrinkles and has elasticity, which is advantageous in securing treatment diversity.

1 is a cross-sectional view schematically showing an endoscope microneedle bullet injection apparatus according to an embodiment of the present invention.
FIG. 2 is a schematic cross-sectional view illustrating a state in which a microneedle bullet of the microneedle bullet injection device for an endoscope shown in FIG. 1 is mounted on a main body.
3 is a cross-sectional view schematically showing a state in which a microneedle bullet is discharged from and penetrated by a trigger operation.
4 is a cross-sectional view schematically showing a state in which an operation unit is loaded by a trigger operation. And,
5 is a diagram schematically illustrating a stopper operation of the microneedle bullet shown in FIG. 1.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. However, the spirit of the present invention is not limited to such an embodiment, and the spirit of the present invention may be proposed differently by addition, change and deletion of components constituting the embodiment, but this is also included in the spirit of the invention. It becomes.

As shown in FIG. 1, the microneedle bullet injection device 1 for an endoscope according to an embodiment of the present invention includes a body portion 10, a microneedle bullet 20, and an operation portion 30.

For reference, the microneedle bullet injection device 1 for an endoscope described in the present invention enters the interior of internal organs such as the stomach, bladder, etc., and is mounted on an endoscope that can be operated, so that a chemical solution such as Botox is applied to a tissue requiring treatment. It is exemplified by penetrating a fixed amount of a chemical solution through the skin. However, the present invention is not limited thereto, and it is natural that it is applied to various surgical devices including an endoscope, so that various types of chemicals, including Botox, can penetrate into the skin.

The main body 10 can be inserted into an endoscope channel (not shown) and has a hollow cylindrical shape to support the microneedle bullet 20 and the operation unit 30 to be described later. The body portion 10 extends in a longitudinal direction parallel to the penetration direction in which the microneedle bullet 20 penetrates the mucosal skin of the tissue requiring treatment, and a movable space 10a in which the manipulation unit 30 is inserted and movable therein. It is illustrated as including a catheter having ).

This body part 10 is coupled so that the penetration guider 11 having a hollow tube shape is protruded and extends parallel to the tip in the penetration direction based on the penetration direction in which the microneedle bullet 20 to be described later penetrates the skin. do. In addition, a chemical guider 12 in which the microneedle bullet 20 is loaded is coupled to the front end of the penetration guider 11 of the main body 10 to have a hollow tube shape.

For reference, the penetration guider 11 is preferably made of multiple twists and has a flexible characteristic. Since the penetration guider 11 is provided flexible in this way, it is possible to prevent damage to the skin due to the penetration guider 11 along with accessibility to a desired penetration site.

The microneedle bullet 20 can be loaded at the front end of the body portion 10 and is provided by solidifying a chemical liquid that can penetrate into the skin. The microneedle bullet 20 is provided in the form of a bullet having a tip 21 shape with a pointed tip, and penetrates and dissolves into the skin by an operation unit 30 to be described later.

Here, the microneedle bullet 20 may be provided with a biocompatible material that can be absorbed into the body after penetrating the inside of the mucous membrane of the skin and releasing the chemical, and the dissolution rate of the microneedle bullet 20 and the release of the chemical The rate is adjustable through the formulation process. In addition, the microneedle bullet 20 solidified by containing a chemical solution in a biocompatible material preferably has sufficient mechanical strength to penetrate a mucous membrane having many wrinkles and elasticity. To this end, the microneedle bullet 20 is preferably provided in various shapes such as arrowheads, multistages, screws, grooves, etc. so as to have a sharp tip such as the tip 11.

As shown in FIG. 2, the microneedle bullet 20 is loaded in the body portion 10 to be described later by the loading portion 22. The loading part 22 has a hollow shape in which a loading groove 23 extending in the longitudinal direction is provided therein, and a microneedle bullet 20 is inserted into the loading groove 23. On the other hand, a pressing member 24 having one end entering the microneedle bullet 20 and the other end extending longitudinally from one end and extending to the outside of the loading part 22 is inserted into the loading groove 23, The pressing member 24 is slidable along the loading groove 23.

At one side of the loading part 22, a connection groove 22a through which the chemical guider 12 provided in the main body 10 is inserted and connected to a predetermined depth is formed stepped. In the state in which the chemical liquid guider 12 is inserted in the connection groove 22a, the pressing member 24 presses the microneedle bullet 20 located in the loading groove 23 with the chemical liquid guider 12, The bullet 20 is loaded into the chemical liquid guider 12.

For reference, one end and the other end of the chemical liquid guider 12 have an open shape. At one end facing the tip 21 of the microneedle bullet 20, a screen 13 such as Parafilm that can protect the microneedle bullet 20 from external foreign substances by isolating the outside and the inside from each other Can be provided. Here, the shielding film 13 is easily torn by the tip 21 of the microneedle bullet 20 due to the material characteristics, so that the microneedle bullet 20 is the main body part 10 by the operation unit 30 to be described later. Does not interfere with emissions from At this time, after the microneedle bullet 20 is loaded with the chemical liquid guider 12 by the loading part 22, the shielding film 13 may be provided at the front end of the chemical liquid guider 12.

In addition, since the chemical liquid guider 12 is coaxially coupled with the penetration guider 11, the microneedle bullet 20 mounted on the chemical liquid guider 12 is mounted in a state coaxially aligned with the operation unit 30 to be described later, so that penetration accuracy It can also contribute to improvement.

The manipulation unit 30 provides a penetrating force capable of penetrating the microneedle bullet 20 loaded in the body unit 10 into the mucosal skin of a tissue requiring treatment by selectively compressible elastic force. This operation unit 30 includes an operation body 31, a shaft 32, an elastic member 33, a trigger 34 and a trigger cover 35.

The operation body 31 is inserted into the body portion 10. This operation body 31 has a cylindrical shape and is inserted into the movable space 10a inside the main body 10, so that it is slidable along the movable space 10a.

Here, the rear end of the main body 10 facing the front end of the main body 10 where the penetration guide 11 is provided has an open shape, and the cap 14 is mounted on the rear end of the open main body 10 It is good to prevent separation of the operation body 31. More specifically, a movable space 10a is provided parallel to the penetration direction between the front end and the rear end of the main body 10, and a microneedle bullet 20 is loaded at the front end of the main body 10, and a cap (14) is fitted to seal the interior. Accordingly, the operation body 31 is slidably operated only within the movable space 10a between the front and rear ends of the main body 10 and is not discharged to the outside through the open rear end of the main body 10.

Here, one end of the cap 14 supports the rear end extending in the longitudinal direction from the front end of the operating body 31 facing the microneedle bullet 20, and the movable space 10a of the main body 10 and An operating space 15 to communicate with is provided. In addition, the other end of the cap 14 is provided to extend from one end in the longitudinal direction to extend to the outside of the main body 10. In this case, it is preferable that the other end of the cap 14 is provided with an operating end 16 extending in the radial direction for convenience of gripping the user.

The shaft 32 extends from the front end of the operating body 31 toward the microneedle bullet 20 based on the penetration direction of the microneedle bullet 20, and selectively interferes with the microneedle bullet 20. One end of the shaft 32 is a fixed end inserted at a predetermined depth into the front end of the operating body 31, and the other end extends in a longitudinal direction parallel to the penetration direction from one end to the inside of the penetration guider 11 and the chemical guider 12. It is provided with a free end that is inserted into. In addition, the shaft 32 is preferably formed of a flexible metal material such as a wire or a plastic material.

Here, the shaft 32 has one end connected to the operating body 31 by a connecting member 31a coupled to the front end of the operating body 31. The connecting member 31a is coupled to the front end of the operating body 31 while supporting the shaft 32, thereby limiting the insertion depth of the shaft 32 to the operating body 31. In addition, the connecting member 31a connects the operating body 31 and the shaft 32 so that the shaft 32 is slidable in connection with the movement of the operating body 31.

The elastic member 33 elastically supports the shaft 32 so as to provide an elastic pressing force for moving the shaft 32. Here, the elastic member 33 is interposed in the operating body 31, interposed between the connection member 31a coupled to the front end of the operating body 31 and the cap 14 supporting the rear end of the operating body 31 It is illustrated as including a coil spring.

At this time, the cap 14 is fixed to the main body 10, and the connecting member 31a is movable in conjunction with the operation body 31, so that the operation body (in the movable space 10a) of the main body 10 The elastic member 33 is compressed or tensioned by interlocking with the sliding operation 31).

More specifically, when the operation body 31 slides toward the rear end (in the direction opposite to penetration) of the main body 10 as shown in FIG. 3, the connection member 31a coupled to the front end of the operation body 31 is also It moves toward the rear end of (10). Accordingly, the elastic member 33 interposed between the connection member 31a and the cap 14 is compressed in association with the movement of the connection member 31a. The elastic operation of the elastic member 33 will be described later in more detail together with the penetration operation of the microneedle bullet injection device 1 for the endoscope.

For reference, the connecting member 31a and the cap 14 respectively connected to the front and rear ends of the operation body 31 have a diameter that is larger than the outer diameter of the operation body 31 and are in close contact with the inner diameter of the movable space 10a. . Accordingly, the elastic member 33 can be interposed in a spaced apart between the inner diameter of the body portion 10 between the connection member (31a) and the cap 14 and the outer diameter of the operation body 31.

The trigger 34 may be inserted into the exposed hole 17 formed through one side of the main body 10 to interfere with the manipulation body 31. The trigger 34 is provided to be rotatable about the hinge 34a, as shown in FIGS. 3 and 4. In addition, the trigger 34 is provided with first and second trigger ends 34b and 34c protruding from both ends extending in the longitudinal direction around the hinge 34a.

The first trigger end 34b of the trigger 34 protrudes toward the outside of the main body 10, and the second trigger end 34c protrudes toward the inside of the main body 10. Accordingly, the first trigger end 34b is exposed to the outside through the exposure hole 17 of the main body 10, and the second trigger end 34c is a manipulation body that slides inside the main body 10 ( 31). Here, the second trigger end (34c) interferes with the connection member (31a) coupled to the front end of the operation body (31), and is illustrated as protruding obliquely from the trigger (34).

The trigger cover 35 is provided to be movable on the main body 10 and exposes the trigger 34 so that the trigger 34 can be rotated around the hinge 34a according to the moving posture. The trigger cover 35 has a hollow cylindrical shape surrounding the outer diameter of the main body 10 so as to surround the exposed hole 17 of the main body 10.

At this time, the trigger cover 35 has a stepped interference jaw 35a formed to face the exposed hole 17. Here, the interference protrusion 35a provided in the trigger cover 35 interferes with the first trigger end 34b through the exposure hole 17, thereby limiting the range in which the trigger cover 35 advances in the penetration direction.

Meanwhile, as shown in FIG. 3, when the trigger cover 35 slides along the outer diameter of the main body 10 in a direction opposite to penetration, the first trigger end 34b of the trigger 34 provided in the exposed hole 17 Is exposed. An external force is applied to the exposed first trigger end 34b by a user and pressed in the direction of the arrow, so that the trigger 34 rotates around the hinge 34a. Accordingly, the interference force between the trigger 34 and the connection member 31a is released, and the compressive force of the elastic member 33 is released.

Meanwhile, as shown in FIG. 5, the microneedle bullet 20 is provided with a stopper 20a for limiting the depth of penetration into the skin. The stopper 20a may be provided to have elasticity such that it can be folded or unfolded at a rear end extending from the tip 21 provided at the front end of the microneedle bullet 20.

More specifically, as shown in Fig. 5 (a), in a state in which the microneedle bullet 20 is loaded in the chemical liquid guider 12, the stopper 20a of the microneedle bullet 20 is a chemical liquid guider ( It is unfolded at a predetermined angle only in the guider hole 12a of 12). This microneedle bullet 20 is interlocked with the operation of leaving the chemical liquid guider 12 as shown in FIG. 5(b), so that the stopper 20a is folded so as to be in close contact with the side of the microneedle bullet 20, and the chemical liquid guider ( 12) and at the same time, the stopper 20a is completely unfolded as shown in (c) of FIG. 5. As a result, the microneedle bullet 20 can penetrate into the skin only by the length h shown in FIG. 5C.

The penetration operation of the microneedle bullet injection device 1 for an endoscope according to the present invention having the above configuration will be described with reference to FIGS. 1 to 4.

First, as shown in FIG. 2, when the chemical liquid guider 12, which is coaxial with the penetration guider 11 of the main body 10, is inserted into the connection groove 22a of the loading part 22, the loading groove of the loading part 22 Along 23, a pressing member 24 presses the microneedle bullet 20. Accordingly, as shown in FIG. 1, the microneedle bullet 20 is discharged from the loading unit 22, and the microneedle bullet 20 is loaded inside the connected chemical liquid guider 12. At this time, the stopper 20a of the microneedle bullet 20 loaded in the chemical liquid guider 12 is unfolded only to the extent inserted into the guider hole 12a of the chemical liquid guider 12 (see Fig. 5(a)). .

With the microneedle bullet 20 loaded in the main body 10, the main body 10 is inserted into an endoscope channel (not shown) so that the main body 10 faces the mucosal skin of the tissue requiring treatment. Position. At this time, as shown in Figure 1, the inside of the body portion 10 in which the microneedle bullet 20 is loaded, an elastic member 33 positioned between the connection member 31a and the cap 14 is formed by the trigger 34. Interfered and compressed in the opposite direction of penetration. That is, as the elastic member 33 is compressed by the connecting member 31a interfered by the trigger 34, the microneedle bullet 20 is in a state in which it is loaded to wait for penetration.

Thereafter, as shown in Fig. 3, the trigger cover 35 is moved in the direction of the arrow shown, that is, in the direction opposite to penetration. Accordingly, the trigger 34 is exposed through the exposure hole 17, and by pressing the first trigger end 34b of the exposed trigger 34 in the direction of the arrow, the trigger 34 is centered on the hinge 34a. It rotates in the direction of the arrow.

At this time, as the second trigger end 34c of the trigger 34 is rotated upward, the interference force of the connecting member 31a that pressed the elastic member 33 due to the interference of the second trigger end 34c is also released. do. Accordingly, the connecting member 31a is elastically pressed in the penetration direction in conjunction with the elastic restoring force of the elastic member 33 that has been compressed.

In conjunction with the movement of the connection member 31a, the tip of the operation body 31 connected to the connection member 31a also moves, and the shaft 32 connected to the tip of the operation body 31 is Guided in the direction of penetration from the inside. As a result, the shaft 32 is advanced in the penetration direction at a high speed in the penetration guider 11 to press the microneedle bullet 20.

Here, by pressing the microneedle bullet 20 with a strong force by the shaft 32 due to the elastic restoring force of the elastic member 33, the microneedle bullet 20 tears the shielding film 13 of the chemical guider 12 Will be discharged toward. For reference, the microneedle bullet 20 is discharged with a force sufficient to penetrate the target skin including the mucous membrane having many wrinkles and high elasticity, so that a quantitative amount of the chemical can penetrate through the mucous membrane skin into the tissue requiring treatment. do.

In addition, the microneedle bullet 20 is unfolded by the elastic force in the state where the stopper 20a is folded while leaving the chemical guider 12 as shown in FIGS. 5B and 5C, and thus the mucous membrane of the tissue requiring treatment The depth of penetration into the skin is limited. Accordingly, even if the microneedle bullet 20 leaves the body portion 10 with a strong force, it is inserted to a desired depth without penetrating the internal tissue to provide a chemical solution. The microneedle bullet 20 penetrated into the skin in this way dissolves with sufficient time, so that a fixed amount of the chemical solution penetrates into the tissue requiring treatment.

After the microneedle bullet 20 has penetrated into the skin, the trigger cover 35 returns to its original position as shown in FIG. 4, so that the elastic force of the elastic member 33 of the operation unit 30 is compressed again, and the microneedle bullet Wait for the next operation to penetrate (20).

As described above, although it has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention without departing from the spirit and scope of the present invention described in the following claims. You will understand that you can do it.

1: microneedle bullet injection device for endoscope 10: main body
11: penetration guider 12: chemical guider
13: screen 14: cap
20: microneedle bullet 20: stopper
21: tip 22: reload
23: loading groove 24: pressing member
30: operation part 31: operation body
32: shaft 33: elastic member
34: trigger 35: trigger cover

Claims (25)

A hollow body portion inserted into the endoscope channel and having a movable space therein;
A microneedle bullet containing a chemical liquid penetrating into the skin and capable of being loaded at the tip of the main body based on the penetration direction; And
A manipulation unit provided in the movable space of the main body and penetrating the loaded microneedle bullet into the skin using an elastic force;
Microneedle bullet injection device for an endoscope comprising a. The method of claim 1,
The body part,
A microneedle bullet injection device for an endoscope comprising a catheter extending in a longitudinal direction in a penetration direction into which the microneedle bullet penetrates, and having the movable space inside the catheter provided parallel to the penetration direction. The method of claim 1,
The operation unit,
An operation body having a shape extending in a longitudinal direction in a penetration direction into which the microneedle bullet penetrates, and being inserted into the body portion, and movable in the penetration direction;
A shaft extending toward the microneedle bullet from the front end of the manipulation body based on the penetration direction, and selectively interfering with the microneedle bullet;
An elastic member elastically supporting the shaft;
A trigger provided in an exposed hole penetrating through one side of the main body and interfering with the movement of the manipulation body; And
A trigger cover provided to be movable along an outer surface of the main body and exposing the trigger according to a movement posture;
Microneedle bullet injection device for an endoscope comprising a. The method of claim 3,
The front end of the operation body is connected to the shaft by a connecting member, and the rear end is connected to a cap fixed to close the open rear end of the main body,
The elastic member is interposed on the outer peripheral surface of the operation body, the elastic member is positioned between the connection member and the cap, the endoscope microneedle bullet injection device comprising a coil spring compressible according to the movement of the connection member. The method of claim 3,
The trigger is provided to be rotatable around the hinge,
When the trigger cover is moved in a direction opposite to the penetration direction, when the trigger is exposed and an external force is applied, the trigger is rotated around the hinge to cancel interference with the shaft. The method of claim 3,
The trigger cover is provided with a stepped interference jaw on at least a part of a surface facing the trigger,
Microneedle bullet injection device for an endoscope in which a range of movement in the penetration direction is limited by interference between the interference jaw and the trigger. The method of claim 3,
A hollow penetration guider is connected to the tip of the control body and extends in the penetration direction,
The shaft is an endoscope microneedle bullet injection device capable of moving inside the penetration guider. The method of claim 7,
The penetration guider is a microneedle bullet injection device for an endoscope that is made of multiple twists and is flexibly provided. The method of claim 7,
A hollow chemical guider in which the microneedle bullet is loaded is coaxially connected to the penetration guider at the tip of the penetration guider based on the penetration direction,
An endoscope microneedle bullet injection device for protecting the microneedle bullet loaded in the chemical guider from the outside is provided with a shielding film that can be torn by the penetration force of the microneedle bullet at the tip of the chemical liquid guider based on the penetration direction . The method of claim 9,
The chemical liquid guider is a microneedle bullet injection device for an endoscope capable of receiving the microneedle bullet from a charging unit having the microneedle bullet. The method of claim 3,
In a state in which the microneedle bullet is mounted on the main body, the trigger compresses and presses the elastic member in a direction opposite to the penetration,
When the interference force between the trigger and the elastic member is released by the movement of the trigger, the shaft presses the microneedle bullet by the elastic restoring force of the elastic member and discharges the microneedle bullet to the outside of the main body. Injection device. The method of claim 1,
The microneedle bullet is an endoscope microneedle bullet injection device having at least one of a tip shape, an arrowhead shape, a multistage shape, a screw shape, and a groove shape with a pointed tip based on the penetration direction penetrating into the skin . The method of claim 1,
The microneedle bullet is provided by solidifying the chemical liquid containing at least a part of botox, and the microneedle bullet injection device for an endoscope is provided with a material absorbable into the body after penetrating into the skin and releasing the chemical liquid. The method of claim 1,
The microneedle bullet is provided such that a stopper limiting the penetration depth into the skin is foldable or unfoldable at the rear end based on the penetration direction,
The stopper of the microneedle bullet is in a folded state when loaded in the body part, and is spread out by elasticity in connection with being discharged from the body part. In the microneedle bullet injection device for an endoscope for injecting microneedle bullets formed by solidifying a chemical solution that penetrates and dissolves into the skin,
A hollow body that can be inserted into an endoscope channel and to which the microneedle bullet is mounted at a tip portion; And
An operation unit provided to be movable inside the body unit to discharge the microneedle bullet to the skin;
Microneedle bullet injection device for an endoscope comprising a. The method of claim 15,
The body part,
A microneedle bullet injection device for an endoscope comprising a catheter extending parallel to the penetration direction and having a movable space in which the manipulation unit is inserted and movable therein. The method of claim 15,
The operation unit,
A manipulation body that has a shape extending parallel to the penetration direction and is inserted into the body portion to move in the penetration direction;
A shaft extending from the tip of the manipulation body toward the microneedle bullet based on the penetration direction, and interlocking with the movement of the manipulation body to selectively interfere with the microneedle bullet;
An elastic member for elastically supporting a connection member connecting the operation body and the shaft to provide a penetration force to the operation body;
A trigger provided in an exposed hole penetrating through one side of the main body and selectively compressing the elastic member by interfering with the movement of the operation body; And
A trigger cover provided to be movable along an outer surface of the main body and selectively exposing the trigger according to a movement posture;
Microneedle bullet injection device for an endoscope comprising a. The method of claim 17,
Based on the penetration direction, the shaft is inserted into the front end of the main body to be connected to the movable hollow penetration guider and the penetration guider, and a hollow chemical guider on which the microneedle bullet is mounted is coaxially connected to each other. ,
A microneedle bullet injection device for an endoscope in which a cap for sealing the inside is mounted at a rear end of the main body, and an operation space in which the operation body is movable is provided inside the cap. The method of claim 18,
The penetration guider is a microneedle bullet injection device for an endoscope that is made of multiple twists and is flexibly provided. The method of claim 18,
The elastic member is interposed on the outer peripheral surface of the operation body,
The elastic member is positioned between the connection member and the cap, the endoscope microneedle bullet injection device comprising a coil spring compressible according to the movement of the connection member. The method of claim 17,
The trigger is provided to be rotatable around the hinge,
When the trigger cover is moved in the penetration direction or in a direction opposite to the penetration to expose the trigger, the trigger is rotated by an external force to release an interference force with the elastic member. The method of claim 17,
In a state in which the microneedle bullet is mounted on the main body, the trigger compresses the elastic member by pressing the connection member in a direction opposite to the penetration,
When the trigger is exposed by the movement of the trigger cover and an external force is applied, the operation body moves in the penetration direction by the elastic restoring force of the elastic member, so that the shaft presses the microneedle bullet, and the body Microneedle bullet injection device for endoscope that discharges to the outside of the unit. The method of claim 15,
The chemical solution of the microneedle bullet contains at least a part of Botox, and is provided with a material absorbable into the body after penetrating the skin and releasing the chemical solution,
The microneedle bullet is an endoscope microneedle bullet injection device having at least one of a tip shape, an arrowhead shape, a multistage shape, a screw shape, and a groove shape with a pointed tip based on the penetration direction. The method of claim 15,
The microneedle bullet is provided such that a stopper for limiting the penetration depth into the skin is foldable or unfoldable at the rear end based on the penetration direction,
The stopper of the microneedle bullet is in a folded state when loaded in the body part, and is spread out by elasticity in connection with being discharged from the body part. The method of claim 19,
A shielding film that can be torn by the penetration force of the microneedle bullet is provided at the tip of the chemical liquid guider based on the penetration direction to protect the microneedle bullet loaded in the chemical liquid guider from the outside,
The chemical liquid guider is a microneedle bullet injection device for an endoscope capable of receiving the microneedle bullet from a charging unit having the microneedle bullet.

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