KR20220084875A - Biportal spine endoscope Sheath - Google Patents

Abstract

The present invention is a body cavity insertion induction device comprising a rigid pedicle, a rigid arthroscopic body, or an endoscope body, and a rigid pedicle instrument coupled thereto, wherein a tube elongated to be inserted into the body is provided at the front of the rigid pedicle instrument. Provided is a body cavity insertion guide mechanism coupled to a pedicle instrument.

Description

Body cavity insertion guidance device {Biportal spine endoscope Sheath}

The present invention relates to a body cavity insertion induction device. More specifically, the present invention relates to a body cavity insertion induction device, in which a tube to be inserted into the body cavity insertion guide device is manufactured in a separate type so that the tube can be replaced quickly and conveniently.

As one of the recent spinal surgery methods. Biportal endoscopic spinal surgery is attracting attention.

As shown in FIG. 1, this surgery is performed by approaching a body cavity insertion guide device 1 ′ equipped with an endoscope and a surgical instrument 2 ′ such as a punch through different incision sites. It is recognized as a minimally invasive surgical method in the spine field because of its advantages of securing a field of view and accessibility of surgical instruments.

In order to minimize body incision, for example, two 5mm-sized holes are drilled into one side and a high-definition endoscope is inserted into the other side and surgical instruments are inserted to remove the cause of pain. With minimal incision, bleeding is minimal, scarring after surgery is small, and recovery is quick. Bidirectional endoscopic surgery can be applied not only to spinal discs, but also to stenosis and osteosynthesis. Osteotomy has the advantage of being able to operate without blood transfusion by removing and expanding only the necessary lesions with this surgical method after vertebral resection.

In Patent No. 10-1681451 related to a rigid spinal endoscope, the applicant has a rigid spinal endoscope having a rigid tube having a lens connected to an imaging device for observing an affected part, a cleaning channel, and a working channel for inserting a surgical instrument. has been proposed. However, this patent does not consider bi-directional spinal surgery despite the advantage of expanding the area of the working channel.

Patent No. 10-1881226 relating to “endoscopic catheter assembly” has a structure for attaching and detaching an endoscope handle 400 ′ equipped with a lens tube 300 ′ to the catheter body 100 ′, as shown in FIG. 2 . is proposing However, the prior art including this patent employs an integrated structure in which the lens tube 300' is not separated from the endoscope handle 400'. The reason is that the end of the lens tube 300' disposed around it must be securely sealed to the endoscope handle 400' so that the water discharged from the cleaning channel does not leak to the outside. However, in this case, it is difficult to exchange or repair the lens tube, and in order to use a lens tube of a different specification, there is a disadvantage that a different endoscope handle 400 ′ must be used. In particular, if the tip of the lens tube is worn or damaged due to repeated surgery, only the lens tube cannot be exchanged, and another endoscope handle 400 ′ must be purchased, resulting in economic loss.

The present invention has been devised in consideration of the above circumstances.

Therefore, an object of the present invention is to provide a body cavity insertion induction device capable of simply and reliably replacing a tube during spinal surgery, particularly during bidirectional spinal surgery, as well as before and after the procedure.

In order to achieve the above object, the present invention provides a body cavity insertion induction device comprising a rigid spinaloscope, a rigid arthroscopic body, or an endoscope body, and a rigid pedicle instrument coupled thereto, wherein the rigid pedicle instrument is inserted into the body in front of the rigid pedicle instrument. A tube elongated as elongated as possible is coupled to the rigid pedicle instrument.

The tube includes a long columnar body, which is a barrel constituting the body, a flange having a larger diameter than the body is formed at the rear end of the tube, and a sealing ring may be mounted adjacent to the flange.

A packing assembly is accommodated in the front of the housing of the rigid pedicle instrument to accommodate the rear end structure of the tube, the packing assembly including a circular hollow body and an inlet portion extending upwardly from the rim of the body, the inlet portion having a circular or It is possible to form a first coupling portion made of an annular circular wall, and a second coupling portion having an inner surface of a rectangular wall shape, which is added to cover between two spaced apart points of the first coupling portion.

The flange of the tube consists of a first curved portion having a circular or annular outer surface to correspond to the shape of the first and second coupling portions, and a second straight portion connecting both ends of the first curved portion and having an outer surface of a flat quadrangle, The tube and the rigid pedicle instrument can be separably coupled by closely pressing each of the first curved portion and the first coupling portion and the second straight portion and the second coupling portion.

An upper surface to which the flange and the first and second coupling portions are coupled forms a flat face-to-face structure, and the sealing ring may be mounted on a boundary portion between the two members of the upper surface.

The front end of the tube may be formed to be vertical or inclined with respect to a horizontal line to secure a viewing angle of the lens endoscope.

The housing for accommodating the rear end structure of the tube includes a circular hollow body and an inlet portion extending upward from the rim of the body, the inlet portion is formed in a circular shape, and the flange of the tube has a complementary circular shape so as to be fastened with the inlet portion. can be formed

According to the present invention, it is possible to quickly and conveniently replace a tube having various tip angles in spinal surgery, particularly in bidirectional spine surgery, and a tube whose tip is worn, damaged or deformed can be replaced with another tube without the need to replace the entire rigid pedicle instrument. It has the effect of being able to be replaced quickly and easily.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing a bidirectional spinal endoscopic surgery method;
2 is a perspective view of the catheter assembly of the prior invention;
Figure 3 is an overall side view before coupling of the body cavity insertion induction device of the present invention;
Figure 4 is an overall side view after the coupling of the body cavity insertion induction mechanism of the present invention;
5 is an overall side view of a tube of the present invention;
6 is a view showing several embodiments of the tube tip of the present invention;
Figure 7 is an enlarged perspective view for showing the coupling structure of the tube of the present invention;
Figure 8 is a side view showing after the tube of the present invention is combined; and
9 is a perspective view after the tube of the present invention and the rigid pedicle instrument are combined.

Each embodiment according to the present invention is merely an example for helping understanding of the present invention, and the present invention is not limited to these embodiments. The present invention may be composed of a combination of at least any one of individual components and individual functions included in each embodiment.

Although the present invention is mainly described with a rigid myeloscope, the present invention can also be applied to rigid arthroscopic procedures and surgeries. In the following description, “rigid pedicles” or “hard pedicles”, despite the wording, are exemplary and do not limit the present invention to spinal procedures or surgeries. should be noted.

3 is an overall side view of the body cavity insertion guide mechanism 1 of the present invention before coupling. The body cavity insertion guide mechanism (1) includes a body (2) and a rigid pedicle device (4) coupled thereto. An elongated tube 10, that is, a lens tube, is mounted in front of the rigid pedicle instrument 4 . A feature of the present invention lies in the structure of the portion (“A”) shown in FIG. 3 .

A light is connected to the handle 2a of the lower portion of the rigid pedicle instrument 4, and an image processor is connected to one end 4a.

4 is an overall side view of the body cavity insertion guide mechanism 1 of the present invention after coupling. The tube (10) of the rigid pedicle instrument (4) is inserted into the body (2) so that the lens mounted in the tube is sufficiently exposed to the open end of the body (2).

5 is an overall side view of a tube 10 of the present invention. The tube 10 includes an elongated body 12 , which is a barrel constituting the body. A first tip portion 16 for accommodating a fiber optic channel connected to a lens is formed at the tip of the column 12 . The optical fiber channel is installed over the entire length of the tube 10 and is connected to an image analysis device (not shown).

As shown in FIG. 6 , the front cross-section of the front end may be inclined to form, for example, 0°, 12° and 30° with a vertical line. If a lens is fitted according to the shape of this cross-section, the surgical or affected area can be viewed from a different angle or a wide field of view. When the tube 10 having a different cross-sectional shape is provided for each type, according to the present invention, the tube 10 can be easily replaced and the operation can be performed more conveniently.

A flange 20 having a larger diameter than the body 12 is formed at the rear end 18 of the tube 10 , and an O-ring 22 for sealing is mounted on the flange 20 .

7 is an enlarged perspective view of a part (“A”) for showing the coupling structure of the tube 10 of the present invention, and shows a state before coupling. A housing 42 is formed to accommodate the structure of the rear end 18 of the tube 10 described above.

A plurality of rows of ribs for accommodating elastic deformation are formed on the outer surface of the inlet portion 46 . The inlet part 46 has a first coupling part 46b made of a circular or annular circular wall, and a first coupling part 46b having a rectangular wall shape with an inner surface added to cover between two spaced points of the first coupling part 46b. Two coupling portions 46a are formed. The space formed by the first coupling portion 46b and the second coupling portion 46a is formed to a size through which the rear end 18 of the tube 10 sufficiently passes.

The flange 20 of the tube 10 of the present invention has a first curved surface portion 20b having a circular or annular outer surface to correspond to the shape of the first and second coupling portions 46a and 46b, and a first curved portion It connects both ends of (20b) and consists of a second straight portion (20a) whose outer surface is a flat rectangular wall. The outer surface of the first curved portion 20b has the same or a slightly larger cross section as the inner surface of the first coupling portion 46b, and the outer surface of the second straight portion 20a is the inner surface of the second coupling portion 46a and They are manufactured to have the same or slightly larger cross-section. Therefore, when the rear end 18 of the tube 10 is forcibly pushed into the packing assembly 50, the flange 20 pushes the first and second coupling parts 46a and 46b to the outside while being completely in close contact with each other. The members are substantially hermetically coupled.

9 is a perspective view after the tube 10 is coupled. The flange 20 and the first and second coupling portions 46a and 46b are completely in close contact and their upper surface forms a flat surface-one structure. And, since the O-ring 22 is attached to the boundary part of this upper surface, a reliable fastening structure can be provided.

In addition, the tube 10 is arbitrarily pushed into the packing assembly 50 and then the tube 10 is forcibly rotated at the point where it is caught so that the first curved portion 20b is in close contact with the first coupling portion 46b, and the second Since it is enough to combine the two members so that the straight part 20a is in close contact with the second coupling part 46a, assembly and separation operations are simple and reliable.

8 is a side view showing after the tube 10 of the present invention is coupled. After combining the two members, it is preferable to cover the cap or stopper 60 from the front of the tube 10 to protect the coupling site from external force or deformation.

The above has been described on the premise that the flange 20 is of a complex shape, but for example, all of the flanges 20 of the tube 10 are curved or circular, and the inlet portion 46 is also curved in correspondence thereto. Or it can be manufactured in a circular shape. In addition, a through hole may be formed in the outer surface of the flange 20 to firmly couple the two members, and a pin may be inserted to fix it.

In this regard, the above-described embodiments are merely illustrative of the technical idea of the present invention. For example, the present invention can be applied not only to a rigid myeloscope, but also to a rigid arthroscopic procedure or surgery.

Various modifications and variations of this embodiment are possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains.

Claims (7)

A body cavity insertion induction device comprising a rigid pedicle, a rigid arthroscopic body, or an endoscope body, and a rigid pedicle instrument coupled thereto, wherein a tube elongated to be inserted into the body is provided at the front of the rigid pedicle instrument. coupled to the body cavity insertion guidance device. The method of claim 1,
The tube includes a long column-shaped body, which is a barrel constituting the body, a flange having a larger diameter than the body is formed at the rear end of the tube, and a sealing ring is mounted adjacent to the flange. 3. The method of claim 2,
A packing assembly is accommodated in the front of the housing of the rigid pedicle instrument to accommodate the rear end structure of the tube, the packing assembly including a circular hollow body and an inlet portion extending upwardly from the rim of the body, the inlet portion having a circular or A body cavity insertion induction device in which a first coupling part made of an annular circular wall and a second coupling part having a rectangular wall shape on the inner surface are added to cover between two spaced apart points of the first coupling part. 4. The method of claim 3,
The flange of the tube consists of a first curved portion having a circular or annular outer surface to correspond to the shape of the first and second coupling portions, and a second straight portion connecting both ends of the first curved portion and having an outer surface of a flat quadrangle, A body cavity insertion induction device, in which the tube and the rigid pedicle instrument are separably coupled by each of the first curved portion and the first engaging portion and the second straight portion and the second engaging portion being closely compressed. 5. The method of claim 4,
An upper surface to which the flange and the first and second coupling portions are coupled form a flat, face-to-face structure, and the sealing ring is mounted on a boundary portion between two members of the upper surface. 3. The method of claim 2,
The distal end of the tube is formed to be perpendicular or inclined with respect to the horizontal line to secure the viewing angle of the lens endoscope, body cavity insertion induction mechanism. 3. The method of claim 2
A housing is formed to accommodate the rear end structure of the tube, the housing including a circular hollow body and an inlet portion extending upward from the rim of the body, the inlet portion is formed in a circular shape, and the flange of the tube is engaged with the inlet portion A body cavity insertion induction device formed in a complementary circular shape as much as possible.

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