KR101999536B1 - Bonescalpel for percutaneous endoscopicoperation - Google Patents

Abstract

The present invention relates to bone scalpel for percutaneous endoscopy.
The present invention includes a surgical channel inserted into the affected area through the working channel in the endoscope for hard spinal surgery having a working channel, an illumination channel, and a lens channel, the surgical blade is one or more incisions on the outer peripheral surface The groove is formed, and also has the function as an ultrasonic electrode, so that only the disk can be removed, so that there is no risk of nerve damage and the stability of the surgery is increased.

Description

Bone scalpel for percutaneous endoscopic surgery {BONESCALPEL FOR PERCUTANEOUS ENDOSCOPICOPERATION}

The present invention relates to an endoscope for hard spinal surgery, and in particular, soft tissues are not incision, only hard bones are cut, and thus the bone scalpel for ultrasound surgery is formed in the working channel of the hard spinal endoscope for cutting structure and the ultrasonic procedure By allowing the ligaments and bones to be separated quickly, the hardened ligaments and the grown bones can be removed, thereby reducing the risk of nerve damage and improving the stability of the surgical bone scalpel for percutaneous surgery.

The spinal canal is a space surrounded by the frontal vertebrae, the intervertebral disc (disc) and the posterior vertebral disc, which passes from the brain and passes through the cervical (neck) and thoracic (backbone) to the lower limbs (hips, legs, It's a nerve pathway to your feet.

Spinal canal stenosis is a symptom caused by the aging of the ligamentum lavum in the spinal canal and the increased use of the spine, causing the nerves to become compressed.

In patients with spinal stenosis, the nerves are compressed due to narrowing of the spinal canal, a passage through which nerves pass, and magnetic resonance imaging (MRI) shows that cerebrospinal fluid does not pass through the dural lining of the normal nerve inside the spinal canal. Severe spinal canal stenosis is seen.

Spinal canal stenosis is defined as the various types of stenosis of the spinal canal, neuromuscular canal, or intervertebral cavity, which may be local, segmental, or general, and the cause of this narrowing is reported to be due to bone or soft tissue. Many scholars have recently used lumbar spinal canal stenosis based on spinal canal, neuromuscular or intervertebral cavitation to involve ganglia (a bundle of nerve roots at the bottom of the spinal cord) or neuromuscular muscles, including intermittent claudication. It is defined as a disease.

In order to cure such spinal canal stenosis, various surgical methods and instruments were introduced through related literature, and clinical results were also reported.

Conventional open discectomy and microdiscectomy and transforaminal endoscopic discectomy are widely used surgical procedures for neuromyopathy caused by lumbar disc herniation.

The open surgical resection of the traditional surgical spinal surgery is to cut the skin of the affected area under general anesthesia, insert the tube into the lesioned area to remove tissue and bone, and remove the bone or ligament of the area where the nerve is pressed. .

These procedures often resulted from anesthesia or serious complications due to spinal anxiety and disc collapse. In general, spinal surgery requires a long recovery time due to relatively large incisions or ruptures in soft tissues. .

KR 10-2016-0007087 A (2016. 01. 20.) KR 10-1681451 B1 (2016. 11. 24.)

Percutaneous endoscopic lumbar discectomy (PELD) has been developed to remedy the above problems of surgical spinal surgery.

Percutaneous endoscopic disc removal is a state-of-the-art surgical technique in which a medical endoscope made for the spine is inserted in a site where spinal canal stenosis has occurred, and the disc squeezing the nerve is removed while the endoscope monitor is being treated.

Spinal endoscopy observes the surgical site during spinal surgery, and it is easy to observe whether the surgical tools work properly at the correct position by inserting other surgical tools through the working channel of the endoscope, and proceeds to local anesthesia without general anesthesia. Patients are also safe, less scars and adhesions in the surgical site, and requires a relatively short hospital stay of 3 to 4 days, it is easy to return to daily life.

As the patients' satisfaction is very high, the number of procedures has recently been the highest among spine surgery.

However, the removal of the disk, using the endoscope-driven punch and drill to remove tissue and bone, it is not easy to punch or drill to remove the ligaments directly attached to the bone, the operator's mistake There is also a risk that can damage nerves, there is a problem of low stability of the surgery. Accordingly, by removing the ligaments and bones by using a device such as specular, there was also a problem that takes a lot of surgery time.

An object of the present invention is to install the ultrasonic surgical knife in the working channel of the endoscope for hard spinal surgery as a method to supplement the problems in the conventional surgical method described above soft bones incision not only incision bone bone can be incision By providing it to the endoscope for hard spinal surgery, it is possible to quickly separate the ligaments and bones that have problems in the spine during the procedure, and to remove only the disc, the nerve damage caused by the use of punches and drills in the conventional surgical method to heal spinal canal stenosis To solve the problem, to provide a percutaneous endoscopy bone scalpel that can be performed without nerve damage.

Another object of the present invention in the process of endoscopic disc resection for hard spinal surgery, it is possible to quickly separate the ligaments and bones in the spine problem during the endoscopic disc resection procedure to remove only the disc, the procedure time without nerve damage By developing an ultrasound surgical knife to fit the endoscope so as to shorten, it provides a bone scalpel for percutaneous endoscopy that can solve the problem of delayed operation time by using Sculculus in the conventional method of treating spinal canal stenosis. I would like to.

In addition to simple disc surgery, even severe disc surgery such as artificial disc replacement surgery or spinal fusion surgery is provided with an endoscope for hard spinal surgery that allows surgery to be performed only by the spinal endoscope.

As a way to compensate for the problems of conventional disc resection, soft tissue can not be incision, only hard bone incision by inserting an ultrasonic surgical knife into the working channel of the hard spinal endoscope to separate ligaments and bones quickly With this in mind, the present invention has been completed.

Accordingly, while cutting by removing the ligaments and bones that are a problem in the spine when performing a spinal endoscopy, by developing an ultrasound surgical knife to fit the endoscope to reduce the procedure time without nerve damage, percutaneous spinal disc resection To solve the technical problem to provide a rigid spinal endoscope suitable for.

Technical features of the hard spinal endoscope for solving the technical problem intended by the present invention is a hard spinal endoscope having a working channel, an erosion channel, and a lens channel, which is inserted into the affected part through the working channel Including bone scalpel, the bone scalpel is characterized in that one or more incision grooves are formed on one side to be able to separate the ligaments and bones.

In addition, another technical feature of the hard spinal endoscope for achieving the intended purpose of the present invention is a hard spinal endoscope having a working channel, an erosion channel, and a lens channel, through the working channel to the affected part Including the bone scalpel is inserted, the bone scalpel is formed with one or more incision grooves on one side to be able to separate the ligaments and bones, characterized in that it has the function of the ultrasonic electrode.

The bone scalpel has a rectangular cross section and the tip portion is located outside the working channel, and one curved portion is formed at one side of the tip portion located outside the working channel, so that the incision groove is formed on the outer surface of the curved portion. It is characterized by.

A plurality of incision grooves extending horizontally from the incision groove formed on the outer surface of the curved portion is characterized in that it is further formed.

The bone scalpel has a rectangular cross section, and a tip end portion is positioned outside the working channel, and a semicircular protrusion is formed at the tip portion located outside the working channel, so that the cut groove is formed on the outer surface of the semicircular protrusion.

A plurality of cutting grooves extending from the cutting groove formed on the outer surface of the semi-circular projection is characterized in that it is further formed.

The bone scalpel has a rectangular cross section, the distal end of which is positioned outside the working channel, and the incision groove is formed on a surface of one side of the distal end located outside the working channel.

The bone scalpel has a rectangular cross section and the tip portion is located outside the working channel, and the tip portion located outside the working channel has a symmetrical protrusion formed to form a cross section that narrows toward the end, so that the incision groove is formed on the outer surface of the symmetrical protrusion. It is characterized in that it is formed.

A plurality of cutting grooves extending from the cutting groove formed on the outer surface of the symmetrical projection is characterized in that it is further formed.

The bone scalpel has a rectangular cross section, and a tip end portion is located outside the working channel, and a tip protrusion positioned outside the walking channel is formed with a triangular protrusion to form the cutting groove on the outer surface of the triangular protrusion.

A plurality of cutting grooves extending from the cutting groove formed on the outer surface of the cutting groove of the triangular protrusion is further formed.

According to the present invention as described above, the configuration of the endoscope used for percutaneous endoscopy is composed of a working channel, an erosion channel, a lens channel, so that the problem disk can be removed at the same time as observation. That is, the present invention can insert the ultrasonic surgical knife through the working channel of the spinal endoscope, it is possible to cut the portion near or in contact with the central nerve without damaging the nerve. In addition, because of the use of the endoscope working channel can be applied to the recently developed minimally invasive surgery can show the advanced results in the existing surgical method.

According to the present invention, the soft tissue is formed in the working channel of the endoscopic for hard spinal surgery, the ultrasonic surgical bone scalpel in which only hard bones are incised, so that ligaments and bones can be quickly separated without removing soft tissues that are difficult to incision. In addition, there is no risk of nerve damage, because only the injured disc can be removed by incision, the stability of the surgery is high, and the recovery speed of the patient can be increased.

1 is a perspective view of an endoscope for hard spinal surgery to which the present invention is applied.
Figure 2 is a rigid tube cross-sectional view of the endoscope for hard spinal surgery to which the present invention is applied.
Figure 3 is a perspective view of the endoscope for hard spinal surgery to which the present scalpel is applied according to an embodiment of the present invention.
4 is a cross-sectional view of the bone scalpel according to the embodiment of the present invention.
5 is a view illustrating a method of using an ultrasonic knife during endoscopic surgery according to an embodiment of the present invention.
6 is a view illustrating a method of using an ultrasound knife during endoscopic surgery according to another embodiment of the present invention.
7 is a perspective view of the bone scalpel according to another embodiment of the present invention.

Features and advantages of the present invention will be more clearly understood by the embodiments described by the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

Before describing an embodiment of the present invention, the application of the present invention is not limited to the details of the configuration and arrangement of the components described in the following embodiments or shown in the drawings. The present invention can be implemented and implemented in other embodiments, and can be carried out in various ways. In addition, the expressions and predicates used in the embodiments with respect to terms such as the direction of the device or element are merely used to simplify the description of the present invention and do not indicate or mean that the related device or element should simply have a specific direction. Do not. For example, terms such as "first" and "second" are used in the embodiments and claims describing the present invention, and such terms are not intended to represent or mean relative importance or intent.

In addition, the terms or words used in the specification and claims are not to be construed as being limited to the common or dictionary meanings, and the inventors should understand the technical spirit of the present invention in order to best explain the terms and concepts of the invention. It should be interpreted as being based on the meaning and concept corresponding to it.

In addition, the contents described in the description and drawings described in the present specification are related to one of the most preferred embodiments of the present invention, and do not represent all of the technical ideas of the present invention. It should be understood that there may be various equivalents and variations.

Therefore, the present invention is not limited to the embodiments presented, and equivalent scope of the technical idea described in the technical idea of the present invention and the claims to be described below by those skilled in the art to which the present invention pertains. Various modifications and changes are possible within.

Next, an embodiment of the present invention will be described.

Figure 1 is a perspective view of the endoscope for hard spinal surgery to which the present invention is applied, Figure 2 is a cross-sectional view showing a hard tube of the endoscope for hard spinal surgery to which the present invention is applied.

Referring to FIG. 1, the endoscope 1 for hard spinal surgery includes a main body 10 and a rigid tube 20 that is formed to extend in one direction from the main body 10.

The main body 10 has the instrument insertion portion 100 is inserted into the surgical instrument from the rear in the upper portion of the handle 100, the orientation connector 200 and the suction connector 300 in a symmetrical position on both sides ) Is formed to be inclined, the image device connecting portion 500 is formed in a direction parallel to the inclination angle of the handle 100, the light source connecting portion 600 is formed in the vertical direction.

As shown in FIG. 2, the inside of the rigid tube 20 connected to the main body 10 is composed of four channels.

The four channels include a working channel 210 into which an instrument is inserted, an aligning channel 310 serving as an aligning role, a suction channel 410 serving as a suction, a lens channel 510 for observing an affected part, and an optical fiber ( 700).

The working channel 210 is made by a working channel tube 220.

The working channel tube 220 is used to make a larger space than the channels to remove the problematic disk by entering a surgical instrument, for example, a forcep, a punch, and also, spinal fusion At run time, they pass through the cage to replace the removed disk.

The working tube 220 is formed of an arcuate curved portion 221 in close contact with the inner circumferential surface of the rigid tube 20 and a flat portion 222 connecting both ends of the first curved portion 132.

In addition, the lower side of the planar portion 222 is arranged such that the irrigation tube 320 and suction tube 420 and the lens tube 520 is concentrated enough to allow the surgical instrument, etc. to enter the working channel 210 Secured.

As a result, a wider range of choices of assistive devices, such as forceps and punches, as well as a large space for handling the assistive devices, make the surgery itself easier.

In addition, it becomes possible to use auxiliaries such as forceps and punches in a slightly larger size, which means that the amount of surgery that can be handled by the assisting device for a certain time is improved, and thus the operation time is shortened to help the patient recover. Given.

In particular, the tunnel shape of the working tube 320 allows insertion of the largest cage through the working channel 310 without touching the neuromuscular muscles when performing artificial disc replacement or spinal fusion.

Therefore, it is possible to proceed and complete the severe disc operation only with the hard spinal endoscope of the present invention without the need to incision the length of the lesion to reduce the burden on the operation, and to expect the rapid recovery speed aimed at the original minimally invasive surgery do.

The association channel 310 is made by an association tube 320.

The Irrigation tube 320 is installed on one side of the lens tube 520 at the bottom of the working tube 220, is connected to the Irrigation Equipment through the Irrigation Connector 300, the procedure to ensure the surgical field of view Supply the saline solution to wash the affected area.

The suction channel 410 is formed by the suction tube 420.

The suction tube 420 is installed at one side of the lens tube 520 at the bottom of the working tube channel 220, is connected to the suction equipment through the section connecting pipe 400, and around the affected area by the surgical instrument during the procedure The resulting cutting deposits are discharged to the outside.

The illumination tube 320 and the suction tube 420 are disposed symmetrically on both sides of the lens tube 520 at the bottom of the working tube 220.

The lens channel 510 is formed by the lens tube 520.

The lens tube 520 is an optical window connected to the image pickup device through the image device connecting part 500 for observing the affected part, and one lens 530 is installed at the front end thereof.

The lens tube 520 is disposed at the farthest distance between the planar portion 222 of the working tube 220 and the inner surface of the rigid tube 20, and is formed smaller in size than the lens tube 520. The gating tube 320 and the suction tube 420 are disposed on both sides of the lens tube 520, thereby extending the size of the working channel 210 formed by the working tube 220 to an optimal size.

In addition, the Irrigation Tube 320 and the Suction Tube 420 may be easily connected to the Irrigation Connector 300 and the Suction Connector 400 disposed on the left and right sides of the main body 10.

The optical fiber 700 is disposed in the remaining space other than the space occupied by the channels, is connected to the light source connector 600, and irradiates the illumination light for observing the affected part.

The Irrigation tube 320, the suction tube 420 and the lens tube 520 are in close contact with each other while being in contact with the lower inner circumferential surface of the rigid tube 20.

3 is a perspective view of an endoscope for hard spinal surgery to which the present scalpel is applied according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view of the present scalpel according to an embodiment of the present invention.

As shown in Figure 3, the endoscope for hard spinal surgery according to the present invention is a bone scalpel 80 is formed in the affected part through the working channel (210).

The bone scalpel 80 is formed to have a rectangular cross section, and at least one incision groove 801 is formed on the outer surface of the curved portion 800 at the tip.

The tip of the cutting groove 801 protrudes outward from the working channel 210, and the other end thereof is fixed to the instrument insertion part 200.

The curved portion 800 is formed so that the corner portion formed by the front and the lower surface at the front end of the scalpel 80 is curved.

The incision groove 801 serves to separate or detach surrounding tissue adjacent to bone, muscle, adipose tissue, ligament or nerve, and the tip should be rounded without being too sharp in order to effectively peel without damaging the bone and muscle. The cross section is preferably formed flat.

In addition, the incision groove 801 may be formed to selectively further extend to the upper surface 802 and the lower surface 803 forming a rectangular cross section. In addition, the upper surface 802 and the lower surface 803 may be formed to extend.

The cutting groove 801 is to be able to cut the disk to be formed in the curved portion 800 to be removed.

This bone scalpel 80 has the function of an ultrasonic electrode to enable the ultrasound procedure in percutaneous endoscopic surgery.

5 is a view illustrating a method using a bone scalpel during spinal endoscopy according to an embodiment of the present invention, Figure 6 illustrates a method using a bone scalpel during spinal endoscopy according to another embodiment of the present invention The figure is shown.

Referring to this drawing, the percutaneous spinal endoscopic procedure using the present invention forms a fine incision hole of a predetermined size in the skin near the affected part, and then inserts a hard tube 20 into the incision hole to close the affected part, and then the optical fiber ( Using the illumination light and the lens 530 irradiated from 700 it is possible to monitor the surgical scene around the affected area using the scalpel 80 seen from an imaging device (not shown).

Percutaneous spinal endoscopic treatment according to the present invention is to contact the disk to be removed to remove the incision groove 801 formed in the bone scalpel 80, the ligament and the ligament through the repeated friction and the ultrasound applied to the bone scalpel 80 Only the disk that needs to be removed without nerve damage will be removed.

At this time, the pulverized product is discharged to the outside through the endoscope by the operation of the operation through the erosion channel 310 and the suction of the suction channel 410.

The present invention, such as without making unnecessary incisions to the skin or muscles, by inserting the ultrasonic bone scalpel into the space secured through the working channel of the endoscopic endoscope to quickly separate the ligaments and bones having problems in the spine and remove only the disc. Therefore, it is possible to perform the procedure in close proximity or contact with the central nerve without damaging the nerve, and can show an advanced result in the minimally invasive surgical method.

Those skilled in the art will understand that the present invention can be implemented in a modified form without departing from the essential features. Accordingly, there may be embodiments that are variously changed from the above embodiments by those skilled in the art.

For example, in the above embodiment, the cutting groove 801 of the scalpel 80 has been described as being formed in the curved portion 800 which is formed to bend the corner portion formed by the front and lower surfaces of the tip, but the tip portion It may be formed in the symmetrical protrusion formed.

The symmetrical protrusions may be formed in a semicircle, a triangle, or the like.

Figure 7 shows a perspective view of the bone scalpel according to another embodiment of the present invention.

Referring to FIG. 7A, the bone scalpel 81 has a rectangular cross section, and a tip portion thereof is located outside the working channel 210, and a semicircular protrusion 810 is disposed at the tip portion outside the working channel 210. Is formed, the cut groove 811 is formed on the outer surface of the semi-circular projection 810.

In addition, the cutting groove 811 formed on the outer surface of the semi-circular protrusion 810 may be further formed to be continuous in a predetermined range on the upper surface 812 and the lower surface 813 of the bone scalpel 81.

Referring to FIG. 7B, the bone scalpel 82 has a rectangular cross section, and a tip end portion thereof is located outside the working channel 210, and a tip portion positioned outside the walking channel 210 narrows toward an end portion thereof. A triangular protrusion 820 is formed to form a cutout groove 821 on the outer surface of the triangular protrusion 820.

In addition, the cutting groove 822 formed on the outer surface of the sensory protrusion 821 may be further formed to be continuous in a predetermined range on the upper surface 822 and the lower surface 823 of the bone scalpel 82.

Referring to FIG. 7C, the bone scalpel 83 has a rectangular cross section, and a tip end thereof is located outside the working channel 210, and is cut on a surface of one side of the tip portion located outside the working channel 210. The groove 831 is formed.

The percutaneous endoscopic procedure using the bone scalpels 81, 82, and 83 is the same as the above-described embodiment.

So far I looked at the center of the preferred embodiment for the present invention.

The embodiments described in the specification and the configuration shown in the drawings are related to the most preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, various equivalents and modified examples that can replace them are It should be understood that there may be.

Therefore, the present invention is not limited to the embodiments presented, and those skilled in the art to which the present invention pertains without departing from the spirit and scope of the technical idea described in the following claims. There may be an embodiment in which various modifications and changes are possible.

1: Endoscopic for hard spine operation 10: Main body
20: rigid tube 80, 81, 82, 83: Bonscalpel
800: curved portion 801: incision groove
802: upper surface 803: lower surface
810: semi-circular protrusion 811: incision groove
812: upper surface 813: lower surface
820: triangular protrusion 820: incision groove
822: upper surface 823: lower surface
200: instrument insertion unit 210: working channel
220: working tube 221: curved portion
222: plane portion 300: the connector connector
310: Irrigation Channel 320: Irrigation Tube
400: suction connector 410: suction channel
420: suction tube 500: video device connection
510: lens channel 520: lens tube
600: light source connection part 700: optical fiber

Claims (9)

In the device for hard spinal surgery,
main body; And
A rigid tube extending from one side of the main body and forming a plurality of channels therein;
Including,
The plurality of channels formed inside the rigid tube
It further includes a working channel into which the bone scalpel is inserted, an irrigation channel for spraying washing water, a suction channel for sucking foreign substances, a lens channel for observing the affected part, and an optical fiber for illuminating illumination,
The bone scalpel
Bonscalpel for percutaneous endoscopy, characterized in that one or more incision grooves and ultrasonic electrodes are formed at the tip to separate the ligaments and bones.
delete The method of claim 1,
The bone scalpel,
It has a rectangular cross section and the tip is located outside of the working channel,
One curved portion that is curved is formed at one side of the tip portion located outside the working channel,
Including the cutting groove is formed on the outer surface of the curved portion,
Bonscalpel for percutaneous endoscopy.
The method of claim 1,
The bone scalpel,
It has a rectangular cross section and the tip is located outside the working channel,
A tip portion located outside the working channel includes a semi-circular protrusion is formed, the cutting groove is formed on the outer surface of the semi-circular protrusion,
Bonscalpel for percutaneous endoscopy.
The method of claim 1,
The bone scalpel has a rectangular cross section and the tip is positioned outside the working channel,
The front end portion which is located outside the working channel is formed with a symmetrical protrusion forming a cross section narrowed toward the end,
Including the cutting groove is formed on the outer surface of the symmetrical projection,
Bonscalpel for percutaneous endoscopy.
The method of claim 1,
The bone scalpel has a rectangular cross section and the tip is positioned outside the working channel,
Including the cutting groove is formed on the surface of one side of the front end portion located outside the working channel,
Bonscalpel for percutaneous endoscopy.
The method of claim 3, wherein
Further comprising a plurality of incision grooves extending horizontally from the incision groove formed on the outer surface of the curved portion,
Bonscalpel for percutaneous endoscopy.
The method of claim 4, wherein
Further comprising a plurality of cutting grooves extending from the cutting groove formed on the outer surface of the semi-circular projection,
Bonscalpel for percutaneous endoscopy.
The method of claim 6,
Further comprising a plurality of incision grooves extending from the incision grooves formed on the outer surface of the symmetrical projection,
Bonscalpel for percutaneous endoscopy.

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