KR20120038174A - Eletrosurgical electrode - Google Patents

Abstract

PURPOSE: An electrode body for electrical surgical operation is provided to easily cut a hardened tissue by forming a blade part capable of easily piercing the hardened tissue on the end of an electrode part. CONSTITUTION: A first electrode(200) having a blade part(220) is detachably combined to one end of a main body(100) of a shaft shape. A section of the main body in which the first electrode is combined is a flexible body(110) having a direction adjustment part which adjusts direction of the one end of the main body. A second electrode is located in the flexible body of the main body by being separated from the first electrode. An insulation part(400) is arranged in an interval between the first electrode and the second electrode. The direction adjustment part comprises a first direction adjustment wire and a second direction adjustment wire. The first direction adjustment wire reflects the one end of the main body to a first direction and the second direction adjustment wire reflects the one end of the main body to a second direction.

Description

Electrode body for electrosurgical operation {ELETROSURGICAL ELECTRODE}

The present invention relates to an electrosurgical electrode body used to locally remove a tissue of a specific part of the body using a radiation frequency, etc. More specifically, it is possible to easily ablate a body tissue such as a solid fiber The present invention relates to an electrode assembly for an electrosurgical operation, in which an electrode body having a blade portion therein is inserted into a portion of tissue to be removed and then the direction of the electrode body is controlled to easily remove tissue at a desired position.

In general, spinal diseases are the most common diseases, because a person's waist is damaged little by little, bad posture, extreme shock, excessive exercise, etc. in everyday life.

In addition to spinal disc herniation, commonly known as the lumbar disc, spinal canal stenosis is a cause of back pain.

The spine is made up of 24 vertebrae and bones, which act as a buffer between the bones, and inside the spine there is a triangular space called the spinal canal, where nerve bundles pass.

Spinal canal stenosis is a disease caused by thickened ligaments or vertebral bones that press on a bundle of nerves. This compression can cause symptoms of numbness in the hips or legs.

The main cause of spinal canal stenosis is the yellow ligament osteoporosis, which has thickened and calcified yellow ligaments that press on the spinal nerves to connect the spinal condyles that surround the spinal nerves.

Surgical method of relieving thickened yellow ligaments to relieve nerve pressure, which can eliminate back pain caused by spinal canal stenosis, and insert the electrode body and apply the radiation frequency to form tissue around the electrode body using the radiation frequency The high-energy electric field removes adjacent tissue in a gaseous state separated by negatively charged electrons and positively charged ions.

A method of removing or removing human tissue and removing wastes from blood vessels using a radiation frequency electrode body having a frequency range of 100 to 20,000 kHz is disclosed in US Pat. No. 6,554,827 B2.

Conventional radiation frequency electrode body has a problem that the access portion in the body is limited by reaching only the insertion position and the site in the straight position in the form of a straight line, the position of the yellow ligament as shown in FIG. Due to the presence of nerves in the spinal region, the position at which the radiofrequency electrode body can be inserted is very limited.

On the other hand, there is also a form in which the electrode body having the end portion bent in a predetermined curvature before insertion from the outside through the induction pipe to reach a portion that is difficult to approach straight by using a restoring force. However, since the bent shape of the part which once entered into the body is restored as predetermined, there is a danger due to proficiency or guesswork, and it is difficult to be widely applied.

In addition, even if the end of the guide tube is bent in advance, there is a problem that it is difficult to remove the tissue at the radiation frequency by accurately placing the electrode on the yellow ligament of the narrowed spinal canal region having various positions for each individual.

Furthermore, since the yellow ligaments needing to be cured have a relatively hard tissue, it is difficult to obtain an effective treatment effect with a general radiation frequency electrode.

Meanwhile, in removing the yellow ligament, the adjacent spinal canal is the place where the nerve fibers are located, and it is very important not to damage the nerve tissue during the procedure because serious pain and disorder can be caused if the nerve tissue is accidentally removed. It is not easy to know whether there is a risk of damage, such as cutting off the adjacent nerve tissue when the power supply of the electrosurgical operation device.

SUMMARY OF THE INVENTION The present invention has been made in view of the foregoing, and provides an electrode assembly for an electrosurgical procedure in which the electrode portion of the electrode assembly for an electrosurgical procedure is easily approached to a treatment site, and safely and effectively removes hardened body tissue. There is a purpose.

Electrode for electrosurgical operation according to the present invention for achieving the above technical problem is coupled to the shaft-shaped main body 100 and one end of the main body 100, the first electrode formed with a blade portion 220 ( And a portion in which the first electrode 200 is coupled in the main body 100 includes a direction adjusting unit 500 for adjusting a direction of one end of the main body 100. It is characterized by that.

In addition, the second electrode 300 provided in the flexible body 110 of the main body 100 is spaced apart from the first electrode 200 and the spaced apart between the first electrode 200 and the second electrode 300. It may further include an insulation portion 400 disposed in.

In addition, the direction adjusting unit 500 is the first direction control wire 510 is connected to bend one end of the main body 100 in the first direction and the first spaced apart from the first direction It may be characterized in that it comprises a second direction control wire 520 connected to be refracted in two directions.

Further, the power control unit connected to the direction control unit 500 to control the direction of one end of the main body 100 and the power intermittent to control the application of power to the first electrode 200. It may be characterized in that it further comprises an operation unit 600 is provided with 620.

In addition, the power intermittent unit 620 may perform a detection mode by generating the power of the power applied to the first electrode 200 to 10 Watt or less.

In addition, the power intermittent part 620 may be composed of a first power intermittent part 621 and a second power intermittent part 622, and the first power intermittent part 621 may supply power of 250 watt or more to the first power intermittent part 620. Application to the electrode 200 is intermittent, and the second power intermittent part 622 is characterized in that to apply a power of 10 watts or less to the first electrode 200.

The electrode body for an electrosurgical operation according to the present invention made as described above is advantageous for cutting the cured tissue, including the blade portion of the end of the electrode portion, and can easily close the electrode portion to the procedure position with a flexible body capable of direction control. have.

In addition, since the electrode having the blade portion has a detachable structure, it is possible to perform an effective treatment by applying an electrode having a blade portion suitable for the position of the treatment site or the characteristics of the tissue.

Furthermore, in combination with an operation unit including a power intermittent for intermitting the power of the electrode body to provide convenience in detecting the procedure and proximity of the nerve tissue, and in conjunction with the power of the power safely target tissue without damaging the nerve tissue Can be removed.

1 is a schematic representation of the structure of the spine and spinal canal stenosis;
2 is a view schematically showing an electrode body for an electrosurgical operation according to an embodiment of the present invention.
3 is a view schematically showing an electrode body for an electrosurgical operation according to another embodiment of the present invention.
4 is a view schematically showing a state including an electrode unit and an operation unit in the electrode body for an electrosurgical operation according to an embodiment of the present invention.
5 is a view schematically showing the use of the electrode body for an electrosurgical operation having an internal lumen according to an embodiment of the present invention.
6 is a view schematically showing the use of an external device coupled to the connecting lumen of the electrode body for an electrosurgical operation according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent by reference to the embodiments described in detail below with reference to the accompanying drawings. Hereinafter, an electrode assembly for an electrosurgical operation having an internal lumen according to an embodiment of the present invention will be described with reference to the accompanying drawings.

Referring to FIG. 2, an electrode assembly for an electrosurgical operation according to an embodiment of the present invention may include a first electrode having a main body 100 having a shaft shape and a blade portion 220 provided at one end of the main body 100. And a portion in which the first electrode 200 is disposed in the main body 100 includes a direction adjusting unit 500 for adjusting a direction of one end of the main body 100. It is characterized by that.

The main body 100 is generally composed of a rigid shaft made of steel having rigidity, and is configured to be easily inserted into the body. One end of the main body 100 provided with the first electrode 200 is in direct contact with the body. It is composed of a flexible body 110 capable of adjusting the direction when inserted into the body as a part.

The first electrode 200 is formed of a blade portion 220 having a relatively sharp blade as a metal material, the blade portion 220 may have a variety of shapes, such as an ax or a window shape of the blade portion 220 The sharp part makes it easy to cut or insert body tissues.

In addition, the first electrode 200 may have a structure that is detachably coupled to the main body 100, and may be applied by replacing electrodes having various shapes according to the treatment site and the treatment purpose.

In addition, when the first electrode 200 is connected to the main body 100, power may be supplied through an electrical connection unit such as the first electrode line 210 through the main body 100, and generally, the first electrode line ( It has a contact portion in contact with 210.

The second electrode 300 is generally spaced apart from the first electrode 200 may be provided in a cylindrical shape in the main body 100, may have a variety of shapes according to the purpose and effect of the procedure.

Referring to FIG. 3, a second electrode 300 may be further provided at a position spaced apart from the first electrode 200 in the flexible body 110, which is one end of the main body 100. An insulating part 400 is disposed between the 200 and the second electrode 300 to electrically insulate each other within the main body.

The first electrode 200 and the second electrode 300 is a tip-shaped portion to which power is supplied, and electrical surgeries such as ablation of tissues by transferring electrical energy in direct contact with body tissues are performed. Element.

When the radiation frequency is applied as above, one electrode acts as an active electrode and the other acts as a passive electrode, and generates plasma through body tissue in contact with the tissue. The removal allows for a more efficient and prognosis surgical procedure.

 The insulating part 400 is not particularly limited as long as it is electrically nonconductive and has heat resistance, and is preferably at least one member selected from the group consisting of ceramic, silicon, fluorine resin, and heat shrinkable polymer.

The material of the first electrode 200 and the second electrode 300 is generally a metal material and is not particularly limited as long as the radiation frequency current can flow, but may be made of stainless steel, general alloy steel, titanium steel, and shape memory alloy. As shown in FIG. 3, the first electrode line 210 and the second electrode line 310 are connected to each other to receive power.

The flexible body 110 is provided in a range including all of the first electrode 200, the second electrode 300, and the insulating part 400 provided at one end of the main body 100 so that the electrode part may be precisely positioned at the surgical site. It is desirable to be able to position, it can be provided in a variety of materials and configurations in a range that one end can be bent.

For example, the flexible body 110 may be formed of a bending material having a predetermined elasticity of the shaft itself as a main body, or the shaft may be formed of several joints and bent at a predetermined curvature, and generally has silicone having heat resistance. Or a synthetic resin material such as a heat shrink polymer.

Since the flexible body 110 is inserted into a surgical part and moves inside the body, it is preferable that the flexible body 110 is made of an elastic material smoothly connected to the main body 100 in a shaft form rather than a structure having a joint and has a smooth surface.

Therefore, the flexible body 110 has a configuration such as a tube made of a polymer compound and forms one end of the main body 100 to connect the first electrode 200, the second electrode 300, and the insulating part 400. Once included, the ends become flexible parts.

Referring to FIG. 3, the flexible body 110 includes a direction adjusting part 500 for adjusting the direction of one end of the main body 100, and the direction adjusting part 500 has one end of the main body 100. It can be configured by various means to bend.

The direction control unit 500 is generally connected to one end of the main body 100 and coupled to the inside of the main body 100 is provided integrally provided with a first direction control wire 510 and the second direction control wire 520 It can be configured to include two or more direction control wires 510, 520, the direction control wires 510, 520 are spaced apart from each other on both sides with respect to the longitudinal direction of the main body 100. It is preferable to be.

Accordingly, when one of the first direction control wire 510 or the second direction control wire 520 is pulled, one end of the main body 100 is refracted in the direction of the main body to which the drawn direction control wire is coupled to insert the electrode body. The electrode portion at the end of the main body of the treatment apparatus may be positioned at the treatment portion which is not positioned in a straight line with the direction.

Referring to FIG. 4, the direction controller 610 may be coupled to the other end of the main body 100 to be connected to the direction control unit 500 of the main body 100 to control the direction of one end of the main body 100. It may further include a manipulation unit 600 is provided.

The operation unit 600 serves as a handle for operating the main body in combination with the main body 100, and is connected to the direction control unit 500 of the main body to control one end of the main body 610. ) Is provided to control the movement of the main body (100).

In addition, the operation unit 600 may further include a power intermittent part 620 for intermittently applying power to the first electrode 200 and the second electrode 300 disposed in the main body 100. The operation of the power intermittent part 620 may interrupt the power applied to the electrode body during the procedure.

The power intermittent part 620 may intermittently intercept the power of the first electrode 200 and apply a fine power of 5 W or less instead of a high voltage of 250 W or more that is applied during the ablation procedure.

Therefore, when the operation of the power intermittent part 620 does not occur, such as excision of the surgical site occurs, only the effect of giving a minute electrical stimulation occurs, and if there is a sensitive area such as nerve tissue near the treatment site without damage Can respond, and so-called detection is implemented.

At this time, the application of the power of the strength required for the procedure may be interrupted by a power interrupter such as a power switch or a pedal separately from the operation unit 600, the power interrupter 620 of the operation unit 600 is a detection mode It mainly performs the function of intermittent application of minute power used in the.

In addition, the power interruption unit 620 may include a first power interruption unit 621 and a second power interruption unit 622, and may be provided in plural. can do.

The first power intermittent part 621 intercepts the application of 250 watts or more of power to the first electrode 200, and the second power intermittent 622 applies the power of 10 watts or less to the first electrode 200. Intermittent application to the system can implement the operation mode and detection mode respectively.

That is, when the first power intermittent part 621 is applied, power is applied to the intensity of ablation of body tissue, and the procedure is performed. When the second power intermittent part 622 is applied, power of minute intensity is applied. Only neural tissues can be identified as adjacent.

Hereinafter, a method of using the electrode body for an electrosurgical operation having an internal lumen according to an embodiment of the present invention will be described in detail.

Referring to FIG. 5, the main body 100 may have a structure in which the first electrode 200 is detachably connected and generally has a screw thread formed therein, and may be coupled in various other forms.

The first electrode 200 may have various shapes according to the treatment site and the purpose of the treatment, and in order to remove relatively hard tissue such as yellow ligaments, it is preferable to have an electrode shape having sharp edges.

In addition, since the most suitable electrode shape can be selected and mounted on the main body 100 according to the characteristics and shapes of body tissues to be removed other than the yellow ligaments, there is an advantage in that the treatment effect can be increased and the procedure time can be shortened.

Referring to FIG. 6, it may be understood that the main body 100 is inserted into a treatment site to manipulate the direction control unit 610 of the flexible body 110 to reach a correct procedure position.

In addition, the blade portion 220 is formed at the end of the first electrode 200 to facilitate the removal of the yellow ligament, and for the safe procedure, the first electrode 200 is supplied with fine power through the power intermittent portion 620. It is preferable to apply to the tissue to confirm the proximity of the tissue after the tissue resection procedure.

That is, when a minute power is applied to the first electrode 200, when a sensitive area such as neural tissue is in close proximity, the patient directly feels pain or a reaction occurs at the treatment site, thereby confirming the presence of neural tissue.

At this time, if the power of the strength used in the procedure is applied, there is a risk of serious damage, such as the nerve tissue is excised, but only the presence of the nerve tissue safely because of applying a fine power.

When the procedure confirms that the neural tissue is present near the electrode body, the electrode body is changed and the microscopic power is applied again through the power intermittent part 620 to check the neural tissue and examine the patient's response. After confirming that the electrodes are not in proximity, target tissues such as yellow ligaments can be removed.

Furthermore, as described above, the power interruption unit 620 may be suitably provided to perform a function of detecting the presence of neural tissue, and when the power is applied by the power interruption unit 620, power of a minute intensity It is applied to prevent accidental nerve tissue damage.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, will be.

Therefore, it should be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims, And all changes or modifications derived from equivalents thereof should be construed as being included within the scope of the present invention.

100; Main body 110; Flexible body
200; First electrode 210; First electrode wire
220; Blade part 300; Second electrode
310; Second electrode line 400; Insulation
500; Direction controller 510; First direction wire
520; Second direction control wire 600; Operation unit
610; Direction controller 620; Power interrupter
621; A first power interrupter 622; Second power interrupter

Claims (6)

The main body 100 in the form of a shaft and
A first electrode 200 coupled to one end of the main body 100 to be detachable and having a blade portion 220 formed therein,
A portion of the main body 100 to which the first electrode 200 is coupled is an electric flexible body 110 having a direction adjusting unit 500 for adjusting the direction of one end of the main body 100. Electrode body for surgical procedure. The method according to claim 1,
A second electrode 300 spaced apart from the first electrode 200 and provided in the flexible body 110 of the main body 100;
Electrode assembly for an electrosurgical operation, characterized in that it further comprises an insulating portion 400 disposed between the spaced apart of the first electrode (200) and the second electrode (300). The method according to claim 1 or 2,
The direction adjusting unit 500 is a first direction control wire 510 connected to bend one end of the main body 100 in the first direction and
Electrode body for electrosurgical treatment, characterized in that it comprises a second direction control wire (520) connected to refracting one end of the main body in a second direction spaced from the first direction. The method according to claim 1 or 2,
A direction control unit 610 connected to the direction control unit 500 to control the direction of one end of the main body 100 and
The electrode assembly for an electrosurgical operation, characterized in that it further comprises an operation unit (600) provided with a power intermittent (620) for intermitting the application of power to the first electrode (200). The method of claim 4, wherein
The power intermittent part 620 is an electrode assembly for electrosurgical operation, characterized in that to generate the intensity of the power applied to the first electrode 200 or less than 10 watts. The method of claim 4, wherein
The power interruption unit 620 is composed of a first power interruption unit 621 and a second power interruption unit 622,
The first power intermittent part 621 intermittently applies the power of 250 watt or more to the first electrode 200,
The second power intermittent part 622 is an electrode assembly for electrosurgical operation, characterized in that to apply a power of 10 watts or less to the first electrode (200).

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