KR100629454B1 - Electrosurgical Electrode - Google Patents

Abstract

Provided are electrodes for electrosurgery used for incision or coagulation of body tissue (site).

Electrosurgical electrode of the present invention is an electrode for electrical surgery that is electrically connected to the electrosurgical operation to perform the procedure, such as incision, coagulation of body tissue, the electrode body configured to perform the treatment of the body tissue while being bipolar, and It is comprised including the insulator which interposes between electrode bodies and comprises a bipolar electrode.

According to the present invention, it is possible to connect both the single pole and the positive pole of an electrosurgical device which applies a high frequency current to the electrode during the procedure, and does not require the use of a counter electrode (patient electrode or a ground pad) in contact with the patient. On the other hand, it can be operated under a lower voltage than the conventional unipolar procedure, which minimizes the carbonization of the tissue by minimizing the carbonization of the tissue by suppressing the occurrence of spark between the tissue and the electrode, thereby minimizing the transmission path of the high frequency current through the electrode. It is possible to obtain a more improved effect of preventing burns, electric shocks, and the like.

Procedure, electrosurgical instrument, surgical electrode, forceps, monopolar electrode, bipolar electrode

Description

Electrosurgical Electrode {Electrosurgical Electrode}             

1 is a schematic diagram illustrating a forcep as an example of a bipolar electrode used in connection with a conventional electrosurgical unit;

Figure 2 is a schematic diagram showing the electrode for unipolar electrosurgery used in connection with a conventional electrosurgical

Figure 3 is a perspective view of the electrode for electrosurgical operation according to the present invention

4 is a main structural diagram showing an electrode of the present invention;

5 is an exploded view of FIG. 4 showing the electrode of the invention.

6 is a perspective view of principal parts showing an electrode of the present invention having a cover body;

Figure 7 shows the state of use of the electrosurgical electrode of the present invention electrosurgical electrode,

(a) is a schematic diagram showing an anode connection state

(b) is a schematic diagram showing a state of using an existing unipolar connection as a bipolar connection

Figure 8 shows the various forms of the present invention electrode for electrosurgery,

(a) is a principal part showing the state which narrowed the space | interval of an electrode

(b) is a principal part showing a state where the distance between electrodes is widened

(c) is a principal part showing a state where the body contact part of the electrode is enlarged;

Explanation of symbols on the main parts of the drawings

1 .... Electrosurgical electrode of the present invention

10a, 10b .... Electrode body 14 .... Insulator fixing protrusion

16 .... Connection terminal 18 .... Handle

30 .... insulator 50 .... cover

The present invention relates to an electrosurgical electrode used in a procedure such as local incision or coagulation of body tissues, and more particularly, a single pole or a bipolar connection of an electrosurgical device applying a high frequency current to the electrode is possible, and is in contact with a patient. It does not require the use of a counter electrode (patient electrode / grounding pad), which makes it easy to use and to operate, while it can be operated under a lower voltage than the conventional unipolar procedure, which suppresses the spark between body tissue and electrodes. The present invention relates to an electrode for electrosurgery which minimizes carbonization and minimizes a transmission path of a high frequency current through the electrode to prevent burns or electric shock caused by the high frequency current.

Electrosurgery is to locally cut or coagulate the tissue of a body. Such an electrosurgery is a radiofrequency (RF) current supplied from an electrosurgical device through electrodes in contact with the body. Electrical energy is applied to the surgical site of the body, and local heating of the tissue occurs, and according to the waveform of the applied electrical energy and the shape of the electrode, the above-described procedure, for example, cutting or solidifying the tissue ( Vascular coagulation).

At this time, by adjusting the power output and the shape of the electrical waveform of the electrosurgical device, it is possible to adjust the heating range or the resulting surgical effect to some extent, for example, a continuous sinusoidal waveform is most suitable for incision, and partially Burst waveforms with periodically spaced bursts of the rectified signal are known to be suitable for coagulation procedures.

Therefore, during the electrosurgical electrode is used to be electrically connected and connected to the electrosurgery unit (Electrosurical Unit) which is an oscillator, the electrosurgery and the electrode will be described again in the following FIGS.

On the other hand, such an electrosurgery can be largely divided into monopolar and bipolar, for example, in the case of bipolar electrosurgery, the tissue to be treated is located between the electrodes of the bipolar electrode. Applied across the electrodes.

In addition, in unipolar electric surgery, electrical excitation energy is applied to a single electrode at the site of treatment, and the counter electrode (patient electrode, grounding pad) is placed in contact with the patient. The high-frequency current transmission path is realized from the monopolar surgical electrode to the counter electrode (ground pad).

Therefore, in the case of bipolar procedure, the area of tissue through which electric current passes is small, and in the case of unipolar bipolar electrolysis, current flows through the electrode and body tissue to the counterplate. It is known to be safer than the procedure because the area where the high frequency current is applied to the new tissue (site) is smaller when bipolar, so that the occurrence of burns or electric shock due to the high frequency current is reduced.

In addition, in the case of unipolar electrosurgery, the voltage used is also higher than that of bipolar, so that sparking between body tissue and electrodes may cause carbonization of body tissue.

On the other hand, in the electrosurgery, the anode means that a high-frequency current flows through two electrodes, and the monopolar electrode is a counter electrode in which a high-frequency current applied to one electrode contacts the body via body tissue from the electrode. It means flowing through the (patient electrode).

Next, looking at such a positive electrode and a monopolar electrode for electrosurgical operation as follows.

First, FIG. 1 schematically shows a bipolar electrosurgical operation. A representative example of such a bipolar electrode is a forceps.

That is, as shown in FIG. 1, when the connection terminal 116 of the forceps 110, which is a surgical electrode, is connected to the anode connector 102 of the electrosurgery 100, both electrodes 112 of the forceps 110 are connected. That is, the high frequency current flows through the inlet and the outlet electrode, which implements the transmission path of the high frequency current (dotted arrow in FIG. 1), and electrical energy is applied to the vessel in the state sandwiched between the two electrodes to perform coagulation of the vessel. do.

In other words, such bipolar electrosurgery mainly uses forceps, and its main purpose is to coagulate blood vessels by picking up blood vessels with both electrodes of the forceps.

Next, unipolar electrosurgery is schematically shown in FIG. 2.

That is, as shown in FIG. 2, in the case of unipolar electrosurgical operation, the connection terminal 122 of the surgical electrode 120 is connected to the unipolar connector 104 of the electrosurgical apparatus 100, and the counter electrode (patient electrode) is connected. When the connection terminal 132 of the 130 is connected to the other single-pole connector 106 of the electrosurgical device, the high frequency current generated by the electrosurgical device 100 passes through the electrode portion 120a of the electrode 120 and the body tissue. It flows through the path leading to the counter plate 130 (dotted arrow in FIG. 2), and local incision or solidification is performed by electrical energy applied to the body contacting part of the electrode part 120a.

Accordingly, for the incision of body tissues or for the coagulation of body parts other than blood vessels, unipolar electrosurgery is performed. As described above, in the case of such unipolar electrosurgery, the counter electrode 130, which is a patient electrode that contacts the patient, is performed. The use of) is a necessity, which makes the procedure cumbersome, especially since the gap between the electrode and the counterplate is larger than the bipolar electrosurgical procedure, there is a risk of burns or electric shock caused by high-frequency currents on other parts of the body that do not need to be treated. .

Accordingly, when the unipolar electrode used in the conventional unipolar electrosurgical is implemented using bipolarity, and the use of the counter electrode is not necessary, various problems such as tissue carbonization, burns, and electric shock generated during the unipolar electrosurgical procedure are required. In order to solve the problem, in particular, it can be used regardless of the positive electrode and the monopole connection port of the electrosurgical device, and it will be more preferable since the electrosurgical treatment as a whole can be more convenient.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and its object is to realize a conventional unipolar electrode with bipolarity, eliminating the use of a counterplate and allowing high frequency current to flow through a monopolar or bipolar connection of an electrosurgical device. All of these can be used to make electrosurgery as a whole more convenient, and in particular, it can be performed at a lower voltage than conventional unipolar electrosurgery, thereby minimizing carbonization of tissues by suppressing the occurrence of sparks between body tissues and electrodes. The present invention provides an electrode for electrosurgery, which suppresses the occurrence of burns, electric shocks and the like of body tissues (sites).

In order to achieve the above object, the present invention is electrically connected to the electrosurgical operation, performing the treatment of the body tissue while being configured bipolar with the induction and withdrawal electrode of the high-frequency current through the electrosurgizer to perform the coagulation of the body tissue And an insulator made of a synthetic resin interposed between the electrode bodies to form a bipolar electrode and detachably fixed between the electrode bodies,
In addition, the front end portion of the insulator located between the ends of the electrode body is reduced to narrow or enlarge the gap between the electrodes is configured to enlarge the distance between the electrodes,
The electrode body and the insulator therebetween are configured to prevent separation from each other as a cover body fitted to the outside,
The electrode body is connected to an operation handle, and the cable connection terminal of the handle provides an electrode for electrosurgical operation selectively connected to a positive electrode connection port of an electrosurgical device that conducts a high frequency current and to each monopolar connection port.
In this case, preferably, protrusions for fixing the insulator are provided on the insulator contact surface of the electrode body.
And, more preferably, the electrode body is configured to expand the body contact portion.

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DETAILED DESCRIPTION Hereinafter, the present invention will be described in detail with reference to the accompanying drawings, in which a configuration related to an electrosurgical instrument is denoted by the same reference numerals as before.

First, FIG. 7 illustrates a state in which the surgical electrode 1 according to the present invention is connected to the electrosurgery 100.

That is, as shown in FIG. 1, a conventional bipolar electrode, for example, a forceps 110, is used to connect only to the anode connector 102 of the electrosurgical device 100, and the conventional unipolar electrode 120 as shown in FIG. 2 is an electrosurgical device ( The counter electrode (ground pad) (which is a feedback electrode of a high frequency current) 130 connected to only the single pole connector 104 of the 100 and simultaneously in contact with the patient is connected to the other single pole connector 106, Electrode electrode 1 of the present invention, as shown in Figure 7a and 7b, it is used to connect to the anode connector 102 of the electrosurgical device 100, and the respective monopolar connector 104, 106 In this way, the electrosurgical electrode 1 of the present invention eliminates the use of the existing counter electrode 130.

Therefore, the electrode 1 for the electrosurgical treatment of the present invention is used as the bipolar electrode 130 by separating the electrode bodies from each other through an insulator, as described in detail below, and using the existing counter electrode 130. The carbonization of body tissues and the occurrence of burns or electric shocks caused by high-frequency currents can be suppressed.

In other words, it is possible to connect and use an electrosurgical device such as unipolarity, but in fact, since bipolar electrolysis is performed, a lower voltage can be used than conventional unipolar electrolysis, and sparks between electrodes and body parts (tissues) are generated. This suppresses the carbonization of the tissue is minimized, while preventing burns and electric shock, it is convenient to use the connection to the connection of the electrosurgical device 100, in particular because the use of the counter electrode is not necessary, The electrode 1 makes the procedure very convenient.

In addition, the electrode 1 for electrosurgery of the present invention may be preferably used mainly for the coagulation procedure of the body part because the high frequency current flows through the bipolar electrode bodies having no gap plate and the gap is not limited thereto.

Meanwhile, FIGS. 3 to 6 illustrate the electrode 1 for treatment according to the present invention. The electrode 1 for treatment according to the present invention is composed of an anode while being in contact with body tissues (sites) for electrical treatment. The electrode body (10a) (10b) to enable the, and interposed between the electrode body and the electrode body is configured to include an insulator (30) consisting of an anode.

At this time, as shown in Figure 3, the electrode body (10a) (10b) is used by being connected to the connection port (18a) of the handle 18 for operation that is held by the doctor or the user during the procedure, the connection of the handle 18 As shown in FIG. 7, connection terminals 16a and 16b connected to the connection ports 102, 104 and 106 of the electrosurgical member 100 are connected to the cable.

Thus, as shown in Figures 3 and 4, the high-frequency current transmitted through the electrosurgical device 100 is through the one-side electrode body (10a) and the body tissue that functions as the induction electrode isolated from each other as the insulator 30 While flowing through the other electrode body 10b serving as the lead electrode, the electrical energy applied to the body tissue (part) is solidified by heating by Joule heat according to the size of the resistance.

As a result, the surgical electrode 1 of the present invention uses the conventional monopolar electrode (120 in FIG. 2) as the insulator 30 to draw and withdraw an electrode to allow bipolar, ie, high-frequency current to flow while applying electrical energy to body tissues. Since it is constituted by the polarity of the dragon, the electrical connection with the electrosurgical apparatus 100 makes it possible to conveniently connect irrespective of the anode or the unipolar electrode while solving problems caused by the unipolar electrode.

3 and 7A, when the electrode 1 for electrosurgical treatment of the present invention is connected to the positive electrode connector 102 of the electrosurgical device 100, the connector electrode 1-> one electrode body 10a is connected. )-> Body tissue-> the other electrode body (10b)-> high junction current flows through the path of the other electrode.

On the contrary, as shown in FIGS. 3 and 7B, when the electrode 1 for electrosurgical treatment of the present invention is connected to each of the monopole connectors 104 and 106 of the electrosurgical instrument 100, the monopole connector 104 is provided. -> One electrode body (10a)-> body tissue-> the other electrode body (10b)-> the high frequency current flows through the path of the other single-pole connection 106, the electrical energy applied to the body tissue between the electrodes, such as coagulation The procedure is performed.

On the other hand, it is preferable that the insulator 30 interposed between the electrode bodies 10a and 10b constituting the electrode 1 for electrosurgical treatment of the present invention to be bipolar is provided detachably between electrodes. As shown in FIGS. 4 and 5, the insulator contact surfaces 12 of the electrode bodies 10a and 10b are provided with a plurality of protrusions 14 for fixing the insulator 30.

4 and 6, the electrode bodies 10a and 10b and the insulator 30 therebetween are integrally fitted to the outer cover body 50, for example, a plastic cover or the like. It is fixed to prevent departure.

In this case, the insulator 30 may be used as long as it is a material that does not conduct electricity, and a synthetic resin that can be easily molded and manufactured, for example, a rubber pad may be preferable.

Therefore, the electrode 1 for electrosurgical treatment of the present invention cuts the existing unipolar electrode 120 of FIG. 2 in half and closes the electrode bodies 10a and 10b by interposing an insulator 30 therein. It is fixed as the protrusions 14, the circular cover body 50, which is an insulating material such as elastic vinyl, is sandwiched between the electrode bodies 10a and 10b and the insulator 30 is assembled to be provided bipolar.

On the other hand, the electrode 1 for electrosurgical operation of this invention can take the form in various forms.

For example, as illustrated in FIG. 8A, when the tip portion 30a of the insulator 30 located at the end of the electrode bodies 10a and 10b is reduced and thinned, the electrode bodies 10a and 10b are reduced. It may be provided in the form of narrowing the interval (D) between.

Alternatively, as shown in FIG. 8B, when the tip portion 30a of the insulator 30 positioned at the end of the electrode bodies 10a and 10b is enlarged and thickened, the gap D between the electrodes is enlarged. Forms are also possible.

Of course, as shown in FIGS. 8A and 8B, when the portion of the tip portion 30a of the insulator 30 is reduced or expanded, the electrode bodies 10a and 10b are narrowed and inclined or widened when viewed in cross section. It is preferable to incline and change correspondingly.

Therefore, the electrosurgical electrode 1 of the present invention will be able to adjust the spacing between the electrode body (10a) (10b) as an insulator, in this case corresponding to the coagulation site during the procedure according to the spacing between the electrodes, For example, it is preferable to use the form of FIG. 8A for coagulation of the micro site, and to use the form of FIG. 8B when the coagulation site is larger than this.

Next, as shown in FIG. 8C, the electrode bodies 10a and 10b may be able to expand the body contact portion T in the vertical direction while the linear insulator 30 is interposed therein, in which case the body of the electrode Since the contact area of the tissue (site) becomes wider to facilitate contact, the procedure will be simpler.

Accordingly, conventionally, as illustrated in FIGS. 1 and 2, the bipolar electrode and the monopolar electrode should be separated and used to connect to the electrosurgical apparatus 100. However, the electrosurgical electrode 1 of the present invention is connected to the electrosurgical apparatus 100. In addition, it is possible to selectively connect to the desired one of the positive electrode and the monopole connection port, and in particular, the use of the existing counter electrode (130 in FIG. 2) necessary for the monopolar connection is eliminated, resulting in the electrode body 10a (10b). ), Since the polarization is implemented, problems caused by unipolar procedures are prevented.

In addition, since the above-described problems of the electrosurgical electrode 1 of the present invention are solved, the risk of the procedure is reduced accordingly, and the carbonization or electrolysis of tissues, such as the brain, eyes, and spinal nerves, which are important parts of the body, are thus performed. It will be possible to perform the procedure without shock.

As described above, according to the electrode for electrosurgical use of the present invention, the conventional unipolar electrode can be implemented bipolarly or bipolarly by an electric surgery instrument which eliminates the use of a counterplate and allows a high frequency current to flow while realizing a bipolar electrode. There is an excellent effect that makes it more convenient.

In addition, it can be performed at lower voltage than the conventional unipolar electric surgery, and it suppresses the spark between the body tissue and the electrode, minimizes the carbonization of the tissue, and burns the body tissue (site), electric shock, etc. by high frequency current. Since it is possible to suppress the occurrence of and to maintain the treatment environment more stably, it is possible to provide another advantage of providing a surgical electrode suitable for the treatment or surgery on micro-sites, such as brain, eyes, spinal nerves.

While the invention has been shown and described in connection with specific embodiments so far, it will be appreciated that the invention can be varied and modified without departing from the spirit or scope of the invention as set forth in the claims below. It will be appreciated that those skilled in the art can easily know.

Claims (9)

An electrode body electrically connected to an electrosurgical member, the electrode body configured to be bipolar as the induction and withdrawal electrodes of the high frequency current through the electrosurgical operation so as to perform coagulation of the body tissue; And, An insulator made of a synthetic resin interposed between the electrode bodies and made of a synthetic resin and detachably fixed between the electrode bodies; It is configured to include, In addition, the front end portion of the insulator located between the ends of the electrode body is reduced to narrow or enlarge the gap between the electrodes is configured to enlarge the distance between the electrodes, The electrode body and the insulator therebetween are configured to prevent separation from each other as a cover body fitted to the outside, And said electrode body is connected to an operation handle, and a cable connection terminal of said handle is selectively connected to an anode connection port of each electrosurgical unit for conducting a high frequency current and each monopole connection port. delete delete The electrode for electrosurgical treatment according to claim 1, wherein protrusions for fixing the insulator are provided on the insulator contact surface of the electrode body. delete The electrode of claim 1, wherein the distal end of the insulator is reduced. The electrode for electrosurgical treatment according to claim 1, wherein the distal end portion of the insulator is enlarged. The electrode for electrosurgical treatment according to claim 1, wherein the electrode body has an enlarged body contact portion. delete

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