KR100758025B1 - Electrode for radio frequency tissue ablation - Google Patents

Abstract

An electrode for a high frequency electrical operating device is provided to position an electric conduction unit on an inferior portion minutely by including the electric conduction unit with a predetermined bending angle. An electrode for a high frequency electrical operating device includes a handle unit(10). The handle unit(10) has a switch(14) controlling power. A cavity electrode(22) is connected to one side of the handle unit(10), is coated on a surface of the cavity electrode(22), and has a space inside the cavity electrode(22). An electrode needle unit(26) is installed on one end of the cavity electrode(22) to be inserted to tissue. A refrigerant conduit is inserted to an inside of the cavity electrode(22) and supplies and discharges refrigerant to cool the cavity electrode(22) and the electrode needle unit(26). A reinforcing unit(24) has a slope surface fluently continued to the cavity electrode(22) and thickly reinforces the thickness of the cavity electrode(22) as one body.

Description

Electrode for radio frequency tissue ablation {Electrode for radio frequency tissue ablation}

1 is a perspective view of an electrode for a high frequency electrosurgery according to the prior art.

Figure 2 is a perspective view of the electrode for high frequency electrosurgical operation according to an embodiment of the present invention.

Figure 3 is a perspective view showing the internal structure of the electrode for high frequency electrosurgical operation according to an embodiment of the present invention.

4 is a perspective view of an electrode for a high frequency electrosurgery according to another embodiment of the present invention.

Figure 5 is a cross-sectional view showing the main part of the refrigerant flow of the electrode for high frequency electrosurgical operation in accordance with an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawing>

10, 110: knob 14: switch

22, 122: hollow electrode 23, 123: insulation coating

24: reinforcement portion 25: inclined surface

26, 126: electrode needle 27, 127: energizing part

32, 132: electrode lines 34, 134: supply pipe

36, 136: discharge pipe α: bending angle

The present invention relates to an electrode for a high frequency electrosurgery, and more particularly, to an electrode for a high frequency electrosurgery having an improved structure.

In general, a technique for coagulation or Avlation of a desired biological tissue with high frequency energy by inserting a high frequency electrosurgical electrode, that is, an electrode having a long hollow tube shape into a biological tissue, is known.

In this case, when a current is applied to the living tissue, the living tissue is heated to coagulate the living tissue and blood vessels by a rather complicated biochemical apparatus, and this process is performed by heat deformation of the protein within the cell (tissue, Coagulation of blood vessels and blood) is achieved mainly.

1 is a perspective view of a high frequency electrosurgical electrode according to the prior art.

As shown in Figure 1, the electrode for the high-frequency electrosurgical surgery, during the operation, the handle portion 110 and the hollow electrode 122 is provided to one side of the handle portion 110 so as to be gripped and elongated, predetermined The insulating coating 123 is provided as long as the length, and the conductive part 126 is provided on one side of the insulating coating part 123, and the electrode needle 126 is inserted into the biological tissue at one end of the conductive part 126. It is made of a horn shape to facilitate, usually a cone or triangular pyramid shape.

In addition, the other side of the handle 110, the supply line 134 is supplied with the electrode line 132 for applying power to the hollow electrode 122 and the refrigerant for controlling the heat generation of the hollow electrode 122 ), And after the refrigerant supplied to the supply pipe 134 completes heat exchange, a discharge pipe 136 is provided to be discharged.

However, the electrode for high frequency electrosurgery as described above, the electrode needle 126 provided at one end of the conducting portion 126 is inserted into the biological tissue in which the lesion site exists, and the electrode needle 126 is positioned at the lesion site. In the process of adjusting so that the insulating coating portion 123 of the hollow electrode 122, which is provided thin and long from one side of the handle portion 110 is bent due to the resistance according to the density of the biological tissue, the conductive portion 127 There was a problem that can not be located accurately in the lesion area.

In addition, in the apparatus using the conventional high frequency electrosurgical electrode, the operator cannot directly control the power of the hollow electrode 122 for the high frequency electrosurgical operation during the operation, and the power switch unit is separately provided to the device controller (not shown). Since there is a need to control the power source wirelessly or wired or orally, there is a problem that the control of the power source connected to the electrode for the high frequency electrosurgical operation is not precisely performed.

In order to solve the above problems, an object of the present invention is to provide a high-frequency electrosurgical electrode that can be directly controlled by the operator, and the radiofrequency electrode can be precisely positioned on the lesion. do.

In order to achieve the above object, the electrode for high-frequency electrosurgical operation according to a preferred embodiment of the present invention and the handle portion having a switch for controlling the power; A hollow electrode connected to one side of the handle part and insulated coated on a surface thereof and having a space inside; An electrode needle provided at one end of the hollow electrode and formed to be inserted into a biological tissue; A refrigerant conduit inserted into the hollow electrode and supplying and discharging a refrigerant to cool the electrode needle and the hollow electrode; And it is provided with an inclined surface that is flexibly connected to the hollow electrode, it comprises a reinforcing portion to integrally reinforce the thickness of the hollow electrode, the hollow electrode is provided bent at a predetermined angle at one end of the reinforcing portion.

In this case, the handle portion further includes a supply pipe connected to the refrigerant conduit provided inside the hollow electrode and a discharge pipe connected to the space between the hollow electrode and the refrigerant conduit, the supply pipe and the discharge pipe is provided through the handle portion This is preferable.

In addition, the hollow electrode may be bent at a predetermined angle at one end of the reinforcing part.

On the other hand, the hollow electrode is provided with a reinforcing part reinforcing the thickness of the hollow electrode thick from the side of the handle portion to a predetermined length, the reinforcing part may be provided so that the diameter gradually decreases in the direction connected to the hollow electrode have.

In addition, the refrigerant conduit has a diameter smaller than the inner diameter of the curved electrode, is inserted into the hollow electrode, and the refrigerant is introduced into the hollow electrode to cool the portion of the hollow electrode in contact with the electrode needle and the biological tissue. The heat exchanged refrigerant is preferably provided to be discharged out of the living body through the discharge pipe through the space between the hollow electrode.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the electrode for high frequency electrosurgery according to the present invention.

2 is a perspective view of an electrode for a high frequency electrosurgery according to an embodiment of the present invention.

As shown in FIG. 2, the electrode for the high frequency electrosurgical operation according to the exemplary embodiment of the present invention preferably includes a handle part 10, a reinforcement part 24, and a hollow electrode 22.

Here, the handle portion 10 is provided with a switch 14 at a predetermined position on the outer surface, the reinforcement portion 24 formed integrally with the hollow electrode 22 is connected to one side, the reinforcement portion 24 An inclined surface 25 is provided at one end thereof and is connected to the insulating coating part 23 of the hollow electrode 22, and the conductive coating part 27 and the electrode needle part 26 are provided on one side of the insulating coating part 23. Is preferred.

At this time, the switch 14 is to control the power of the electrode for the high-frequency electrosurgical operation is preferably provided in a sliding method or a dial method that can be adjusted step-by-step strength, such as a button of a conventional vacuum suction cleaner, but the button method It may be.

In addition, the electrode needle 26 is preferably made of a pointed horn shape that becomes thinner toward one end so as to be inserted into the biological tissue, it may be made of a cone or triangular pyramid shape.

On the other hand, the hollow electrode 22 is an electrode portion 26 and the conductive portion 27 is connected to one side of the electrode needle portion 26, and the insulating coating portion 23 and the conductive portion 27 is connected to one side of the conductive portion 27 It is preferable that the inclined surface 25 provided at one side of the reinforcing part 24 is bent at a predetermined angle to be formed at one side.

In this case, the predetermined angle is a bending angle, the conduction portion 27, which is a heat generating portion of the hollow electrode 22 is provided to be more accurately positioned on the lesion site of the patient is preferably made of 0 ° ~ 45 °. .

In addition, the handle part 10 is connected to the reinforcing part 24 which is integrally provided with the hollow electrode 22 and the insulating coating part 23 on one side, and transfers power to the hollow electrode 22 on the other side. Supply line 34 to which the electrode line 32 and the refrigerant for controlling the temperature of the hollow electrode 22 are supplied, and the discharge pipe 36 discharged after the refrigerant supplied to the supply pipe 34 completes heat exchange. ) Is connected.

At this time, the supply pipe 34 and the discharge pipe 36 is preferably provided through the handle portion 10.

The procedure using the electrode for high-frequency electrosurgical operation as described above is inserted into the biological tissue in the order of the electrode needle 26, the conducting portion 27, and the insulating coating portion 23, the reinforcement portion 24 The reinforcement part 24 is flexibly inserted by the inclined surface 25 provided at one side of the reinforcement part. The reinforcement part 24 is positioned at the lesion part, and then heat is applied to the conduction part 27 by applying power. It is delivered in order to treat the lesion.

In this case, the conductive part 27 can be accurately positioned at the lesion site regardless of the resistance according to the density of the biological tissue by the reinforcing part 24, and is provided with the bending angle α to more precisely. Being able to be located on the lesion site, the operator can directly control the power by the switch 14 provided in the handle portion 10 can be made more precisely the procedure.

Figure 3 is a perspective view showing the internal structure of the electrode for a high frequency electrosurgical operation according to an embodiment of the present invention.

As shown in FIG. 3, the electrode for the high frequency electrosurgical operation according to the exemplary embodiment of the present invention may be disposed inside the hollow electrode 922 having the electrode needle 26, the conducting portion 27, and the insulating coating 23. The refrigerant conduit 40 is inserted, and the temperature sensor line 50 is preferably inserted into the refrigerant conduit 40.

At this time, the refrigerant conduit 40 is supplied with a power to the electrode for the high-frequency electrosurgical operation is inserted into the refrigerant for controlling the heat generated in the current-carrying portion 27 provided in the hollow electrode 22, the temperature sensor inside Line 50 can be inserted.

In addition, the temperature sensor line 50 is inserted into the inside of the refrigerant conduit 40 and extends to a predetermined position inside the conduction portion 27 to sense heat generated from the conduction portion 27 to generate high frequency. A control unit (not shown) for controlling the power of the electrode for the electrosurgical operation may determine the time to control the power.

4 is a perspective view of an electrode for a high frequency electrosurgery according to another embodiment of the present invention.

As shown in Figure 4, the electrode for a high frequency electrosurgical operation according to another embodiment of the present invention preferably comprises a handle portion 10, the reinforcing portion 24, and the hollow electrode (22).

Here, the handle portion 10 is provided with a switch 14 at a predetermined position on the outer surface, the reinforcement portion 24 formed integrally with the hollow electrode 22 is connected to one side, the reinforcement portion 24 One end is connected to the insulating coating portion 23 of the hollow electrode 22, it is preferable that the conductive coating portion 27, the electrode needle portion 26 is provided on one side of the insulating coating portion 23.

At this time, the electrode needle 26 is preferably made of a pointed horn shape that becomes thinner toward one end to be inserted into the biological tissue, it may be made of a cone or triangular pyramid shape.

In addition, the reinforcing portion 24 is provided with the same diameter as the outer diameter of the insulating coating portion 23 at a predetermined position of the insulating coating portion 23, gradually increasing the thickness until reaching the handle portion (10). Is preferred.

On the other hand, the hollow electrode 22 is the electrode needle portion 26 and the conductive portion 27 is connected to one side of the electrode needle portion 26, and the insulating coating portion 23 and the conductive portion connected to one side of the conductive portion 27 It is preferable that the reinforcing part 24 is bent and formed at a predetermined angle to a side where the reinforcing part 24 is continued.

Here, the predetermined angle is a bending angle (α) is provided so that the conduction portion 27, which is a heat generating portion of the hollow electrode 22 can be positioned more precisely on the lesion site of the patient is made of 0 ° ~ 45 ° This is preferable.

In addition, the handle part 10 is connected to the reinforcing part 24 which is integrally provided with the hollow electrode 22 and the insulating coating part 23 on one side, and transfers power to the hollow electrode 22 on the other side. Supply line 34 to which the electrode line 32 and the refrigerant for controlling the temperature of the hollow electrode 22 are supplied, and the discharge pipe 36 discharged after the refrigerant supplied to the supply pipe 34 completes heat exchange. ) Is connected.

At this time, the supply pipe 34 and the discharge pipe 36 is preferably provided through the handle portion 10.

The procedure using the electrode for high-frequency electrosurgical operation as described above is inserted into the biological tissue in the order of the electrode needle 26, the conducting portion 27, and the insulating coating portion 23, the reinforcement portion 24 Since one side of is formed to be the same as the outer diameter of the insulating coating 23, the reinforcing portion 24 is flexibly inserted to position the conduction portion 27 in the lesion area, and then applying power to the conduction portion ( 27) in order to treat the lesion by transferring heat.

In this case, the conductive part 27 can be accurately positioned at the lesion site regardless of the resistance according to the density of the biological tissue by the reinforcing part 24, and is provided with the bending angle α to more precisely. Being able to be located on the lesion site, the operator can directly control the power by the switch 14 provided in the handle portion 10 can be made more precisely the procedure.

5 is a cross-sectional view illustrating main parts of a refrigerant flow of an electrode for a high frequency electrosurgical operation, according to an exemplary embodiment.

As shown in Figure 5, looking at the flow of the refrigerant of the electrode for a high-frequency electrosurgical operation according to an embodiment of the present invention, there is provided a refrigerant conduit 40 that allows the refrigerant to flow into the inner space of the hollow electrode 22 The inside of the refrigerant conduit 40 is provided with a temperature sensor line 50 capable of sensing the heat generated in the conduction unit 27.

Here, a refrigerant for controlling the heat generation of the conduction portion 27 provided on one side of the hollow conduit 22 along the space between the temperature sensor line 50 and the refrigerant conduit 40 is supplied, The supplied coolant is ejected to one end of the coolant conduit 40, flows into the current conduction part 27 to complete heat exchange, and then, between the inner wall of the hollow electrode 22 and the outer wall of the coolant conduit 40. It will be discharged along the space.

Meanwhile, as shown in FIGS. 2 to 4, the flow of the refrigerant is circulated through the supply pipe 34 and the discharge pipe 36 which are inserted and connected to one side of the handle part 10.

Referring to the effects of the high-frequency electrosurgical electrode according to the present invention described above are as follows.

First, by providing a reinforcing part, it is possible to reinforce the strength of the insulating coating part of the hollow electrode so that the conducting part can be accurately positioned on the lesion site regardless of the resistance according to the density of the biological tissue.

Second, by providing a switch in the handle portion, the operator can directly control the power supply during the operation using the electrode for high frequency electrosurgical operation, it is possible to precisely control the heat generation of the energization portion.

Third, it is possible to position the lesion portion more accurately by being provided with a conduction portion that generates heat having a predetermined bending angle.

Claims (6)

A handle part having a switch for controlling a power supply; A hollow electrode connected to one side of the handle part and insulated coated on a surface thereof and having a space inside; An electrode needle provided at one end of the hollow electrode and formed to be inserted into a biological tissue; A refrigerant conduit inserted into the hollow electrode and supplying and discharging a refrigerant to cool the electrode needle and the hollow electrode; And It is provided with an inclined surface that is flexible to the hollow electrode, including a reinforcement portion integrally reinforced with the thickness of the hollow electrode, The hollow electrode is a high frequency electrosurgical electrode, characterized in that provided with a predetermined angle bent at one end of the reinforcement. The method of claim 1, The handle part further includes a supply pipe connected to a refrigerant conduit provided inside the hollow electrode and a discharge pipe connected to a space between the hollow electrode and the refrigerant conduit, wherein the supply pipe and the discharge pipe are provided through the handle part. Electrode for high frequency electrosurgery. delete The method of claim 1, The hollow electrode is provided with a reinforcing part to thicken the thickness of the hollow electrode from the handle side to a predetermined length, the reinforcing part is characterized in that the diameter is gradually reduced in the direction connecting to the hollow electrode High frequency electrosurgical electrode. delete The method of claim 2, The refrigerant conduit has a diameter smaller than the inner diameter of the curved electrode, is inserted into the hollow electrode, and introduces a refrigerant into the hollow electrode to cool a portion of the hollow electrode in contact with the electrode needle and the biological tissue, and exchanges heat. The high frequency electrosurgical electrode, characterized in that the refrigerant is made to be discharged out of the living body through the discharge pipe through the space between the hollow electrode.

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