JP2023121719A - Electrode unit and medical treatment instrument - Google Patents

Abstract

To provide an electrode unit capable of simplifying a structure and reducing costs for manufacturing, in a case where an electric wire and a thermocouple for a high frequency current are provided.SOLUTION: An electrode unit 1 comprises an electrode 2, a connector 5, a conductor for high frequency 13, and a thermocouple 10. The thermocouple 10 and one end of the conductor for high frequency 13 are connected to the connector 5, and the other end of the conductor for high frequency 13 is soldered integrally with a chromel wire 11 and an alumel wire 12 constituting the thermocouple 10 inside the electrode 2 so as to conduct with the electrode 2.SELECTED DRAWING: Figure 3

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrode unit and the like having a high-frequency conducting wire and a temperature sensor.

As a conventional electrode unit, one described in Patent Document 1 is known. This electrode unit is for performing a cauterization treatment of the heart, and has an electrode at its distal end which is connected to an operation console via a cable. In this electrode unit, power is supplied from the operation console to cause high-frequency current to flow between the electrode at the tip and the grounding pad attached to the patient's body, thereby performing cardiac ablation therapy.

JP 2020-182843 A

In the case of an electrode unit used for stereotactic neurosurgery, etc., a temperature sensor must be installed in the electrode unit in addition to the high-frequency lead wire in order to control the temperature of the treatment site during thermocoagulation treatment. Sensors and RF conductors must be properly arranged within the electrode unit.

On the other hand, in the case of the electrode unit of Patent Literature 1, since it is for cauterization treatment, there is no point of view of arranging the temperature sensor other than the high-frequency conducting wire. Therefore, when the technique of Patent Document 1 is applied to an electrode unit in which a temperature sensor is arranged, the structure of the electrode unit becomes complicated due to the arrangement of the temperature sensor and its support structure, and as a result, the manufacturing process becomes complicated. This may lead to increased costs.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an electrode unit or the like that can simplify the structure and reduce the manufacturing cost when a high-frequency conducting wire and a temperature sensor are provided. and

In order to achieve the above object, the invention according to claim 1 provides an electrode arranged on a treatment target and a high-frequency lead wire for electrically connecting the electrode to a high-frequency power generation device that generates high-frequency power. , a connection that electrically connects a temperature sensor placed on an electrode, a high-frequency lead wire, and an electrode, and holds the temperature sensor or the sensor lead wire electrically connected to the temperature sensor at a single specified portion of the electrode and a part.

According to this electrode unit, the configuration for electrically connecting the high-frequency conducting wire and the electrode, and the configuration for holding the temperature sensor or the conducting wire for the sensor, are provided by a component called a connecting portion that holds a single specified portion of the electrode. can be realized. Thereby, the structure of the electrode unit can be simplified, and the manufacturing cost can be reduced accordingly.

The invention according to claim 2 is characterized in that, in the electrode unit according to claim 1, the connecting portion is made of solder or a conductive brazing material welded to the electrode.

According to this electrode unit, when assembling the electrode unit, the configuration for electrically connecting the high-frequency lead wire and the electrode and the configuration for holding the temperature sensor or the sensor lead wire are soldered or brazed. can be performed simultaneously. As a result, the assembly work of the electrode unit can be facilitated, and the manufacturing cost can be reduced accordingly.

The invention according to claim 3 is the electrode unit according to claim 1, wherein the connection part is composed of a first connection part made of solder or a conductive brazing material welded to the electrode and an adhesive. a second connection, wherein the high-frequency conductor is connected to the electrode by the first connection, and the temperature sensor or the sensor conductor is held by the second connection.

According to this electrode unit, when assembling the electrode unit, the configuration for electrically connecting the high-frequency conductor and the electrode can be performed by soldering or brazing, and the temperature sensor or the sensor conductor can be held. The configuration can be implemented by a gluing operation. As a result, even if the temperature sensor or sensor leads are susceptible to high heat such as soldering or brazing, they can be held by the adhesive without being affected by the heat.

The invention according to claim 4 is the electrode unit according to claim 2 or 3, wherein the electrode has an internal space that houses at least a part of the temperature sensor, and the designated portion is a base end side opening that communicates with the internal space. It is characterized by being a part.

According to this electrode unit, a soldering operation or a brazing operation is performed, or a soldering operation or a brazing operation and an adhesion operation are performed so as to close the base end side opening connected to the internal space of the electrode. The connecting part is constructed by As a result, compared to the case where the connection portion is arranged on the inner side of the internal space of the electrode, the work of forming the connection portion can be easily performed. Thereby, the assembly work of the electrode unit can be further facilitated.

The invention according to claim 5 is characterized in that, in the electrode unit according to any one of claims 1 to 3, the temperature sensor is composed of a thermocouple provided with an insulating coating.

According to this electrode unit, since the temperature sensor is composed of a thermocouple, which is relatively simple and versatile, the manufacturing cost of the electrode unit can be reduced accordingly. In addition, since the thermocouple is provided with an insulating coating, even if the thermocouple and the high-frequency lead wire are set in the same wiring route, there is no need to cover the high-frequency lead wire with an insulating cover, and the degree of freedom in wiring between the two is improved. be able to. Thereby, the manufacturing cost of the electrode unit can be further reduced.

The invention according to claim 6 is a medical treatment instrument to which the electrode unit according to any one of claims 1 to 3 is attached during use, the electrode unit further comprising a needle base to which the electrode is fixed. The medical treatment instrument is characterized by comprising a guide for guiding the electrode, a fixture for fixing the needle base, and a frame to which the guide and the fixture are attached.

According to this medical treatment instrument, when the electrode unit is used, the electrode unit is attached to the medical treatment instrument by fixing the needle base to the frame via the fixture while the electrode is guided by the guide. Thus, the electrode unit can be made ready for use with a relatively simple configuration of the guide and fixture.

It is a figure which shows the external appearance of the electrode unit which concerns on 1st Embodiment of this invention. FIG. 4 is a cross-sectional view showing the configuration around the tip of an electrode; Fig. 3 is a cross-sectional view showing the configuration of the needle base and its surroundings; FIG. 3 is a perspective view showing the structure of a portion where a high-frequency lead wire and a thermocouple are soldered to electrodes; 4 is a cross-sectional view showing the configuration of a connector; FIG. 1 is a perspective view showing the configuration of a stereotaxic neurosurgery instrument; FIG. It is a perspective view which shows the structure of a stopper. It is a perspective view which shows the structure of a guide. FIG. 10 is a cross-sectional view showing the configuration of the needle base and its surroundings of the electrode unit according to the second embodiment; FIG. 10 is a perspective view showing the structure of a portion where the high-frequency conducting wire and the thermocouple of the second embodiment are soldered to the electrodes; FIG. 11 is a cross-sectional view showing the configuration of the needle base and its surroundings of the electrode unit according to the third embodiment; FIG. 4 is a perspective view showing the structure of a portion where a high-frequency lead wire and a thermocouple are soldered and adhered to electrodes;

An electrode unit according to a first embodiment of the present invention will be described below with reference to the drawings. The electrode unit 1 shown in FIG. 1 of the first embodiment is used for stereotactic neurosurgery such as treatment for Parkinson's disease, and performs thermal coagulation treatment of the treatment site of the brain by emitting high-frequency power from the tip. It is for

As shown in FIG. 1, the electrode unit 1 comprises an electrode 2, a needle base 3, a cover tube 4 and a connector 5. As shown in FIG. The electrode 2 has an elongated cylindrical shape, and when the electrode unit 1 is not in use, the electrode 2 is entirely covered by a protector 6 indicated by a chain double-dashed line in FIG. The protector 6 is attached to the electrode unit 1 by fitting the opening of the protector 6 to the distal end of the needle base 3 .

On the other hand, during stereotaxic brain surgery, the electrode 2 is inserted into the brain from the distal end side with the protector 6 removed, and the electrode unit 1 is fixed to a surgical instrument (not shown) in this state. be.

The electrode 2 is made of a conductive metal (for example, stainless steel), and an insulating coating (fluororesin coating) is applied to the outer peripheral surface other than the active chip portion 2c described later.

The electrode 2 includes a fine needle tube portion 2a and a needle tube portion 2b. The thin needle tube portion 2 a is a hollow cylindrical member with a closed tip, and is arranged on the tip side of the electrode 2 . As shown in FIG. 2, the distal end portion of the fine needle tube portion 2a is formed into an active tip portion 2c having a curved surface with rounded edges, and which is not coated with an insulating coating.

In the active tip portion 2c, when high-frequency power is supplied to the electrode 2, high-frequency power is emitted from the active tip portion 2c to the treatment site of the brain, as will be described later. Thermal coagulation treatment is thereby performed at the treatment site of the brain.

A thermocouple 10 (temperature sensor) is provided inside the inner hole 2d of the fine needle tube portion 2a. The thermocouple 10 extends along the extending direction of the electrode 2, and more specifically, extends between the tip of the active tip portion 2c and a connector 5, which will be described later, through the inside of the electrode 2. . The thermocouple 10 is of type K and is composed of a pair of chromel wire 11 and alumel wire 12 .

The surfaces of the chromel wire 11 and the alumel wire 12 are both coated with an insulating coating, and the joints of the tips of the wires are arranged inside the tip of the active tip portion 2c. This junction is covered with an adhesive 14 to insulate it from the active chip portion 2c.

The needle tube portion 2b is a cylindrical member having a slightly larger diameter than the fine needle tube portion 2a, and is formed integrally with the fine needle tube portion 2a. The needle tube portion 2b extends between the fine needle tube portion 2a and the needle base portion 3, and the base end opposite to the fine needle tube portion 2a is fixed to the needle base portion 3. As shown in FIG.

Next, the needle base portion 3 will be described. This needle base 3 is a portion fixed to a surgical instrument during stereotaxic neurosurgery. As shown in FIG. 3, an inner hole 3a is formed in the needle base portion 3. The inner hole 3a has a circular cross section and extends in the horizontal direction in the figure while penetrating the needle base portion 3. As shown in FIG.

A portion of the inner hole 3a on the side of the electrode 2 has a constant diameter. The proximal end of the electrode 2 is inserted into the electrode 2 side of the inner hole 3a and fixed to the needle base 3 via an adhesive (not shown) while being fitted therein.

Also, solder 20 (connecting portion) is provided at the proximal end portion of the electrode 2 so as to block the proximal end side opening of the electrode 2 . The chromel wire 11 , the alumel wire 12 and the high-frequency conducting wire 13 are integrally fixed to the electrode 2 via the solder 20 . Also, the chromel wire 11 and the alumel wire 12 pass through the solder 20 and extend between the active chip portion 2 c and the connector 5 .

The high-frequency conducting wire 13 is for supplying high-frequency power, has an insulating coating on its surface, and is fixed with one end embedded in the solder 20 . As a result, the high-frequency conducting wire 13 is in a state of electrical continuity with the electrode 2 . The other end of the high-frequency conducting wire 13 is connected to a terminal 5b of the connector 5, which will be described later.

A portion of the inner hole 3a of the needle base 3 on the side of the cover tube 4 is formed in a truncated cone shape whose diameter decreases from the side of the cover tube 4 toward the side of the electrode 2. As shown in FIG. A hollow connecting tube 4a is inserted and fitted into the inner hole 3a of the needle base 3. As shown in FIG. This connection tube 4a is fixed to the needle base 3 via an adhesive (not shown).

Further, the cover tube 4 is fixed to the connecting tube 4a by solvent bonding with its distal end inserted into the inner hole of the connecting tube 4a. Thereby, the cover tube 4 is fixed to the needle base 3 via the connecting tube 4a. This connecting tube 4a is for reinforcing the connecting portion of the cover tube 4 and the needle base portion 3. As shown in FIG.

The cover tube 4 is for covering the chromel wire 11 , the alumel wire 12 and the high-frequency conducting wire 13 and extends between the needle base 3 and the connector 5 .

The connector 5, as shown in FIG. 5, includes a base 5a, a pair of terminals 5b and 5c, a case 5d, and the like. The case 5d is attached to the base 5a by fitting into the base 5a while covering the terminals 5b and 5c of the connector 5 except for the base portions thereof, as indicated by the two-dot chain line in FIG. When the electrode unit 1 is not in use, the tip portions of the terminals 5b and 5c protruding from the connector 5 are covered by the terminal cover 7 shown in FIG.

An inner hole is formed in the base 5a, and a hollow connecting tube 4b is inserted and fitted into the inner hole of the base 5a. This connection tube 4b is fixed to the base 5a via an adhesive (not shown).

Further, the cover tube 4 is fixed to the connection tube 4b by solvent bonding with its tip inserted into the inner hole of the connection tube 4b. Thereby, the cover tube 4 is fixed to the connector 5 via the connection tube 4b. The connection tube 4b is intended to reinforce the connecting portion of the cover tube 4 and the connector 5, like the connection tube 4a.

A groove is formed in the central portion of the terminal 5b along the longitudinal direction of the terminal 5b. The high-frequency conducting wire 13 and the chromel wire 11 extend from the cover tube 4, and are fixed to the terminal 5b in a state in which their tip portions are integrally wound around the groove of the terminal 5b. The parts of the high-frequency conducting wire 13 and the chromel wire 11 wound around the terminal 5b are not covered with an insulating coating, so that the high-frequency conducting wire 13 and the chromel wire 11 are electrically connected to the terminal 5b. .

A groove is formed in the central portion of the terminal 5c along the longitudinal direction of the terminal 5c. The alumel wire 12 extends from the cover tube 4 and is fixed to the terminal 5c in a state in which the tip thereof is integrally wound around the groove of the terminal 5c. The portion of the alumel wire 12 wound around the terminal 5c is not covered with an insulating coating, so that the alumel wire 12 is electrically connected to the terminal 5c.

When this electrode unit 1 is used in stereotactic neurosurgery, it is attached to, for example, a stereotactic neurosurgery instrument 30 (medical treatment instrument) shown in FIG. This stereotaxic neurosurgery instrument 30 includes a fixing ring 31, an arm 32, a stopper 33, a guide 34, and the like. The fixed ring 31 is fixed to the head H of the patient to be operated, and the arm 32 (frame) is attached to the fixed ring 31 so as to be rotatable about the axis 31a of the fixed ring 31 .

A stopper 33 (fixing tool) is attached to the tip of the arm 32 , and a guide 34 is attached to a portion of the arm 32 closer to the fixing ring 31 than the stopper 33 .

As shown in FIG. 7, the stopper 33 is formed in a cylindrical shape and has a recess 33b and three through holes 33a. The recessed portion 33b is a countersunk hole of a predetermined depth arranged in the central portion of the upper surface of the stopper 33, and has a shape in which three holes overlap each other when viewed from above. The three through holes 33a are formed side by side in the bottom of the recess 33b and pass through the stopper 33 in the vertical direction in FIG. The number of through holes 33a of the stopper 33 is not limited to three, and may be one to two or four or more.

Further, as shown in FIG. 8, the guide 34 has a hollow cylindrical shape with a diameter decreasing toward the tip, and three through holes 34a are formed in the central portion thereof. The three through holes 34a are arranged side by side and pass through the guide 34 in the vertical direction in FIG. The number of through holes 34a of the guide 34 is not limited to three, and may be one to two or four or more.

When the electrode unit 1 is used with monopolar output during stereotactic neurosurgery, as shown in FIG. inserted into the Then, the electrode unit 1 is fixed to the stereotaxic neurosurgical instrument 30 by inserting the needle base 3 into the recess 33b of the stopper 33 and engaging with the edge of the recess 33b.

With the electrode unit 1 fixed to the stereotaxic neurosurgical instrument 30 as described above, the terminals 5b and 5c of the connector 5 are inserted into the plugs of the high-frequency power generator (not shown). As a result, high-frequency power is supplied from the high-frequency power generation device to the high-frequency lead wire 13, and the high-frequency power is emitted from the tip of the electrode 2 to the treatment site (treatment target) of the brain, thereby performing thermal coagulation treatment. . At that time, the high-frequency power generator measures the temperature of the treatment site based on the potential difference between the chromel wire 11 and the alumel wire 12 .

On the other hand, when the two electrode units 1, 1 are used for bipolar output, although not shown, the two electrodes 2 are inserted into the left and right holes 33a of the stopper 33, respectively, and then the left and right holes 34a of the guide 34 are inserted. , the two needle bases 3 are engaged with the edges of the recess 33b of the stopper 33 and fixed. Then, during treatment, a high-frequency current is passed between the two electrode units 1,1.

As described above, according to the electrode unit 1 of the first embodiment, one end of the high-frequency conducting wire 13 is soldered to the base end of the electrode 2 while being integrated with the chromel wire 11 and the alumel wire 12. . Therefore, when assembling the electrode unit 1, the work of fixing the high-frequency lead wire 13 to the electrode 2 in a conductive state and the work of fixing the three wires 11 to 13 to the electrode 2 are simultaneously performed by soldering. be able to.

Also, since the three wires 11 to 13 are soldered to the proximal end of the electrode 2, the soldering work can be easily performed compared to the case of soldering them to the distal end of the electrode 2. As described above, the assembly work of the electrode unit 1 can be facilitated, and the manufacturing cost can be reduced accordingly.

In addition to this, the temperature of the electrode 2 can be measured by the thermocouple 10, which is relatively simple and highly versatile, so that the manufacturing cost of the electrode unit 1 can be further reduced.

Furthermore, since the chromel wire 11 and the alumel wire 12 are coated with an insulating coating, even when the chromel wire 11 and the alumel wire 12 are fixed to the electrode 2 via the solder 20, the chromel wire 11 and the alumel wire 12 can be Between the electrodes 2 can be maintained in an insulated state.

For the same reason, even if the three wires 11 to 13 are set in the same wiring path, the high-frequency conducting wire 13 does not need to be insulated and the degree of freedom in wiring between them can be improved.

Next, the electrode unit 1A of the second embodiment will be described with reference to FIGS. 9-10. The electrode unit 1A of the present embodiment differs from the electrode unit 1 of the first embodiment only in the method of fixing the high-frequency lead wire 13 to the electrode 2, as shown in FIGS. , different points will be mainly described, and the same reference numerals will be assigned to the same configurations as in the first embodiment, and the description thereof will be omitted.

In this electrode unit 1A, as shown in both figures, the tip of the high-frequency conducting wire 13 is spirally wound around the outer peripheral surface of the base end of the electrode 2, and in this state, the solder 21 (connection part) to the electrode 2 . This solder 21 is provided in a belt shape so as to cover the surface of the electrode 2 , and the tip of the high-frequency lead wire 13 is embedded in the solder 21 . As a result, the high-frequency conducting wire 13 is in a state of electrical continuity with the electrode 2 .

A solder 21 (connecting portion) is provided at the proximal end of the electrode 2 so as to close the proximal opening of the electrode 2 . is fixed to the electrode 2 .

As described above, according to the electrode unit 1A of the second embodiment, effects similar to those of the electrode unit 1 of the first embodiment can be obtained. In addition, since one end of the high-frequency conducting wire 13 is spirally wound around the outer peripheral surface of the electrode 2 and soldered, the high-frequency conducting wire 13 can be firmly fixed to the electrode 2 in a conducting state. can be done.

Each embodiment is an example using a K-type thermocouple 10, but the thermocouple of the present invention is not limited to this, and may be of other types such as N-type and E-type. As long as it is equipped.

Further, each embodiment is an example in which the chromel wire 11 and the alumel wire 12 of the thermocouple 10 are directly connected to the connector 5, but instead of this, the chromel wire 11 and the alumel wire 12 are indirectly connected to the connector 5. may be configured to be connected to For example, a substrate may be provided in the needle base 3, two compensating conductors may be used to connect the substrate and the connector, and one end of the chromel wire 11 and the alumel wire 12 may be connected to the substrate.

Furthermore, each embodiment is an example using the thermocouple 10 as a temperature sensor, but the temperature sensor of the present invention is not limited to this, and may be arranged on electrodes. For example, a thermistor or a platinum resistance thermometer may be used as the temperature sensor. In that case, the high-frequency conducting wire 13 and the temperature sensor itself may be soldered to the electrode 2 , or the high-frequency conducting wire 13 and the temperature sensor conducting wire may be soldered to the electrode 2 .

On the other hand, each embodiment is an example using a cylindrical electrode 2, but the electrode of the present invention is not limited to this, and may have an internal space that accommodates at least part of the temperature sensor. For example, the electrodes may be hollow rods having a polygonal cross section. Further, each embodiment is an example in which an electrode 2 having a shape having a stepped portion is used, but an electrode 2 having a shape without a stepped portion may be used.

Moreover, although each embodiment is an example in which the electrode unit 1 is used for stereotactic neurosurgery, the application of the electrode unit of the present invention is not limited to this, and can be used for various treatments using high-frequency power. For example, the electrode unit of the present invention may be used for ablation therapy other than stereotactic neurosurgery.

Furthermore, each embodiment is an example using the solders 20 and 21 as the connecting portion, but the connecting portion of the present invention may instead use a conductive brazing material welded to the electrodes. . In that case, for example, silver solder, copper solder, brass solder, or the like may be used as the brazing material.

Furthermore, the second embodiment is an example in which the tip of the high-frequency conducting wire 13 is spirally wound around the outer peripheral surface of the proximal end of the electrode 2 and soldered. may be fixed to the proximal end of the electrode 2 by soldering or brazing.

Next, an electrode unit 1B according to the third embodiment will be described. As shown in FIG. 11, the electrode unit 1B of the third embodiment has a needle base 3B. As is clear from a comparison of FIGS. 3 and 11, the needle base 3B is configured to have a smaller diameter than the needle base 3 of the electrode unit 1 of the first embodiment.

In the case of the needle base 3 of the first embodiment, the proximal end of the electrode 2 is in contact with the stepped portion of the inner hole of the needle base 3, whereas in the case of the needle base 3B, the inner hole is A step like the needle base 3 does not exist. Furthermore, the proximal end of the electrode 2 is fixed to the needle base 3 via an adhesive (not shown) in a state where the outer peripheral surface thereof fits into the surface of the inner hole of the needle base 3B.

In the case of the electrode unit 1B configured as described above, when using the two electrode units 1B, 1B with bipolar output, it has the following advantages over the electrode unit 1 of the first embodiment. there is

That is, in the case of the electrode unit 1 of the first embodiment, one electrode unit 1 is already attached to the stereotaxic neurosurgery instrument 30, and the operator grasps the needle base 3 of the remaining electrode unit 1. When inserting into the hole 33 a of the stopper 33 , the operator's finger or the needle base 3 may interfere with the adjacent needle base 3 .

On the other hand, in the case of the electrode unit 1B of the third embodiment, since the needle base 3B has a smaller diameter than the needle base 3 of the electrode unit 1 of the first embodiment, the above interference state occurs. Hateful. As a result, when the two electrode units 1B, 1B are used with bipolar output, it is possible to easily attach them to the stereotaxic neurosurgical instrument 30. FIG.

Further, as described above, in the case of the electrode unit 1B of the third embodiment, there is no stepped portion in the inner hole of the needle base 3B unlike the needle base 3 of the electrode unit 1 of the first embodiment. Thereby, when assembling the electrode unit 1B, it is possible to adjust the position where the proximal end of the electrode 2 is fixed to the needle base 3B. As a result, even if the length of the electrodes 2 varies due to a manufacturing error or the like, the electrode unit 1B can be assembled while maintaining the length of the entire electrode unit 1B constant without being affected by the variations.

Next, an electrode unit 1C of a fourth embodiment will be described with reference to FIG. The electrode unit 1C of the present embodiment differs from the electrode unit 1 of the first embodiment in the method of holding the chromel wire 11 and the alumel wire 12 as shown in FIG. The explanation will be focused, and the same components as those of the electrode unit 1 of the first embodiment will be given the same reference numerals, and the explanation thereof will be omitted.

In the case of this electrode unit 1C, as shown in FIG. 12, a solder 22 and an adhesive 23 are provided at the proximal end of the electrode 2 so as to close the proximal end opening of the electrode 2. As shown in FIG. The solder 22 is configured in an arcuate shape when viewed from the axial direction, and the adhesive 23 is configured in a shape of a circle with the arcuate portion removed. In this embodiment, the solder 22 corresponds to the connecting portion and the first connecting portion, and the adhesive 23 corresponds to the connecting portion and the second connecting portion.

The high-frequency conducting wire 13 is fixed to the electrode 2 via solder 22 , and the chromel wire 11 and alumel wire 12 are fixed to the electrode 2 via adhesive 23 . This is for the following reasons.

That is, when trying to solder the chromel wire 11 and the alumel wire 12 together with the high-frequency conducting wire 13 as in the electrode unit 1 of the first embodiment, the insulation coating of the chromel wire 11 and the alumel wire 12 is soldered. It is necessary to carry out the soldering operation while being careful not to peel off due to the heat of the operation. On the other hand, in the case of the electrode unit 1C of the present embodiment, since the chromel wire 11 and the alumel wire 12 are fixed to the electrode 2 via the adhesive 23, such a careful work is not required. , the chromel wire 11 and the alumel wire 12 can be more easily fixed to the electrode 2 .

1 electrode unit 1A electrode unit 1B electrode unit 2 electrode 10 thermocouple (temperature sensor)
11 Chromel wire 12 Alumel wire 13 Conductor wire for high frequency 20 Solder (connection part)
21 Solder (connection)
22 solder (connection part, first connection part)
23 Adhesive (connection part, second connection part)
30 Stereotaxic Neurosurgical Instrument (Medical Treatment Instrument)
32 arm (frame)
33 stopper (fixing tool)
34 guide

Claims (6)

an electrode placed on a treatment target;
a high-frequency conductor for electrically connecting the electrode to a high-frequency power generation device that generates high-frequency power;
a temperature sensor positioned on the electrode;
a connecting portion that electrically connects the high-frequency conducting wire and the electrode and that holds the temperature sensor or the sensor conducting wire electrically connected to the temperature sensor at a single specified portion of the electrode;
An electrode unit comprising: In the electrode unit according to claim 1,
The electrode unit according to claim 1, wherein the connecting portion is made of solder or conductive brazing material welded to the electrode. In the electrode unit according to claim 1,
The connection portion has a first connection portion made of solder or a conductive brazing material welded to the electrode, and a second connection portion made of an adhesive,
The high-frequency conducting wire is connected to the electrode by the first connecting portion,
The electrode unit, wherein the temperature sensor or the sensor wire is held by the second connection portion. In the electrode unit according to claim 2 or 3,
the electrode has an internal space that accommodates at least a portion of the temperature sensor;
The electrode unit, wherein the specified portion is a base end side opening connected to the internal space. In the electrode unit according to any one of claims 1 to 3,
The electrode unit, wherein the temperature sensor is composed of a thermocouple with an insulating coating. A medical treatment instrument to which the electrode unit according to any one of claims 1 to 3 is attached during use,
The electrode unit further comprises a needle base to which the electrode is fixed,
The medical treatment instrument is
a guide for guiding the electrode;
a fixture for fixing the needle base;
a frame to which the guide and the fixture are attached;
A medical treatment instrument comprising:

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