阅读说明：本技术 高频处置器具 (High-frequency treatment tool ) 是由 樋高裕也 冈本春树 于 2016-06-02 设计创作，主要内容包括：高频处置器具包括：细长的筒状的护套；直棒状的电极构件,其以能够沿长度轴线方向进退的方式配置在该护套内,并被供给高频电流；顶端构件,其配置于护套的顶端,并具有供电极构件贯穿的通孔；以及送液部件,其连接于护套的基端侧,电极构件包括：电极顶端部,其设于电极构件的顶端且向径向外方呈放射状延伸；以及大致旋转体形状的止挡件部,其配置在比顶端构件靠基端侧的位置,顶端构件具有朝向顶端变得尖细的锥形内表面,在电极构件最大限度地移动到顶端侧时,止挡件部在长度轴线方向上抵靠于该锥形内表面,在该锥形内表面和止挡件部中的任一者上设有凹部,该凹部构成在该锥形内表面和止挡件部相互抵靠的状态下能够使液体流通的流路。(A high-frequency treatment instrument includes: an elongated cylindrical sheath; a straight rod-shaped electrode member which is disposed in the sheath so as to be able to advance and retreat in the longitudinal axis direction and to which a high-frequency current is supplied; a tip member disposed at the tip of the sheath and having a through hole through which the electrode member passes; and a liquid feeding member connected to the proximal end side of the sheath, the electrode member including: an electrode tip portion provided at a tip of the electrode member and extending radially outward in a radial direction; and a stopper portion of a substantially rotor shape disposed on a base end side of the tip member, the tip member having a tapered inner surface tapered toward a tip end, the stopper portion abutting against the tapered inner surface in a longitudinal axis direction when the electrode member moves to the tip end side to the maximum, and a recess portion constituting a flow path through which a liquid can flow in a state in which the tapered inner surface and the stopper portion abut against each other being provided on either the tapered inner surface or the stopper portion.)

1. A high-frequency treatment tool, wherein,

the high-frequency treatment tool includes:

a long and thin cylindrical sheath in which a sheath flow path is formed;

an electrode member which is disposed in the sheath so as to be capable of advancing and retreating in the longitudinal axis direction and to which a high-frequency current is supplied;

a tip member disposed at the tip of the sheath and having a through hole through which the electrode member passes and which communicates with the sheath flow passage via a gap between the tip member and the electrode member,

the electrode member includes a columnar portion, an electrode tip portion provided at a tip end of the columnar portion, and a stopper portion provided at a base end of the columnar portion and capable of abutting against a tapered inner surface on a base end side of the tip member,

a recess portion that communicates the sheath flow path with the through hole in a state where the tapered inner surface and the stopper portion abut against each other is provided in the stopper portion or the tapered inner surface,

the electrode tip portion includes, in a circumferential direction, protruding portions extending radially outward of a diameter of the circular through hole in a radial direction of the electrode tip portion, and small-diameter portions recessed inward of the diameter of the through hole, and a position of the small-diameter portion in the circumferential direction coincides with a position of a flow path formed by the recessed portion.

2. A high-frequency treatment instrument according to claim 1,

the tapered inner surface is in the shape of a conical inner surface that tapers toward the tip end side.

3. A high-frequency treatment instrument according to claim 1 or 2,

the stopper portion is in surface contact with the tapered inner surface with a tapered surface of a shape complementary to the tapered inner surface.

4. A high frequency treatment instrument according to claim 3,

the tapered surface is concentric with the cylindrical portion.

5. A high frequency treatment instrument according to claim 3,

the tapered surface is provided with the concave portion that is recessed radially inward and extends along the longitudinal axis direction.

6. A high-frequency treatment instrument according to claim 1 or 2,

the stopper portion has a cylindrical edge or a spherical solid shape and is in line contact with the tapered inner surface in a circular ring shape.

7. A high-frequency treatment instrument according to claim 6,

the stopper portion is provided with the recess that is recessed radially inward and extends in the longitudinal axis direction at a portion that contacts the tapered inner surface.

8. A high-frequency treatment instrument according to claim 1 or 2,

the concave portion is provided on the tapered inner surface.

9. A high-frequency treatment instrument according to claim 1 or 2,

in a state where the electrode member is maximally retracted, the protruding portion abuts against the distal end surface of the tip member, and only the electrode distal end portion is exposed to the distal end surface of the tip member.

10. A high-frequency treatment instrument according to claim 1 or 2,

the top end part of the electrode is in a polygonal, star-shaped or oval flat plate shape.

Technical Field

The present invention relates to a high-frequency treatment instrument.

Background

Conventionally, there is known a high-frequency treatment instrument for treating a living tissue such as a mucous membrane by applying a high-frequency current (see, for example, patent document 1).

The rod-shaped electrode portion of the high-frequency treatment instrument is inserted into a through hole of an electrically insulating cover member provided at the distal end of the sheath so as to be capable of advancing and retreating in the axial direction, and has a structure capable of discharging the liquid fed inside the sheath forward through a liquid feeding opening of the cover member.

Since the distal end portion of the rod-shaped electrode portion is provided with the radially extending distal end portion, at least a part of the liquid feeding opening is formed to be exposed to the outside of the distal end portion when the cover member is viewed from the front, and the liquid discharged from the liquid feeding opening is prevented from being blocked on the back side of the distal end portion of the rod-shaped electrode portion. In the high-frequency treatment instrument of patent document 1, the liquid feeding opening is configured to have a non-circular shape having a small diameter portion supported in proximity to the rod-shaped electrode portion and a large diameter portion exposed to the outside of the distal end portion.

Documents of the prior art

Patent document

Patent document 1: japanese laid-open patent publication No. 2012 and 70793

Disclosure of Invention

Problems to be solved by the invention

However, since the cover member is an extremely small member requiring precise machining, it is not easy to precisely form the non-circular liquid feeding opening. On the other hand, when the liquid feeding opening is formed in a simple shape such as a circular shape which is easy to process, the diameter of the liquid feeding opening needs to be increased so as to be exposed to the outside of the distal end portion in a plan view in order to discharge the liquid straight forward.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a high-frequency treatment instrument which can be easily manufactured while satisfying both smooth liquid feeding and stable support of an electrode.

Means for solving the problems

In order to achieve the above object, the present invention provides the following technical solutions.

An aspect of the present invention provides a high-frequency treatment instrument, including: an elongated cylindrical sheath inserted into the body; a straight rod-shaped electrode member which is disposed in the sheath so as to be able to advance and retreat in the longitudinal axis direction and to which a high-frequency current is supplied; a tip member disposed at the tip of the sheath and having a through hole through which the electrode member passes; and a liquid feeding member connected to a proximal end side of the sheath and discharging a liquid to a front side in a longitudinal axis direction of the sheath through a flow path formed in the sheath and a gap between the electrode member and the through hole communicating with the flow path, wherein the electrode member includes an electrode tip portion provided at a tip end of the electrode member and radially extending outward in a radial direction, and a stopper portion of a substantially rotary body shape disposed on a proximal end side of the tip member and centered on a central axis of the electrode member, the tip member has a tapered inner surface tapered toward the tip end, the tapered inner surface abuts against the stopper portion in the longitudinal axis direction when the electrode member is maximally moved to the tip end side, and a concave portion is provided in either the tapered inner surface or the stopper portion, the concave portion being configured to enable the liquid to flow in a state where the tapered inner surface and the stopper portion abut against each other And a flow path which passes through the electrode tip portion, the electrode tip portion having a small diameter portion recessed in a radial direction at least in a part of a circumferential direction thereof, and the recessed portion being provided at the same circumferential position as the small diameter portion.

The electrode member is advanced relative to the sheath to increase the amount of protrusion of the electrode distal end portion and supply a high-frequency current to the electrode member, thereby performing a treatment such as cutting of a body tissue. When cutting or peeling off a tissue, the radial electrode tip portion is caught by a peripheral tissue, whereby a treatment can be stably performed without slipping.

In this case, when the electrode member is advanced, the stopper portion provided on the proximal end side of the electrode member abuts against the tapered inner surface of the distal end member disposed at the distal end of the sheath and having the electrode member inserted through the through hole, and the electrode member is restricted from further advancing. In this case, the stopper portion is formed in a substantially rotor shape, so that when the stopper portion abuts against the tapered inner surface, the stopper portion abuts against the tapered inner surface at each position surrounding the electrode member, whereby the electrode member can be held in a centered state with respect to the through hole.

In this case, a flow path is formed between the tapered inner surface and the stopper portion abutting against each other by a recess provided in either one of the tapered inner surface and the stopper portion. When bleeding occurs in a site to be treated, the liquid feeding means is operated to discharge the liquid to the front side in the longitudinal axis direction of the sheath through the flow path formed in the sheath and the gap between the electrode member and the through hole of the tip member provided at the tip end of the sheath, whereby the liquid can be discharged to the vicinity of the bleeding site and washed.

In addition, the phase of the flow path formed by the recess and the phase of the small diameter portion of the electrode tip portion are always kept in a state in which the stopper portion and the tapered inner surface are in abutment with each other, and even if the electrode tip portion is rotated about the longitudinal axis with respect to the through hole, the liquid discharged from the flow path can always be discharged straight forward via the small diameter portion of the electrode tip portion.

In this case, the electrode member is also firmly supported by abutting the tapered inner surface and the stopper portion at each position surrounding the electrode member, and therefore, even if liquid flows in the gap between the electrode member and the through hole, the electrode tip portion is kept from vibrating.

That is, according to the present invention, the electrode member is not supported by the through hole, but is centered and firmly supported by the abutment between the tapered inner surface provided on the tip member and the stopper portion provided on the electrode member, so that the gap between the through hole and the electrode member can be sufficiently secured. As a result, the liquid discharged forward through the gap can be discharged without being obstructed by the electrode tip portion and without causing the electrode member to vibrate.

In the above aspect, the stopper portion may have a tapered surface that comes into surface contact with the tapered inner surface.

With this arrangement, the electrode member can be more firmly supported by the distal end member while being centered on the through hole by the surface contact between the stopper portion and the tapered inner surface.

In the above aspect, a projected shape of the through hole in the longitudinal axis direction at the distal end opening may be a circle, and a projected shape of the electrode distal end portion in the longitudinal axis direction may be a non-circle having an inscribed circle larger than a diameter of the distal end opening and an inscribed circle smaller than the diameter.

With this arrangement, when the electrode member is retracted to the maximum extent relative to the sheath, the radially protruding portion of the electrode distal end portion formed into a non-circular shape abuts against the distal end surface of the distal end member relative to the distal end opening of the through hole formed into a circular shape, and the electrode member is restricted from being further retracted. In addition, in the distal end opening of the through hole formed in a circular shape, the liquid discharged from the distal end opening is easily discharged straight forward without being completely blocked by the electrode distal end portion at the portion of the electrode distal end portion formed in a non-circular shape that protrudes in the radial direction.

In the above aspect, the stopper portion may be formed with the recess.

With this arrangement, the phase between the flow path formed by the recess and the electrode tip portion is always kept constant in a state where the stopper portion and the tapered inner surface abut against each other, and the flow path is prevented from being changed by the electrode tip portion even if the electrode tip portion is rotated about the longitudinal axis with respect to the through hole.

In the above aspect, the plurality of small diameter portions may be provided at equal intervals in the circumferential direction, and the recess may be provided at a position corresponding to each of the small diameter portions.

With this configuration, the flow of the liquid discharged straight forward of the electrode tip portion via the recess and the small diameter portion can be distributed evenly in the circumferential direction without being offset in the circumferential direction of the electrode tip portion, and the liquid can be discharged straight forward.

ADVANTAGEOUS EFFECTS OF INVENTION

According to the present invention, smooth liquid feeding and stable electrode supporting can be achieved at the same time, and the present invention has an effect of facilitating manufacturing.

Drawings

Fig. 1 is an enlarged partial overall configuration diagram of a distal end portion of a high-frequency treatment instrument according to an embodiment of the present invention.

Fig. 2 is an enlarged vertical cross-sectional view showing a distal end portion of the high-frequency treatment instrument of fig. 1 in a state where an electrode member is maximally retracted.

Fig. 3 is a perspective view showing an electrode member of the high-frequency treatment instrument of fig. 1.

Fig. 4 is a front view showing a relationship between an electrode distal end portion of the high-frequency treatment instrument of fig. 1 and a through hole of a support member.

Fig. 5 is a partial vertical cross-sectional view showing a tip portion of a modification of the high-frequency treatment instrument of fig. 1.

Fig. 6 is a partial vertical cross-sectional view showing a distal end portion of another modification of the high-frequency treatment instrument of fig. 1.

Fig. 7 is a partial vertical cross-sectional view showing a distal end portion of another modification of the high-frequency treatment instrument of fig. 1.

Fig. 8 is a perspective view showing a stopper portion of another modification of the high-frequency treatment instrument of fig. 1.

Fig. 9 is a cross-sectional view of a top end portion of the stopper portion of fig. 8.

FIG. 10 is a partial longitudinal cross-sectional view of the distal end portion of the high-frequency treatment instrument of FIG. 8.

Detailed Description

Hereinafter, a high-frequency treatment instrument 1 according to an embodiment of the present invention will be described with reference to the drawings.

The high-frequency treatment instrument 1 of the present embodiment is, for example, a treatment instrument whose distal end is introduced into the body through a channel provided in an insertion portion of an endoscope, and includes, as shown in fig. 1: a sheath 2 formed in an elongated cylindrical shape insertable into the passage and having flexibility; an electrode member 3 which advances and retreats at the distal end of the sheath 2; an operation unit 4 that pushes and pulls the electrode member 3 toward the proximal end of the sheath 2; and a liquid feeding member 5 that discharges liquid from the distal end of the sheath 2 through an inner hole (flow path) 2a of the sheath 2.

A plug-shaped distal end member 6 is fixed to the distal end of the sheath 2 so as to close the inner hole 2 a. As shown in fig. 2, the distal end member 6 is provided with a through hole 6a that penetrates in the longitudinal axis direction and through which the electrode member 3 movably penetrates. The through hole 6a has a circular cross section, and a tapered inner surface 6b having a conical inner surface shape that is tapered toward the tip end side is provided on the base end side thereof. The sheath 2 and the distal end member 6 are made of an electrically insulating material.

The electrode member 3 is made of a conductive material. The electrode member 3 includes: a columnar portion 3a having a circular cross section and having a diameter size sufficiently smaller than that of the through-hole 6 a; a 3-corner flat-plate-like electrode tip portion 3b provided at the tip of the columnar portion 3a and radially extending outward; and a stopper portion 7 provided at the base end of the columnar portion 3a, having a cross-sectional shape with a diameter larger than that of the columnar portion 3a, the stopper portion 7 being configured in a columnar shape concentric with the columnar portion 3 a. The stopper portion 7 has a tapered surface 7a having a shape complementary to the tapered inner surface 6b on the distal end side.

The tapered surface 7a is provided with groove-like recesses 9 recessed radially inward at 3 at intervals in the circumferential direction and extending in the longitudinal axis direction. As shown in fig. 3, each recess 9 is provided at a circumferential position corresponding to the center of each side of the 3-corner-shaped electrode tip portion 3 b.

As shown in fig. 4, the electrode tip portion 3B has a shape in which the circumscribed circle a is larger than the diameter of the through-hole 6a and the inscribed circle B is smaller than the diameter of the through-hole 6 a. Preferably, the circumscribed circle A has a size ofThe size of the through-hole 6a isThus, when the electrode member 3 is moved to the proximal end side as much as possible with respect to the distal end member 6, most of the electrode member 3 is accommodated in the sheath 2, and the rear surface of the electrode distal end portion 3b abuts against the distal end surface 6c of the distal end member 6, thereby restricting the electrode member 3 from continuing to retreat. At this time, as shown in fig. 4, the circular through hole 6a is exposed radially outward of the electrode distal end portion 3b without being completely closed by the electrode distal end portion 3b, and is partially opened by the opening 10.

Further, as shown in fig. 1, when the electrode distal end portion 3b is moved to the distal end side to the maximum extent with respect to the distal end member 6, the electrode member 3 protrudes forward from the distal end surface 6c of the distal end member 6, and the tapered surface 7a of the stopper portion 7 abuts against the tapered inner surface 6b of the distal end member 6, thereby restricting the electrode member 3 from further advancing. At this time, the tapered surface 7a having a shape complementary to the tapered inner surface 6b is in close contact with the tapered inner surface 6b by surface contact, and the electrode member 3 is firmly supported by the distal end member 6. Further, the tapered surface 7a concentric with the columnar portion 3a of the electrode member 3 is made to fit against the tapered inner surface 6b connected to the through hole 6a, whereby the electrode member 3 is aligned (centered) with its central axis with the through hole 6 a.

The operation section 4 includes: a handle 4b attached to the proximal end side of the sheath 2 and having a finger hooking hole 4 a; a movable portion 4c provided on the handle 4b so as to be movable in the longitudinal axial direction of the sheath 2; and a wire 4d disposed in the inner hole 2a of the sheath 2 and connecting the movable portion 4c and the electrode member 3, the wire 4d being made of a conductive material. In the figure, reference numeral 4e denotes a finger hooking hole provided in the movable portion 4 c.

When the movable portion 4c is moved toward the distal end side of the sheath 2 with respect to the handle 4b, the pressing force is transmitted to the electrode member 3 via the wire 4d, and the electrode member 3 moves in the forward direction with respect to the distal end member 6. When the movable portion 4c is moved toward the proximal end side of the sheath 2 with respect to the handle 4b, the pulling force is transmitted to the electrode member 3 via the wire 4d, and the electrode member 3 is retracted in a direction of being drawn into the through hole 6a of the distal end member 6.

A power supply, not shown, is connected to the proximal end side of the wire 4d, and a high-frequency current can be supplied to the electrode member 3 via the wire 4 d.

The handle 4b is provided with a connection port 8 communicating with the inner hole 2a of the sheath 2.

The liquid feeding unit 5 is a syringe, a pump, or the like connected to the connection port 8, and feeds a liquid such as a physiological saline solution into the inner hole 2a of the sheath 2 by the operation of the liquid feeding unit 5.

The operation of the high-frequency treatment instrument 1 of the present embodiment configured as described above will be described below.

When the endoscopic submucosal dissection is performed using the high-frequency treatment instrument 1 according to the present embodiment, the operation section 4 is operated to introduce the sheath 2 into the body from the distal end side through the channel of the insertion section of the endoscope in a state where the electrode member 3 is maximally retracted, and to protrude the distal end of the sheath 2 from the distal end of the insertion section of the endoscope, as shown in fig. 4.

Thus, the distal end portion of the sheath 2 enters the field of view of the endoscope, and the operator performs treatment while checking the image acquired by the endoscope with the monitor. Since only the electrode distal end portion 3b of the electrode member 3 is exposed to the distal end surface 6c of the distal end member 6 in the state where the electrode member 3 is maximally retracted, even if a high-frequency current is applied to the electrode member 3 in this state, the tissue is not deeply incised, and so-called marking, in which only the tissue surface is cauterized, can be performed.

That is, the operator can form a mark surrounding the lesion site to be excised by pressing the distal end surface 6c of the distal end member 6 against a plurality of sites surrounding the site of the lesion considered to be excised in the endoscopic image displayed on the monitor and applying current to the electrode member 3, and can set the target of the subsequent treatment.

Thereafter, the operation unit 4 is operated to protrude the electrode member 3 from the distal end surface 6c of the distal end member 6 as shown in fig. 3, and a high-frequency current is applied to incise the tissue and to pierce the distal end member 6 into the vicinity of the submucosal layer below the lesion site. Next, the operation operating unit 4 is operated to retract the electrode member 3 to the maximum extent, and the liquid feeding member 5 is operated to discharge a liquid such as a physiological saline solution from the opening 10 of the distal end surface 6 c. Thus, the liquid is locally injected into the submucosa, and the lesion site is highlighted.

In this state, the sheath 2 is pulled out from the submucosal layer, the operation unit 4 is operated again to project the electrode member 3, and the tissue around the lesion site is incised with a mark formed by marking as a target.

When bleeding occurs during incision, the liquid feeding unit 5 is operated to discharge a liquid such as physiological saline from the opening 10 of the distal end surface 6c of the distal end member 6, and the cleaning is performed.

In this case, when the electrode member 3 is advanced to the maximum extent with respect to the sheath 2 and the electrode distal end portion 3b is projected from the distal end surface 6c of the distal end member 6, the tapered surface 7a of the stopper portion 7 comes into close contact with the tapered inner surface 6b of the distal end member 6, and the electrode member 3 is fixed in a state centered with respect to the through hole 6 a. Even in a state where the tapered surface 7a and the tapered inner surface 6b are in close contact with each other, the recess 9 provided in the tapered surface 7a maintains a state where the front and rear spaces of the stopper 7 communicate with each other.

In this state, when the liquid feeding means 5 is operated, the liquid fed through the inner hole 2a of the sheath 2 is discharged to the front of the distal end member 6 through the gap C formed between the tapered surface 7a and the tapered inner surface 6b by the concave portion 9 and further through the cylindrical gap C between the columnar portion 3a and the through hole 6 a.

Although a force that vibrates the columnar portion 3a acts due to the flow of the fluid flowing through the gap C between the columnar portion 3a and the through hole 6a, since the electrode member 3 is firmly supported by the tip member 6 by bringing the tapered surface 7a into close contact with the tapered inner surface 6b, the vibration of the columnar portion 3a is suppressed to a small level, and the fluid can be stably discharged forward of the tip member 6.

Namely, there are advantages in that: even if the inner diameter of the through hole 6a is made sufficiently larger than the outer diameter of the columnar portion 3a, since the columnar portion 3a is supported so as not to vibrate by the adhesion between the tapered surface 7a and the tapered inner surface 6b, the flow area between the through hole 6a and the columnar portion 3a can be secured sufficiently large, and a large flow rate of fluid can be discharged smoothly. This enables more reliable and rapid flushing of bleeding.

In addition, there are also advantages in that: since the columnar portion 3a is supported so as not to vibrate in the radial direction without using the through hole 6a, the through hole 6a itself can be formed in a simple cross-sectional circular shape having an inner diameter sufficiently larger than the outer diameter of the columnar portion 3a, and can be easily manufactured.

When the liquid locally injected into the submucosa in the middle of cutting the peripheral tissue of the affected part is absorbed by other parts and the affected part sinks, the tip member 6 is pressed against the submucosa again to locally inject the liquid. In this case, too, the electrode member 3 can be retreated to eject the liquid to the maximum extent, so that the electrode member 3 does not excessively pierce the tissue.

In this case as well, in the high-frequency treatment instrument 1 of the present embodiment, even when the electrode member 3 is retracted to the maximum extent and the electrode distal end portion 3b is brought into contact with the distal end surface 6c of the distal end member 6, the large-diameter through hole 6a is exposed and opened outward in the radial direction of the 3-corner-shaped electrode distal end portion 3b, and therefore, it is possible to discharge liquid from the opening 10. In particular, since the phase of the recess 9 provided in the tapered surface 7a is aligned with the phase of the portion (small diameter portion) of the electrode tip portion 3b in which the amount of projection in the radial direction is small, the fluid flowing through the recess 9 can be easily discharged forward without being completely blocked by the electrode tip portion 3 b.

In the present embodiment, the electrode tip portion 3b is in the form of a triangular flat plate, but the present invention is not limited to this, and any electrode tip portion 3b in which radially protruding portions and radially recessed portions are alternately arranged in the circumferential direction may be used, such as a polygon having 4 sides or more, a star shape, or an oval shape. Any shape may be used as long as the circumscribed circle a and the inscribed circle B are larger than the diameter of the through-hole 6a and smaller than the diameter of the through-hole 6 a. In these cases, it is preferable to provide the groove-like recessed portion 9 at a position corresponding to the portion (small diameter portion) recessed in the radial direction.

In the present embodiment, the stopper portion 7 has a tapered surface 7a that is in surface contact with the tapered inner surface 6b, but instead of the tapered surface 7a, a circular line contact system having a rotating body shape such as a cylindrical edge 7b or a spherical surface 7c as shown in fig. 5 and 6 may be adopted.

Further, the groove-like recess 9 for allowing the fluid to flow between the tapered surface 7a and the tapered inner surface 6b even when the tapered surface 7a is in close contact with the tapered inner surface 6b is provided on the tapered surface 7a side, but instead, the recess 9 may be provided on the tapered inner surface 6b side as shown in fig. 7.

In the present embodiment, the recess 9 of the stopper portion 7 is formed in a groove shape, but the present invention is not limited to this, and may be formed of a D-shaped cut portion 11 and grooves 12 provided at equal intervals around the longitudinal axis of the sheath 2 with the D-shaped cut portion 11 interposed therebetween along the longitudinal axis of the sheath 2 as shown in fig. 8 and 9. Reference numeral 13 is a hole provided for brazing the wire 4d to the stopper portion 7, and reference numeral 14 is a hole provided for brazing the columnar portion 3a to the stopper portion 7.

In this case, as shown in fig. 10, a gap E is formed between the tapered surface 7a and the tapered inner surface 6a by the D-cut portion 11, and a gap F is formed between the tapered surface 7a and the tapered inner surface 6a by the groove 12. Thus, the gap E formed by the D-shaped cut portion 11 having a larger groove width than the groove width of the groove 12 has a larger flow rate per unit time than the gap F formed by the groove 12, and therefore the total flow rate per unit time can be increased by the entire circumference of the stopper portion 7.

Description of the reference numerals

1. A high-frequency treatment tool; 2. a sheath; 2a, an inner hole (flow path); 3. an electrode member; 3b, electrode tip part; 5. a liquid feeding member; 6. a tip member; 6a, a through hole; 6b, a tapered inner surface; 7. a stopper portion; 7a, a conical surface; 9. a recess; C. a gap.