JP7183854B2 - Endoscope clip device - Google Patents

Description

TECHNICAL FIELD The present invention relates to an endoscopic clipping device used for hemostasis of living tissue.

2. Description of the Related Art An endoscopic clipping device is provided for resecting a body tissue in a body cavity under an endoscope and ligating the cut site to stop bleeding or block tissue. Regarding this type of endoscopic clipping device, Patent Document 1 discloses a clip, a clip connecting portion that connects the clip (referred to as a tip connecting portion in the same document), and a sleeve that accommodates the clip connecting portion. An endoscopic clipping device is disclosed that includes a treatment instrument body having an operation wire provided at a distal end thereof. The clip has an engaging portion that engages with the clip connecting portion on the proximal end side. The locking portion has a receiving portion for receiving the clip connecting portion, and a protruding portion protruding inward from the base end side of the receiving portion.

In particular, the endoscopic clipping device disclosed in Patent Document 1 has a function of indwelling a clip ligated with living tissue.
Specifically, after ligating the living tissue with the clip, the practitioner pulls the operation wire so as to retract the clip connecting portion from the sleeve to a position that is proximal to the sleeve and does not interfere with the sleeve. The projecting portion (a portion including the projecting portion is also called a projecting piece portion) is deformed outward. Due to the deformation of the projecting piece, the receiving portion is opened and the clip connecting portion can be removed from the locking portion. By removing the clip connecting portion from the locking portion, the clip is separated from the operation wire and left in the body cavity with the living tissue ligated.

Japanese Unexamined Patent Application Publication No. 2016-193002

However, in the endoscopic clipping device disclosed in Patent Document 1, when the clip is left in the body, the position of the protruding portion of the clip is limited to a position where deformation of the protruding portion of the clip is not interfered with by the sleeve. It had been.
Specifically, as described above, in a state in which the protrusion provided on the projecting piece of the clip is arranged on the proximal side of the sleeve, the clip connecting portion is retracted, and the projecting piece is moved by the clip connecting portion. It was pressed and deformed outward. In other words, the mutual relationship between the sleeve and the clip sometimes limits the degree of freedom in designing the length in the longitudinal direction (axial direction).
On the other hand, since clips come in various lengths depending on the ligation site and the forceps hole of the endoscope to which they are compatible, the restrictions on the length of the sleeve and clip described above can be relaxed. Therefore, there has been a demand for an endoscope clip device that is versatile and easy to use.

SUMMARY OF THE INVENTION The present invention has been made in view of the problems described above, and provides an endoscope clipping device that is versatile and easy to use with respect to clips of different lengths.

The endoscopic clipping device of the present invention comprises a clip having a plurality of arms for gripping living tissue and locking portions provided on the base end sides of the arms, a long sheath, and the sheath. a treatment instrument main body having a sleeve provided on the inner side of the distal side of the treatment instrument body, and an operation wire inserted movably forward and backward through the interior of the sleeve and provided with a lump-like tip connecting portion at the distal end; wherein the locking portion has a receiving portion having a space inside for receiving the distal end connecting portion, and a protruding piece portion having a protruding portion protruding inward from the base end side of the receiving portion. The projecting piece portion is elastically deformed outward by pressing the projecting portion from the distal end connecting portion, and the receiving portion is adapted to engage with the projecting portion. When the piece portion is deformed outward, it is opened so that the distal end connecting portion can be inserted in the advancing/retreating direction of the operation wire, and the arm portion can be used for the operation while the distal end connecting portion is received in the receiving portion. When the wire is pulled proximally in the advancing/retreating direction, the arm is closed to grasp the living tissue, and the sleeve has a deformable portion that can deform outward, and the deformable portion is adapted to the engaging portion. It is disposed at a position covering the projecting piece at a position where the clip is separated from the treatment instrument main body by unlocking the distal end connecting portion from the stop portion, and permits outward deformation of the projecting piece. Then, the tip connecting portion can be pulled out from the receiving portion.

According to the endoscopic clip device of the present invention, it is possible to provide an endoscopic clip device that is versatile and easy to use with respect to clips of different lengths.

It is a side view showing an example of a clip device concerning an embodiment of the present invention. 2 is a cross-sectional view showing a cross-section of the clip device shown in FIG. 1; FIG. FIG. 3 is an enlarged view of the III section of FIG. 2, and is an enlarged cross-sectional view showing the periphery of the clip connecting portion in a state where the clip is not attached. FIG. 10 is an explanatory view showing a state in which the clip connecting portion is pulled out from the locking portion of the clip; FIG. 10 is a cross-sectional view showing a cross section near the clip with the arms opened. FIG. 11 is a cross-sectional view showing a state in which the clip with its arms open is drawn toward the sheath; FIG. 11 is a side view showing the side of the clip with the arms open; FIG. 11 is a side view showing the side of the clip with the arms closed; It is a side view which shows the side surface of a sleeve. FIG. 10 is a view in the direction of arrow X in FIG. 9 and is a rear view showing the rear surface of the sleeve. FIG. 10 is a view in the direction of arrow XI in FIG. 9 and is a front view showing the front of the sleeve. It is an enlarged side view showing an enlarged sheath. FIG. 10 is an explanatory diagram showing a state in which the clip is accommodated in the sheath; FIG. 7 is a cross-sectional view showing a state in which the clip is drawn further toward the sheath from the state shown in FIG. 6;

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described below with reference to the drawings.
The embodiments described below are merely examples for facilitating understanding of the present invention, and do not limit the present invention. That is, the shape, size, arrangement, etc. of the members described below can be changed and improved without departing from the scope of the present invention, and the present invention naturally includes equivalents thereof.
Moreover, in all the drawings, the same constituent elements are denoted by the same reference numerals, and overlapping descriptions are omitted as appropriate.

＜＜Overview＞＞
First, an endoscope clipping device 100 (hereinafter also simply referred to as the clipping device 100) according to the present embodiment will be described with reference to FIGS. 1 to 4. FIG. FIG. 1 is a side view showing an example of a clip device 100 according to an embodiment of the invention, and FIG. 2 is a cross-sectional view showing a cross section of the clip device 100 shown in FIG. FIG. 3 is an enlarged view of the III section of FIG. 2, and is an enlarged cross-sectional view showing the periphery of the clip connecting portion 50 in a state where the clip 110 is not attached. FIG. 4 is an explanatory diagram showing a state in which the clip connecting portion 50 is pulled out from the engaging portion 130 of the clip 110. FIG.

In this specification, the term "axial direction" means the forward and backward direction of the wire rope 20, which will be described later, unless otherwise specified. In addition, unless otherwise specified, the term "cross section" means a vertical cross section obtained by cutting the clip device 100 in the axial direction. Unless otherwise specified, the “distal side” refers to the side of the clip device 100 or the clip 110 constituting the clip device 100 far from the operator. It means the side on which the part 120 is located. In addition, the “proximal side” refers to the side of the clip device 100 or clip 110 that is closer to the operator unless otherwise specified. Further, distal movement of the components of the clip device 100 may be referred to as advancing, and conversely, proximal movement may be referred to as retracting.

Note that FIG. 4 omits illustration of the coil spring 80, which will be described later, and in order to clarify the deformation state of the deformable portion 70a and the projecting piece portion 135, which will be described later, the amounts of deformation thereof are shown larger than they actually are. ing. 4 and the like, for convenience, the sleeve 70 and the tightening member 150, which will be described later, are shown in cross section and hatched, and the wire rope 20, the clip connecting portion 50, and the arm portion 120 are shown in side views. .

As shown in FIGS. 1 to 4, the endoscopic clipping device 100 according to the present embodiment includes a plurality of arms 120 for gripping a living tissue (not shown), and arms 120 provided on the proximal end side of the arms 120. A clip 110 having a locking portion 130 attached thereto, a long sheath 10, a sleeve 70 provided inside the distal side of the sheath 10, and a distal end inserted into the sleeve 70 so as to be movable forward and backward. and a treatment instrument main body 1 having an operation wire (wire rope 20) provided with a block-shaped distal end connecting portion (clip connecting portion 50).
The locking portion 130 includes a receiving portion 134 having a space for receiving the clip connecting portion 50 therein, and a projecting piece portion 135 having a projecting portion 140 formed to protrude inward from the base end side of the receiving portion 134 . It has and is comprised so that it can be latched by the clip connection part 50. As shown in FIG.
As shown in FIG. 4, the projecting piece 135 is pushed outward (outward in the radial direction of the wire rope 20 among the directions indicated by the arrows in FIG. 4) by pressing the projecting portion 140 from the clip connecting portion 50. It deforms elastically.
The receiving portion 134 is opened so that the clip connecting portion 50 can be inserted in the advancing/retreating direction of the wire rope 20 when the protrusion portion 135 is deformed outward.
When the wire rope 20 is pulled proximally in the advancing/retreating direction while the clip connecting portion 50 is received in the receiving portion 134, the arm portion 120 is closed and grips the living tissue.
The sleeve 70 has an outwardly deformable deformable portion 70a. As shown in FIG. 4, the deformable portion 70a is disposed at a position covering the projecting piece portion 135 at a position where the clip connecting portion 50 is released from the locking portion 130 and the clip 110 is separated from the treatment instrument main body 1. ing. The deformation portion 70 a is characterized by allowing the outward deformation of the protruding piece portion 135 to allow the clip connecting portion 50 to be pulled out from the receiving portion 134 .

According to the above configuration, the sleeve 70 can be deformed outward, so that when the clip 110 is left in the body, the position where it does not interfere with the sleeve 70 (in other words, the position shifted in the axial direction with respect to the sleeve 70) ). Therefore, it becomes easy to pull out the clip connecting portion 50 from the clip 110 (receiving portion 134) to separate the clip 110 from the treatment instrument main body 1 and leave it in the body. Therefore, the operability of the endoscope clipping device 100 and the versatility of clips having different lengths can be improved, and the operator's usability is improved.
Specifically, regarding the configuration of the deformable portion 70a that allows deformation of the projecting piece portion 135, the deformable portion 70a is pressed by the projecting piece portion 135, which is about to deform outward, and is deformed outward. Deformation of the projecting piece 135 is allowed.

<<Configuration>>
Next, the details of the configuration of the clip device 100 will be described. As shown in FIGS. 1, 2 and 4, the clip device 100 includes a clip 110 and a treatment instrument main body 1 for disposing and operating the clip 110 in the body and indwelling it in the body.
The treatment instrument main body 1 includes an elongated sheath 10, a housing main body portion 97 to which the proximal end of the sheath 10 is fixed, a sleeve 70 provided inside the distal side of the sheath 10, and a sheath 10. , a wire rope 20 having a clip connection 50 , and a finger ring 92 and a slider 94 for manipulating the wire rope 20 .

[clip]
First, the clip 110 for ligating living tissue will be described mainly with reference to FIGS. 5 to 8. FIG. 5 is a cross-sectional view showing a cross-section near the clip 110 with the arm 120 open, and FIG. 6 is a cross-sectional view showing a state in which the clip 110 with the arm 120 open is pulled toward the sheath 10. As shown in FIG. be. 7 is a side view showing the clip 110 with the arms 120 open, and FIG. 8 is a side view showing the clip 110 with the arms 120 closed.

As shown in FIG. 7, the clip 110 includes a pair of arms 120 for gripping a living tissue, an engaging portion 130 provided on the base end side of the arms 120, and a ring-shaped tightening member 150. and have
By ligating the living tissue with the arm portion 120 of the clip 110, treatment such as hemostasis, suturing, and marking can be performed. The pair of arm portions 120 of the clip 110 has a self-expanding force, and by protruding the arm portions 120 in the closed state from the sheath 10, the arm portions 120 are naturally expanded to be in the open state. In addition, the arm portion 120 has a narrow portion 123 whose width dimension is locally reduced.
The narrow portion 123 is for locking the clip 110 in the arm-closed state by engaging the tightening member 150 and engaging with the arm portion 120 .

As shown in FIGS. 5 and 7, the locking portion 130 of the clip 110 includes a receiving portion 134 having a space 132 for receiving the clip connecting portion 50 therein, and protruding inward toward the proximal end side of the receiving portion 134. and a projection 135 having a projection 140 formed thereon.
The protruding piece 135 extends in the axial direction and is composed of two diametrically opposed pieces, and a protruding portion 140 is formed at the proximal end.
By receiving the clip connecting portion 50 in the space 132 of the engaging portion 130, the clip 110 and the wire rope 20 having the clip connecting portion 50 are connected to each other.

[sleeve]
Next, the sleeve 70 that acts on the fastening member 150 when ligating the living tissue with the clip 110 will be described mainly with reference to FIGS. 9 to 11. FIG. 9 is a side view showing the side surface of the sleeve 70, FIG. 10 is a view taken in the direction of arrow X in FIG. 9 and a rear view showing the rear face of the sleeve 70, and FIG. 2 is a front view showing the front of the sleeve 70. FIG.

The sleeve 70 according to the present embodiment is a member for restricting the retracting movement of the tightening member 150 with respect to the sheath 10 and transitioning the clip 110 in the open arm state (see FIG. 6) to the closed arm state (see FIG. 4). be.
The sleeve 70 is a member that enables the clip 110 to regrasp the living tissue, and as shown in FIG. is.
The sleeve 70 is a substantially cylindrical plate piece formed by pressing, bending, heat-treating, or the like to deform along the outer peripheral surface of a cylindrical core material (not shown).

The sleeve 70 is fixed to a coil spring 80 to be described later and provided at the distal portion of the wire rope 20 . In addition, when the wire rope 20 is advanced, the sleeve 70 is pressed by the coil spring 80 fixed to the wire rope 20, and as shown in FIG. Advancement is possible to a position where 72 protrudes from the sheath 10 .

The sleeve 70 of this embodiment has an enlarged diameter portion 72, a reduced diameter stepped portion 74, and a sleeve body 76, as shown in FIGS.
At least the enlarged diameter portion 72 of the sleeve 70 has a quadrangular cross-sectional shape (quadrangular shape with C-chamfering) in which four are evenly formed radially in the front view shown in FIG. is configured to allow
An enlarged diameter portion 72 is provided on the distal side of the sleeve 70 and is elastically self-expandable. Specifically, the expanded diameter portion 72 has a larger diameter than the inner diameter of the sheath 10 in a natural state, and the outer diameter is reduced by being deformed to be smaller in diameter than in the natural state when the sleeve 70 is accommodated in the sheath 10 . The diameter is smaller than the inner diameter of the sheath 10 (see FIG. 3). Then, as shown in FIG. 5, the expanded diameter portion 72 of the sleeve 70 projects distally from the sheath 10, so that the expanded diameter portion 72 is elastically restored to its natural state.

The reduced-diameter stepped portion 74 is provided on the proximal side of the enlarged-diameter portion 72 , and is tapered between the sleeve main body 76 and the enlarged-diameter portion 72 so as to decrease in diameter toward the proximal side. . The distal side of the reduced diameter stepped portion 74 has a larger diameter than the inner diameter of the sheath 10 in a natural state, and the proximal side of the reduced diameter stepped portion 74 has a smaller diameter than the inner diameter of the sheath 10 in a natural state.
The sleeve main body 76 is provided closer to the proximal side than the diameter-reduced step portion 74 and has a smaller diameter than the inner diameter of the sheath 10 in a natural state.

As shown in FIGS. 5 and 6, the enlarged diameter portion 72 can accommodate a tightening member 150 . In other words, the inner diameter of the expanded diameter portion 72 in its natural state is slightly larger than the outer diameter of the tightening member 150 .
By accommodating the tightening member 150 , the enlarged diameter portion 72 is restricted from being deformed to be smaller than the outer diameter of the tightening member 150 . At this time, the sleeve 70 is prevented from entering the sheath 10 by restricting the diameter-reducing deformation of the enlarged diameter portion 72 .
That is, the diameter-reduced stepped portion 74 is engaged with the distal end of the sheath 10, and the tightening member 150 is accommodated in the enlarged diameter portion 72, whereby the backward movement of the sleeve 70 is restricted. Therefore, by pulling the clip 110 using the wire rope 20 , the arm portion 120 of the clip 110 can be retracted relative to the enlarged diameter portion 72 and the tightening member 150 .
As a result, the wire rope 20 can be removed from the clip 110 by closing the arm portion 120 of the clip 110 and further withdrawing the wire rope 20 .
When the tightening member 150 is not accommodated in the expanded diameter portion 72, when the wire rope 20 is retracted, the enlarged diameter portion 72 is re-accommodated in the sheath 10 while undergoing diameter reduction deformation.

In the present embodiment, the deformed portion 70a described in the outline above is configured by a slit (proximal side slit 70c) formed up to the proximal end of the sleeve 70. As shown in FIG. The proximal slit 70c forms a space for allowing deformation of the deformable portion 70a, thereby allowing the deformable portion 70a to be elastically deformed in the radial direction.
According to the above configuration, the deformable portion 70a is configured by the proximal slit 70c, so that it can be easily deformed (bent) outward. In other words, the connection between the clip 110 and the wire rope 20 can be released within the sleeve 70 without moving the clip 110 to the position where the locking portion 130 (projecting portion 140) protrudes from the sleeve 70 .

The deformable portions 70a are plate pieces extending in the axial direction and having four fan-shaped transverse cross-sections that are evenly formed radially in the rear view shown in FIG. It has a side wall surface extending on an imaginary plane passing through. Of the four deformable portions 70a, one deformable portion 70a is composed of two split pieces 70aa having the same shape, and the two split pieces 70aa are joined by an adhesive or the like at their opposing side surfaces. Note that any joining method may be used. For example, if the sleeve 70 is made of metal, it may be joined by welding.

Four proximal slits 70c according to the present embodiment are formed radially in a rear view so as to configure (form or partition) four deformable portions 70a. Each proximal slit 70c is defined by a wall surface extending on a virtual plane passing through the axial center of the sleeve 70 in the deformed portion 70a. A distal end portion of the proximal slit 70c is formed in a semicircular shape on the peripheral surface of the sleeve 70 .

Note that the proximal slit 70c may be a cut having a certain width as in the present embodiment, or may be a linear cut.
On the other hand, the deformable portion 70a is not limited to being deformable by the provision of the slit 70c as long as it is deformable in the direction perpendicular to the axial direction. For example, the deformable portion 70a may be made of a flexible material, and may be deformable according to the properties of the material of the sleeve 70 itself.

The slit forming the deformed portion 70a is the proximal side slit 70c as described above, and the distal side slit 70c formed to the distal end of the sleeve 70 beyond the deformed portion 70a in the sleeve 70 A slit 70d is formed. The distal side slit 70d allows the enlarged diameter portion 72 to be elastically deformable in the radial direction by forming a space that allows deformation of the enlarged diameter portion 72 in a part of the distal side of the sleeve 70 in the circumferential direction. It is. The distal slit 70d has a longer circumferential length than the proximal slit 70c, and is formed between the enlarged diameter portion 72 and the reduced diameter stepped portion 74 adjacent in the circumferential direction. from the distal end to the central portion. The central axis of the proximal slit 70 c and the central axis of the distal slit 70 d extend at positions offset in the circumferential direction of the sleeve 70 .
As described above, since the central axis of the proximal side slit 70c and the central axis of the distal side slit 70d are extended at offset positions, a load is applied to the proximal side and the distal side of the sleeve 70. When the slits (proximal side slit 70c and distal side slit 70d) overlap, stress concentration near the slits (proximal side slit 70c and distal side slit 70d) can be suppressed to suppress unintended excessive deformation.

The sleeve 70 includes a rigid portion 70b having a higher rigidity than the deformed portion 70a, distal to the deformed portion 70a. The rigid portion 70b according to this embodiment refers to a central portion where the proximal side slit 70c and the distal side slit 70d are not formed.
Since the sleeve 70 has the rigid portion 70b, even if the protruding piece portion 135 attempts to deform in the diameter expanding direction at a position overlapping the rigid portion 70b in the axial direction, the deformation is prevented by the rigid portion 70b. can be restricted by That is, the clip 110 can be separated from the clip connecting portion 50 at any position at which the protrusion 140 overlaps the deformation portion 70a in the axial direction or at any position proximal to this position and at any timing.

Note that the rigid portion 70b according to the present embodiment does not have the proximal slit 70c and the distal slit 70d. The present invention is not limited to such configurations. For example, by combining different materials, the rigidity may be relatively increased compared to other parts, or by increasing the cross-sectional area of one part, the rigidity may be relatively increased compared to other parts. may

The rigid portion 70b is formed continuously around the entire circumference of the sleeve 70. As shown in FIG. Neither the proximal side slit 70c nor the distal side slit 70d is formed in the circumferentially formed rigid portion 70b.

In this specification, the term "circumferential" refers to a shape that is continuous in the circumferential direction through a route with the same axial direction and a route that is deviated in the axial direction on the circumferential surface of the sleeve 70 . In other words, the “circumferential shape” is not limited to a shape in which the sleeves 70 are continuously circulated so as to be perfectly linearly overlapped when viewed from the side.
In other words, even if the proximal side slit 70c and the distal side slit 70d overlap in the axial direction of the sleeve 70, if these positions are shifted in the circumferential direction, they will rotate all the way around. It is assumed that a rigid portion 70b that is continuous with is formed.
According to the above configuration, since the rigid portion 70b is formed continuously around the entire circumference of the sleeve 70, deformation of the protruding portion 135 of the clip 110 can be suitably restricted at any position in the circumferential direction. can.

A portion of the fixing wire 82 (a portion of the region where there is a gap between windings) is welded and fixed to the rigid portion 70b in a circular fashion. That is, when the fixing wire 82 is welded in a circular shape, the rigid portion 70b is formed in a circular shape, so that the weld bead reaches the inside of the sleeve 70 through the proximal side slit 70c or the distal side slit 70d. It can be suppressed from being formed.

On the other hand, as shown in the present embodiment, if the rigid portion 70b has a shape in which the rigid portion 70b continuously circulates so as to overlap completely linearly in a side view of the sleeve 70, welding of a part of the fixing wire 82 is possible. can be preferably performed in a straight path on the circumference of the sleeve 70 . Furthermore, since deformation due to stress in the axial direction of the sleeve 70 can be suppressed, the sleeve 70 can be suitably formed into a substantially cylindrical shape by press working.

In addition, although it is preferable that the rigid portion 70b is formed in a circular shape as described above, it is not limited to such a configuration, and may be partially formed. In this case, it is preferable to fix the fixing wire 82 to the rigid portion 70b by caulking.

[Housing body and slider]
As shown in FIG. 2, the housing main body portion 97 is generally formed in an elongated bar shape, and includes a proximal side main body portion 98 and a distal end portion assembled to the distal end side of the proximal side main body portion 98. and a side body portion 99 .
A compression spring 30 (see FIG. 1) is built into the proximal body portion 98 . The compression spring 30 applies a load to a part of the slider 94 in the backward direction, which is the direction in which the clip 110 contacts the sheath 10 .
Distal body portion 99 is connected to the distal end of proximal body portion 98 by a cap 99a at the proximal end.
The slider 94 is attached in the vicinity of the proximal end of the wire rope 20 to be described later, and performs forward/backward operation and rotation operation of the clip 110 with respect to the sheath 10 via the wire rope 20 .

[Wire rope]
The wire rope 20 is inserted through the inside of the sheath 10 and the inside of the housing main body 97 so as to be able to advance and retreat in the axial direction. The wire rope 20 is made of, for example, a highly rigid metallic material such as stainless steel, steel wire with a corrosion-resistant coating, titanium or a titanium alloy. The distal end of the wire rope 20 is provided with a coiled spring 80 , a lumped clip connection 50 and a sleeve 70 . The clip connecting portion 50 is located inside the sleeve 70 in the natural state. A resin layer (not shown) made of a fluoropolymer may be provided so as to cover the outer peripheral surface of the wire rope 20 .

[Coil spring]
As shown in FIG. 3 , the treatment instrument main body 1 further includes an extendable portion connected to the sleeve 70 and the wire rope 20 and capable of extending and retracting in the axial direction of the wire rope 20 . The telescoping portion is a coiled spring 80 having a smaller diameter proximally than distally and is disposed between the distal end of the wire rope 20 and the sleeve 70 to connect them in a close-separable manner. .
The coil spring 80 is configured by a coil formed by spirally winding a metal or resin wire or by an elastomer such as rubber, and is configured to be expandable and contractable in the axial direction.

At least a portion (proximal portion) of the coil spring 80 is formed in a three-dimensional spiral whose diameter decreases toward the rear end (proximal end).
According to the above configuration, since the expandable portion is the coil spring 80 having a smaller diameter on the proximal side than on the distal side, the clearance between the sheath 10 and the coil spring 80 can be increased. Therefore, even when the sheath 10 is in a bent state, the contact area between the sheath 10 and the coil spring 80 can be reduced, and the wire rope 20 can be moved relatively to the sheath 10 described later (proximal side). It is possible to reduce the resistance when pulling it). The operation of pulling the wire rope 20 to the proximal side is performed by retracting the slider 94 with respect to the sheath 10 .

The distal portion of the wrap spring 80 includes a fixation wire 82 fixed around the rigid portion 70b of the sleeve 70 and around the sleeve body 76 distal to the fixation wire 82, as shown in FIG. and a loosely attached non-attached wire 84 . The distal end of the coil spring 80 abuts the proximal side of the reduced diameter step 74 .

The practitioner pulls the wire rope 20 proximally with respect to the sheath 10 in order to ligate living tissue (or to detach the clip 110 from the clip connecting portion 50 and leave it in place). At this time, for example, when a centering member (not shown) that abuts on the inner wall surface of the sheath 10 is provided at a portion (extendable portion) of the wire rope 20 that moves relative to the sheath 10, the inner wall surface of the sheath 10 and the centering member are provided. Friction occurs between them and resistance increases. In other words, the ligation operation of the living tissue and the placement operation of the clip 110 become "heavy", and the problem is that these operations cannot be performed smoothly.

On the other hand, according to the coil spring 80, the practitioner pulls the wire rope 20 proximally with respect to the sheath 10 in a state in which the sheath 10 is bent by passing the treatment instrument main body 1 through the bent body cavity. It is possible to remarkably reduce the resistance when performing a ligation operation or the like.
Specifically, each wire of the coil spring 80 has a circular cross-section as shown in FIG. be able to. Therefore, the frictional force when operating the wire rope 20 in contact with the inner wall surface of the sheath 10 can be reduced compared to the wire rope 20 .
Therefore, by arranging the coil spring 80 that partially covers the wire rope 20, the resistance when the wire rope 20 is operated can be reduced.

[sheath]
Next, the sheath 10 will be described with reference to FIG. 12 in addition to FIGS. 1 and 3. FIG. FIG. 12 is an enlarged side view showing the sheath 10 in an enlarged manner.
Sheath 10 is an elongated flexible tubular member. At least part of the sheath 10 is formed of a close-wound coil 10a, and as shown in FIG. and a joining portion 10d that coaxially joins with 10c.
The joint portion 10d has a proximal end portion 10da and a distal end portion 10db having a smaller diameter than the proximal end portion 10da, and is attached to the proximal portion 10b and the distal portion 10c of the sheath 10. welded.
According to the above configuration, since the distal portion 10c of the sheath 10 has a large diameter, the proximal end of the sleeve 70 and the clip 110 and the distal end of the wire rope 20 (the clip connecting portion 50) can be suitably accommodated.

More specifically, the proximal end portion 10da has an opening that is larger than the outer peripheral surface of the proximal portion 10b, and the distal end portion 10db is larger than the inner peripheral surface of the distal portion 10c. It has a small outer peripheral surface. The opening of the distal end portion 10db is formed in a tapered shape so that the diameter becomes smaller toward the proximal side.

The opening of the distal end portion 10db is connected to the opening at a position where the diameter is smaller than that of the opening of the proximal end portion 10da, thereby forming a step 10dc at the connecting portion with the opening. is doing. The proximal portion 10b and the joint portion 10d are joined with the distal end surface of the proximal portion 10b in contact with the step 10dc. It reliably limits relative distal movement.

As described above, the distal end portion 10db is formed to have a smaller diameter than the proximal end portion 10da, thereby forming a step 10dd at the connecting portion. The distal portion 10c and the joint portion 10d are joined with the proximal end surface of the distal portion 10c in contact with the step 10dd. It certainly limits relative movement proximally.

An inner layer (not shown) made of a fluoropolymer may be provided on the inner peripheral surface of the coil 10a. Further, the sheath 10 may be formed of a coil wound with a resin wire, or may be a flexible resin tube.

Further, when the practitioner rotates the clip 110 to adjust the direction in which the living tissue is clamped, the operator rotates the wire rope 20 by rotating the finger ring 92 with respect to the sheath 10 . Since the clip 110 is connected to the wire rope 20 via the clip connecting portion 50, the orientation of the clip 110 can be adjusted.
In this case, the distal portion 10c is formed to have a large diameter as described above, and a clearance is formed between the inner surface of the distal portion 10c and the coil spring 80 fixed to the outer circumference of the sleeve 70. , resistance when adjusting the orientation of the clip 110 can be suppressed.

The small diameter of the proximal portion 10b reduces the rigidity, and when moving forward or backward in the channel of an endoscope (not shown), the contact surface with the inner wall surface of the channel can be reduced, thereby reducing friction. , the operating resistance can be suppressed. In the present embodiment, the sheath 10 as a whole is composed of a close-wound coil, but it is not limited to such a configuration, and only a portion thereof may be composed of a close-wound coil.

The clearance between the inner wall of the proximal portion 10b and the operation wire (wire rope 20) in the sheath 10 is smaller than the clearance between the inner wall of the distal portion 10c and the operation wire (wire rope 20).
According to the above configuration, the clearance between the inner wall of the proximal portion 10b and the wire rope 20 in the sheath 10 is smaller than the clearance between the inner wall of the distal portion 10c and the wire rope 20, so that the proximal portion Swinging of the wire rope 20 can be restricted at 10b.

<<Operation>>
13 and 14 in addition to FIGS. 1 to 12, the clip connecting portion 50 of the wire rope 20 is connected to the clip 110, the clip 110 is closed, and the clip connecting portion 50 is removed from the clip 110. Explain a series of procedures until release. FIG. 13 is an explanatory diagram showing a state in which the clip 110 is housed in the sheath 10. FIG. FIG. 14 is a cross-sectional view showing a state in which the clip 110 is pulled further toward the sheath from the state shown in FIG.

As shown in FIG. 8, the clip 110 is housed in a cartridge (not shown) in the initial state with the fastening member 150 attached to the outer periphery of the arm portion 120 . Then, the wire rope 20 and the clip 110 are connected by pressing the clip connecting portion 50 of the wire rope 20 from the base end side (proximal side) against the locking portion 130 of the clip 110 housed in the cartridge. be.

Specifically, when the clip connecting portion 50 of the wire rope 20 is pressed against the protrusion 140 of the locking portion 130 from the base end side, the protrusion 135 having the protrusion 140 is elastically deformed outward. As a result, the receiving portion 134 is opened so as to receive the clip connecting portion 50 in the advancing/retreating direction of the wire rope 20 .

The operator inserts a finger (for example, a thumb) through the finger hooking ring 92 and holds the slider 94 with other fingers (for example, an index finger and a middle finger). do. As a result, the wire rope 20 connected to the slider 94 advances and retreats inside the sheath 10 .
In addition, the orientation of the clip 110 can be changed by rotating the proximal body portion 98 about its axis while holding the cap 99a.

From the state in which the projecting piece 135 is elastically deformed outward and the receiving portion 134 is opened, the clip connecting portion 50 passes through the projecting portion 140 distally in the advancing/retreating direction, so that the projecting piece 135 is directed inward. to elastic recovery. As a result, the projecting portion 140 is locked to the clip connecting portion 50 and the clip connecting portion 50 and the locking portion 130 are connected.

By retracting the wire rope 20, the clip 110 and the sleeve 70 are housed inside the sheath 10 as shown in FIG. Thus, when the clip 110 is positioned inside the sheath 10, the pair of arms 120 are closed.
When the sleeve 70 is accommodated in the sheath 10 , an external force is applied to the enlarged diameter portion 72 of the sleeve 70 so that the outer diameter of the enlarged diameter portion 72 becomes smaller than the inner diameter of the sheath 10 . back. Such external force can be provided by the cartridge described above.

With the clip 110 housed in the sheath 10 as shown in FIG. 13, the sheath 10 is advanced into the body cavity through the forceps hole of the endoscope. When the distal end of the sheath 10 reaches the vicinity of the living tissue to be ligated, the practitioner pushes the slider 94 distally to push the wire rope 20 distally. As a result, the clip 110 and the tightening member 150 protrude from the distal end of the sheath 10 as shown in FIG. 5, and the clip 110 naturally expands to the maximum opening width due to its self-expanding force.

At this time, at least the enlarged diameter portion 72 and the reduced diameter stepped portion 74 of the sleeve 70 protrude from the distal opening of the sheath 10 and are expanded and deformed to their natural diameter. That is, the expanded diameter portion 72 of the sleeve 70 that has been deformed to reduce its diameter by being pulled into the sheath 10 is elastically restored to a large diameter by protruding from the distal opening of the sheath 10 . Then, the tightening member 150 is fitted inside the expanded diameter portion 72 .

From this state, when the practitioner relaxes the force applied to the slider 94 on the distal side, the slider 94 moves proximally due to the restoring force of the elastically deformed compression spring 30 . Due to this movement of the slider 94, the wire rope 20 connected to the slider 94 is pulled proximally and moved. As a result, the clip 110 is moved from the state shown in FIG. 5 to the distal end of the sheath 10 via the tightening member 150 and the diameter-reduced step portion 74 of the sleeve 70 shown in FIG. It moves to a position where it is supported against the extremity.

That is, the pair of arms 120 provided on the clip 110 are indirectly supported by the distal end of the sheath 10 in an open state when they are in the contact support position shown in FIG.
Since the pair of arms 120 are abutted and supported on the distal end of the sheath 10 in an open state, the clip 110 does not tilt or swing with respect to the sheath 10 and maintains a stable shape. becomes possible. Therefore, the operator can easily operate the clip 110 so as to grasp the living tissue.

After determining the position and orientation of the clip 110, when grasping the living tissue with the clip 110, the operator operates the slider 94 to move to the proximal side to pull the wire rope 20 to the proximal side. to close the clip 110.
Specifically, the practitioner moves the wire rope 20 from the state shown in FIG. Pull to the end to pull the clip 110 by the clip connector 50 . This operation closes the arm portion 120 of the clip 110 as shown in FIG.
More specifically, when in the state shown in FIG. 6, the tightening member 150 abuts against the inner surface of the diameter-reduced stepped portion 74 and is fitted inside the diameter-enlarged portion 72. Retraction movement relative to the sheath 10 is restricted. Further, since the tightening member 150 is fitted to the enlarged diameter portion 72, even if the enlarged diameter portion 72 is subjected to an external force, it is suppressed from being deformed to reduce its diameter.

By pulling the wire rope 20 proximally in the forward/backward direction while the clip connecting portion 50 is received in the receiving portion 134, the arm portion 120 is closed as shown in FIG. Grasp.
More specifically, when the wire rope 20 is further pulled in a state in which the sleeve 70 and the tightening member 150 are restricted from moving proximally with respect to the sheath 10, the arm portion 120 moves into the tightening member 150. pulled in and closed his arms.
When the wire rope 20 is pulled proximally, the protruding piece 135 receives a load applied from the proximal end of the clip connecting portion 50 in the diameter expanding direction. Due to the rigidity of the projecting piece 135 itself or the rigidity of the combination with the sleeve 70 that covers the projecting piece 135 and can come into contact when the diameter of the projecting piece 135 is expanded, the arm 120 is in the closed state. , the receiving portion 134 is configured not to open depending on the above load.

In addition, it is possible to open the arms 120 again by interrupting the retraction while the arms 120 are closing and pushing the wire rope 20 again. Specifically, the arms 120 apply a load to the proximal side of the clamping member 150 due to their own elastic restoring force applied in the expansion direction of the arms 120 and move relative to each other in the axial direction. It will expand again.
When the wire rope 20 is further pulled proximally after the optimum ligation is confirmed, the tightening member 150 is fitted into the narrow portion 123 (see FIG. 8) provided on the arm portion 120 to clip. 110 is locked. As a result, the clip 110 is in the closed arm state shown in FIGS.

According to such a configuration, when only the biasing force of the compression spring 30 is applied, the clip 110 is abutted and supported by the distal end of the sheath 10 in a non-closed state (open state). Therefore, the clip 110 can be easily manipulated because the slider 94 can be intentionally pulled proximally when grasping the living tissue while moving the clip 110 to the living tissue in an open state.

The wire rope 20 and sleeve 70 are connected by a coil spring 80 . Therefore, even after the sleeve 70 is restrained from moving proximally relative to the clip device 100 , the wire rope 20 is pulled proximally to extend the coil spring 80 , and the clip connecting portion 50 is further pushed into the sheath 10 . It is possible to retract proximally.

As shown in FIGS. 4 and 14, the protrusion 140 of the locking portion 130 is located at a position where it axially overlaps with the deformed portion 70a in which the proximal slit 70c is formed, or at a position closer to the deformed portion 70a (sleeve 70) than the deformed portion 70a (sleeve 70). When on the proximal side, the prongs 135 with the protrusions 140 are able to deform radially outward to a large extent.
Specifically, unlike the rigid portion 70b, the sleeve body 76 does not limit the diameter expansion of the projecting piece portion 135 at the deformed portion 70a. Further, the sleeve main body 76 naturally does not limit the diameter expansion of the projecting piece 135 even when the projecting portion 140 is at a position shifted in the axial direction on the proximal side from the deformed portion 70a (sleeve 70).

When the practitioner pulls the wire rope 20 to the proximal side and the projection 140 rides on the peripheral surface of the clip connecting portion 50 as shown in FIG. An outward load is applied. Due to this load, the protruding piece 135 is expanded and deformed to exceed the inner diameter of the sleeve body 76 in its natural state.

The expansion deformation of the projecting piece 135 opens the receiving portion 134 and allows the clip connecting portion 50 to be pulled out from the receiving portion 134 in the direction indicated by the arrow toward the proximal side shown in FIG.
In this way, the clip connecting portion 50 is removed from the locking portion 130 by further retracting the slider 94 (see FIG. 1) continuously with the motion of retracting the slider 94 (see FIG. 1) when ligating the living tissue. As a result, the clip 110 is separated from the wire rope 20 and left in the body cavity with the living tissue ligated.

In particular, when the clip 110 is separated from the clip connecting portion 50, the clip 110 can be left in the body even if the protrusion 140 of the clip 110 is not shifted proximally from the sleeve 70. becomes.
Specifically, as described above, if the protrusion 140 of the clip 110 is positioned to overlap the deformed portion 70a in the axial direction, clips having different lengths can be separated from the clip connecting portion 50 and left in the body. It becomes possible to

By the above operation, a series of procedures for connecting the clip connecting portion 50 to the clip 110, closing the clip 110, and detaching the clip connecting portion 50 from the clip 110 are completed. By repeating the above procedure, a large number of clips 110 can be used to ligate living tissue.

In the above embodiment, the clip 110 has been described as including the tightening member 150, but the present invention is not limited to such a configuration. That is, the clip 110 may be configured to be supported by the sheath 10 only via the sleeve 70 .

Further, in the above-described embodiment, the configuration using the compression spring 30 as an example of the elastic member has been described as an example, but any configuration that can generate an elastic load so as to move the clip 110 to the contact support position may be used. Just do it. For example, a configuration in which a tension spring is provided between a portion of the slider 94 and a portion closer to the proximal side than the portion may be used.

Moreover, as a configuration for projecting and retracting the clip 110 with respect to the sheath 10 , any configuration is possible as long as it can be moved relative to the sheath 10 . Specifically, in the present embodiment, the clip 110 is moved by moving the slider 94 connected to the wire rope 20 with respect to the finger ring 92 connected to the sheath 10, but the configuration is reversed. There may be. That is, the wire rope 20 may be connected to the finger ring 92 and the sheath 10 may be connected to the slider 94 .

Further, in the above embodiment, the clip 110 is configured to move with respect to the sheath 10 , but the configuration is not limited to such a configuration as long as the clip 110 can be projected and retracted with respect to the sheath 10 . For example, the configuration may be such that the sheath 10 is moved with respect to the clip 110 . In this case, the elastic member may be configured to urge the sheath 10 to move to the position where it contacts and supports the clip 110 .

It should be noted that the various components of the clip device 100 and clip 110 of the present invention do not need to exist individually. that a plurality of constituent elements are formed as one member, that one constituent element is formed of a plurality of members, that a certain constituent element is part of another constituent element, or that a certain constituent element is one It is permissible for a part and a part of another component to overlap.

The above embodiments include the following technical ideas.
(1) a clip having a plurality of arms for gripping living tissue and locking portions provided on the base end sides of the arms;
An elongated sheath, a sleeve provided inside the distal side of the sheath, and an operation wire inserted movably back and forth through the interior of the sleeve and provided with a massive tip connecting portion at the distal end. a treatment instrument body having
The locking portion has a receiving portion having a space for receiving the distal end connecting portion therein, and a protruding piece portion having a protruding portion protruding inward from the base end side of the receiving portion. configured to be lockable to the tip connecting portion,
The projecting piece portion is elastically deformed outward by pressing the projecting portion from the tip connecting portion,
the receiving portion is opened so that the distal end connecting portion can be inserted in the advancing/retreating direction of the operation wire when the projecting portion is deformed outward;
The arm closes and grasps the living tissue by pulling the operation wire proximally in the advancing/retreating direction while the distal end connecting portion is received in the receiving portion,
the sleeve has an outwardly deformable deformable portion,
The deformable portion is disposed at a position covering the protruding piece portion at a position where the distal end connecting portion is released from the locking portion and the clip is separated from the treatment instrument main body. a clip device for an endoscope, wherein the distal end connecting portion can be pulled out from the receiving portion while allowing outward deformation of the endoscope.
(2) The endoscopic clip device according to (1), wherein the sleeve includes a rigid portion having a rigidity higher than that of the deformable portion, on the distal side of the deformable portion.
(3) The endoscope clip device according to (2), wherein the rigid portion is formed continuously around the sleeve.
(4) The endoscopic clip device according to (2) or (3), wherein the deformation portion is formed by a slit extending to the proximal end of the sleeve.
(5) the slit is a proximal slit,
A distal side slit formed to reach the distal end of the sleeve is formed on the distal side of the deformed portion of the sleeve,
The endoscopic clip device according to (4), wherein the central axis of the proximal slit and the central axis of the distal slit extend at positions offset in the circumferential direction of the sleeve.
(6) the treatment instrument body further includes an extendable and extendable section connected to the sleeve and the operation wire;
The endoscopic clipping device according to any one of (1) to (5), wherein the elastic portion is a coil spring having a smaller diameter on the proximal side than on the distal side.
(7) at least a portion of the sheath,
It is formed with a close-wound coil,
Any one of (1) to (6), comprising a small-diameter proximal portion, a large-diameter distal portion, and a joint portion that coaxially joins the proximal portion and the distal portion. 11. The endoscope clip device according to claim 1.
(8) The endoscope according to (7), wherein the clearance between the inner wall of the proximal portion of the sheath and the operation wire is smaller than the clearance between the inner wall of the distal portion and the operation wire. clip device.

1 Treatment instrument body 10 Sheath 10a Tightly wound coil 10b Proximal part 10c Distal part 10d Joint part 10da Proximal side end part 10db Distal side end part 10dc Step 10dd Step 20 Wire rope (operation wire)
30 compression spring 50 clip connecting portion (tip connecting portion)
70 sleeve 70a deformation portion 70aa split piece 70b rigid portion 70c proximal side slit (slit)
70d Distal side slit 72 Expanded diameter portion 74 Reduced diameter stepped portion 76 Sleeve main body 80 Coiled spring (extendable portion)
82 Fixed wire 84 Non-fixed wire 92 Finger ring 94 Slider 97 Housing main body 98 Proximal side main body 99 Distal side main body 99a Cap 100 Clip device (clip device for endoscope)
110 Clip 120 Arm 123 Narrow portion 130 Locking portion 132 Space 134 Receiving portion 135 Protruding piece 140 Protruding portion 150 Fastening member

Claims (8)

a clip having a plurality of arms for gripping a living tissue and locking portions provided on the base end sides of the arms;
An elongated sheath, a sleeve provided inside the distal side of the sheath, and an operation wire inserted movably back and forth through the interior of the sleeve and provided with a massive tip connecting portion at the distal end. a treatment instrument body having
The locking portion has a receiving portion having a space for receiving the distal end connecting portion therein, and a protruding piece portion having a protruding portion protruding inward from the base end side of the receiving portion. configured to be lockable to the tip connecting portion,
The projecting piece portion is elastically deformed outward by pressing the projecting portion from the tip connecting portion,
the receiving portion is opened so that the distal end connecting portion can be inserted in the advancing/retreating direction of the operation wire when the projecting portion is deformed outward;
The arm closes and grasps the living tissue by pulling the operation wire proximally in the advancing/retreating direction while the distal end connecting portion is received in the receiving portion,
the sleeve has an outwardly deformable deformable portion,
The deformable portion is disposed at a position covering the protruding piece portion at a position where the distal end connecting portion is released from the locking portion and the clip is separated from the treatment instrument main body. a clip device for an endoscope, wherein the distal end connecting portion can be pulled out from the receiving portion while allowing outward deformation of the endoscope. 2. The endoscopic clip device according to claim 1, wherein the sleeve includes a rigid portion having higher rigidity than the deformable portion, on the distal side of the deformable portion. 3. The endoscope clip device according to claim 2, wherein the rigid portion is formed continuously around the sleeve. 4. The endoscopic clip device according to claim 2, wherein the deformation portion is formed by a slit extending to the proximal end of the sleeve. The slit is a proximal slit,
A distal side slit formed to reach the distal end of the sleeve is formed on the distal side of the deformed portion of the sleeve,
5. The endoscopic clip device according to claim 4, wherein the central axis of the proximal slit and the central axis of the distal slit extend at positions offset in the circumferential direction of the sleeve. The treatment instrument body further includes an extendable and extendable section connected to the sleeve and the operation wire,
The endoscopic clip device according to any one of claims 1 to 5, wherein the expandable portion is a coil spring having a diameter smaller on the proximal side than on the distal side. at least a portion of the sheath,
It is formed with a close-wound coil,
7. The method according to any one of claims 1 to 6, comprising a small-diameter proximal portion, a large-diameter distal portion, and a joint portion that coaxially joins the proximal portion and the distal portion. An endoscopic clip device as described. 8. The endoscopic clip device according to claim 7, wherein the clearance between the inner wall of the proximal portion of the sheath and the operation wire is smaller than the clearance between the inner wall of the distal portion and the operation wire. .

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