JP2009028552A - Ligation device for anatomy - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a ligation device for anatomy, maintaining the holding state of biological tissue without loosening the holding state of a clip. <P>SOLUTION: The ligation device for anatomy includes: the clip 2 having an arm for holding biological tissue; a retaining pipe 4 serving as a tightening member fitted over the clip 2 for closing the arm of the clip 2; a coupling member 3 insertable into the retaining pipe 4 for engagement with the clip 2, and a projection 2d serving as a locking part for holding the closing state of the arm of the clip 2 by engagement of the clip 2 with the retaining pipe 4. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a living tissue ligating apparatus that is inserted into a body cavity, for example, endoscopically and ligates the living tissue with a clip.

  For example, JP-A-8-280701 is known as a ligation device for living tissue, and WO 01 / 10321A1 is known as a polypectomy snare device. In JP-A-8-280701, a clip having a pair of arms for gripping a living tissue is fitted to a fastening ring to close the arm of the clip and project from the fastening ring, thereby opening the arm. It comes to leg. The clip and the tightening ring can be accommodated in an introduction tube that is inserted into a channel of the endoscope, and the clip is connected to an operation wire that is inserted into the introduction tube so as to be able to advance and retract through a connecting member.

  Then, the clip can be opened and closed by moving the operation wire back and forth with the hand operation unit. Further, the direction of the clip can be changed by rotating the operation wire by the rotation operation member of the hand operation section, and the clip can be approached to the target site.

  WO 01/10321 A1 has a snare at the tip of a shaft that is inserted into the sheath so as to be able to advance and retract. In addition, a first handle that rotates the snare and changes the direction of the snare and a second handle that opens and closes the snare are provided.

  A clip case for storing the clip unit has already been filed as Japanese Patent Application No. 2001-244402. The clip case is formed of a transparent synthetic resin material, and the clip unit is sterilized while being stored in the clip case. And in the state accommodated in the clip case, it can connect with the operation wire penetrated by the introduction pipe | tube, without touching fingers.

That is, the clip case has a clip unit storage portion and an introduction tube insertion portion, and when the introduction tube is inserted into the clip case from the introduction tube insertion portion, the introduction tube is formed by an elastic pressing portion provided in the clip case. Is pressed by the elastic restoring force. In this state, when the operation wire inserted through the introduction tube is advanced, the arrowhead hook provided at the tip of the operation wire is elastically engaged with the connecting member.
JP-A-8-280701 WO 01/10321 A1

  Therefore, the above-mentioned Japanese Patent Application Laid-Open No. 8-280701 and WO 01 / 10321A1 can rotate the clip and snare by operating the hand operation unit, and can change the direction. In addition, it is necessary to be able to rotate the operating wire in the axial direction while being able to advance and retract in the axial direction, which is structurally complicated.

  Further, in Japanese Patent Laid-Open No. 8-280701, even when the clip is pulled into the clamping ring and the clip arm is closed and the living tissue is ligated, the clamping ring presses the clip arm to the closed leg state. However, the clip is only in contact with the inner surface of the tightening ring, and there is a possibility that the gripping force of the living tissue is loosened.

  The object of the present invention is that when the clip is pulled into the tightening member by the operating member, the clip locking portion and the locking member locking portion are locked when the clip arm is fully opened. Then, the clip is held in a state where the legs are opened to the maximum, and in this state, the clip is pressed against the living tissue, and the clip is closed to provide a living tissue ligating apparatus that can hold the living tissue by the clip. There is.

According to the first aspect of the present invention, there is provided a clip having an arm for grasping a living tissue, a fastening member that closes the arm by being fitted to the clip, a clip that can be inserted into the fastening member, and the clip. A coupling member that engages with each other, and a locking portion that is provided on both the clip and the tightening member and that holds the clip arm in an opened state by engaging with each other. This is a ligating apparatus for living tissue.
The invention according to claim 2 is characterized in that the locking part is a protrusion provided on the clip and an inner diameter step part provided on an inner surface of the fastening member. It is a tissue ligation device.
The invention according to claim 3 is the living tissue ligating apparatus according to claim 1 or 2, wherein the fastening member is made of a deformable resin.

  According to the present invention, when the clip is pulled into the fastening member by the operation member, the clip locking portion and the locking member locking portion are locked when the clip arm is fully opened, Is held in a state where the legs are opened to the maximum, and in this state, the clip is pressed against the living tissue, and the clip is closed, whereby the living tissue can be grasped by the clip.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIGS. 1-23 shows 1st Embodiment, FIG. 1 is a perspective view of the clip unit 1 of the ligation apparatus of a biological tissue. The clip unit 1 includes a clip 2, a connecting member 3, and a presser tube 4 as a fastening member.

  As shown in FIGS. 2A to 2C, the clip 2 is formed with a loop portion 2 a by bending a metal plate material such as a plate spring material such as stainless steel at the center. Further, after crossing at a position in the vicinity of the loop portion 2a, a pair of arms 2b having spreading habits are extended in a state where the distal end portions are separated from each other, and a tissue grasping portion 2c is provided at the distal end portion. Is formed.

  Further, the crossing portion of the arms 2b of the clip 2 is formed to be narrower than the distal end side, and the tissue gripping portions 2c are opposed to each other. Further, a saw blade-like projection 2d protruding in the plate width direction is provided in the vicinity of the loop portion 2a of the arm 2b. That is, the protrusion 2d slides on the inner surface of the presser tube 4 with respect to the direction in which the clip 2 is pulled into the presser tube 4, but the tissue gripping portion side so as to bite into the inner surface of the presser tube 4 in the direction opposite to the pulling direction. Is formed with an acute slope, and the loop side has an obtuse slope.

  Further, both side edges 2e in the vicinity of the distal end of the arm 2b are formed with a chamfering of 0.05 mm or more or an R chamfering of 0.05 mm or more so that the inside of the introduction pipe described later can easily slide. Furthermore, the tissue gripping portion 2c is bent inward at approximately 90 ° to 150 °, and one of the tissue gripping portions 2c is a substantially triangular convex portion 2f, and the other is a substantially triangular concave portion 2g that meshes with the convex portion 2f. Is formed.

  Here, the dimensions of the clip 2 will be described. The size is set in consideration of the grasping ability of the living tissue and the insertion into the endoscope. For example, the thickness is 0.1 mm to 0.5 mm, and the total length is 5 mm. -10 mm. The loop portion 2a is circular or elliptical with a major axis of 1 mm to 5 mm and a minor axis of 1 mm to 5 mm. Furthermore, the tissue gripping portion 2c has a length of about 1 mm and a width of about 1 mm to 2 mm. Further, the protrusion 2d is set to have a width and thickness that can be pulled into the presser tube 4 and a tip tube described later.

  As shown in FIGS. 3 (a) and 3 (b), the connecting member 3 is manufactured by injection molding a high-strength resin material such as liquid crystal polymer or nylon, and is formed in a cylindrical bar shape. A protruding portion 3a is provided. The base portion 3b of the projecting portion 3a has a substantially disk shape, and a flat elliptical projection portion 3c that is long in the axial direction is formed on the tip side of the base portion 3b. The protrusion 3c is configured such that the loop 2a of the clip 2 is hooked and the clip 2 and the connecting member 3 are engaged.

  Furthermore, the other end portion of the connecting member 3 is bifurcated and formed with a grip portion 3e that has a notch portion 3d at the branch portion and grips an arrowhead hook described later. Further, the intermediate portion of the connecting member 3 is formed into a small-diameter portion 3f, a medium-diameter portion 3g, and a large-diameter portion 3h as a rupture portion from the front end side toward the rear end side. The dimensions are set to break when force is applied. Further, the large diameter portion 3h is set to an outer diameter that closely fits with the inner peripheral surface of the presser tube 4, and a locking projection 3i is provided on a part of the outer peripheral surface.

  Here, the dimensions of the connecting member 3 will be described. The total length is about 10 mm, and the protrusion 3 c has a height of 0.2 mm or more and a width of 0.2 mm or more. The gripping part 3e has an inner diameter φ of about 0.6 mm. The outer diameter φ of the small diameter portion 3f is 0.3 mm or more, and the large diameter portion 3h is φ1 mm to φ1.3 mm. Further, the height of the locking projection 3i is set to 0.1 mm or more.

  The presser tube 4 is manufactured by injection molding a soft material having moderate elasticity such as a material softer than the clip 2, for example, PPA (polyphthalamide) or PA (polyamide). This presser tube 4 closes the arm 2b of the clip 2 by being fitted to and mounted on the arm 2b of the clip 2.

  A tip tube 4 a made of a high-strength metal such as stainless steel is fitted to the tip of the presser tube 4. The outer diameter of the distal end tube 4a is the same as that of the presser tube 4, and the inner diameter is formed in the inner diameter inclined portion 4c so as to gradually increase from the minimum inner diameter portion 4b of the base end portion toward the distal end portion. . Further, the outer diameter of the distal end tube 4a is formed in the outer diameter inclined portion 4c 'so as to gradually become smaller toward the distal end portion so as to be slippery inside the introduction tube described later.

  A pair of projecting and retracting wings 4 d that are elastically projectable and retractable in the radial direction is provided on the outer periphery of the presser tube 4, and a rear end inclined portion 4 e is provided at the rear end of the presser tube 4. The inner diameter of the presser tube 4 is slightly larger on the tip side, and an inner diameter step portion 4f is formed between the inner diameter on the rear end side.

  Here, the dimensions of the presser tube 4 will be described. The overall length and the inner and outer diameters are set according to the size of the clip 2. The inner diameter inclined portion 4c of the distal end tube 4a has an angle of 15 to 90 ° and an inlet diameter of about 1.6 mm, and has an inlet diameter and an angle suitable for the clip 2 to be pulled in for tissue grasping. The outer diameter inclined portion 4c 'has an angle of 5 to 120 ° and comes into surface contact with the curved introduction tube. The projecting and retracting wing 4d is substantially triangular, and the maximum projecting width 4g is 2 mm or more, which is set to be equal to or larger than the inner diameter of the introduction tube.

  Furthermore, the stepped portion 4e between the rear end inclined portion 4e of the presser tube 4 and the large diameter portion 3h of the connecting member 3 is 0.5 mm or less, and the inner diameter step portion 4f is set to have a height of 0.1 mm or more. Yes.

  Here, the assembly of the clip unit 1 will be described. As shown in FIGS. 3A and 3B, the connecting member 3 is inserted from the rear end side of the presser tube 4, and the projection 3c of the connecting member 3 is inserted into the presser tube. 4 is projected from the tip tube 4a. In this state, when the loop portion 2a of the clip 2 is hooked on the protrusion 3c, the clip 2 and the connecting member 3 are engaged. Next, when the connecting member 3 is pulled toward the hand side, the loop portion 2 a of the clip 2 comes into contact with the inner diameter inclined portion 4 c of the distal end tube 4 a of the presser tube 4. At this time, the locking protrusion 3i of the connecting member 3 is engaged with the end surface of the presser tube 4 at the rear end side, and the clip 2, the connecting member 3, and the presser tube 4 are in an engaged state, as shown in FIGS. The assembly as shown is complete.

  In this state, when the connecting member 3 is pulled toward the hand side, the loop portion 2 a of the clip 2 is drawn into the presser tube 4 from the distal end tube 4 a of the presser tube 4. Therefore, since the loop portion 2a of the clip 2 is crushed, the arm 2b is opened.

  When the connecting member 3 is further pulled toward the proximal side, the protrusion 2d of the clip 2 comes into contact with the inner diameter step portion 4f of the presser tube 4 and the inside of the presser tube 4 of the clip 2 as shown in FIGS. 4 (a) to 4 (c). Retraction is stopped, and the arm 2b is held in the maximum open state.

  When the connecting member 3 is further pulled from this state, the protrusion 2d of the clip 2 gets over the inner diameter step portion 4f of the presser tube 4, and the clip 2 is drawn into the presser tube 4, so that FIG. As shown in b), the arm 2b of the clip 2 is closed.

  At this time, since the presser tube 4 is formed of a resin having an appropriate elasticity softer than the clip 2, the protrusion 2 d of the clip 2 bites into the inner wall of the presser tube 4, and the clip 2 is axially moved inside the presser tube 4. The movement is restricted and the leg is maintained in a closed state. Since the protrusion 2d of the clip 2 is formed in a saw blade shape protruding in the plate width direction of the loop portion 2a, the clip 2 moves lightly on the tightening side (the closing leg direction of the arm 2b), but the clip 2 is on the return side. In the arm 2b leg opening direction, the protrusion 2d does not bite into the inner wall of the presser tube 4 and move.

  Next, the introduction tube 5 and the operation wire 6 shown in FIGS. 6A, 6B, and 6C will be described. The introduction tube 5 is a flexible coil having a flexible proximal coil 5a having a flexible spring material such as stainless steel and a flexible spring material such as stainless steel connected to the tip of the proximal coil 5a. It is comprised from the front end side coil 5b which has.

  The hand side coil 5a has an outer diameter that can be inserted into a channel of the endoscope, for example, φ2 mm to φ6 mm, and an inner diameter that allows the operation wire 6 to be inserted, and has a wall thickness of about 0.25 to 0.7 mm. . The distal end side coil 5b has an outer diameter that can be inserted into a channel of the endoscope, for example, φ2 mm to φ6 mm, and is formed to have an inner diameter that allows the clip unit 1 and the operation wire 6 to be inserted. It is about 7 mm. Furthermore, a thin portion 5c is formed in the vicinity of the tip of the tip side coil 5b by post-processing such as grinding, and the length is about 1 mm to 10 mm, and the thickness is about 0.2 mm to 0.65 mm.

  By providing the thin portion 5c in the vicinity of the distal end of the distal end side coil 5b, the flexibility is increased and the turning ability of the distal end of the sheath is improved, so that the insertion property and extraction property of the endoscope into the channel are improved. Moreover, although the front end side coil 5b is heat-treated and has a substantially brown surface, it is ground after the heat treatment to form the thin portion 5c. Therefore, since the thin portion 5c has a metallic gloss surface different from other portions, there is a marking effect, and when protruding from the distal end portion of the endoscope, the protruding amount can be confirmed by the endoscope.

  A tip tip 7 made of a metal such as stainless steel is provided at the tip of the tip coil 5b. The distal tip 7 has an outer diameter that can be inserted into a channel of the endoscope, for example, φ2 mm to φ6 mm, and an inner diameter of φ2 mm or more so that the clip unit 1 and the operation wire 6 can be inserted. A tip inclined surface portion 7a having an angle of 5 ° to 90 ° is formed on the outer peripheral surface of the tip tip 7 so as to gradually become smaller in diameter toward the tip.

  The operation wire 6 is formed of a stranded wire composed of a core strand and a side strand of a metal wire having moderate elasticity such as stainless steel and NiTi. For example, when the inner diameter of the introduction tube 5 is about φ2 mm, the operation wire 6 has an outer diameter of φ1.2 mm to φ1.8 mm, a clearance from the inner diameter of the distal end side coil 5b of 0.4 mm or less, and an outer A Teflon (registered trademark) coat is applied to the surface. By making the operation wire 6 thick and reducing the clearance between the distal end side coil 5b and the inner diameter of the proximal side coil 5a to 0.4 mm or less, the role of regulating the displacement of the proximal side coil 5a and the distal end side coil 5b is controlled. As a result, deformation and buckling of the proximal coil 5a and the distal coil 5b can be prevented.

  Further, by setting the clearance small, the bending of the operation wire 6 when the operation wire 6 is pushed to the distal end side can be reduced, and the amount of pressing force can be transmitted efficiently. Further, the surface of the operation wire 6 is coated with a Teflon (registered trademark) coat to reduce the sliding resistance with the introduction pipe 5.

  A cylindrical wire fixing portion 8a made of a metal material such as stainless steel is fitted to the distal end portion of the operation wire 6, and an arrowhead hook 8 is integrally provided on the wire fixing portion 8a via a shaft portion 8c. . The wire fixing portion 8a is provided with a fixing hole 8e, and a brazing material is poured into the fixing hole 8e and fixed to the operation wire 6.

  The arrowhead hook 8 has a conical shape and has an arrowhead slope portion 8b having an angle of 10 ° to 120 °, and the arrowhead large diameter portion 8d has a diameter of approximately φ0.8 mm to φ1.2 mm. The diameter of the shaft portion 8c is about φ0.6 mm. The arrowhead hook 8 has a substantially vertical pushing surface 8 f, and can efficiently apply a force when the clip unit is protruded from the introduction tube 5.

  7A and 7B show a modification of the fixing structure of the arrowhead hook 8 provided at the distal end portion of the operation wire 6. The operation wire 6 is formed of a stranded wire composed of one core strand 22 and a plurality of side strands 23. Then, one of the core strands 22 is protruded from the end surface of the side strand 23 to form a protruding portion 24.

  On the other hand, the wire fixing portion 8a of the arrowhead hook 8 is provided with an insertion hole 25 into which the protruding portion 24 is inserted and a fixing hole 26 at a right angle thereto, and the fixing hole 26 is inserted in the state where the protruding portion 24 is inserted into the insertion hole 25. The brazing material is poured into the operation wire 6 by pouring. According to this modification, the operation wire 6 and the wire fixing portion 8a can be formed to have the same outer diameter, the step difference as in the first embodiment can be eliminated, and the operation wire in the introduction tube 5 can be eliminated. The operation of 6 can be made smoother.

  As shown in FIG. 8A, the arrowhead hook 8 is detachably engaged with the grip portion 3e of the connecting member 3, and the length 8c ′ of the shaft portion 8c is the length of the grip portion 3e. It is formed longer than this by 0.5 mm or more. Therefore, as shown in FIG. 8 (b), in the state where the arrowhead hook 8 is engaged with the grip portion 3e of the connecting member 3, it is between the rear end surface of the grip portion 3e and the tip contact surface of the wire fixing portion 8a. An interval of 8 g is formed.

  Further, as shown in FIG. 8A, the gripping portion 3e of the connecting member 3 is formed with a conical hole 3j following the inclined surface of the arrowhead slope portion 8b so that it can be easily coupled to the arrowhead hook 8. . Furthermore, the holding part 3e is formed with a concave groove 3k that is continuous with the conical hole 3j and fits into the shaft part 3d. When the arrowhead hook 8 is engaged with the grip portion 3e, the arrowhead hook 8 is engaged with the notch portion 3d, and the arrowhead large diameter portion 8d is engaged with the step portion 3m of the grip portion 3e.

  Therefore, by pressing the tip of the arrowhead hook 8 against the conical hole 3j formed in the gripping portion 3e of the connecting member 3 and pushing the arrowhead hook 8 into the gripping portion 3e, the gripping portion 3e and the arrowhead hook 8 are coupled. The Further, when removing the connecting member 3 from the arrowhead hook 8, as shown in FIGS. 8A and 8B, the connecting member 3 is moved along the opening direction of the notch 3d with respect to the axis o of the operation wire 6. By rotating in the direction of the arrow, the arrowhead hook 8 can be extracted from the notch 3 d of the connecting member 3. At this time, since the gap 8g is formed between the rear end surface of the grip portion 3e and the tip contact surface of the wire fixing portion 8a, the grip portion 3e does not interfere with the wire fixing portion 8a.

  9 to 11 show the operation unit 9. The operation unit main body 10 includes a cylindrical part 10 a on the front end side, a shaft part 10 b that extends integrally with the cylindrical part 10 a toward the rear end side, and the shaft part. It is comprised from the finger ring 10c rotatably provided in the base end part of 10b. A slit 10d is provided in the axial direction in the shaft-like portion 10b of the operation portion main body 10, and a slider 11 having a finger-hanging recess 11a on the outer peripheral surface is provided in the slit 10d so as to freely advance and retract.

  A proximal end portion of the operation wire 6 inserted through the cylindrical portion 10 a of the operation portion main body 10 is introduced into the lumen 11 b of the slider 11. A wire fixing member 12 divided into two is provided at a position biased toward the proximal end side of the lumen 11 b of the slider 11. And the base end part 6b of the operation wire 6 is clamped and fixed by the wire fixing member 12 divided into two. The wire fixing member 12 is fixed to the slider 11 by a lid body 14 fixed by screws 13.

  Therefore, the operation wire 6 moves forward and backward in the introduction tube 5 by moving the slider 11 forward and backward with respect to the operation portion main body 10. Further, since the distal end side of the inner cavity 11b of the slider 11 is open, when the slider 11 is moved forward most, the proximal end large diameter portion 10a ′ of the cylindrical portion 10a of the operation portion main body 10 is shown in FIG. As shown, it is designed to be fitted so that the stroke of the slider 11 can be increased while shortening the length of the operation portion 9.

  Although the wire fixing member 12 is provided at a position biased toward the proximal end side of the lumen 11b of the slider 11, the wire fixing member 12 is provided at a position biased toward the distal end side of the lumen 11b of the slider 11 so that the operation unit main body is provided. Even if it is fitted to the base end side of 10, the same effect is obtained.

  A pipe 15 made of stainless steel is fitted to the operation wire 6 inserted through the cylindrical portion 10 a of the operation unit main body 10. Further, an inner peripheral enlarged diameter portion 16 is formed at the tip of the cylindrical portion 10a, and a coil joint pipe 17 fixed to the cylindrical portion 10a is fixed to the inner peripheral enlarged diameter portion 16.

  A folding stop pipe 18 is connected to the coil joint pipe 17. The folding tube 18 is formed of a spring material such as stainless steel or a resin material having an appropriate softness such as a silicon heat-shrinkable tube, and is connected to the coil joint tube 17 so as to be fitted on the operation wire 6. The coil 5a is fitted on the proximal side coil 5a of the introduction tube 5. The folding tube 18 is provided for the purpose of protecting the coupling portion between the coil joint tube 17 and the folding tube 18 that are easily broken. Further, the coupling portion between the coil joint tube 17 and the folding coil 18 is connected to the operation unit body 10. By providing it inside, the weak joint part can be protected by the operation part main body 10 and the resistance can be greatly improved.

  FIGS. 12 to 17 show a clip case 30 that houses the clip unit 1, which is composed of an upper case 31 and a lower case 32 having the same dimensions and the same shape, and can be molded with the same molding die. . The upper case 31 and the lower case 32 have an appropriate hardness such as ABS, PC, PP, PS, acrylic, cycloolefin polymer, etc., and are manufactured by injection molding a transparent resin. The clip case 30 has a width of about 10 mm to 20 mm, a length of about 50 mm, a thickness of about 5 mm, and a size that is easy to hold in the hand.

  A clip unit storage portion 33 is provided at one end of the upper case 31 and the lower case 32 in the longitudinal direction, and a pressing portion 34 is provided at the other end. The pressing part 34 is about 20 mm x 20 mm, and is formed in a size suitable for picking with fingers. And the compression part 34 of the upper case 31 and the lower case 32 is bent so that it may mutually space apart from the connection part 33a of the clip unit storage part 33 and the compression part 34, and the space | interval 34a is formed between the compression parts 34. Yes.

  In the upper case 31 and the lower case 32, three engagement claws 35 project from the inner surface of the clip unit storage portion 33, and three engagement holes 36 are provided. The engaging claw 35 of the upper case 31 engages with the engaging hole 36 of the lower case 32, and the engaging claw 35 of the lower case 32 engages with the engaging hole 36 of the upper case 31 and The lower case 32 can be assembled.

  Since the upper case 31 and the lower case 32 have the same shape, only one lower case 32 will be described. When the clip 2 of the clip unit 1 is accommodated in an open leg state on the inner surface of the clip unit accommodating portion 33. A clip storage portion 37 formed of a letter-shaped recess is provided, and a presser tube storage portion 38 and a connecting member storage portion 39 formed of an arc groove are provided continuously with the clip storage portion 37. The bottom portion of the presser tube storage portion 38 has a protruding and retracting wing storage recess 38a in which the protruding and retracting wing 4d is stored. In addition, the bottom portion of the connecting member storage portion 39 has a grip portion escape recess 39 a so that the grip portion 3 e can be deformed when engaged with the arrowhead hook 8.

  Furthermore, the inner surface of the squeezing part 34 is provided with an introduction pipe insertion part 40 consisting of an arc groove continuously with the connecting member storage part 39, and a plurality of hemispherical concave parts 40b of about φ1 mm to φ3 mm are provided on the outer surface. Forms a non-slip.

  Further, a tip tip abutting portion 41a and a projecting / reducing wing diameter reducing portion 41 having an inclined surface of about 5 ° to 90 ° are provided at a boundary portion between the connecting member storage portion 39 and the introduction tube insertion portion 40, and the presser tube 4 When passing through the projecting and retracting wing reduced diameter portion 41, the projecting and retracting wing 4d is pushed inward.

  Furthermore, the introduction pipe insertion part 40 is provided with a slope part 43 so that the diameter gradually increases toward the inlet 42. The inlet 42 has a diameter of 3 mm or more, and a semicircular arc surface 44 is formed in plan view. Further, a convex part having a length of 1 mm to 5 mm is formed on the bottom surface of the introduction pipe insertion part 40, and an introduction pipe fixing part 45 for pressing and fixing the introduction pipe 5 from the vertical direction is formed by this convex part.

  Engaging recesses 46 are provided on both side walls of the clip storage portion 37 so as to face each other. Engaging convex portions 48 provided at both ends of the clip abutting member 47 are detachably engaged with the engaging concave portion 46. The clip abutting member 47 has abutting surfaces 47a and 47b on the front and rear sides to prevent the clip 2 from moving forward, and the engaging projection 48 is biased with respect to the abutting surfaces 47a and 47b. Is provided.

  Therefore, when the clip 2 stored in the clip storage portion 37 is small in size, the engagement convex portion of the clip abutting member 47 so that the abutting surface 47a abuts against the clip 2 as shown in FIG. 48 can be engaged with the engaging recess 46. When the clip 2 stored in the clip storage portion 37 is of a medium size, the clip abutting member 47 is inverted so that the abutting surface 47b abuts against the clip 2 as shown in FIG. The mating convex portion 48 can be engaged with the engaging concave portion 46. Further, when the clip 2 stored in the clip storage portion 37 is large in size, the clip abutting member 47 is removed as shown in FIG. 16C, and the clip 2 hits the front wall 37 a of the clip storage portion 37. Can be.

  As a modification of the clip abutting member 47, a protruding clip abutting member 49 is provided at the bottom of the clip storage portion 37 as shown in FIG. In this case, regardless of the size of the clip 2, it is possible to prevent the clip 2 from moving forward due to the crossing portion of the arm 2 b of the clip 2 hitting the clip abutting member 49.

  Next, the operation of the ligation apparatus for living tissue configured as described above will be described.

  The clip unit 1 is accommodated between the upper case 31 and the lower case 32 of the clip case 30, the clip 2 is connected to the clip storage portion 37, the presser tube 4 is connected to the presser tube storage portion 38, and the connecting member 3 is connected. It is set in the member storage part 39.

  To attach the clip unit 1 to the ligating apparatus from this state, first, as shown in FIG. 18 (a), the distal end portion of the introduction tube 5 is inserted into the introduction tube insertion portion 40 from the inlet 42 of the clip case 30, and the distal end The tip 7 is abutted against the tip abutment portion 41a.

  Next, when the squeezing part 34 of the clip case 30 is picked with fingers, the squeezing part 34 is elastically deformed, and as shown in FIG. 18B, the introduction pipe 5 is clamped by the introduction pipe fixing part 45 so as not to move in the axial direction. Fix it.

  In this state, when the slider 11 of the operation portion 9 is moved to the distal end side, the arrowhead hook 8 protrudes from the distal end portion of the introduction tube 5 through the operation wire 6 as shown in FIG. Accordingly, when the tip end of the arrowhead hook 8 comes into contact with the conical hole 3j formed in the gripping portion 3e of the connecting member 3 and the slider 11 is further moved to the tip end side, the gripping portion 3e is pushed outward by the arrowhead slope portion 8b. It is done. Thereafter, when the arrowhead hook 8 is further pushed into the gripping portion 3e, the gripping portion 3e passes through the arrowhead hook 8 and is blocked by an elastic force. As shown in FIG. 19A, the shaft portion 8a is moved to the gripping portion 3e. It is pinched. In this state, since the arrowhead large-diameter portion 8d of the arrowhead hook 8 engages with the step portion 3m of the grip portion 3e, the arrowhead hook 8 cannot be removed from the grip portion 3e, and the clip unit 1 is coupled to the operation wire 6. .

  In this state, when the slider 11 is moved to the proximal end side, the clip unit 1 is drawn into the introduction tube 5 through the operation wire 6. At this time, as shown in FIG. The projecting and retracting wing 4 d is pushed inward by the inclined surface of the projecting and retracting wing reduced diameter portion 41 and is pulled into the presser tube 4. Accordingly, as shown in FIG. 19 (c), the clip unit 1 is drawn into the introduction tube 5 without the projecting / retracting wing 4 d being caught by the end surface of the tip 7.

  At this time, the arm 2 b of the clip 2 is closed according to the inner diameter of the introduction tube 5. Further, since the projecting and retracting wing 4 d of the presser tube 4 is in contact with the inner surface of the introduction tube 5, the presser tube 4 is elastically deformed and kept in the presser tube 4.

  After the clip unit 1 is drawn into the introduction pipe 5, if the amount of force for grasping the squeezing part 34 of the clip case 30 is weakened, the squeezing part 34 spreads in the vertical direction by the elastic restoring force, and as shown in FIG. Can be extracted from the introduction tube insertion portion 40 of the clip case 30.

  Next, as shown in FIG. 21, the introduction tube 5 is introduced into the body cavity via the channel 21 of the endoscope 20 inserted in advance into the body cavity, and the introduction tube is observed while observing the inside of the body cavity with the endoscope 20. Guide the tip of 5 to the target site.

  22 and 23 show a procedure for ligating a living tissue with the clip 2. As shown in FIG. 22A, the clip unit 1 moves forward through the introduction tube 5 through the operation wire 6 by pushing the slider 11 toward the distal end side. At this time, the outer diameter of the distal end tube 4a of the presser tube 4 is formed in the outer diameter inclined portion 4c ′ so as to gradually become smaller toward the distal end portion so that the inside of the introduction tube 5 is easily slipped. Move smoothly inside the tube 5. This is particularly effective when the endoscope is strongly curved as shown in FIG.

  When the operation wire 6 is further advanced by the slider 11, the clip unit 1 protrudes from the introduction tube 5 as shown in FIG. At this time, since the projecting and retracting wing 4d of the presser tube 4 is inclined downward toward the tip, the clip unit 1 is pushed out smoothly and without resistance. Then, the projecting and retracting wing 4 d of the presser tube 4 is released from the contact state with the inner surface of the introduction tube 5 and protrudes in the outer peripheral direction of the presser tube 4. Further, as shown in FIG. 23 (a), the pair of arms 2b of the clip 2 has the spreading habit, so that the legs are opened to some extent at the same time as protruding from the introduction tube 5.

  Thereafter, when the slider 11 is moved to the proximal end side, the operation wire 6 is pulled back to the proximal end side as shown in FIG. Engage with the end face.

  When the slider 11 is further moved to the proximal end side and the operation wire 6 is pulled back, the loop 2a of the clip 2 is drawn into the presser tube 4 via the connecting member 3, and the clip 2 is further opened. Then, the protrusion 2d of the clip 2 comes into contact with the inner diameter step portion 4f of the presser tube 4, and the arm 2b is maximally opened as shown in FIGS. 4 (c) and 23 (b).

  In this state, while observing with the endoscope 20, the clip 2 is approached to the target site of the living tissue, and the tissue gripping portion 2c of the clip 2 is pressed. At this time, a thumb is inserted into the finger ring 10c of the operation unit 9 and the slider 11 is sandwiched between the index finger and the middle finger for operation. The finger ring 10c is rotatable with respect to the operation unit main body 10. Therefore, when the clip 2 is rotated to change the direction, the operation unit body 10 is rotated. However, the operation unit body 10 can be rotated even when the thumb is inserted into the finger ring 10c.

  When the slider 11 is further moved to the proximal end side, the operation wire 6 is retracted, and the arm 2 b of the clip 2 is drawn into the presser tube 4 via the connecting member 3. Accordingly, the protrusion 2d of the clip 2 passes over the inner diameter step portion 4f of the presser tube 4, and the arm 2b of the clip 2 is closed as shown in FIGS. 5 (a), 5 (b) and 23 (c). The living tissue is securely sandwiched between the arms 2 b of the clip 2. At this time, since the presser tube 4 is formed of a resin having an appropriate elasticity softer than the clip 2, the protrusion 2 d of the clip 2 bites into the inner wall of the presser tube 4, and the clip 2 is axially moved inside the presser tube 4. The movement is restricted and the leg is kept closed.

  When the slider 11 is further moved to the proximal end side and the operation wire 6 is retracted, the narrow-diameter portion 3f as the fracture portion of the connecting member 3 of the clip 2 is broken as shown in FIG. Is released from the coupling member 3 and the clip 2 is detached from the ligation apparatus and is left in the body cavity while holding the living tissue.

  For example, the biological tissue at the bleeding site in the body cavity is sandwiched and compressed between the arms 2b of the clip 2, and the clip 2 is placed in that state, thereby compressing the blood vessel at the bleeding site and stopping bleeding. The biological tissue is held by the clip 2 and left for several days until bleeding stops, but the protrusion 2d of the clip 2 bites into the inner wall of the presser tube 4, and the clip 2 moves in the axial direction inside the presser tube 4. Is restrained and maintained in a closed leg state.

  After placement of the clip 2, the ligating apparatus is removed from the channel 21 of the endoscope 20. When the connecting member 3 is removed from the arrowhead hook 8 in order to reload the clip unit, the connecting member 3 is notched 3d with respect to the axis of the operation wire 6 as shown in FIGS. The arrowhead hook 8 can be extracted from the notch 3d of the connecting member 3 by rotating in the direction of the arrow along the opening direction. At this time, since the gap 8g is formed between the rear end surface of the grip portion 3e and the tip contact surface 6b of the wire fixing portion 8a, the grip portion 3e does not interfere with the wire fixing portion 8a.

  FIGS. 24-26 shows 2nd Embodiment and shows the peel pack 50 which accommodates the sterilized clip case 30. FIG. As shown in FIG. 24, the peel pack 50 is a combination of a polyethylene-coated PET film and a high-density polyethylene / polyethylene coating, and has a rectangular bag shape and a triangular notch 51. . Therefore, as shown in FIG. 25, the opening 52 can be formed by tearing from the notch 51 with fingers.

  In order to attach the clip unit 1 to the ligating apparatus after providing the opening 52 in the peel pack 50 that houses the clip case 30, first, as shown in FIG. The distal end portion of the introduction tube 5 is inserted through the opening 52 of the 50, and the introduction tube 5 is inserted into the introduction tube insertion portion 40 from the introduction tube insertion inlet 44 of the clip case 30 as shown in FIG. And the pressing part 34 of the clip case 30 can be picked up with a finger from the top of the peel pack 50, and the clip unit 1 can be attached to a ligation apparatus by the procedure of FIG.18 and FIG.19 mentioned above.

  27 to 34 show a third embodiment, and the same components as those of the first embodiment are denoted by the same reference numerals and description thereof is omitted. In Japanese Patent Application Laid-Open No. 8-280701 described in the section of the prior art, a clip is pulled into a clamping ring by an operation wire, and the arm of the clip is closed to ligate a living tissue. However, the clamping ring is a cylindrical tubular body having both ends opened, and has a structure in which a connecting member is inserted. Then, the clip loop portion is engaged with the distal end portion of the connecting member, and the connecting member is retracted toward the hand side so that the clip is housed in a closed leg state inside the tightening ring.

  Therefore, there is a possibility that the connecting member moves in the axial direction of the tightening ring inside the clip case or the introduction pipe, the engagement between the clip and the connecting member is released, and the clip is separated from the connecting member. The present embodiment solves the above-described problems.

  As shown in FIG. 27, the base end portion of the loop portion 2a of the clip 2 constituting the clip unit 1 is formed to be narrower than the other portions, and is locked to both side portions of the loop portion 2a continuous from the base end portion. A loop step 2h as a member is formed. Further, a saw blade-like protrusion 2d protruding in the plate width direction is provided at a substantially intermediate portion of the arm 2b. That is, the protrusion 2d slides on the inner surface of the presser tube 4 in the direction in which the clip 2 is pulled into the presser tube 4, but bites into the inner surface of the presser tube 4 in the direction opposite to the pulling direction.

  Here, the dimensions of the clip 2 will be described. The loop step portion 2h is 0.1 mm or more, and the protrusion 2d is set to have a width that can be pulled into the presser tube 4 and a tip tube described later, and 1 mm or more.

  As shown in FIGS. 28 (a) (b) to 31 (a)-(d), the connecting member 3 is manufactured, for example, by injection molding a high-strength resin material such as liquid crystal polymer or nylon. It is a cylindrical bar, and a protrusion 3k is provided at its tip. The protrusion 3k protrudes laterally from the base 3b. The width w of the projection 3k is about 0.6 mm to 1.2 mm. When the loop 2a of the clip 2 is hooked on the projection 3k and the clip 2 is pulled into the presser tube 4, the clip 2 is pressed by the presser tube 4. The clip 2 is designed to slide into the inner peripheral surface of the plate in a pressure contact state, that is, to be slowly pulled in with a large sliding resistance.

  Further, on the opposite surface of the large diameter portion 3h of the connecting member 3, a planar portion 3j as an engaging portion is formed in the axial direction, and the large diameter portion 3h is formed in a non-circular shape. A locking projection 3i is provided on a part of the outer peripheral surface of the large-diameter portion 3h at the terminal portion of the flat surface portion 3j.

  Here, the dimensions of the connecting member 3 will be described. The total length is about 10 mm, and the grip portion 3 e has an inner diameter φ of 0.6 mm. The outer diameter φ of the small diameter portion 3f is 0.3 mm or more, and the large diameter portion 3h is φ1 mm to φ1.3 mm. Further, the height of the locking projection 3i is set to 0.1 mm or more.

  The presser tube 4 is manufactured by injection molding a soft material having moderate elasticity such as a material softer than the clip 2, for example, PPA (polyphthalamide) or PA (polyamide). The presser tube 4 closes the arm 2b of the clip 2 by being fitted and attached to the arm 2b of the clip 2, and a tip tube 4i made of a high-strength metal such as stainless steel is fitted to the tip. Has been.

  The inner diameter of the tip tube 4i is an inner diameter that can be fitted onto the presser tube 4, and the outer diameter is approximately the same as the outer diameter of the presser tube 4 and is shorter than the tip fitting portion 4j of the presser tube 4. Since the tip tube 4i is located behind the tip of the tip fitting portion 4j and forms a pseudo taper portion, the tip tube 4i can move smoothly without being caught by the curved inner wall of the introduction tube 5. It is like that.

  The inner diameter at the base end portion of the presser tube 4 has a rear end reduced diameter portion 4c so as to closely fit with the large diameter portion 3h of the connecting member 3, and the height of the step is 0.1 mm or more. An inner diameter step portion 4h as a member is formed. When the clip 2 is pulled into the presser tube 4, the loop step portion 2 h and the inner diameter step portion 4 h of the clip 2 are engaged (contacted), and the clip 2 passes the closed leg position and enters the presser tube 4. It is designed to prevent you from being drawn into.

  Here, the assembly of the clip unit 1 will be described. As shown in FIGS. 32 (a) and 32 (b), the distal end portion of the connecting member 3 is inserted from the proximal end portion side of the presser tube 4, and the distal end portion of the connecting member 3 is inserted. The protruding portion 3k is projected from the distal end portion of the presser tube 4. At this time, the large-diameter portion 3h of the connecting member 3 is press-fitted into the presser tube 4, but the large-diameter portion 3h is formed into a non-circular shape by the flat surface portion 3j, so that the presser tube 4 is smoothly elliptical. Transforms into Therefore, the locking projection 3 i provided on the large diameter portion 3 h is not scraped by the presser tube 4.

  In this state, when the loop portion 2a of the clip 2 is hooked on the protrusion 3k, the clip 2 and the connecting member 3 are engaged. Next, when the connecting member 3 is pulled toward the proximal side until the loop portion 2a of the clip 2 comes into contact with the distal end of the presser tube 4, the locking protrusion 3i of the connecting member 3 protrudes from the proximal end of the presser tube 4 It enters a state and engages with the proximal end of the presser tube 4.

  According to the third embodiment described above, the engagement protrusion 3i and the proximal end portion of the presser tube 4 engage with each other, so that the connecting member 3 moves to the distal end side in the axial direction inside the presser tube 4. And the movement of the connecting member 3 toward the proximal end in the axial direction inside the presser tube 4 is restricted by engaging the loop portion 2a of the clip 2 with the end portion on the distal end side of the presser tube 4. Therefore, the connecting member 3 is not inadvertently moved in the axial direction inside the presser tube 4, and the clip 2 can be prevented from being separated from the connecting member 3 inside the clip case 30 or the introduction tube 5.

  In the third embodiment, the flat portion 3j is formed on the shaft portion of the connecting member 3 so that the locking projection 3i is not scraped when the clip is assembled. However, the shaft portion of the connecting member 3 is polygonal. Alternatively, it may be oval and the shape is not limited.

  FIG. 33 shows a modification of the presser tube 4, in which a key groove 4 j is provided on the inner peripheral portion of the presser tube 4 corresponding to the locking projection 3 i provided on the connecting member 3. According to this modification, when the clip unit 1 is assembled, the locking projection 3 i engages with the key groove 4 j, and the connecting member 3 can restrain movement in the axial direction and the circumferential direction inside the presser tube 4.

  FIG. 34 shows a modified example of the clip 2, in which the tissue gripping portion 2c provided at the tip of the arm 2b of the clip 2 is bent at an angle of 90 °, and the length of the arm 2b is varied by the thickness. The tissue grasping part 2c overlaps the front and rear when the legs are closed. According to this modification, the width of the closed leg of the arm 2b when the leg is closed can be reduced, and the inside of the introduction tube 4 can be moved smoothly.

  35 and 36 show a fourth embodiment, and the same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted. In Japanese Patent Laid-Open No. 8-280701 described in the section of the prior art, when the clip is pulled into the clamping ring by the operation wire, the loop portion of the clip is pressed by the inner peripheral surface of the clamping ring, and the clip arm When the clip is further pulled into the clamping ring while the arm is pressed against the living tissue after the leg is fully opened, the clip arm is pulled into the clamping ring and the arm is closed to remove the living tissue. To ligate.

  However, the clamping ring is a cylindrical body with no steps on the cylindrical inner surface that is open at both ends, so that when the clip is pulled into the clamping ring by the operation wire and the clip arm is temporarily opened, If you do not look carefully at the end of the arm under endoscopy, it will be difficult to determine whether the arm is fully open, and if you apply too much force, it will close past the maximum open state and will open. Can not hold in. Therefore, there are problems that an intended gripping amount cannot be obtained and operability is poor. The present embodiment solves the above-described problems.

  As shown in FIGS. 35 and 36, a saw blade-like protrusion 2d is provided in the vicinity of the loop portion 2a of the clip 2 so as to protrude in the plate width direction. The protrusion 2d slides on the inner surface of the presser tube 4 in the direction in which the clip 2 is pulled into the presser tube 4, but bites into the inner surface of the presser tube 4 in the direction opposite to the pulling direction.

  Further, the presser tube 4 closes the arm 2b of the clip 2 by being fitted and attached to the arm 2b of the clip 2. The inner diameter of the presser tube 4 is formed to be slightly larger at the front end side, and an inner diameter step portion 4f that is engaged with the protrusion 2d of the clip 2 is formed between the inner diameter of the presser tube 4 and the rear end side.

  Therefore, as shown in FIGS. 35A and 35B, when the connecting member 3 is pulled toward the hand side, the loop portion 2 a of the clip 2 is pulled into the inside of the presser tube 4 from the distal end tube 4 a of the presser tube 4. Therefore, since the loop portion 2a of the clip 2 is crushed, the arm 2b is opened.

  When the connecting member 3 is further pulled toward the hand side, as shown in FIGS. 36A to 36C, the protrusion 2d of the clip 2 comes into contact with the inner diameter step portion 4f of the presser tube 4, and the retraction of the clip 2 is temporarily stopped. Thus, the arm 2b is in a state where the leg is opened to the maximum.

  In this state, the clip 2 is approached to the target site of the living tissue while observing with an endoscope, and the tissue gripping portion 2c of the clip 2 is pressed. At this time, the protrusion 2d of the clip 2 comes into contact with the inner diameter step portion 4f of the presser tube 4, and the drawing of the clip 2 is temporarily stopped and the arm 2b is held in a state where it is opened to the maximum.

  According to the present embodiment, the clip 2 is held in the state where the legs are opened to the maximum. In this state, the clip 2 is pressed against the living tissue, and the clip 2 is closed, whereby the grasping amount intended for the living tissue by the clip 2 Can be. Therefore, the grasping amount of the living tissue by the clip 2 can be increased, and the operability can be improved because the arm 2b is held in a state where the arm 2b is opened to the maximum.

  FIG. 37 shows a fifth embodiment, and the same components as those of the first embodiment are denoted by the same reference numerals and description thereof is omitted. In the case of Japanese Patent Laid-Open No. 8-280701 described in the section of the prior art, all of the clip, the fastening ring, and the connecting member are made of a stainless material. In the prior application, Japanese Patent Application No. 2001-244402, only the clip is made of a stainless steel material, and the other members are made of a synthetic resin material.

  In particular, if the tightening ring is made of stainless steel, or if it is formed in a natural color without coloring the white resin, the color is close to white, and the illumination light of the endoscope is irradiated. If this is done, halation will occur and visibility will be worsened.

  Also, when coloring, when the color of the tissue in the body cavity is substantially the same color, the visibility of the clip, clip clamping ring and connecting member is poor in the endoscope visual field, and the clip is the target site of the living tissue. It is difficult to reliably ligate a living tissue, and it is difficult to distinguish a clip and a presser tube remaining in the tissue after ligation. The present embodiment solves the above-described problems.

  As shown in FIG. 37, the outer peripheral surface of the presser tube 4 constituting the clip unit 1 is colored in a color that is highly visible in the endoscope visual field. The color with good visibility is colored in a color different from the body cavity tissue such as blue and green. For example, red or a color close to it is almost the same color as tissue in the body cavity, poor visibility, and in the case of white, halation occurs when irradiated with endoscope illumination light. It is desirable to avoid it. Furthermore, the outer peripheral surface of the connecting member 3 or the entire material is also colored with a good visibility within the endoscope field of view.

  In the above-described embodiment, both the connecting member 3 and the presser tube 4 are colored with good visibility in the endoscope field of view. However, at least one of the connecting member 3 and the presser tube 4 may be colored. 3 and the presser tube 4 may be colored in different colors. Although it is effective to color one of the connecting member 3 and the presser tube 4, the presser tube 4 is retained in the body together with the clip 2, so it is more effective to color the presser tube 4.

  According to the clip unit 1 configured as described above, when the clip 2 is approached to the target site of the living tissue while observing with the endoscope 20, and the tissue gripping portion 2c of the clip 2 is pressed, the connecting member 3 and The presser tube 4 is colored with a good visibility in the endoscope visual field, such as blue or green, so that it can be easily distinguished from the tissue in the body cavity, and halation is caused by the light from the endoscope. The clip 2 can be pressed against the target site of the living tissue. Therefore, the clip 2 can be approached to the target site of the living tissue, and the living tissue can be reliably ligated.

  FIG. 38 shows a sixth embodiment, and the same components as those of the first embodiment are denoted by the same reference numerals and description thereof is omitted. In Japanese Patent Application Laid-Open No. 8-280701 described in the section of the prior art, the introduction tube is made of a flexible coil sheath, and an operation wire made of a stranded wire is inserted through the introduction tube so as to freely advance and retract. Then, by advancing the operation wire by the hand operation unit, the clip and the clamping ring are projected from the distal end opening of the introduction pipe through the connecting member, the clip arm is opened, and the operation wire is retracted. The clip is pulled into the tightening ring, and the arm of the clip is closed to ligate the living tissue.

  However, the outer diameter of the operation wire is sufficiently smaller than the inner diameter of the introduction tube so that it can easily advance and retreat inside the introduction tube. Therefore, there is a clearance between the inner diameter of the introduction tube and the outer diameter of the operation wire, and when the operation wire is advanced and retracted by the hand operation part, the introduction tube is buckled by the clearance and the clip of the operation wire is reliably secured. May not be able to be communicated to.

  Endoscopes are often used in a curved state, and the introduction tube is also curved along the curved portion. In this state, the introduction tube is buckled by repeatedly closing the clip and breaking the connecting member. Further, when the clip is protruded from the introduction tube, there is a problem that the operation wire meanders in the introduction tube and the protrusion amount is not sufficiently transmitted to the sheath tip. The present embodiment solves the above-described problems.

  As shown in FIG. 38, a tip tip 7 made of a metal such as stainless steel is provided at the tip of the tip coil 5b of the introduction tube 5. The distal tip 7 has an outer diameter that can be inserted into a channel of the endoscope, for example, φ2 mm to φ6 mm, and an inner diameter that is about φ2 mm so that the clip unit 1 and the operation wire 6 can be inserted. A tip inclined surface portion 7a having an angle of 5 ° to 90 ° is formed on the outer peripheral surface of the tip tip 7 so as to gradually become smaller in diameter toward the tip.

  The operation wire 6 is formed of a stranded wire composed of a core strand and a side strand of a metal wire having moderate elasticity such as stainless steel and NiTi. The operation wire 6 has an outer diameter of φ1.2 mm or more so that the clearance C with respect to the inner diameter of the distal end side coil 5b is 0.3 mm or less, and a Teflon (registered trademark) coat is applied to the outer surface. Has been. Thus, by making the operation wire 6 thick and reducing the clearance C from the inner diameter of the distal end side coil 5b to 0.3 mm or less, deformation and buckling of the introduction tube 5 can be prevented.

  According to the present embodiment, since the clearance C between the inner diameter of the introduction tube 5 and the outer diameter of the operation wire 6 is small, there is an effect that the amount of meandering of the operation wire 6 is small and the force pushing the slider 11 is efficiently transmitted to the distal end side. .

  Further, the breaking force amount of the connecting member 3 is 20N to 60N, and the same compressive force amount is applied to the introduction pipe 5 at the time of breaking, but the clearance C with the operation wire 6 is set to be as small as 0.3 mm or less. Therefore, the operation wire 6 works as a reinforcing material, and buckling of the introduction pipe 5 can be prevented.

  39 to 42 show a seventh embodiment, and the same components as those of the first embodiment are denoted by the same reference numerals and description thereof is omitted. Japanese Patent Laid-Open No. 8-280701 and WO 01 / 10321A1 described in the section of the prior art have a structure that rotates the operation wire by rotating the clip and the snare by rotating the operation portion, but the operation wire is rotated. In addition, it is necessary to fix and rotate the operation wire inserted into the sheath from the outside, which is structurally complicated.

  In addition, it is necessary to rotate in the vicinity of the forceps hole of the endoscope in consideration of torque transmission and operability. Therefore, it is necessary to prepare a plurality of products in which the position of the rotary handle is changed with respect to the endoscope having the above, which causes an increase in manufacturing cost and confusion to the user. The present embodiment solves the above-described problems.

  As shown in FIGS. 39 (a) and 39 (b), an annular groove 116 is provided in the inner peripheral portion of the connecting portion between the operation portion main body 10 and the tubular portion 10a. The annular groove 116 is engaged with a flange portion 117 a of a coil joint tube 117 made of a stainless material that connects the proximal end portion 5 x of the introduction tube 5 and the operation portion main body 10. The coil joint tube 117 is provided so as to be rotatable with respect to the operation unit main body 10.

  An enlarged diameter portion 10b is formed on the inner peripheral portion on the distal end side of the cylindrical portion 10a of the operation portion main body 10, and an O-ring 118 such as silicon rubber fitted to the introduction tube 5 is provided on the inner peripheral portion. The rotary operation unit and the operation unit main body 10 are fixed.

  Further, a clip rotation operation unit 119 is provided on the distal end side of the cylindrical portion 10a of the operation unit main body 10. As shown in FIG. 40, the clip rotation operation unit 119 includes a gripping tube 120 such as silicon rubber fitted to the introduction tube 5, a plurality of gripping claws 121a in the circumferential direction, and an axial direction between the gripping claws 121a. A grip tube 121 made of a synthetic resin material having a slit groove 121b and fitted to the grip tube 120, a first grip 122 fitted to the tip of the grip tube 121, and a grip tube The second grip 123 is fitted to the base end portion of the body 121 and screwed into the first grip 122.

  The first grip 122 has a tapered lumen 122a and a female screw portion 122b into which the gripping claws 121a of the gripping tube body 121 are fitted, and the outer peripheral surface is knurled. Further, a male screw portion 123a that is screwed into the female screw portion 122b is provided at the tip of the second grip 123. A cylindrical portion 123b that can be inserted into the enlarged diameter portion 10b of the cylindrical portion 10a is provided at the base end portion of the second grip 123, and a concave groove 123c that engages with the O-ring 118 is provided in the cylindrical portion 123b. It has been. Further, the outer peripheral surface of the second grip 123 is knurled.

  According to the clip rotation operation unit 119 configured as described above, when the first grip 122 is gripped and the second grip 123 is rotated and the male screw portion 123a is tightened with respect to the female screw portion 122b, the holding tube body The diameter 121 is reduced, and the introduction tube 5 can be gripped through the grip tube 120. Therefore, when the clip rotation operation unit 119 is fixed to the introduction tube 5 and the grip rotation operation unit 119 is rotated, the introduction tube 5 and the operation wire 6 are rotated, and the orientation of the clip 2 can be changed.

  Further, when the clip rotation operation unit 119 loosens the male screw portion 123a with respect to the female screw portion 122b, the diameter of the grip tube 121 is increased, so that the clip rotation operation unit 119 is movable in the axial direction with respect to the introduction tube 5. Thus, the clip rotation operation unit 119 can be moved to an arbitrary position. Therefore, as shown in FIG. 41, the clip rotation operation portion 119 is moved to the operation portion main body 10 with the introduction tube 5 being inserted into the channel from the forceps port 125 of the endoscope 20, or as shown in FIG. In addition, it can be moved to the introduction tube 5 in the vicinity of the forceps port 125 and grasped.

  In particular, by gripping the clip rotation operation unit 119 with the introduction tube 5 in the vicinity of the forceps port 125, there is no loss of torque, the direction of the clip 2 can be finely adjusted, and the target site can be easily approached.

  Next, the operation of the ligation apparatus for living tissue configured as described above will be described. As in the first embodiment, the introduction tube 5 is introduced into the body cavity via the channel 21 of the endoscope 20 inserted in advance into the body cavity, and the introduction tube 5 is observed while observing the inside of the body cavity with the endoscope 20. Guide the tip of the to the target site. Then, by the operation of pushing the slider 11 to the distal end side, the clip unit 1 advances through the introduction tube 5 through the operation wire 6. When the operation wire 6 is further advanced by the slider 11, the clip unit 1 protrudes the introduction pipe 5 from the coil pipe 8. At this time, the projecting and retracting wing 4d of the presser tube 4 is inclined downwardly toward the distal end side, so that the clip unit 1 is pushed out smoothly and without resistance. The projecting and retracting wing 4 d of the presser tube 4 is released from the contact state with the inner surface of the introduction tube 5 and protrudes from the presser tube 4 in the outer peripheral direction. In addition, since the pair of arms 2b of the clip 2 has the spreading habit, the leg 2 is opened at the same time as protruding from the introduction tube 5.

  Thereafter, when the slider 11 is moved to the base end side, the operation wire 6 is pulled back to the base end side, and the base end side end face of the projecting and retracting wing 4 d of the presser tube 4 is engaged with the end face of the tip end 7.

  When the slider 11 is further moved to the proximal end side and the operation wire 6 is pulled back, the loop 2 a of the clip 2 is drawn into the presser tube 4 through the connecting member 3. Then, the protrusion 2d of the clip 2 comes into contact with the inner diameter step portion 4f of the presser tube 4, and the arm 2b is opened to the maximum.

  In this state, while observing with the endoscope 20, the clip 2 is approached to the target site of the living tissue, and the tissue gripping portion 2c of the clip 2 is pressed. In this state, since the projecting / retracting wing 4d and the tip 7 are pressed against each other, a large frictional resistance is generated, and when the introduction tube 5 is rotated, the clip unit 1 is also rotated. Furthermore, in order to obtain a large frictional resistance, the surface of the tip 7 may be roughened or uneven.

  At this time, when changing the direction by rotating the clip 2, the direction of the clip 2 can be finely adjusted by rotating the introduction tube 5 and the operation wire 6 by gripping and rotating the clip rotation operation unit 119. , You can easily approach the target site.

  43 and 44 show an eighth embodiment, which has the same purpose as that of the seventh embodiment. FIGS. 43 and 44 show the operation unit 9, and the operation unit body 10 has a cylindrical shape on the distal end side. It is comprised from the part 10a, the cylindrical part 10a, the axial part 10b extended to a rear-end side integrally, and the finger ring 10c rotatably provided in the base end part of this axial part 10b. A slit 10d is provided in the axial portion 10b of the operation unit body 10 in the axial direction, and a slider 11 having a finger hanging recess 11a on the outer peripheral surface is fitted in the slit 10d so as to freely advance and retract.

  A proximal end portion of the operation wire 6 inserted through the shaft-like portion 10 a of the operation portion main body 10 is introduced into the lumen 11 b of the slider 11. A wire fixing member 12 divided into two is provided at a position biased toward the proximal end side of the lumen 11 b of the slider 11. And the base end part 6b of the operation wire 6 is clamped and fixed by the wire fixing member 12 divided into two. The wire fixing member 12 is fixed to the slider 11 by a lid body 14 fixed by screws 13.

  A pipe 15 made of stainless steel is fitted to the operation wire 6 inserted through the cylindrical portion 10 a of the operation unit main body 10. A fitting recess 10b is provided concentrically at the tip of the cylindrical portion 10a, and a fitting projection 126a of the rotary grip 126 is rotatably fitted in the fitting recess 10b. An annular groove 126b is provided on the outer peripheral surface of the fitting convex portion 126a, and a fixing pin 127 protruding radially from the outer periphery of the tubular portion 10a is engaged with the annular groove 126b. Therefore, the rotation grip 126 is rotatably fitted to the cylindrical portion 10a. Further, the outer peripheral surface of the rotating grip 126 is knurled.

  An inner peripheral enlarged diameter portion 128 is formed at the tip of the rotary grip 126, and a coil joint pipe 129 fixed to the rotary grip 126 is fixed to the inner peripheral enlarged diameter portion 128. The coil joint pipe 129 is connected to the proximal coil 5 a of the introduction pipe 5.

  45 and 46 show the ninth embodiment, which has the same purpose as that of the seventh embodiment. In this embodiment, the proximal end of the introduction tube 5 is provided at the distal end of the cylindrical portion 10a of the operation portion main body 10. The operation wire 6 inserted into the introduction tube 5 is extended to the slider 11.

  A wire fixing member 12 divided into two parts is provided in the inner cavity 11 b of the slider 11. The flat wire receiving member 6c integrally joined to the base end portion 6b of the operation wire 6 is clamped and fixed by the wire fixing member 12 divided into two. The wire fixing member 12 is fixed to the slider 11 by a lid body 14 fixed by screws 13.

  Accordingly, since the introduction pipe 5 and the operation wire 6 can be rotated integrally by rotating the operation section main body 10, a larger torque can be generated than when the introduction pipe 5 is rotated alone, and the direction of the clip 2 can be changed. It can be finely adjusted and can easily approach the target site.

  47 shows the tenth embodiment for the same purpose as the seventh embodiment. The base end portion of the channel 131 built in the insertion portion of the endoscope 130 shown in FIG. 132 is connected to the branch tube 133, one of the branch tubes 133 communicates with the push button 134 of the operation unit main body 132, and the other communicates with the forceps port 135. And the connecting pipe 136 between the branch part 133a of the branch pipe 133 and the forceps port 135 is formed with a thick inner diameter.

  Therefore, a large-diameter introduction pipe 138 that can be inserted into the connection pipe 136 is connected to the proximal end portion of the introduction pipe 5 via the connection pipe 137, and the large-diameter introduction pipe 138 and the operation unit main body 132 are connected. is there.

  According to the present embodiment, by rotating the operation portion main body 132, rotation can be transmitted to the introduction tube 5 with a large torque via the large diameter introduction tube 138, and the introduction tube 5 and the operation wire 6 are integrated. The direction of the clip 2 can be finely adjusted and the target site can be easily approached.

  According to the seventh to tenth embodiments described above, the clip is rotated by changing the direction of the clip by rotating the introduction tube by the clip rotation operation unit provided on the hand operation unit side of the introduction tube. Can approach the target site. Further, as compared with the case where the operation wire is rotated, there are effects that the structure is simple and a larger torque can be generated.

  48 and 49 show an eleventh embodiment. The clip case of Japanese Patent Application No. 2001-244402 described in the conventional section is formed of a transparent synthetic resin material, and the clip unit is stored in the clip case. Sterilized in a wet state. And in the state accommodated in the clip case, it can connect with the operation wire penetrated by the introduction pipe | tube, without touching fingers.

  However, the clip case described above has a structure in which the introduction tube is pressed by the elastic restoring force of the elastic pressing portion provided in the clip case, and the holding force of the introduction tube is insufficient. Therefore, the introduction pipe moves in the direction of coming out of the introduction pipe insertion portion of the clip case due to the reaction force when the operation wire is advanced to elastically engage the arrowhead hook with the connection member, and the arrowhead hook and the connection member There is a problem that the engagement cannot be performed with one touch.

  In addition, when the elastic restoring force of the elastic pressing part is increased, the amount of insertion force of the introduction pipe also increases, and repeated installation of the clip places an excessive load on the introduction pipe and may induce buckling of the introduction pipe. It was. The present embodiment solves the aforementioned problems.

  48 (a) to 48 (c) and FIG. 49 show a clip case 230 that houses the clip unit 1, and is configured in a substantially trapezoidal shape in plan view from an upper case 231 and a lower case 232 having the same dimensions and the same shape. The same molding die can be used for molding. The upper case 231 and the lower case 232 have an appropriate hardness such as ABS, PC, PP, PS, acrylic, cycloolefin polymer, etc., and are manufactured by injection molding a transparent resin. The clip case 230 has a width of about 10 mm to 20 mm, a length of about 50 mm, and a thickness of about 5 mm.

  A clip unit storage portion 233 is provided at one end of the upper case 231 and the lower case 232 in the longitudinal direction, and a pressing portion 234 is provided at the other end. A clip confirmation window 235 formed of a trapezoidal opening is provided at a portion corresponding to the clip unit storage portion 233. Moreover, the pressing part 234 has a trapezoidal shape suitable for grasping with a finger, and a continuous slit 234b is formed on the remaining three sides, leaving the connecting part 234a on one side. And the pressing part 234 of the upper case 231 and the lower case 232 is bent so that it may mutually separate from the connection part 234a, and the space | interval 234c is provided between the pressing parts 234. FIG.

  Therefore, when the pressing part 234 of the upper case 231 and the lower case 232 is picked with fingers, the pressing part 234 is elastically deformed with the connecting part 234a as a fulcrum.

  Since the upper case 231 and the lower case 232 have the same shape, one lower case 232 will be described. The clip storage in which the clip 2 of the clip unit 1 is stored in an open state on the inner surface of the clip unit storage portion 233. A portion 237 is provided, and a presser tube storage portion 238 and a connecting member storage portion 239 each having an arc groove are provided continuously with the clip storage portion 237. The bottom portion of the presser tube storage portion 238 has a protruding and retracting wing storage recess 238a in which the protruding and retracting wing 4d is stored.

  Furthermore, the inner surface of the squeezing portion 234 is provided with an introduction tube insertion portion 240 formed of an arc groove continuously with the connecting member storage portion 239, and the outer surface is provided with a plurality of ridges 240b to form a slip stopper. . Further, a stopper 234 d that protrudes from the inner surface of the pressing portion 234 is provided at the inner end of the introduction tube insertion portion 240, and an insertion hole 242 is provided at the outer end of the introduction tube insertion portion 240. The insertion hole 242 has a tapered portion 242a that increases in diameter toward the insertion inlet, the position of the introduction tube insertion portion 240 is known at a glance, and the introduction tube 5 is inserted and guided into the insertion hole 242. ing.

  As shown in FIG. 49, the clip case 230 configured as described above has a thick central portion and a substantially arc shape, and both end portions are thin. Therefore, when the clip case 230 is placed on a table or the like, the distance H is 1 mm or more between the both ends of the clip case 230 and the table, and the clip case 230 is formed in a shape that can be easily picked up with fingers.

  Next, the operation of the clip case configured as described above will be described. The clip unit 1 is accommodated between the upper case 231 and the lower case 232 of the clip case 230. The clip 2 is connected to the clip storage portion 237, the presser tube 4 is connected to the presser tube storage portion 238, and the connecting member 3 is connected. It is set in the member storage part 239.

  In order to attach the clip unit 1 to the ligating apparatus from this state, first, as shown in FIG. 48 (b), the squeezed portion 234 of the clip case 230 is picked with fingers and the interval is narrowed to some extent. In this state, the distal end portion of the introduction tube 5 is inserted into the introduction tube insertion portion 240 from the insertion hole 242 of the clip case 230, and the distal tip 7 is abutted against the stopper 241.

  Next, when the squeezed part 234 is picked with fingers, the squeezed part 234 is elastically deformed, and as shown in FIG. 48 (c), the introduction tube 5 is clamped and fixed in the axial direction by the inner surface of the squeezed part 234.

  In this state, when the slider 11 of the operation portion 9 is moved to the distal end side, the arrowhead hook 8 protrudes from the distal end portion of the introduction tube 5 through the operation wire 6. Accordingly, when the tip end of the arrowhead hook 8 comes into contact with the conical hole 3j formed in the gripping portion 3e of the connecting member 3 and the slider 11 is further moved to the tip end side, the gripping portion 3e is pushed outward by the arrowhead slope portion 8b. It is done. Thereafter, when the arrowhead hook 8 is further pushed into the gripping portion 3e, the gripping portion 3e passes through the arrowhead hook 8 and is blocked by an elastic force, and the shaft portion 8c is clamped by the gripping portion 3e. In this state, since the arrowhead large-diameter portion 8d of the arrowhead hook 8 engages with the step portion 3m of the grip portion 3e, the arrowhead hook 8 cannot be removed from the grip portion 3e, and the clip unit 1 is coupled to the operation wire 6. . When the slider 11 is moved to the proximal end side in this state, the clip unit 1 is drawn into the introduction tube 5 through the operation wire 6.

  At this time, the arm 2 b of the clip 2 is closed according to the inner diameter of the introduction tube 5. Further, since the projecting and retracting wing 4 d of the presser tube 4 is in contact with the inner surface of the introduction tube 5, the presser tube 4 is elastically deformed and kept in the presser tube 4.

  After the clip unit 1 is drawn into the introduction pipe 5, if the amount of force for grasping the squeezing part 234 of the clip case 230 is weakened, the squeezing part 234 spreads in the vertical direction by the elastic restoring force, and the introduction pipe 5 is connected to the introduction pipe of the clip case 230. It can be extracted from the insertion portion 240.

  FIG. 50 shows the twelfth embodiment, (a) is a plan view, (b) is a cross-sectional view taken along the line TT, and the same components as those in the eleventh embodiment are given the same reference numerals. Is omitted.

  The upper case 251 and the lower case 252 constituting the clip case 250 of the present embodiment are satin-finished and are translucent. Furthermore, the pressing part 253 is provided in a direction perpendicular to the insertion direction of the introduction pipe insertion part 240. The pressing part 253 is a rectangular shape having a size suitable for picking with fingers, and a continuous slit 253b is formed on the remaining three sides, leaving the connecting part 253a on one side. And the pressing part 253 of the upper case 251 and the lower case 222 is bent so that it may mutually separate from the connection part 253a, and the space | interval 253c is provided between the pressing parts 253.

  Therefore, the pressing part 253 is elastically deformed by using the connecting part 253a as a fulcrum by pinching the pressing part 253 of the upper case 251 and the lower case 252 with fingers. That is, if the pressing part 253 is picked with a finger, the pressing part 253 is elastically deformed, and the introduction tube 5 can be held and fixed in an axially immovable manner by the inner surface of the pressing part 253.

  FIG. 51 shows a thirteenth embodiment, where (a) is a plan view and (b) is a side view. The upper case 61 and the lower case 62 constituting the clip case 60 of the present embodiment have an appropriate hardness such as ABS, PC, PP, PS, acrylic, cycloolefin polymer, etc., and are formed by injection molding a transparent resin. Manufactured.

  A clip unit storage portion 63 is provided at one end of the clip case 60, and a pressing portion 64 is provided at the other end. The clip unit housing portion 63 has an annular frame 65, and a clip confirmation window 66 made of a lens is provided in the frame 65. The clip unit 1 stored in the clip unit storage unit 63 can be enlarged and observed.

  The pressing part 64 has a substantially trapezoidal shape in plan view, and is bent so that the pressing parts 64 of the upper case 61 and the lower case 62 are separated from the connecting part 67 with the clip unit storage part 63, and between the pressing parts 64. Is provided with an interval 64a.

  Therefore, the pressing part 64 is elastically deformed with the connecting part 67 as a fulcrum by pinching the pressing part 64 of the upper case 61 and the lower case 62 with fingers. When the squeezed part 64 is picked with fingers, the squeezed part 64 is elastically deformed, and the introduction tube 5 can be held and fixed in an axially immovable manner by the inner surface of the squeezed part 64.

  According to the said 11th-13th embodiment, after inserting the introduction pipe which penetrated the operation member in the insertion part of a case main body, if an expression part is squeezed with fingers, an introduction pipe will be fixed to a case main body. When the operation member is advanced in this state, the distal end portion of the operation member is engaged with the connection member of the clip unit stored in the case body, and the operation member and the clip unit are connected. Can be connected with one touch.

According to each of the embodiments, the following configuration is obtained.
(Appendix 1) A clip having an arm for grasping a living tissue, a fastening member that fits and attaches to the clip, and closes the arm of the clip, and can be inserted into the fastening member. A living tissue comprising: a connecting member that engages; and an engaging portion that directly engages the fastening member and the connecting member while being fitted to the fastening member. Ligation equipment.

  (Supplementary note 2) The living tissue ligating apparatus according to supplementary note 1, wherein the engaging portion is a non-circular portion formed in a shaft portion of the connecting member.

  According to Supplementary notes 1 and 2, when the connecting member is inserted into the tightening member when the clip unit is assembled, and the clip is engaged with the tip of the connecting member, the connecting member is pulled into the tightening member. The clip is housed in the fastening member, and the fastening member and the connecting member are directly engaged with each other, so that the connecting member does not inadvertently move in the axial direction inside the fastening member. It is possible to prevent the clip from separating from the connecting member inside the tube.

  (Additional remark 3) The clip which has an arm which grasps a living tissue, The fastening member which closes the arm of a clip by attaching and attaching to this clip, The clip which can be inserted in this fastening member, A living tissue comprising: a connecting member to be engaged; and a locking portion that is provided on both of the clip and the fastening member and that directly engages to hold an arm of the clip in an open leg state. Ligating device.

  (Additional remark 4) The said latching | locking part is the protrusion provided in the said clip, and the internal diameter step part provided in the said clamping member, The ligation apparatus of the biological tissue of Additional remark 3 characterized by the above-mentioned.

  According to the supplementary notes 3 and 4, when the clip is pulled into the fastening member by the operation member, the clip locking portion and the locking member locking portion are locked when the clip arm is fully opened. The clip is held in a state where it is opened to the maximum, and in this state, the clip is pressed against the living tissue, and the clip is closed, whereby the living tissue can be grasped by the clip.

  (Additional remark 5) It consists of a clip having an arm for grasping a living tissue and a tightening member that closes the arm of the clip by being fitted to this clip and inserted into the body cavity transendoscopically. A living tissue ligating apparatus for ligating a living tissue with a clip, wherein the fastening member is colored in a color that is highly visible in an endoscope visual field.

  (Supplementary note 6) The living tissue ligating apparatus according to supplementary note 5, wherein the fastening member is colored in a color different from that of the tissue in the body cavity.

  (Supplementary note 7) The ligating apparatus for living tissue according to supplementary note 5, wherein the fastening member is colored blue or green.

  (Supplementary note 8) The living tissue ligation apparatus according to supplementary note 5, wherein the fastening member is colored in a color other than white.

  (Supplementary note 9) A clip having an arm for gripping a living tissue, a fastening member that closes the arm of the clip by fitting and attaching to the clip, and a connecting member connected to the clip, In a living tissue ligating apparatus that is inserted into a body cavity endoscopically and ligates the living tissue with a clip, the living body is characterized in that the connecting member is colored in a color that is highly visible in the endoscope field of view. Organization ligation device.

  (Additional remark 10) The ligation apparatus of the biological tissue of Additional remark 9 characterized by coloring the said connection member in the color different from the tissue in a body cavity.

  (Additional remark 11) The ligation apparatus of the biological tissue of Additional remark 9 characterized by coloring the said connection member in blue or green.

  (Additional remark 12) The ligation apparatus of the biological tissue of Additional remark 9 characterized by coloring the said connection member in colors other than white.

  According to the supplementary notes 5 to 12, since the fastening member and the connecting member are colored in a color different from the tissue in the body cavity, the visibility of the fastening member and the connecting member in the endoscope visual field is improved. Therefore, the clip can be approached to the target site of the living tissue, and the living tissue can be reliably ligated.

  (Additional remark 13) The clip which has an arm which grasps living tissue, The fastening member which closes the arm of a clip by attaching and attaching to this clip, The clip which can be inserted in this fastening member, An engaging pipe that can accommodate the clip and the tightening member; and an operating member that is engaged with the connecting member and is movably inserted into the introducing pipe. A living tissue ligating apparatus characterized in that the clearance between the outer diameter of the operating member and the operating member is 0.3 mm or less.

  (Supplementary note 14) The living tissue ligating apparatus according to supplementary note 13, wherein the introduction tube is a flexible coil sheath in which a spring material is tightly wound.

  (Supplementary note 15) The living tissue ligating apparatus according to supplementary note 13, wherein the operation member is an operation wire made of a stranded wire.

  According to appendix 13 to appendix 15, since the clearance between the inner diameter of the introduction tube and the outer diameter of the operation member is very small, the introduction tube does not buckle during the advance / retreat operation of the operation member. It can be reliably transmitted to the clip.

  (Supplementary Note 16) A clip having an arm for grasping a living tissue, a fastening member that fits and attaches to the clip and closes the arm of the clip, and can be inserted into the fastening member. A connecting member that engages; an introduction pipe that can accommodate the clip and the fastening member; an operation member that is inserted into the introduction pipe so as to freely advance and retreat; and an introduction pipe that is provided on the proximal operation portion side of the introduction pipe. A living tissue ligation apparatus comprising: a clip rotation operation unit that rotates to change the direction of the clip.

  (Supplementary note 17) The ligating apparatus for living tissue according to supplementary note 16, wherein the clip rotation operation unit is movable in the axial direction of the introduction tube.

  According to the sixteenth and seventeenth aspects, by rotating the clip rotation operation portion, the introduction tube and the operation member rotate, and the clip can be rotated to approach the target site.

  (Additional remark 18) The clip which has an arm which grasps a living tissue, the fastening member which closes the arm of this clip by fitting and attaching to this clip, and can be inserted in this fastening member, The clip A body tissue ligation clip case for storing a clip unit comprising a coupling member that engages with a case, a case main body having a clip unit storage portion, and an introduction tube provided in the case main body and connected to the coupling member For ligation of living tissue, comprising: an insertion portion for inserting the insertion tube; and a squeezing portion for fixing the introduction tube by squeezing the introduction tube provided in a part of the case main body and inserted into the insertion portion. Clip case.

  (Additional remark 19) The case of the clip for biological tissue ligation according to additional remark 18, wherein the case body has a shape in which a thickness of a central portion is thicker than both end portions.

  (Additional remark 20) The case of the clip for biological tissue ligation of Additional remark 18 characterized by the said insertion part having the taper-shaped insertion hole which the inlet side diameter-expanded.

  (Additional remark 21) The case of the clip for biological tissue ligation according to additional remark 18, wherein the case main body has an opening window through which a clip stored inside can be confirmed.

  According to Supplementary notes 18 to 21, after the introduction tube inserted through the operation member is inserted into the insertion portion of the case body, the introduction tube is fixed to the case body when the squeezing portion is squeezed with fingers. When the operating member is advanced in this state, the distal end portion of the operating member is engaged with the connecting member of the clip unit stored inside the case body, and the operating member and the clip unit are connected.

The perspective view of the clip unit which shows 1st Embodiment of this invention. The embodiment is shown, (a) is a perspective view of a clip, (b) is a perspective view of a loop part, (c) is sectional drawing which follows the AA line. The embodiment is shown, (a) is a longitudinal plan view of the clip unit, (b) is a longitudinal side view of the clip unit. The clip unit of the state which the clip of the embodiment opened is shown, (a) is a longitudinal side view, (b) is a sectional view along the line BB, (c) is a longitudinal plan view. The clip unit of the state which the clip of the embodiment closed is shown, (a) is a longitudinal side view, (b) is a longitudinal plan view. The same embodiment is shown, (a) is a longitudinal side view of the distal end portion of the ligating apparatus, (b) is a longitudinal side view of a connecting member, (c) is a cross-sectional view showing a fixing structure of an arrowhead hook. The modification of the embodiment is shown, (a) is a cross-sectional view showing the fixing structure of the arrowhead hook, (b) is a cross-sectional view taken along line FF. The same embodiment is shown, (a) (b) is a perspective view which shows the state which removes a connection member from an arrowhead hook. The operation part of the ligation apparatus of the embodiment is shown, (a) is a longitudinal side view, (b) is a sectional view taken along the line CC, (c) is a sectional view taken along the line DD. The operation part of the ligation apparatus of the embodiment is shown, (a) (b) is a vertical side view. The longitudinal section side view of the front-end | tip part of the operation part main body which shows the same embodiment. The perspective view of the clip case which shows the same embodiment. The exploded perspective view of the clip case which shows the embodiment. The embodiment is shown, (a) is a top view of a lower case, (b) is a vertical side view of a clip case. The embodiment is shown, (a) is a sectional view taken along line GG in FIG. 14, (b) is a sectional view taken along line H-H in FIG. 14, and (c) is taken along line II in FIG. FIG. The same embodiment is shown and (a)-(c) is a top view of a lower case. The modification of the embodiment is shown, (a)-(c) is a plan view of the lower case. The same embodiment is shown and (a)-(c) is an operation explanatory view of a clip case. The same embodiment is shown and (a)-(c) is an operation explanatory view of a clip case. The operation explanatory view of a clip case which shows the embodiment. The embodiment is shown, (a) is a longitudinal side view of the insertion portion of the endoscope, (b) is a cross-sectional view taken along the line EE. The embodiment is shown, (a)-(c) is an operation explanatory view. The same embodiment is shown, (a)-(d) is an operation explanatory view. The top view of the peel pack which shows 2nd Embodiment of this invention. The perspective view of the peel pack which shows the embodiment. The same embodiment is shown, (a)-(c) is an operation explanatory view of a peel pack. The 3rd Embodiment of this invention is shown, (a) is a perspective view of a clip, (b) is a perspective view of a loop part, (c) is sectional drawing which follows a JJ line | wire. The embodiment is shown, (a) is a longitudinal plan view of the clip unit, (b) is a longitudinal side view of the clip unit. The clip unit of the state which the clip of the embodiment opened is shown, (a) is a longitudinal side view, (b) is a sectional view along the line KK. The longitudinal section side view showing the clip unit in the state where the clip of the embodiment opened. The clip of the embodiment is shown closed, (a) is a longitudinal plan view, (b) is a longitudinal side view, (c) is a cross-sectional view taken along line LL, (d) is taken along line MM. FIG. The clip unit of the embodiment is shown, (a) is a longitudinal side view, (b) is a cross-sectional view along the line NN. The modification of the clip unit of the embodiment is shown, (a) is a longitudinal side view, (b) is a cross-sectional view along the line OO. The longitudinal cross-sectional side view of the state which showed the modification of the clip of the embodiment and inserted the clip in the introduction pipe. The 4th Embodiment of this invention is shown, (a) is a vertical plane view of a clip unit, (b) is a vertical side view of a clip unit. The clip unit of the state which the clip of the embodiment opened is shown, (a) is a longitudinal side view, (b) is a sectional view along the line PP, (c) is a longitudinal plan view. The perspective view of the clip unit which shows 5th Embodiment of this invention. The vertical side view of the front-end | tip part of a ligation apparatus which shows 6th Embodiment of this invention. The 7th Embodiment of this invention is shown, (a) (b) is a vertical side view of the front-end | tip part of an operation part main body. The exploded perspective view of the clip rotation operation part which shows the same embodiment. The operation explanatory view of a clip rotation operation part which shows the embodiment. The operation explanatory view of a clip rotation operation part which shows the embodiment. The perspective view of the operation part which shows 8th Embodiment of this invention. The same embodiment is shown, (a) is a longitudinal side view of the operation part, (b) is a longitudinal side view in which the Q part is enlarged, and (c) is a sectional view taken along line RR. The 9th Embodiment of this invention is shown, and the perspective view of an operation part. The same embodiment is shown, (a) is a longitudinal side view of the operation unit, (b) is a sectional view taken along the line SS. The 10th Embodiment of this invention is shown, and the side view of an operation part. The clip case of 11th Embodiment of this invention is shown, (a) is a top view, (b) is a vertical side view, (c) is a vertical side view of the state which squeezed the pressing part with fingers. The front view of the clip case which shows the same embodiment. The 12th Embodiment of this invention is shown, (a) is a top view of a lower case, (b) is sectional drawing which follows a TT line. The 13th Embodiment of this invention is shown, (a) is a top view of a lower case, (b) is a side view.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Clip unit 2 ... Clip 2d ... Protrusion 3 ... Connecting member 4 ... Presser tube 5 ... Introducing tube 6 ... Operation wire

Claims (3)

A clip having an arm for grasping a living tissue;
A fastening member that closes the arm by fitting to the clip;
A connecting member that can be inserted into the fastening member and engages the clip;
An engaging portion that is provided on both the clip and the fastening member and is held by the fastening member in a state where the arm of the clip is opened by engaging with each other.
A living tissue ligation apparatus comprising:   The ligation apparatus for living tissue according to claim 1, wherein the locking portion is a protrusion provided on the clip and an inner diameter step portion provided on an inner surface of the fastening member.   The living tissue ligating apparatus according to claim 1, wherein the tightening member is made of a deformable resin.

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