JP2009226135A - Connected clip package and method for loading clips - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a connected clip package which allows a user to load a plurality of connected clips to a sheath with an easy operation and sets opening/closing directions of the reloaded clips always in an identical direction with respect to the sheath, and also to provide a method for loading connected clips into the sheath. <P>SOLUTION: In the connected clip package, a plurality of clips arranged in a row and engaging with clips in front of and behind themselves are received within a case. The case has, on its proximal end, a fitting section that fits to the sheath loaded with the clips. A first identification part showing a reference circumferential position of the sheath is arranged at the distal part of the sheath that fits to the fitting section. The problems are solved by arranging a second identification part corresponding to the first identification part on the proximal end of the case. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a package for distribution and storage of an endoscopic clip used for hemostasis or wound closure in a living body and the like, and a clip loading method from the package to a sheath. The present invention relates to a connection clip package and a clip loading method for a repetitive clip treatment instrument that can be used.

  Endoscopic clip treatment tool is designed to project the clip from the tip of the endoscope inserted into the living body, pick the treatment part after removal of the bleeding part or lesion tissue with the clip, and stop hemostasis or wound closure Used. A conventionally used endoscope clip is a clip in which one clip is detachably attached to the tip of an operation wire, and the entire sheath is pulled out of the endoscope each time a clip treatment is performed. A cumbersome work of setting the clip, inserting it again into the endoscope, and performing the next clipping is required.

On the other hand, an endoscope clip device that enables continuous clipping treatment has been proposed. For example, Patent Document 1 discloses a living body in which a plurality of operation wires are inserted into an introduction tube, a plurality of clips are arranged in series in the introduction tube, and the clips and the operation wires are engaged one-on-one. A tissue clip device is described.
Further, in Patent Document 2, a plurality of clips are alternately turned 90 degrees by engaging the front end claw portion of the rear clip with a connecting hole formed in the rear end portion of the front clip. An endoscopic clip device that is directly coupled is described.

Japanese Patent Laid-Open No. 2002-272751 JP 2006-187391 A

  According to the devices of Patent Literature 1 and Patent Literature 2, continuous clip treatment can be performed. However, in the device of Patent Document 1, however, in the device of Patent Document 1, when loading the clip into the introduction tube, each clip is attached to each of the plurality of operation wires inserted through the introduction tube, Furthermore, it is necessary to arrange the clips so that they are arranged in a line, and it takes time and effort to load them. Further, in the device of Patent Document 2, it is necessary to load the clips into the sheath while connecting the clips one by one, and it takes time and effort to load the clips.

  Further, when the treatment is not completed even if all the loaded clips are used, a new clip is reloaded and the treatment is continued. However, in the devices disclosed in Patent Document 1 and Patent Document 2, reloading is performed. Therefore, when resuming a subsequent procedure, the clip appearing from the sheath tip must be observed on the monitor to adjust the direction of the clip. I must.

  An object of the present invention is to solve the above-mentioned problems of the prior art and provide a user with a plurality of clips connected to each other, and the user can easily operate the plurality of clips in a connected state. A connection clip package in which the opening and closing direction of the reloaded clip can always be determined in the same direction with respect to the sheath, and a method of loading the connection clip into the sheath is there.

In order to solve the above problems, the present invention includes a cylindrical case,
A removable lower cap attached to the rear end of the case;
A connected clip package having a plurality of clips that are housed in the case and are arranged in a row in engagement with the front and rear clips,
The case has a fitting portion with which a sheath for loading the clip is fitted at a rear end portion, and a reference position in a circumferential direction attached to a distal end portion of the sheath fitting with the fitting portion The connection clip package which has the 2nd identification part which should be made to respond | correspond to the 1st identification part which shows this in the rear-end part of the said case is provided.

Here, it is preferable that the first identification portion is a mark written on the surface of the sheath, and the second identification portion is a mark written on the surface of the case.
The first identification part is a groove formed in a predetermined length in the axial direction from the distal end of the sheath, and the second identification part is formed on an inner surface of the fitting part of the case, A protrusion that can be inserted into the groove is preferable.

  Furthermore, it is preferable that a position restricting means for restricting a position in the circumferential direction is provided between the case of the package and the plurality of clips accommodated in the case.

In addition, a connection ring that covers the engagement portion and maintains the connection state of the clip is fitted to the engagement portion of the clip,
The connection ring has a skirt portion that expands in a skirt shape in a natural state where no external force is applied, protrudes in the radial direction of the connection ring, and closes inward when pressed in the radial direction;
The case has an inner diameter slightly larger than an outer diameter of the connection ring in the clip and the connection ring receiving portion, and spreads in a natural state at a position corresponding to the skirt portion of the connection ring to be received. A recess for accommodating the skirt portion;
The position restricting means is preferably a skirt portion of the connecting ring and a concave portion of the case.

Further, the rear end member attached to the rearmost clip in the case has a diameter larger than the outer diameter of the connecting clip and smaller than the outer diameter of the sheath at one or a plurality of positions in the circumferential direction. A position restricting member protruding to
The case has one or a plurality of invitation grooves into which the position restriction member is fitted at a position of the front end portion of the fitting portion that should correspond to the position restriction member,
The position restricting means is preferably the position restricting member and the invitation groove.

  Moreover, it is preferable that the plurality of clips are connected by changing the spreading direction by 90 degrees.

The present invention also provides a clip loading method for loading the clip and the connection ring of the connection clip package on a sheath.
A distal end of an operation wire provided in the sheath for pulling a clip row composed of the plurality of clips is connected to a connection member attached to the last clip in the case, and the sheath Matching the first identification part and the second identification part of the case, and fitting the sheath to the fitting part of the case;
Provided is a connecting clip loading method in which the sheath and the connection ring are accommodated in the sheath while the case is moved to the distal end side by moving the sheath toward the distal end side.

  According to the present invention, a plurality of clips can be provided to the user in a connected state, and the user can load the plurality of clips in the connected state with a simple operation, and can be reloaded. The opening / closing direction of the clip can be always set in the same direction with respect to the sheath.

  The connected clip package and clip loading method according to the present invention will be described in detail below based on a preferred embodiment shown in the accompanying drawings.

1A and 1B are schematic cross-sectional views showing a first embodiment of a repetitive clip treatment device of the present invention, and FIG. 1B is an angle that is 90 degrees different from FIG. It is the figure seen from.
The clip treatment device 10 shown in FIG. 1 is a repetitive clip treatment device that can continuously use clips, and is connected to a plurality of clips 12 (12A, 12B, 12C, 12D, 12E) and the last clip 12D. The dummy clip 18, the operation wire 20 connected to the dummy clip 18 via the connecting member 19, and the connection ring 14 (14 </ b> A, 14B, 14C, 14D, 14E) and these are fitted in the sheath 16. FIGS. 1A and 1B show an initial state immediately before the start of the clip treatment operation by the head clip 12.

  One clip 12 and one connection ring 14 constitute one hemostatic clip body for an endoscope, and the clip treatment tool 10 is a plurality of the hemostatic clip bodies loaded inside the distal end of a long sheath 16. It is. The terminal end of the continuous hemostatic clip body is engaged with and coupled to the dummy clip 18, and the operation wire 20 extends to the proximal end portion of the sheath 16 and is connected to an operation portion described later. By pulling the operation wire 20 from the operation unit by a predetermined length and moving the dummy clip 18 by a predetermined length in one direction, the series of clips 12 are moved by the same amount, and the leading clip 12 holds it. A clip treatment (clipping) for hemostasis or marking by the leading clip 12 is performed by being tightened by the connection ring 14. After the clip treatment with the first clip 12 is completed, the sheath 16 is pulled to the operation unit side by a predetermined length, so that the next clip 12 can be used (standby state), and then the clip treatment is performed. Can do.

  FIGS. 1A and 1B show the state in which the leading clip 12A protrudes from the distal end of the sheath 16. However, when the clip 12 or the like is loaded into the sheath 16, FIG. As shown, the leading clip 12A is set in a state of being completely contained within the sheath 16. In FIG. 1, five clips 12 are provided as a five-shot clip treatment device, but the number of clips 12 may be two or more.

  FIG. 2 is a perspective view of the clip 12. The clip 12 is a closed clip having a turn part 24 that is turned 180 degrees with respect to the claw part 22. That is, the clip 12 is formed by bending a long thin plate 180 degrees to form a closed end, intersecting both pieces, and bending the two open ends so that the ends are opposed to each other. It has a shape in which the claw portions 22 and 22 are formed. With this intersection 26 as a boundary, the open end side is the arm portions 28 and 28, and the closed end side is the turn portion 24. Convex portions 30, 30 that are partially wide are formed at the central portions of the arm portions 28, 28. The clip 12 can be made of a biocompatible metal, for example, SUS631 which is stainless steel for springs.

  The clip 12 is moved by a predetermined amount toward the claw portions 22 and 22 while the front end portion (clamping portion 40 described later) of the connecting ring 14 fitted to the intersecting portion 26 presses the arm portions 28 and 28. By doing so, the arm portions 28 and 28 and the claw portions 22 and 22 are closed, and a predetermined fitting force, for example, 0.62N is exhibited in the claw portions 22 and 22.

  The nail | claw parts 22 and 22 are formed in the V-shaped male type | mold and the female type | mold, in order to pick up a target part reliably. Further, as shown in FIG. 2, the arm portion 28 of the clip 12 is gradually widened from the intersecting portion 26 to the convex portion 30.

  The convex portion 30 has a width wider than the portion of the opening on the distal end side and the opening on the proximal end side of the connection ring 14 with which the convex portion 30 abuts. Therefore, portions other than the convex portion 30 of the clip 12 can enter the inside of the connecting ring 14, but the convex portion 30 cannot enter the inside from the front end side or the base end side of the connecting ring 14.

  As shown in FIGS. 1 (A) and 1 (B), the first clip 12A and the second clip 12B are closed with the claw portion 22 of the second clip 12B engaged with the turn portion 24 of the first clip 12A. By being held by the connection ring 14A, the connection state is established. As shown in FIG. 1 (A), the claw portions 22 and 22 of the second clip 12B are engaged with and joined to the turn portion 24 of the first clip 12A in the orthogonal direction, and the first clip 12A and the second clip 12B are connected to each other. , They are connected in different directions by 90 degrees. Similarly, the following clips 12C, 12D, and 12E are connected with their orientations alternately changed by 90 degrees.

  The connection ring 14 is fitted in the sheath 16 so as to be able to advance and retract while covering the engaging portions of the two clips 12 and 12 and maintaining the connection state. That is, the outer diameter of the connection ring 14 is substantially equal to the inner diameter of the sheath 16, and the connection ring 14 can smoothly move back and forth in the sheath 16 as the clip 12 moves. 3A to 3C show a schematic configuration of the connection ring 14. 3A is a front view of the connecting ring 14, FIG. 3B is a cross-sectional view, and FIG. 3C is a bottom view.

  The connection ring 14 includes a tightening portion 40 and a holding portion 42. The connection ring 14 has a metal fastening part 40 fixed to the tip of a resin holding part 42 and has an integral structure with two members. The resin holding part 42 is in charge of maintaining the connected state and holding the clip in the connecting ring, and the metal fastening part 40 is in charge of fastening the clip. The connection ring 14 may be formed of one member as long as both functions of the tightening portion 40 and the holding portion 42 can be exhibited.

  The tightening portion 40 is a metal cylindrical (ring-shaped) part attached to the distal end side of the connection ring 14, and is larger than the width of the clip 12 near the intersection 26 and larger than the width of the convex portion 30. A small inner diameter hole is formed. Therefore, the tightening portion 40 can move in the vicinity of the intersecting portion 26 of the clip 12 to be held, but cannot be pulled out beyond the convex portion 30. That is, the convex portion 30 functions as a stopper that determines the movement limit of the connecting ring 14 that moves forward with respect to the clip 12.

  The tightening portion 40 is set at a predetermined position in the vicinity of the intersecting portion 26 of the clip 12. The tightening portion 40 moves from the initial position to the convex portion 30 side from the intersecting portion 26 where the arm portion 28 of the clip 12 becomes wide, so that both the arm portions 28 of the clip 12 that has spread. , 28 is closed and fixed. For the tightening portion 40, a biocompatible metal is used. For example, stainless steel SUS304 can be used. Since the tightening portion 40 is made of metal, it is possible to exert a frictional force as a tightening force on the metal clip 12.

  The holding portion 42 is a resin-molded, generally cylindrical (ring-shaped) part. The holding unit 42 includes a first area 32 that holds the previous clip 12 and a second area 34 that is a connected holding area that holds the next clip 12 in a state of being connected to the previous clip.

  In the first region 32, a circular hole larger than the hole of the tightening portion 40 that can accommodate the turn portion 24 of the clip 12 is formed. A stepped portion for fitting the tightening portion 40 is formed on the outer surface of the distal end portion of the first region 32. The tightening portion 40 and the holding portion 42 are in a state in which they are loaded in the sheath 16 and a clipping operation. It is fitted with an interference fit that does not come off at times. Further, the first region 32 has a skirt portion 38 that is inclined and spreads in a skirt shape with respect to the axis of the connecting ring 14 main body.

  The skirt portion 38 has a distal end side, that is, an upper base in FIG. 3 connected to the main body of the holding portion 42, and a lower expanding portion is partially separated from the main body so as to expand or close in the radial direction. It has become. The skirt portion 38 is formed at two positions 180 degrees apart at the same position in the pulling direction of the clip 12, that is, the vertical direction in FIG.

  The skirt portions 38 and 38 spread in a skirt shape as shown in FIG. 3A in a natural state where no external force is applied. At this time, the inside of the first region 32 of the holding portion 42 is a columnar space as shown in FIG. On the other hand, when the connecting ring 14 is loaded into the sheath 16, for example, as shown in the second connecting ring 14B in FIG. 1 (B), the skirt portion 38 is pushed inward and enters the internal space. The portion on the inner peripheral side of the portion 38 presses the side surface (edge portion) of the turn portion 24 of the clip 12B held in the first region 32, and the clip 12B moves in the rotation direction and the forward / backward direction in the connecting ring 14B. Do not hold. The skirt portion 38 may press and hold a clip held in the second region 34, that is, a rear clip.

  As shown in the first connecting ring 14A of FIG. 1A, the skirt portions 38, 38 are released from the distal end of the sheath 16, and at the same time, are opened by their own elasticity to release the holding of the clip 12A, and It becomes wider than the inner diameter of 16 to prevent the connecting ring 14 </ b> A from retracting into the sheath 16. In this state, the operation wire 20 is pulled and the clip 12A moves backward, whereby the connecting ring 14A moves forward relative to the clip 12A and tightens the clip 12A.

  Therefore, the skirt portion 38 needs to have elasticity so that it can be closed inward within the sheath 16 and spreads in a skirt shape when released from the external force from the distal end of the sheath 16. . At the same time, the skirt portion 38 needs to have a rigidity that can hold the clip 12 inside the sheath 16 and a rigidity that can withstand a reaction force of the tightening force of the clip 12 at the distal end of the sheath 16.

  From these viewpoints, the holding portion 42 is made of a material that is biocompatible and satisfies the elasticity and rigidity required for the skirt portion 38. The shape is determined so as to satisfy the elasticity and rigidity required for the skirt portion 38. For example, PPSU (polyphenylsulfone) can be used as the material of the holding unit 42. From the standpoint of ease of manufacture, the holding portion 42 is preferably integrally formed.

  The second region 34 is provided on the proximal end side of the first region 32, and the claw portions 22, 22 of the next clip 12 that engages with the clip 12 held in the first region 32 are the previous clips. The closed end (tail) of the 12 turn parts 24 is held in a closed state.

  The second region 34 has a length substantially equal to the moving length required for the tightening portion 40 set at the initial position with respect to the clip 12 to complete the tightening of the clip 12 as the region length. . That is, the second region 34 of the connection ring 14 holds the connection between the two clips 12 and 12 held therein while the clip 12 is retracted and tightened relative to the connection ring 14. In addition, the traction force of the rear clip 12 is transmitted to the front clip 12, and when the tightening is completed, the engaging portions of the two clips 12, 12 are disengaged from the second region 34, whereby the clip 12 , 12 are released.

  In the second region 34, as shown in FIG. 3C, a hole 43 having the same inner diameter as that of the proximal end portion of the first region 32 is formed, and a groove (concave portion) 43a is formed at two opposing positions. Is formed. The grooves 43a and 43a can accommodate the arm portions 28 and 28 of the clip 12 held in the second region 34 with the claw portions 22 and 22 closed. In the second region 34, as shown in FIGS. 3A to 3C, slits 44 cut from the base end are formed in two places.

  The grooves 43a and 43a are provided at two locations in the opening / closing direction (left and right direction in FIG. 3) of the claw portion 22 of the clip 12 held in the second region 34. The plate surfaces of the arm portions 28 and 28 of the clip 12 held in the second region 34 abut against the inner walls of the grooves 43a and 43a. The width (opening width) of the groove 43a is slightly larger than the maximum width of the arm portion 28 of the clip 12, and the distance from the wall surface of one groove 43a to the wall surface of the other groove 43a is the two claw portions 22 of the clip 12. , 22 (length in the expanding direction) is approximately equal to the total length. Further, the width of the groove 43 a is smaller than the width of the convex portion 30 formed in the arm portion 28. Therefore, the convex portion 30 of the clip 12 held in the second region 34 cannot enter the groove 43a.

In addition, the distance from the wall surface to the wall surface of both grooves 43a and 43a should just be a dimension in which the engagement between the turn part 24 of the previous clip 12 and the claw parts 22 and 22 of the next clip 12 is not released. What is necessary is just to make shorter than the length which added the length of the two nail | claw parts 22 and 22 and the width | variety of the part which the nail | claw parts 22 and 22 of the turn part 24 engage.
For example, the claw portions 22 and 22 of the clip 12 held in the second region 34 may be in a slightly overlapped state, or with a slight gap between the claw portions 22 and 22, The connection with the clip 12 may be maintained.

  The engaging portions of the two clips 12 and 12 are held in a portion of the second region 34 that is close to the boundary with the first region 32. Since the previous clip 12 (for example, the clip 12B in the connecting ring 14B in FIG. 1B) is held by the closed skirt portion 38 of the first region 32 in the sheath 16, Forward / backward movement and rotational movement are suppressed. Further, the next clip 12 that engages with the previous clip 12 (for example, the clip 12C in the connection ring 14B in FIG. 1B) is held in a direction different from the previous clip by 90 degrees by the groove 43a of the second region 34. Thus, the rotational movement is suppressed, and the forward / backward movement is suppressed by engaging with the previous clip in which the forward / backward movement is suppressed. That is, the engaging portions of the front and rear clips are held by the connection ring 14 with a very small play.

  The slits 44 are formed at two positions shifted by 90 degrees from the skirt portions 38 and 38 to a position shallower than the upper end of the second region 34. In other words, the slit 44 is provided at a position shifted by 90 degrees from the spreading direction of the clip 12 held in the second region 34.

  By providing the slit 44, the flexibility of the connection ring 14 can be improved, and the clip treatment tool 10 can pass through a curved portion having a small curvature. Further, since the skirt (base end portion) of the connection ring 14 is partially turned up by providing the slit, the connection is made when the front and rear clips 12, 12 are connected before the clip 12 is loaded into the sheath 16. There is also an advantage that it can be easily connected by turning the skirt of the ring 14.

  The depth of the slit 44 is set to a position shallower than the skirt portion 38, and the strength of the connecting ring 14 is prevented from greatly decreasing. The depth of the slit 44 is set to the position of the rear end of the clip 12 held in the first region 32, that is, a position shallower than the engaging position of the clips 12 and 12, and is loaded into the sheath 16. Even in the previous connecting clip unit, the holding of the clip 12 in the second region 34 of the connecting ring 14 can be maintained.

  As shown in FIG. 1, the claw portions 22 and 22 of the second clip 12B engage with the turn portion 24 of the first clip 12A, and the connecting ring 14A holds the engaging portion. The claw portions 22 of the second clip 12B are held in a closed state by the inner wall of the connection ring 14A (the second region 34). Thereby, the connection state of the first clip 12A and the second clip 12B is maintained. Similarly, the connection state of the second clip 12B and the third clip 12C is determined by the connection ring 14B, and the connection state of the third clip 12C and the fourth clip 12D is determined by the connection ring 14C and the fifth clip 12D and the fifth clip 12C. The connection state with the clip 12E is maintained by the connection ring 14D, and the connection state between the fifth clip 12E and the dummy clip 18 is maintained by the connection ring 14E.

  A dummy clip 18 that is not used for clip treatment is engaged with the rearmost clip 12E. The dummy clip 18 has a spring-like portion having a shape similar to that of the half on the open end side from the crossing portion 26 of the clip 12 at the tip, and the clip 12E is turned with the claw portion closed. The clip 12E is released when the claw is opened. A connection member 19 is provided at the proximal end portion of the dummy clip 18, and an operation wire 20 is connected to the connection member 19.

  The connection member 19 (the rear end portion of the dummy clip 18) and the tip of the operation wire 20 may be detachable and may be configured not to be detached by the forward / backward movement of the operation wire 20, and the configuration is particularly limited. Not.

  The sheath 16 is, for example, a flexible coil sheath in which a metal wire is tightly wound. The inner diameter of the sheath 16 is such that the engagement between the turn portion 24 of the previous clip 12 and the claw portions 22 of the next clip 12 is released. That is, the inner diameter of the sheath 16 is larger than the total length of the lengths of the two claw portions 22 and 22 and the width of the portion of the turn portion 24 where the claw portions 22 and 22 are engaged.

  The proximal ends of the operation wire 20 and the sheath 16 are attached to the operation unit. 4A and 4B are partial cross-sectional views illustrating a schematic configuration of the operation unit. FIG. 4A is a plan view and FIG. 4B is a front view. 4A and 4B, the left side is the distal end side connected to the clip treatment instrument 10, and the right side is the rear end side (or the proximal end side).

  The operation unit 50 includes a wire operation handle 52 that is a cylindrical main body of the operation unit, and a sheath operation handle 54 that is a sheath operator. The operation unit 50 performs a clip treatment operation by pulling the operation wire 20 and sets the clip to an initial state by pulling the sheath 16.

  The wire operation handle 52 includes a cylindrical case 58, a positioning pipe 56 that is fixed to the tip of the case 58 with its axis aligned, and a lever 60 and a spring 62 that are held inside the case 58. .

  The lever 60 is held inside the case 58 so as to be movable in the front-rear direction (the axial direction of the wire operation handle 52). A part of the rear end side of the lever 60 appears in a through window 59 provided in the central portion of the case 58 so that the operator can pull the lever 60 toward the rear end side by placing a finger. A spring 62 is attached to the rear end of the lever 60. The spring 62 is compressed by pulling the lever 60 backward, and when the force pulling the lever 60 is released, the spring 60 pushes the lever 60 forward by a repulsive force. Thereby, the lever 60 returns to the original position (home position).

  The rearward movement limit of the lever 60 is defined by the through window 59. That is, the position at which the surface 60 a on which the finger of the lever 60 is applied coincides with the rear end of the through window 59 is the movement limit of the lever 60. Note that a restriction plate may be provided behind the lever 60, and the rearward limit of the lever 60 may be defined by the rear end of the lever 60 hitting the restriction plate.

On the other hand, a regulating plate 61 is provided in front of the lever 60 to define the home position of the lever 60. The lever 60 is urged by the spring 62 and moves forward, stops against the restriction plate 61, and returns to the home position.
Thus, the lever 60 can move only a certain amount from the home position to the rearward movement limit in the front-rear direction.
In FIG. 4, the spring 62 is shown as a coil spring, but the spring 62 only needs to be able to urge the lever 60 forward, and a leaf spring or other elastic body may be used.

An operation wire 20 for pulling the clip 12 is rotatably held at the tip of the lever 60 and is fixed in the front-rear direction. For example, the circumferential direction of the rear end portion of the operation wire 20 is held rotatably with respect to the lever 60 by a member having good slipperiness, a bearing mechanism, or the like. When the lever 60 is pulled backward, the lever 60 is integrated with the lever 60. Is kept moving.
The operation wire 20 passes through the sheath operation handle 54 and the positioning pipe 56 and reaches the lever 60.

  When the operator inserts a finger into the penetrating window 59 and pulls the lever 60 so that the lever 60 moves backward, the operation wire 20 attached to the tip of the lever 60 also moves in the same manner, and the tip of the operation wire 20 is moved. Moves backward. When the pulling force of the lever 60 is released and the lever 60 returns to the original position, the operation wire 20 moves in the same manner, and the tip thereof returns to the original position.

  The distal end of the operation wire 20 is connected to the clip 12, and when the clip 12 rotates around the axis, the operation wire 20 also rotates, but the lever 60 holds the rear end portion of the operation wire 20 rotatably. Therefore, the operation wire 20 can be prevented from accumulating torsional stress.

  Since the pulling amount of the operation wire 20 in the clip treatment is a very small amount such as 3.1 mm, for example, the pulling amount of the operation wire 20 and the operation amount of the lever 60 are given in order to give a reliable operation feeling in the operation unit 50. Between them, a mechanism for changing the pulling amount of the operation wire 20 may be provided, and the movement amount of the lever 60 may be a predetermined multiple of the movement amount of the operation wire 20.

  The positioning pipe 56 is a hollow pipe-like member through which the operation wire 20 passes. Further, the inner diameter of the positioning pipe 56 is larger than the outer diameter of the sheath 16, and the sheath 16 can be inserted into the positioning pipe 56. The distal end portion of the positioning pipe 56 is inserted into the sheath operation handle 54, and a retaining ring 64 is attached to the distal end portion. As shown in FIG. 4A, a hole slightly larger than the outer diameter of the sheath 16 is formed at the center of the retaining ring 64, and the retaining ring 64 can move the sheath 16 in the axial direction. Hold on.

  As shown in FIG. 4B, a spiral guide groove 67 is formed on the surface of the positioning pipe 56. The guide groove 67 has a path parallel to the axis in the section of the first length L from the front end side, and the same in the circumferential direction every time the length L moves in the axial direction to the rear end side portion thereof. It has a spiral path that rotates 90 degrees in the direction. The guide groove 67 is formed with a plurality of depressions (recesses) 66 at a predetermined interval L in the axial direction. Adjacent indentations 66 are shifted by 90 degrees in the circumferential direction except for the first and second indentations 66 from the tip side. More than the number of the depressions 66 corresponding to the continuous number of the clips 12 is provided. In the example of FIG. 4, six depressions 66 are provided, and it is possible to deal with five consecutive clips.

  The sheath operation handle 54 includes a cylindrical case 68 whose rear end is released, a support block 70, a sheath holding ring 72, a ball holding member 74 that holds a ball 76, and a cover case 78. .

  The support block 70 is disposed at the rear end portion of the sheath operation handle 54 (in the illustrated example, the front end side of the ball holding member 74), and slidably supports the positioning pipe 56 inserted into the sheath operation handle 54. To do. Further, as shown in FIG. 4B, the support block 70 has a surface on the tip side abutting against a retaining ring 64 attached to the tip of the positioning pipe 56, and the positioning pipe 56 is connected to the sheath operation handle 54. To prevent it from exiting.

  The sheath holding ring 72 is provided on the axis of the sheath operation handle 54 at the distal end of the case 68 and fixedly holds the outer periphery of the sheath 16 inserted into the sheath operation handle 54. Therefore, when the sheath operation handle 54 moves in the axial direction or the circumferential direction, the sheath 16 also moves.

  The ball holding member 74 is a ring-shaped component having an inner diameter larger than the outer diameter of the positioning pipe 56, and is fixed to the rear end portion of the case 68. The ball holding member 74 holds one ball 76 in a state in which a part thereof protrudes from the inner peripheral surface of the ball holding member 74. The ball 76 can rotate while being held by the ball holding member 74.

A positioning pipe 56 is inserted into the ball holding member 74, and a ball 76 is engaged with a guide groove 67 of the positioning pipe 56.
Further, the ball holding member 74 includes means (not shown) for urging the ball 76 toward the inner peripheral side. As this urging means, a spring or a highly elastic member provided between the ball 76 and the ball holding member 74 can be used.

  The ball 76 may not be rotatable as long as the friction with the guide groove 67 of the positioning pipe 56 is small, and a convex member may be used instead of the ball holding member 74 and the ball 76.

  The cover case 78 covers the outside of the case 68 and is in contact with the front end and the rear end of the case 68. The contact surface between the case 68 and the cover case 78 is a low friction surface, and the case 68 can rotate and move with respect to the cover case 78 with the front end and the rear end in contact with the cover case 78. . Further, since the front and rear ends of the case 68 are held by the cover case 78, when the cover case 78 moves in the axial direction, the case 68 moves in the axial direction together with it.

  When the cover case 78 of the sheath operation handle 54 is pulled toward the wire operation handle 52 by the operator, the case 68 held by the cover case 78 also moves toward the wire operation handle 52 in the axial direction. Here, since the protruding portion (projection) of the ball 76 held by the ball holding member 74 is engaged with the guide groove 67 of the positioning pipe 56, the guide groove 67 moves by the length L in the axial direction. In a portion that is a path that rotates 90 degrees in the circumferential direction every time when the case 68 moves in the axial direction, the ball 76 is guided in the guide groove 67, so that the case 68 also moves in the circumferential direction. To do. Thereby, the sheath 16 fixedly held in the case 68 by the sheath holding ring 72 rotates 90 degrees in the circumferential direction every time it moves by the length L in the axial direction.

In this way, by moving the cover case 78 in the axial direction, the sheath 16 can be moved in the axial direction and simultaneously rotated.
Instead of the cover case 78, a flange-like component that is rotatable around the axis with respect to the case 68 is provided on the outer surface of the case 68, and the flange portion is moved in the axial direction, whereby the cover case 78 is pivoted. You may make it move to a direction and a rotation direction. Further, without providing the cover case 78, while the operator twists the case 68 or leaves the case 68 to rotate when the case 68 is pulled backward, the sheath operation handle 54 is moved to the wire operation handle 52 side. You may make it move to.

  Since the ball 76 is urged toward the inner peripheral side by urging means (not shown), the portion other than the recess 66 of the guide groove 67 is slightly pressed toward the guide groove 67. The recess 66 has a size that allows the ball 76 to be fitted (hooked). When the ball 76 that moves while being energized in the guide groove 67 is fitted into the recess 66, the resistance to movement back and forth increases, and the wire 76 The movement of the sheath operation handle 54 relative to the operation handle 52 is restricted.

  Therefore, every time the sheath operating handle 54 and the sheath 16 move by the length L in the axial direction, the sheath operating handle 54 and the sheath 16 rotate 90 degrees in the circumferential direction, and temporarily stop at that position. Thereafter, when the cover case 78 is further drawn and a force sufficient to ride on the ball 76 from the recess 66 is applied, the ball 76 moves along the guide groove 67 to the next recess 66. As a result, the sheath operation handle 54 and the sheath 16 are further moved by the length L in the axial direction and rotated 90 degrees in the circumferential direction.

  In this way, the sheath 16 can move in the length unit L of one stroke, where the axial interval L of the recess 66 in the guide groove 67 is one stroke. This L is, for example, 15.5 mm. Then, it rotates 90 degrees around the axis during one stroke of movement.

  When the sheath 16 moves as the sheath operating handle 54 moves, the proximal end of the sheath 16 advances through the hole of the retaining ring 64 and enters the positioning pipe 56.

  Next, the operation of the continuous clip treatment device 10 will be described with reference to FIG. FIGS. 5A to 5E are partial cross-sectional views showing a stepped state during the clip treatment operation of the clip treatment device 10.

  First, as shown in FIG. 5A, after five hemostatic clip bodies (hereinafter simply referred to as clip bodies) comprising clips 12A to 12E and connecting rings 14A to 14E are loaded on the sheath 16, Inserted into the forceps channel of the endoscope. In the illustrated example, the tip of the clip 12A substantially coincides with the tip of the sheath 16, as shown in FIG.

  The leading clip 12 </ b> A is held closed by the inner wall of the sheath 16. Each of the connection rings 14A to 14E is fitted so that the tightening portion 40 comes to an initial position in the vicinity of the intersecting portion 26 of the clips 12A to 12E. At this time, the upper ends of the convex portions 30 of the clips 12B to 12E are positioned directly below the coupling rings 14A to 14D, respectively.

  When the distal end of the sheath 16 reaches the distal end of the insertion portion of the endoscope inserted into the living body and protrudes from the distal end of the endoscope, the ball 76 of the sheath operation handle 54 is moved in the operation portion 50 shown in FIG. The sheath operation handle 54 (its cover case 78) is pulled so as to move from the first recess 66 to the second recess 66 by a length L in the axial direction. Since the sheath 16 is fixed to the case 68 of the sheath operation handle 54, the sheath 16 is retracted by the same amount L as the movement amount L of the sheath operation handle 54. At this time, the operation wire 20 does not move. Therefore, the clips 12A to 12E and the dummy clip 18 connected to the operation wire 20 do not move in the axial direction, and only the sheath 16 is pulled toward the operation unit.

  Since the guide groove 67 from the first recess 66 to the second recess 66 is parallel to the axial direction of the operation unit 50, that is, the pulling direction of the sheath 16, the ball 76 moves from the first recess 66 to the second recess 66. Even if it moves, the case 68 does not rotate. Therefore, the sheath 16 fixed to the case 68 does not rotate.

  When the sheath 16 is pulled by a predetermined amount L corresponding to the distance between the first recess 66 and the second recess 66, the distal end of the sheath 16 is lowered to a position where the skirt portion 38 of the leading connecting ring 14A is opened. The claw portions 22 and 22 of the clip 12A protruding from the side are spread by the urging force to be in the state of FIG. As a result, the first clip 12A can be used. In FIG. 5B, the skirt portion 38 of the connecting ring 14A is not shown in the figure because it is in the direction perpendicular to the paper surface.

  Since the coupling portion between the clip 12A and the clip 12B is located immediately below the skirt portion 38 of the connecting ring 14A, the tip of the clip 12B substantially coincides with the tip of the sheath 16 in the state of FIG. ing.

  When the sheath 16 is pulled, a frictional force acts between the sheath 16 and the connection rings 14 </ b> A to 14 </ b> E fitted into the sheath 16. However, between the connecting rings 14A to 14E and the clips 12A to 12E, the pressing force of the clip 12 by the inner portion of the closed skirt portion 38 and the spring to open the claw portion 22 of the rear clip 12 are opened. A pressing force is applied to the inner wall surface of the connecting ring 14 (second region 34, see FIG. 3) by force. Furthermore, the convex part 30 of clip 12B-12E contact | abuts to the base end of connection ring 14A-14D, and cannot enter into the hole 43 (refer FIG. 3) of the connection ring 14. FIG. Therefore, even if the sheath 16 is pulled, the connection rings 14A to 14E do not move unnecessarily. Therefore, the connection rings 14A to 14E can maintain the state in which the clips 12A to 12E are held, respectively.

  Next, the clip treatment instrument 10 in the state shown in FIG. 5B is moved, and the claw portions 22 and 22 of the expanded clip 12A are pressed against the portion to be clipped, and the lever of the operation unit 50 (see FIG. 4). By pulling 60, the operation wire 20 is pulled by a predetermined amount. By pulling the operation wire 20, all the clips 12A to 12E engaged in order from the dummy clip 18 are pulled uniformly.

  At this time, in the state shown in FIGS. 5B and 5C, the skirt portion 38 of the connecting ring 14A protruding from the distal end of the sheath 16 is open, and the pressing and holding of the clip 12A by the skirt portion 38 is released. . Further, the connecting ring 14 </ b> A is prevented from retreating into the sheath 16 because the skirt portion 38 is opened at the distal end of the sheath 16. Therefore, as shown in FIG. 5C, the leading clip 12A moves backward with respect to the connecting ring 14A. When the tip of the connection ring 14A, that is, the tightening portion 40 is pushed down to just below the convex portion 30 of the clip 12A, the fastening of the clip 12A by the connection ring 14A is completed.

  At the same time, the engaging portion between the clip 12A and the next clip 12B comes out from the rear end of the connecting ring 14A. When the engaging portion of the clip 12A and the clip 12B is disengaged from the connecting ring 14A, the arm portion 28 is expanded by the spring force of the clip 12B until it hits the inner wall of the sheath 16, and the turn portion of the clip 12A is between the claws 22 and 22. Opening wider than 24, the connection between the clip 12A and the clip 12B is released. Thereby, the clip 12A and the connection ring 14A can be detached from the sheath 16, and the clip treatment by the clip 12A and the connection ring 14A is completed.

  On the other hand, the subsequent clips 12B to 12E are held so as not to move in the rotational direction and the forward and backward direction with respect to the connection rings 14B to 14E by the connection rings 14B to 14E with the skirt portion 38 closed. Furthermore, the claw part 22 is caused to expand in the second region of the coupling rings 14B to 14E by the force (biasing force) of the claw part 22 of the clips 12C to 12E engaging with the clips 12B to 12E and the claw part of the dummy clip 18. 34 (see FIG. 3), and the frictional force between the clips 12B to 12E and the connection rings 14B to 14E is increased. Therefore, the connection rings 14B to 14E move with the movement of the clips 14B to 14E.

  That is, the clips 12B to 12E and the connecting rings 14B to 14E other than the leading clip 12A and the connecting ring 14A that holds the leading clip 12A and the connecting rings 14B to 14E move forward and backward integrally with the sheath 16 by operating the operating wire 20. -14E and the connection state of the dummy clip 18 are maintained by the connection rings 14B-14E.

  The operation wire 20 is configured so that a certain amount can be pulled from the initial state. The fixed amount is equal to or slightly larger than the region length of the second region 34 of the connecting ring 14 and at the same time holds the clip 12 from the lower end of the convex portion 30 of the clip 12. The amount is equal to or slightly smaller than the length to the tip of the connecting ring 14. This fixed amount is determined by the length from the home position of the lever 60 to the rearward movement limit in the operation unit 50 of FIG.

  The operation wire 20 is pulled back by a certain amount by a spring 62 that biases the lever 60 of the operation unit 50, and then immediately returns by the certain amount. When the operation wire 20 pulled from the state of FIG. 5B to the state of FIG. 5C releases the pulling force of the lever 60 in the operation unit 50, the lever 60 returns to the original position, thereby the operation wire. 20 returns to the original position, and the state shown in FIG. That is, the distal end of the second clip 12B returns to a position that substantially coincides with the distal end of the sheath 16, similar to the case of FIG.

  On the other hand, the clip 12A and the clip 12B are engaged with each other by shifting the expanding direction of the claws 22 and 90 degrees by 90 degrees, and therefore, the clip 12B that is the head in the sheath 16 as shown in FIG. The opening direction of is different from the opening direction of the previous clip 12A shown in FIG. 5B by 90 degrees. However, in the clip treatment instrument 10, the expanding direction of the clip 12B can be changed by 90 degrees and aligned with the expanding direction of the clip 12A by the following operation.

  That is, in order to make the second clip 12B usable, the sheath operation handle 54 is moved from the second recess 66 to the third recess 66 by the length L in the operation unit 50 (see FIG. 4). Moved. Thereby, the sheath 16 is pulled by a predetermined stroke, that is, the length L, and the tip of the sheath 16 is lowered to a position where the skirt portion 38 of the next connecting ring 14B is opened. In addition, when the ball 76 moves from the second depression 66 to the third depression 66 in the operation unit 50, the case 68 rotates 90 degrees in the circumferential direction. Therefore, the sheath 16 fixed to the case 68 rotates 90 degrees around the axis.

  Between the sheath 16 and the connection rings 14B to 14E fitted in the sheath 16, an urging force that the arms 28 of the clips 12B to 12E use for expansion and a skirt portion 38 of the connection rings 14B to 14E are provided. The frictional force due to the urging force to spread is working for the number of connecting rings 14. Moreover, the mechanism which restrict | limits the rotational movement around the axis | shaft of clip 12B-12E and connection ring 14B-14E is not provided. Therefore, when the sheath 16 rotates, the connection rings 14 </ b> B to 14 </ b> E and the clips 12 </ b> B to 12 </ b> E and the dummy clips 18 held by the connection rings 14 </ b> B to 14 </ b> E rotate together with the sheath 16. Thereby, the claw portions 22 and 22 of the clip 12B protruding from the sheath 16 spread in the same direction as the claw portions 22 and 22 of the previous clip 12A, and the state shown in FIG.

  After that, as in the case of the above-described clip 12A, the claw portion of the clip 12B is pressed against the portion to be clipped, and the operation wire 20 is pulled by a predetermined amount. Thereby, the fastening of the clip 12B by the connecting ring 14B is completed, and at the same time, the connection between the clip 12B and the clip 12C is released, and the clip treatment by the clip 12B is completed.

  By repeating the above operation, the clip treatment can be performed continuously by the number of clips 12 loaded in the sheath 16. Here, the sheath 16 is rotated in the same direction by the number of clip treatments by the operation unit 50, and the operation wire 20 connected to the clip 12 (dummy clip 18) is also rotated following the rotation. However, as described above, since the rear end portion of the operation wire 20 is rotatably held by the operation portion 50, the twist of the operation wire 20 accompanying the rotation of the sheath 16 can be appropriately eliminated, and the twist of the operation wire 20 can be eliminated. It is possible to suppress the accumulation of stress.

  In the case where the connecting portion between the distal end of the operation wire 20 and the connection member 19 at the rear end portion of the dummy clip 18 is connected by a method that transmits traction force and does not transmit rotational torque, You may hold | maintain a rear end in the form which cannot be rotated in the operation part 50. FIG. The path of the guide groove 67 in the operation unit 50 may be a path that rotates in a different direction in the circumferential direction every time the length L moves in the axial direction.

Next, the connection clip package of the present invention will be described.
The connection clip package of the present invention accommodates a clip body (with the connection ring 14 fitted to the clip 12) used in the repetitive clip treatment instrument 10 as described above in a case in a state where a predetermined number is connected in advance. , Packaged.

  6 (A) to 6 (C) are views showing an embodiment of the connection clip package of the present invention, where (A) is a front view, (B) is a sectional view, and (C) is orthogonal to the axis of the case. It is sectional drawing of a surface. In the following, the left side in FIGS. 6A and 6B is referred to as the front end, and the right side is referred to as the rear end.

As shown in FIG. 6A, the connection clip package 80 includes a case 82, an upper cap 84, and a lower cap 86.
The case 82 has a cylindrical shape and houses a clip body including the clip 12 and the connection ring 14 therein. As shown in FIGS. 6A and 6C, the case 82 is formed by combining two case parts 82a and 82b having a semi-cylindrical shape and substantially the same shape. An upper cap 84 is fitted to the front ends of the two case components 82a and 82b, and a lower cap 86 is fitted to the rear ends, thereby keeping the case 82 closed.

  The case 82 is preferably transparent or translucent so that the inside can be seen. Moreover, it is preferable to form with resin which does not change in the fluctuation | variation range (for example, 5 to 38 degreeC) of ambient temperature from impact resistance, ease of handling, and easy shaping | molding. In the present embodiment, the case 82 is cylindrical, but the outer shape of the case 82 is not limited to a columnar shape, and may be a prism.

  The connection clip package 80 needs to keep the case 82 hermetically sealed in order to store medical clips. Therefore, the case 82 covers the outer surfaces of the case components 82a and 82b with a cover 88 made of a transparent resin, and ensures the sealing inside the case 82. Alternatively, in the case 82, the case parts 82a and 82b are made of an elastic material, and the case parts 82a and 82b are held by the upper cap 84 and the lower cap 86 in a state where they are pressed on the mating surfaces, so as to ensure sealing performance. It may be. Further, a seal may be secured by providing a packing between the case parts 82a and 82b.

  The upper cap 84 and the lower cap 86 only need to seal the case parts 82a and 82b in a sealed state, and can be made of rubber or resin. The lower cap 86 is removable. When the clip body in the case 82 is loaded onto the sheath, the lower cap 86 is removed and the internal clip body is pulled out while being connected. The top cap 84 may or may not be removable. Moreover, it is good also as a form which comprises a front-end | tip part with the case 82 and does not provide the upper cap 84. FIG.

  As shown in FIG. 6B, the case 82 is formed with a hole having an inner diameter slightly larger than the outer diameter of the connecting ring 14 and having an inner diameter substantially equal to the inner diameter of the sheath loaded with the clip body. The five clips 12A to 12E and the dummy clip 18 that are connected to each other and the five connection rings 14A to 14E that cover the connection portion are accommodated in the holes. The tip of the top clip 12A is protected by a portion protruding from the upper cap 84 into the case 82. Further, the connecting member 19 at the rear end of the dummy clip 18 connected to the rearmost clip 12E is held by the lower cap 86.

  A sheath fitting portion 98 into which a sheath can be inserted is formed at the rear end portion of the case 82. The sheath fitting part 98 has a diameter substantially equal to the outer diameter of the sheath loaded with the clips 12A to 12E and the connection rings 14A to 14E. Since the diameter of the sheath fitting portion 98 is larger than the diameter of the straight portion 90 of the hole of the case 82 by the thickness of the sheath, a step is formed at the tip of the sheath fitting portion 98. When the clip body in the case 82 is loaded into the sheath, the sheath is inserted up to the tip of the sheath fitting portion 98.

  FIG. 7 is a partially enlarged view of FIG. As shown in FIG. 7, a concave portion 96 corresponding to the shape of the skirt portion 38 is provided on the inner surface of the case 82 at a position where the coupling rings 14 </ b> A to 14 </ b> E are accommodated. The concave portion 96 has a first inclined portion 92 that extends radially outward from the straight portion 90 at substantially the same angle as the inclination of the skirt portion 38 in the natural state and substantially coincides with the spread of the skirt portion 38. The inclined portion 92 is formed by a second inclined portion 94 that narrows in the radial direction from the widened end portion (rear end) of the inclined portion 92.

  As described above, the clips 12A to 12E are connected to each other by changing the direction by 90 degrees, and correspondingly, the connecting rings 14A to 14E also change the direction from the front and rear connecting rings 14 by 90 degrees to the clips 12A to 12E. It is fitted. Therefore, the position of the recess 96 in the case 82 is also shifted by 90 degrees in the circumferential direction at the positions corresponding to the connection rings 14A to 14E. In FIG. 6 (B), the concave portions 96 corresponding to the skirt portions 38 of the connecting rings 14A, 14C, and 14E are shown in two upper and lower portions. Concave portions 96 corresponding to the skirt portions 38 of the coupling rings 14B and 14D are formed at two locations in a direction perpendicular to the paper surface of FIG.

  Due to the first inclined portion 92 of the recess 96, the coupling rings 14A to 14E are accommodated in the case 82 in a state where the skirt portion 38 is expanded without receiving external force. Therefore, the elasticity of the skirt portion 38 can be prevented from deteriorating while being stored in the case 82, and the performance of the coupling rings 14A to 14E can be maintained.

  Further, when the clips 12A to 12E and the connection rings 14A to 14E are pulled out from the case 82, the skirt portion 38 opened by the recess 96 is gradually closed by being guided by the second oblique portion 94, and thus exits the recess 96. It does not turn up sometimes, but it can fit in the straight part 90 and can move in the case 82.

  In order to obtain the connection clip package 80, the clips 12A to 12E are connected in advance, the dummy clip 18 is connected to the last clip 12E, the connection clip is assembled, and the connection clip is attached to one of the cases 82. After storing in the case part 82a, the other case part 82b may be put on the case part 82a and the upper cap 84 and the lower cap 86 may be fitted.

  Also, as shown in FIG. 6A, an alignment mark 100 is written on the surface of the rear end portion of the case 82 as an identification portion for aligning the position in the circumferential direction with the sheath 16. The alignment mark 100 of the case 82 is attached to the contact part of the case parts 82a and 82b in the illustrated example. As described above, since the concave portions 96 are formed in the case parts 82a and 82b at the positions where the skirt portions 38 of the connecting ring 14 are accommodated, the circumferential direction of the clips 12A to 12E in the case parts 82a and 82b. Is specified. Therefore, the relationship between the alignment mark 100 and the opening direction (opening / closing direction) of the leading clip 12A in the case 82 is always constant.

On the other hand, as shown in FIG. 8, an alignment mark 102 is written on the outer peripheral surface of the distal end of the sheath 16 as an identification portion indicating the reference position in the circumferential direction.
When the connection clip package 80 is fitted to the distal end of the sheath 16 for loading the clip, the alignment mark 100 of the connection clip package 80 and the alignment mark 102 of the sheath 16 are set together. Thereby, the expansion direction of the clip 12 </ b> A with respect to the sheath 16 can always be defined constant.

Next, with reference to FIGS. 9A to 9C, a method of loading the clip body from the connected clip package 80 to the sheath 16 will be described.
First, as shown in FIG. 9A, the lower cap 86 of the connection clip package 80 is removed, and the operation wire 20 projected from the distal end of the sheath 16 is connected to the connection member at the rear end portion of the dummy clip 18 in the case 82. 19 is connected. The dummy clip 18 that has been engaged with the tail end of the clip 12 that has already been used is removed in advance with the operation wire 20 protruding from the sheath 16.

  When the operation wire 20 is connected to the dummy clip 18 in the case 82, the sheath 16 is inserted to the tip of the sheath fitting portion 98 as shown in FIG. After the operator holds the sheath 16 and the case 82 and inserts the end portion of the sheath 16 into the sheath fitting portion 98 of the case 82, the sheath operation handle 54 of the operation unit 50 (see FIG. 4) is connected to the wire operation handle 52. , The sheath 16 can be advanced with respect to the operation wire 20, and the sheath 16 can be inserted up to the distal end of the sheath fitting portion 98. At this time, the alignment mark 100 of the case 82 is fitted so as to match the alignment mark 102 of the sheath 16.

  In a state where the sheath 16 is fitted to the sheath fitting portion 98 of the case 82, the inner diameter of the straight portion 90 of the case 82 and the inner diameter of the sheath 16 are substantially equal.

  Next, as shown in FIG. 9C, the position of the operation wire 20 is kept as it is, and only the sheath 16 is moved to the distal end side, and the case 82 is moved to the distal end side together with it. The sheath 16 is moved by moving the sheath operation handle 54 of the operation unit 50 toward the distal end side with respect to the wire operation handle 52. At this time, it is preferable to move the sheath 16 and the case 82 while pressing the vicinity of the distal end portion of the sheath fitting portion 98 indicated by an arrow in FIGS. 9B and 9C. By movement of the sheath 16 and the case 82, the clips 12A to 12E and the connection rings 14A to 14E in the case 82 are loaded into the sheath 16 in order from the rear end side.

  For loading the clip, the sheath 16 may be moved forward relative to the operation wire 20 and moved to a position where the leading clip 12A is completely accommodated in the sheath 16. The clip body may be pulled into the sheath 16 and loaded by pulling the operation wire 20 without moving the.

  In the case 82, the skirt portions 38 of the coupling rings 14 </ b> A to 14 </ b> E are accommodated in the recessed portion 96 in an open state, but when the case 82 moves to the distal end side, the skirt portion 38 becomes the second oblique portion of the recessed portion 96. It closes while being guided by 94, fits in the straight portion 90, and is pulled into the sheath 16 as it is. The skirt portion 38 of the coupling rings 14A to 14C passes through the other recessed portion 96 on the rear end side. At this time, even if the skirt portion 38 is opened at one end by the first inclined portion 92, the second inclined portion 94 again. It is closed and guided to the straight part 90.

  The inner walls of the second regions 34 (see FIG. 3) on the rear end side of the connecting rings 14A to 14E are pressed by the urging force that the rear clips 12B to 12E and the claw portions 22 of the dummy clips 18 try to spread. ing. Therefore, in the case 82, the connection state of the clips and the positional relationship between the clips 12A to 12E and the connection rings 14A to 14E are maintained.

  Furthermore, when the sheath 16 is loaded, the skirt portion 38 moves from the recess 96 to the straight portion 90 and closes, so that the clips 12A to 12E inside the coupling rings 14A to 14E are pressed by the inner portion of the skirt portion 38. The connection rings 14A to 14E hold the connection state of the clips 12A to 12E and the dummy clip 18. Therefore, it is possible to prevent the clips 12A to 12E and the dummy clip 18 from being disconnected and the positional relationship with the connection rings 14A to 14E from being shifted when the sheath 16 is loaded.

  The distal end of the sheath 16 moves to a position where the distal end of the leading clip 12A is accommodated, and the loading of the clip into the sheath 16 is completed. When the loading is completed, the operation unit 50 (see FIG. 4) is in a state in which the sheath operation handle 54 moves to the distal end side and the ball 76 is fitted in the first recess 66.

  As described above, the connected clip package 80 can be distributed and stored in a state where the clips are connected, and can be loaded into the sheath 16 by a simple operation while maintaining the connected state. Therefore, the work burden on the operator is small, and the clip can be easily loaded in a short time. Furthermore, since the connecting clip package 80 can be loaded with the clip expanding direction aligned with the sheath 16 in a certain direction, for example, even when the clip is reloaded during the procedure, the operator can quickly perform the procedure. Can be continued.

Next, another embodiment of the connection clip package of the present invention will be described.
In the above example, the alignment mark 100 marked on the case 82 of the connection clip package 80 and the alignment mark 102 marked on the sheath 16 align the direction of the clip inside the connection clip package 80 with respect to the sheath. The alignment between the connection clip package 80 and the sheath 16 may be performed by other configurations.

  FIG. 10A shows an axial section of the rear end portion of the case 82A, and FIG. 10B shows a view seen from the rear end side of the case 82A. In the example of FIG. 10, the case 82 </ b> A has a protrusion 104 that protrudes from the inner surface to the inner peripheral side at a predetermined position in the circumferential direction of the sheath fitting portion 98. The protrusion 104 has a lower height than the inner surface of the straight portion 90.

  Further, as shown in FIG. 11, a groove 106 extending in the axial direction is formed on the outer surface of the distal end of the sheath 16A fitted into the case 82A. The depth of the groove 106 corresponds to the height of the protrusion 104. Since the distal end portion of the sheath 16A functions at the time of the clip treatment operation by the clip 12, it is preferable that the groove 106 does not penetrate the thickness of the sheath 16A. The length of the groove 106 is equal to the length from the tip of the sheath fitting portion 98 of the case 82A (left end in FIG. 10A) to the rear end of the protrusion 104 (right end in FIG. 10A).

  When fitting the sheath 16A to the case 82A, the sheath 82A is fitted so that the positions of the protrusions 104 of the case 82A and the grooves 106 of the sheath 16A coincide. Since the opening direction of the leading clip 12A in the case 82A is determined by the position of the protrusion 104 of the case 82A, the expanding direction of the loaded clip 12A can be defined in a fixed direction with respect to the sheath 16A.

  Contrary to the above example, the directions of the sheath 16A and the case 82A can also be matched by providing a projection on the outer surface of the sheath 16A and a groove on the inner surface of the sheath fitting portion 98 of the case 82A. When there is a possibility of damaging the forceps channel of the endoscope by providing a projection on the outer surface of the sheath 16A, the above configuration in which the groove is formed in the sheath 16A is preferable.

Next, still another embodiment of the connection clip package of the present invention will be described.
In the above example, the clip accommodating portion in the case 82 of the connection clip package 80 is provided with the recess 96 corresponding to the skirt portion 38 of the connection ring 14, so that the case components 82 a and 82 b of the case 82 and the clip to be accommodated Although the positional relationship in the circumferential direction of 12A to 12E is determined, in addition to this, or when the recess 96 is not provided, the direction of the case 82 and the internal clip 12 may be aligned by other methods. .

  For example, when the connecting ring 14 is not provided in the connecting portion of the clip 12, the concave portion 96 is not provided in the case 82, and the positions of the case 82 and the clip 12 are regulated by the following method. In the above example, the concave portion 96 may be formed over the entire circumference at a position corresponding to the skirt portion 38. In this case as well, a configuration for restricting the positions of the case 82 and the clip 12 is provided as follows.

In FIG. 12A, the sheath 16 is fitted to the sheath fitting portion 98 of the case 82B, and the operation wire 20 of the clip treatment instrument 10 is coupled to the connection member 19 at the rear end of the clip row accommodated in the case 82B. The axial cross section of the rear-end part of case 82B of the state is shown. FIG. 12B shows a view of only the case 82B of FIG. 12A viewed from the rear end side.
In the example of FIG. 12, the case 82 </ b> B has a guide groove 110 having a diameter larger than that of the straight portion 90 and smaller than that of the sheath fitting portion 98 at the distal end portion of the sheath fitting portion 98. Further, the rear end portion of the connecting member 19B has a plate-like position regulating member 108 that protrudes to the outer peripheral side at a part in the circumferential direction. The outer edge of the position restricting member 108 has a diameter larger than that of the straight portion 90 and protrudes to a position where the diameter engages with the guide groove 110.

  When the coupling clip package 80 is assembled, when the coupling clip assembled in the coupled state is stored in the case 82B (case part 82a or 82b), the position regulating member 108 of the connection member 19B matches the guide groove 110 of the case 82B. Set as follows. Thereby, the direction of the clip 12 in the case 82B is determined.

  On the other hand, as shown in FIG. 13, a groove 112 for allowing the position regulating member 108 to escape is formed on the inner peripheral surface of the distal end of the sheath 16B. When the clip 12 is loaded from the connected clip package 80 of FIG. 12 to the sheath 16B, the sheath 16B is positioned so that the groove 112 of the sheath 16B matches the position restricting member 108 of the connecting member 19B, and the sheath 16B is placed in the case 82B. To fit. Since the expansion direction of the leading clip 12A in the case 82B is determined by the position of the position regulating member 108 of the connection member 19B, the expansion direction of the loaded clip 12A is defined in a certain direction with respect to the sheath 16B. Can do.

Note that a plurality of the position regulating members 108 of the connection member 19B may be provided in the circumferential direction. In that case, a plurality of invitation grooves 110 of the case 82B and grooves 112 of the sheath 16B may be provided at corresponding positions.
The groove 112 is narrower than the width of the skirt portion 38 of the connecting ring 14 so that the groove 112 does not get caught in the groove 112 when the skirt portion 38 passes through the distal end portion of the sheath 16 and spreads at the distal end. . Also in the case of a clip body that does not have the connection ring 14, it is important that the width and position of the groove 112 prevent the clip or the like from being caught.

  In addition, when a groove is provided at the distal end portion of the sheath 16 as in the example of FIG. 11 or the example of FIG. 13, an auxiliary member that can be attached to and detached from the distal end of the sheath 16 is prepared. It may be formed at the tip of the auxiliary member, and when loading the clip, the auxiliary member may be attached to the tip of the sheath 16 for loading.

  In the above description, as a preferred example, the configuration in which the coupling of the clip is held by the coupling ring has been described. However, the present invention does not use the coupling ring, but uses a clip that is directly coupled by changing the direction by 90 degrees. It can also be applied to treatment tools.

  In each of the above examples, the clip 12 is connected by changing the direction by 90 degrees, but the present invention is not limited to this. For example, a clip having a shape twisted by 90 degrees at a portion between the claw portions 22 and 22 and the turn portion 24 may be used, and continuous clips may be connected in the same direction.

  In addition, the use of a closed clip having a turn part is preferable in that a spring force (biasing force) that presses the turn part and expands to the arm part can be applied, but the present invention has a turn part. The present invention can also be applied to those using no open clip (U-shaped clip).

  As described above, the connected clip package and the clip loading method according to the present invention have been described in detail. However, the present invention is not limited to the above-described embodiments, and various improvements and modifications can be made without departing from the gist of the present invention. Of course it is also good. Moreover, the continuous clip treatment tool of the present invention can be used for a rigid endoscope as well as a flexible endoscope.

(A) And (B) is a fragmentary sectional view showing an example of a repetitive clip treatment instrument. It is a perspective view of a clip. (A)-(C) are figures which show an example of a connection ring, (A) is a front view, (B) is sectional drawing, (C) is a bottom view. (A) And (B) is a fragmentary sectional view which shows schematic structure of an operation part, (A) is a top view, (B) is a front view. (A)-(E) are the fragmentary sectional views which show the stepped state in the clip treatment operation of the repetitive type clip treatment tool of FIG. (A)-(C) are figures which show one Embodiment of the connection clip package of this invention, (A) is a front view, (B) is sectional drawing, (C) is a surface orthogonal to the axis | shaft of a case. It is sectional drawing. FIG. 7 is a partially enlarged view of FIG. It is a schematic diagram which shows the case rear end part of a package, and the front-end | tip part of a sheath. (A)-(C) are the fragmentary sectional views which show the stepped state in loading operation of the clip body from a connection clip package to a sheath. It is a figure which shows the rear-end part of the case in other embodiment of the connection clip package of this invention, (A) is sectional drawing, (B) is a side view. It is a perspective view which shows the front-end | tip shape of the sheath fitted to the case of FIG. It is a figure which shows the rear-end part of the case in other embodiment of the connection clip package of this invention, (A) is sectional drawing, (B) is a side view. It is a perspective view which shows the front-end | tip shape of the sheath fitted to the case of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Clip treatment tool 12 Clip 14 Connection ring 16, 16A, 16B Sheath 18 Dummy clip 19 Connection member 19a Hole 19b Surface 20 Operation wire 20a Tapered part 20b Wide part 20c Surface 20c
22 Claw part 24 Turn part 26 Intersection part 28 Arm part 30 Convex part 32 1st area | region 34 2nd area | region (connection holding | maintenance area | region)
38 Skirt portion 40 Tightening portion 42 Holding portion 43 Hole 43a, 44 Groove 44a Inner wall 46 Slit 50, 50A Operation portion 52 Wire operation handle 54 Sheath operation handle 56 Positioning pipe 58, 68 Case 59 Through window 60 Lever 61 Restriction plate 62 Spring 64 Retaining ring 66 Recess (recess)
67 Guide groove 70 Support block 70
72 Sheath retaining ring 74 Ball retaining member 76 Ball 78 Cover case 80 Clip package 82, 82A, 82B Case 82a, 82b Case component 84 Upper cap 86 Lower cap 88 Cover 90 Straight part 92 First oblique part 94 Second oblique part 96 Concave part 98 Sheath fitting part 100, 102 Position alignment mark 104 Projection 106, 112 Groove 108 Position regulating member 110 Invitation groove

Claims (8)

A cylindrical case,
A removable lower cap attached to the rear end of the case;
A connected clip package having a plurality of clips that are housed in the case and are aligned with a front and rear clip,
The case has a fitting portion with which a sheath for loading the clip is fitted at a rear end portion, and a reference position in a circumferential direction attached to a distal end portion of the sheath fitted with the fitting portion. The connection clip package which has the 2nd identification part which should be made to respond | correspond to the 1st identification part which shows this in the rear-end part of the said case. The first identification part is a mark marked on the surface of the sheath,
The connected clip package according to claim 1, wherein the second identification part is a mark written on a surface of the case. The first identification portion is a groove formed in a predetermined length in the axial direction from the distal end of the sheath,
The connection clip package according to claim 1 or 2, wherein the second identification portion is a protrusion formed on an inner surface of the fitting portion of the case and insertable into the groove.   Furthermore, the connection clip package in any one of Claims 1-3 which has a position control means which controls the position of the circumferential direction between the said case of the said package, and the said some clip accommodated in the said case. The engagement portion of the clip is fitted with a connection ring that covers the engagement portion and maintains the connection state of the clip.
The connection ring has a skirt portion that expands in a skirt shape in a natural state where no external force is applied, protrudes in the radial direction of the connection ring, and closes inward when pressed in the radial direction;
The case has an inner diameter slightly larger than an outer diameter of the connection ring in the clip and the connection ring receiving portion, and spreads in a natural state at a position corresponding to the skirt portion of the connection ring to be received. A recess for accommodating the skirt portion;
The connection clip package according to claim 4, wherein the position restricting means is a skirt portion of the connection ring and a recess of the case. A rear end member attached to the rearmost clip in the case protrudes to one or a plurality of locations in the circumferential direction with a diameter larger than the outer diameter of the connecting clip and smaller than the outer diameter of the sheath. A position regulating member
The case has one or a plurality of invitation grooves into which the position restriction member is fitted at a position of the front end portion of the fitting part that should correspond to the position restriction member,
The connected clip package according to claim 4, wherein the position restricting means is the position restricting member and the guide groove.   The connected clip package according to any one of claims 1 to 6, wherein the plurality of clips are connected by changing an expanding direction by 90 degrees. A clip loading method for loading a sheath of the clip and the connection ring of the connection clip package according to claim 1,
A distal end of an operation wire provided in the sheath for pulling a clip row composed of the plurality of clips is connected to a connection member attached to the last clip in the case, and the sheath Matching the first identification part and the second identification part of the case, and fitting the sheath to the fitting part of the case;
A method of loading a connecting clip that accommodates all of the clip and the connecting ring in the sheath while moving the case to the tip side by moving the sheath to the tip side.

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