CN215458983U - Clutch assembly of tissue closing device - Google Patents

Abstract

The utility model provides a clutch component of a tissue closing device, wherein the clutch component comprises a clutch mechanism, the clutch mechanism comprises a connecting seat which is detachably connected with a base clutch end, a clamping piece which enables the base clutch end to be connected with the connecting seat, and an operating lever which can provide driving force for a driving component; the operating rod is set to move between a first position and a second position relative to the clamping piece, and when the operating rod moves towards the near end from the second position, the operating rod supporting part can drive the clamping piece to move towards the near end simultaneously, so that the coupling seat and the separation end of the base can be separated relatively. In the process of separating the clutch end of the operating lever from the clutch end of the transmission rod, the coupling seat and the clutch end of the base can also be synchronously separated; the whole separation action can be completed in one step, and the connection relation of all the components does not need to be separated through a plurality of complicated steps.

Description

Clutch assembly of tissue closing device

Technical Field

The present invention relates to medical devices, and more particularly to a clutch assembly for a tissue closure device.

Background

The most common treatment of mitral regurgitation relies on prosthetic valve replacement, as well as valvuloplasty, such as posterior leaflet rectangular resection, chordae folding, edge-to-edge (edge-to-edge) repair techniques, prosthetic chordae implantation techniques, which typically rely on open heart surgery, wherein the patient's chest is typically opened by a sternotomy and the patient is placed in cardiopulmonary bypass.

With advances in medical technology, minimally invasive catheter procedures are increasingly replacing traditional high-risk surgical procedures. Minimally invasive interventional techniques currently being developed and applied by the market primarily include: indirect annuloplasty, direct annuloplasty, edge-to-edge repair, chordae tendineae repair.

The edge-to-edge repair technique is gradually mature in the clinical practice of surgically treating mitral regurgitation and shows good therapeutic effect.

The valve forceps instrument developed according to the technical principle of surgical valve edge-to-edge suturing is the most certain at present because of high safety, simple technical principle and great feasibility.

In the prior art, the valve clamping device needs to be conveyed to a designated position of the heart through a conveying assembly, then the implant is left in the heart after being clamped and fixed by the valve clamping device, and the delivery assembly needs to be relatively separated from the valve clamping device by a clutch mechanism, however, since the conveying component not only plays a conveying role, but also needs to play a control path in the conveying process, and to provide a driving force to control the opening and clamping action of the clamping member of the valve clamping device, when the valve clamping device is separated from the conveying assembly, the connecting structures for transmitting relevant driving force are required to be separated completely, the separation process of the clutch mechanism in the prior art is complex, the connection is too firm, the separation is difficult, since the structure that is easily separated causes deterioration in reliability, it is necessary to provide a clutch mechanism that is easily separated and reliably connected, and to apply the clutch mechanism to the tissue closing device.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a clutch component of a tissue closing device, which enables a coupling seat and a base clutch end to be synchronously separated in the process of separating the clutch end of an operating rod and the clutch end of a transmission rod by improving a clutch mechanism and a driving mechanism therein; the whole separation action can be completed in one step, the connection relation of all parts is not required to be separated through a plurality of complicated steps, and the connection stability when the separation is not required is ensured.

Specifically, the method comprises the following scheme:

a clutch assembly for a tissue closure device comprising a support mechanism including a stationary coupling assembly and a drive assembly movable relative to the stationary coupling assembly, the stationary coupling assembly including a base clutch end;

the clutch mechanism comprises a connecting seat which is detachably connected with the clutch end of the base, a clamping piece which enables the clutch end of the base to be connected with the connecting seat, and an operating lever which can provide driving force for the driving assembly;

the operating rod comprises an operating rod clutch end and an operating rod supporting part, the operating rod is axially separable from the driving component and is connected with the driving component in a relative rotation-resistant mode, the operating rod is arranged to move between a first position and a second position relative to the clamping piece, and when the operating rod moves towards the near end in the second position, the operating rod supporting part can drive the clamping piece to move towards the near end simultaneously, so that the coupling seat and the base clutch end can be separated relatively.

Furthermore, the coupling seat comprises a coupling seat connecting end, a coupling seat clutch end and a coupling seat inner cavity penetrating through the coupling seat, the clamping piece is arranged in the coupling seat inner cavity, the coupling seat clutch end is connected with the base clutch end through the clamping piece, and the coupling seat connecting end is used for being connected with the conveying device.

Furthermore, the coupling seat clutch end is provided with a coupling seat clamping hole, and the base clutch end is provided with a base clamping hole corresponding to the coupling seat clamping hole;

the clamping piece comprises a buckle which simultaneously penetrates through the connecting seat clamping hole and the base clamping hole so as to enable the connecting seat and the base clutch end to be relatively fixed;

and the buckle is arranged to be disengaged from the coupling seat clamping hole and/or the base clamping hole when the buckle piece moves towards the near end relative to the coupling seat so as to enable the coupling seat and the base separation end to be separated relatively.

Further, the buckle is made of flexible materials, and when the clamping piece moves towards the near end relative to the coupling seat, the buckle deforms.

Furthermore, the clamping piece also comprises a clamping jaw bottom ring and clamping jaw connecting rods which are the same in number with the clamping buckles and are used for connecting the clamping buckles with the clamping jaw bottom ring, and the clamping jaw bottom ring is provided with a bottom ring opening;

the operating rod further comprises an operating rod connecting end connected with the near end of the operating rod supporting portion, the near end of the operating rod connecting end penetrates through the bottom ring opening hole and then is connected with a driving source, and the outer diameter of the near end of the operating rod supporting portion is larger than the inner diameter of the bottom ring opening hole.

Further, the length of the operating lever supporting part is less than that of the jaw connecting rod, and the outer diameter of the operating lever supporting part is set so that when the operating lever supporting part is positioned in the connecting seat clamping hole, the outer surface of the operating lever supporting part blocks the clamping buckle from being separated from the connecting seat clamping hole and the base clamping hole

Furthermore, the number of the jaw connecting rods is 3-6, and the jaw connecting rods are uniformly distributed on the side face of the jaw bottom ring.

Further, the driving assembly comprises a transmission rod clutch end, the operating lever clutch end is connected with the transmission rod clutch end in a rotation-resisting mode, and when the pulling force between the operating lever clutch end and the transmission rod clutch end is larger than a preset value, the operating lever clutch end is separated from the transmission rod clutch end.

Furthermore, one of the operating lever clutch end and the transmission rod clutch end is provided with a deformable buckle, the other one of the operating lever clutch end and the transmission rod clutch end is provided with a clutch connecting groove, a clamping shaft which is matched and connected with the deformable buckle is arranged in the clutch connecting groove, the operating lever clutch end and the transmission rod clutch end are connected through the deformable buckle and the clamping shaft, and when the pulling force between the operating lever clutch end and the transmission rod clutch end is greater than a preset value, the deformable buckle is separated from the clamping shaft.

Furthermore, a cavity which penetrates through and communicates the near end of the operating rod to the clutch end of the operating rod is arranged in the operating rod.

As described above, the present invention has the following advantageous effects:

(1) in the process of separating the clutch end of the operating lever from the clutch end of the transmission rod, the coupling seat and the clutch end of the base can also be synchronously separated; the whole separation action can be completed in one step, and the connection relation of all the components does not need to be separated through a plurality of complicated steps.

(2) When the clutch end of the operating rod is required to be separated from the clutch end of the transmission rod, the clutch end of the transmission rod can be pulled to be separated when a preset value is reached only by pulling the operating rod towards the near end in the axial direction and keeping the clutch end of the transmission rod still. The whole separation structure is simple and quick.

(3) The buckle is made for flexible material, and when the joint spare moved to the near-end for the hookup seat, the buckle produced deformation, and the buckle can directly break away from hookup seat card hole and base card hole and can not take place to kick-back and lead to unable effective separation from this.

(4) The radial surface of the shaft-shaped or rod-shaped operating lever support part props against the movement of the buckle to the center, so that the buckle can be limited from accidentally dropping out of the base clamping hole and the connecting seat clamping hole, and the connection between the base separation end and the connecting seat is further kept; the connection relation between the connecting seat and the separation end of the base is stably kept when the connection seat is not required to be separated.

Drawings

In order to more clearly illustrate the technical solution of the present invention, the drawings used in the description of the embodiment or the prior art will be briefly described below. It is obvious that the drawings in the following description are only some embodiments of the utility model, and that for a person skilled in the art it is also possible to derive other drawings from these drawings without inventive effort.

FIG. 1 is a schematic view of a clamping mechanism of the present application positioned at a mitral valve;

FIG. 2 is a schematic diagram of the overall structure of the present application;

FIG. 3 is a partial cross-sectional view of the overall structure of the present application;

figure 4 is a schematic view of the present application with the catch in a different position;

figure 5(a) is a side view of a closure of the present application;

FIG. 5(b) is a schematic structural view of a closure of the present application;

FIGS. 6(a) - (d) are schematic illustrations of the closure of the present application;

figure 7(a) is a schematic view of the structure of the present capture member;

figure 7(b) is a cross-sectional view of a catch according to one embodiment of the present application;

figure 7(c) is a cross-sectional view of a catch according to another embodiment of the present application;

FIGS. 8(a) - (e) are detail views of the support mechanism of the present application;

figures 9(a) - (c) are schematic views of the motion of the occluding member and the capturing member of the present application during the clamping process;

FIGS. 10(a) - (d) are views of the clutch mechanism of the present application;

FIG. 11 is an enlarged partial view of the steering wire in the disengaged position;

FIGS. 12(a) - (d) are diagrams of the motion of the clamping mechanism releasing the closure of the present application;

fig. 13(a) - (d) are the motion process diagrams of the clamping mechanism for realizing capture and fixation.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. In this embodiment, the description "proximal" refers to a direction close to the operator; "distal" means away from the operator. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

Example 1:

in the present embodiment, a clutch assembly of a tissue closing device is described, and specifically, the clutch assembly includes a clutch mechanism 3000 and a support mechanism cooperating therewith. The tissue closure device includes a clamping mechanism 1000 for closing tissue; a support mechanism 2000 for mounting clamping mechanism 1000, and a clutch mechanism 3000 at a distal end of support mechanism 2000 for releasable connection to a delivery control assembly for delivering and controlling a tissue closure device, in this embodiment, clutch mechanism 3000 includes an actuating lever 3100 rotationally and axially releasably connected to drive assembly 2200, actuating lever 3100 being rotatable to drive assembly 2200 in an axial direction; and the lever 3100 is arranged to bring the clutch mechanism 3000 out of engagement with the fixture when a proximal movement is preset. The principle of disengagement of the clutch mechanism 3000 from the support mechanism 2000 is explained below with particular reference to fig. 3, 8 and 10:

the supporting mechanism 2000 for mounting the clamping mechanism 1000 comprises a fixed connecting component 2100 and a driving component 2200 capable of moving relative to the fixed connecting component 2100, wherein, in particular, the driving component 2200 comprises a driving shaft 2230, the driving shaft 2230 comprises a driving thread part 2231 matched with a base thread part 2131, a rotary motion exists between a driving output shaft 2210 and a base shell to realize the axial motion of the driving shaft 2230, the rotation of the driving output shaft is realized by applying a rotating moment through an operating rod 3100 in a clutch mechanism 3000, and in particular, the supporting mechanism 2000 comprises an operating rod clutch end 3120 which is axially separated from the driving component 2200 and is connected with the driving component in a relative rotation resisting way and an operating rod supporting part 3130; specifically, the drive assembly 2200 includes a transfer lever clutch tip 2220, a lever clutch tip 3120 rotationally fixedly coupled to the transfer lever clutch tip 2220, the lever clutch tip 3120 disengaging the transfer lever clutch tip 2220 when a pulling force between the lever clutch tip 3120 and the transfer lever clutch tip 2220 is greater than a predetermined value; since the lead angle of the spiral groove is smaller than the friction angle between the contact surfaces of the two spiral grooves, when the base housing or the driving shaft 2230 is stopped, if only an axial force is applied to the base housing or the driving shaft 2230, the base housing or the driving shaft 2230 will not be axially displaced, and therefore, when the lever clutch end 3120 and the driving rod clutch end 2220 need to be separated, the lever 3100 needs to be pulled axially toward the proximal end, and the driving rod clutch end 2220 is kept stationary, i.e., the base housing or the driving shaft can be pulled away when a predetermined value is reached.

Specifically, in this embodiment, the specific implementation structure of pull-off when the preset value is reached is as follows:

one of the operating lever clutch end 3120 and the transmission lever clutch end 2220 is provided with a deformable buckle 3121, the deformable buckle 3121 may be made of an elastic biocompatible material, for example, some biocompatible polymer materials, the other one is provided with a clutch connection groove 2222, a clamping shaft 820 in fit connection with the deformable buckle 3121 is arranged in the clutch connection groove 2222, the clamping shaft 820 is inserted into the combination shaft hole 222, specifically, the deformable buckle 3121 is provided with a bayonet 3122 and a clamping hole 3123 matched with the clamping shaft 820 after passing through the bayonet 3122; the lever clutch end 3120 and the transmission rod clutch end 2220 are connected by the deformable latch 3121 and the latch shaft 820, and when the pulling force between the lever clutch end 3120 and the transmission rod clutch end 2220 is greater than a preset value, the deformable latch 3121 is disengaged from the latch shaft 820, in this embodiment, the deformable latch 3121 is disposed at the lever clutch end 3120, and the clutch connection slot 2222 is disposed at the transmission rod clutch end 2220, or vice versa.

In order to separate the outer housing of the supporting mechanism 2000 from the outer housing of the clutch mechanism 3000 during the process of separating the operating lever clutch end 3120 from the driving lever clutch end 2220, specifically, in this embodiment, the clutch mechanism 3000 is further provided with a coupling seat 3300 detachably connected to the base clutch end 2120, and a clamping member 3200 connecting the base clutch end 2120 with the coupling seat 3300; the operating lever 3100 is configured to be capable of moving between a first position and a second position relative to the latch member 3200, and when the operating lever 3100 moves proximally in the second position, the operating lever support 3130 can drive the latch member 3200 to move proximally at the same time, so that the coupling seat 3300 and the base clutch end 2120 can be separated relatively, and thus the coupling seat 3300 and the base clutch end 2120 can be separated synchronously during the process of separating the operating lever clutch end 3120 from the driving lever clutch end 2220;

specifically, in this embodiment, the coupling base 3300 includes a coupling base connecting end 3310, a coupling base engaging end 3320, and a coupling base inner cavity 3330 penetrating the coupling base 3300, the clamping member 3200 is disposed in the coupling base inner cavity 3330, the coupling base engaging end 3320 is connected to the base engaging end 2120 through the clamping member 3200, and the coupling base connecting end 3310 is used for connecting to the conveying device.

The main body of the base clutch end 2120 is an extension of a base tubular structure, the coupling seat clutch end 3320 can be sleeved on the base clutch end 2120 or inserted into the base clutch end 2120, the contact surfaces of the two clutch ends are respectively called a base matching surface and a coupling seat matching surface, wherein the base matching surface is provided with a base clamping hole 2121 in the radial direction, the corresponding coupling seat matching surface is provided with a coupling seat clamping hole 3321 in the same direction in the radial direction, the coupling seat clutch end 3320 is provided with a coupling seat clamping hole 3321, and the base clutch end 2120 is provided with a base clamping hole 2121 corresponding to the coupling seat clamping hole 3321; the clamping member 3200 includes a buckle 3220 passing through the coupling seat clamping hole 3321 and the base clamping hole 2121 simultaneously to fix the coupling seat 3300 and the base engaging and disengaging end 2120 relatively; and the catch 3220 is configured such that when the catch 3200 is moved proximally relative to the coupling seat 3300, the catch 3220 disengages from the coupling seat catch bore 3321 and/or the base catch bore 2121 to enable relative disengagement of the coupling seat 3300 and the base catch end 2120.

The catch 3220 is made of a flexible material, and when the catch 3200 moves proximally relative to the coupling seat 3300, the catch 3220 deforms, so that the catch may be directly separated from the coupling seat catch hole 3321 and the base catch hole 2121 without rebounding to cause an inefficient separation. The material of the clasp 3220 is a biocompatible plastic or metal that does not rebound after bending.

Further, in this embodiment, the clamping member 3200 further includes a claw bottom ring 3230 and claw connecting rods 3210 which are the same in number as the buckles 3220 and connect the buckles 3220 and the claw bottom ring 3230, and the claw bottom ring 3230 is provided with a bottom ring opening; the number of the jaw connecting rods 3210 is 3-6, and the jaw connecting rods are uniformly distributed on the side surface of the jaw bottom ring 3230. Preferably, the jaw connecting rods 3210 are 3 in number; wherein, the radial surface of the shaft-shaped or rod-shaped lever support 3130 supports the clip 3220 to move towards the center, so as to limit the clip 3220 from accidentally coming out of the base clip hole 2121 and the coupling seat clip hole 3321, and further keep the base clutch end 2120 connected with the coupling seat 3300;

the operating lever 3100 further includes an operating lever coupling end 3110 coupled to a proximal end of the operating lever support 3130, the proximal end of the operating lever coupling end 3110 passing through the bottom ring opening for coupling to the driving source, and an outer diameter of the proximal end of the operating lever support 3130 being larger than an inner diameter of the bottom ring opening.

The lever support 3130 has a length less than that of the jaw connecting rod 3210, and the lever support 3130 has an outer diameter such that, when the lever support 3130 is positioned in the coupling seat tap hole 3321, the catch 3220 is blocked by the outer surface of the lever support 3130 from being separated from the coupling seat tap hole 3321 and the base tap hole 2121, so that the catch 3220 is deformed only when the lever support 3130 contacts the jaw bottom ring 3230 and moves further proximally.

Based on the above structure, when the base clutch end 2120 and the coupling seat 3300 need to be separated, the operating rod moves towards the bottom ring 3230 of the jaw under the action of the axial force, and the operating rod supporting portion 3130 is also separated from the catch 3220 while the bottom ring 3230 of the jaw is pressed by the operating rod, without limiting the radial movement thereof, and under the condition that the external force is sufficient, the catch 3220 can be pulled away from the base catch hole 2121 and the coupling seat catch hole 3321, thereby separating the base clutch end 2120 and the coupling seat 3300.

As further illustrated in the above example, the coupling housing engaging end 3320 fits over the base engaging end 2120. as shown in fig. 11, the clamp 3200 includes a wire retention groove 3322. the head of the wire 610 of the transfer control assembly that engages the catch 1200 of the clamping mechanism 1000 has an expansion feature that is received in a base end hole 2122 that has a minimum dimension that is larger than the wire retention groove 3322 and smaller than the base end hole 2122. When the coupling seat 3300 is connected with the base clutch end 2120, the disengagement of the control wire 610 is limited by the control wire limit groove 3322;

in one embodiment, a cavity penetrating through the operating rod 3100 and communicating the proximal end thereof with the operating rod clutch end 3120 is arranged in the operating rod, and since the operating rod is not required to be solid and then is connected through threads as in the prior art, in the present application, since the clutch connecting groove 2222 is matched with the deformable buckle 3121, the operating rod can be arranged to be hollow, and then a flexible shaft for controlling the direction is arranged, so that an external operating structure for controlling the turning is saved.

The present invention also provides a system for clamping tissue, in particular a valve clamping system in this embodiment, comprising the aforementioned fixing device, i.e. comprising a clamping mechanism 1000 for closing tissue, a supporting mechanism 2000 for mounting the clamping mechanism 1000, the supporting mechanism 2000 comprising an actuating assembly 2200 for actuating the clamping mechanism 1000 to open and close;

and a conveyance control assembly including a pushing shaft 600 for pushing the fixing device to a specified position and a clutch mechanism 3000 for detachably connecting the pushing shaft 600 with the fixing device.

In order to further explain how the heart fixing and clamping function is realized in this embodiment, the specific structure of the clamping mechanism 1000 and the supporting mechanism 2000 will be described in detail in this embodiment.

Referring to fig. 2-4, wherein the support mechanism 2000 includes a stationary attachment assembly 2100 and a drive assembly 2200 movable relative to the stationary attachment assembly 2100; among other things, the stationary linkage assembly 2100 in the support mechanism 2000 may be used to connect the clamping mechanism 1000 at its distal end and the delivery control device at its proximal end detachably via the clutch mechanism 3000.

In the present embodiment, specifically, the gripping mechanism 1000 includes a pair of closure members 1100 and a pair of catches 1200 provided in correspondence with each closure member 1100; the occluding member 1100 is opened and closed by the driving assembly 2200, and the capturing member 1200 is opened and closed by the manipulation wire 610, and when clamping tissue, clamping is performed by cooperation of the inside of the occluding member 1100 and the outside of the capturing member 1200. In the present embodiment, the heart valve clamping is taken as an implementation scenario to explain a specific application principle of the fixing device for clamping tissue, referring to fig. 1, the fixing device of the present application is delivered to a specified position of the heart through a delivery control assembly, specifically, the delivery control assembly comprises a pushing shaft 600 for pushing the fixing device to the specified position and a clutch mechanism 3000 for detachably connecting the pushing shaft 600 with the fixing device; in an embodiment of the present invention, the pushing shaft 600 is a rod-shaped body or a hollow tubular body with an inner cavity, and is made of a biocompatible material. In this embodiment, the clamping shaft is round rod-shaped or round tube-shaped, and the surface of the pushing shaft 600 is smooth, so that the pushing shaft 600 is prevented from damaging the valve leaflets or hooking chordae tendineae. The pushing shaft 600 and the catheter 500 enter the operation channel 600 together, and after reaching the focal attachment, the pushing shaft 600 extends out of the catheter 500 to deliver the fixing device to the mitral valve. The distal end of the fixation device, i.e., the distal end of the fixture 1000, is preferably covered with a protective covering layer made of a biocompatible material and completely covering the outer periphery of the fixture 1000, the protective covering layer can prevent the device from damaging the tissue, and the outer surface of the fixation device can be completely protected by the protective covering layer when the fixation device is left in the heart as an implant.

After reaching the focus position, the position where the anterior leaflet and the posterior leaflet of the heart valve can not be normally involuted is clamped by the closing element 1100 and the catching element 1200 of the clamping mechanism 1000 in the embodiment, so that the partial positions which can not be normally involuted are folded together, the mitral valve can be completely closed or the area of the opening is reduced, and the mitral regurgitation is relieved or treated.

Clamping mechanism 1000 of other embodiments of the present invention may also be used to reduce or treat "tricuspid regurgitation," i.e., the occluding member 1100 and the capturing member 1200 may be added one more over the original pair for treating "tricuspid regurgitation. The principle and structure of the valve are the same as those used for solving mitral regurgitation in the embodiments of the present invention, and are not described herein again. It will be appreciated that other embodiments of the present invention may be applied to other minimally invasive surgical procedures requiring the clamping of several pieces of tissue, and that the number of occlusive members 1100 and catches 1200 may vary depending on the actual needs of the application.

After clamping of the mitral valve is completed, the fixation device is separated from the delivery control assembly by the clutch mechanism 3000, and the fixation device is thereby left at the lesion to maintain fixation of the valve.

With respect to clamping mechanism 1000, referring again to fig. 4-9 and 12-13, in this embodiment, an occlusive member 1100 of clamping mechanism 1000 includes an occlusive connection 1120 and an occlusive grip 1110, occlusive grip 1110 for engaging with catch 1200 to clamp tissue;

a guide chute 1121 is arranged on the closed connecting part 1120; the fixed connecting assembly 2100 is provided with a chute driving member 850 at least partially located in the non-linear guide chute 1121, the guide chute 1121 at least comprises a section of non-linear section, and the driving assembly 2200 connects the two closing connecting portions 1120 and is configured such that when the driving assembly 2200 moves relative to the fixed connecting assembly 2100, the chute driving member 850 can slide relatively in the guide chute 1121 to drive the two closing clamping portions 1110 to move relatively close to or away from each other.

Specifically, the distal end of the closing connection portion 1120 is rotatably connected to the driving assembly 2200, specifically, the distal end of the driving assembly 2200, in this embodiment, the closing connection portion 1120 is provided with a connection shaft hole 1122, and is connected to the driving assembly 2200 through a rotation shaft, in other embodiments, other hinge manners may be selected. When the closed clamp 1110 is in the initial position before the fixture is delivered to the designated location, as in the state of fig. 12(a), the chute drive 850 is located at the proximal end of the guide chute 1121, with the closure grip 1110 in the closed state, upon actuation of the drive assembly 2200, due to the engagement of the chute actuator 850 with the guide chute 1121, as the rotational connection of the drive assembly 2200 to the closure link 1120 moves proximally, that is, as the connecting portion shaft hole 1122 moves proximally, the guide chute 1121 moves in a synchronous proximal direction, and since the chute driving member 85 does not move, that is, the sliding groove driving member 85 moves distally relative to the guiding sliding groove 1121, and in order to adapt to the change of the distance, the sliding groove driving member 850 forces the sliding groove 1121 to rotate appropriately relative to the connecting shaft hole 1122, so that the rotating of the closing clamping member 1110 around the connecting shaft hole 1122 is realized. The closing clamping portion 1110 is turned outwards by taking the connecting shaft hole 1122 as an axis, so as to achieve the state shown in fig. 12(b) and (c), and further drives the connecting shaft hole 1122 to move proximally, so that the closing clamping portion 1110 can achieve the state shown in fig. 12(d), at this time, the two closing clamping portions 1110 form an included angle of 180 degrees relatively, and the distance between the end portions reaches the maximum distance capturing distance.

Due to the design of the guiding sliding chute 1121, after the two closed clamping portions 1110 form an included angle of 180 degrees relatively, the two closed clamping portions 1110 can be further turned over so as to be relatively opened to an obtuse angle as shown in fig. 13(a), so that the fixing device can be suitable for the situation that the position is inaccurate or the fixing device needs to be withdrawn from the heart due to other problems. The principle of the opening angle of the closing clamp 1110 achieved by the sliding slot driving member 850 cooperating with the guiding sliding slot 1121 will be described in detail later.

In this embodiment, the opening and closing of the closure profiles 1110 is accomplished by the drive assembly 2200 moving relative to the chute driver 850, but the chute driver 850 and the attached anchor attachment assembly 2100 are not moved, so that the distal closure attachment portion 1120 is moved proximally during the initial position of the closure profiles 1110 of the closure 1100 to the open position, which allows the closure 1100 to achieve a radially wider deployment distance than the prior art closure element which only has a deployment eversion motion, which is the case with the closure 1100 of the present invention. And in its initial position, the closure junction 1120 also has no additional mechanism, thus reducing the overall height of the fixation device and facilitating turns during delivery, based on which the closure element 1100 can also be correspondingly longer and thus have a greater capture distance.

After the closed clamping portion 1110 cooperates with the capturing member 1200 to clamp the tissue, the closed clamping portion 1110 needs to be further folded, and during the folding process, the distal closing connection portion 1120 thereof moves distally, so the closed clamping portion 1110 has a distal pulling effect, so that the closing process has a "biting" motion characteristic, and on the premise that the tissue is firmly clamped, the leaflet on the closed clamping portion 1110 obtains a "pulling" effect, so that the leaflet and the closed clamping portion 1110 are more firmly contacted.

The guiding chute 1121 includes at least two guiding grooves, namely a first guiding groove and a second guiding groove, which are at least communicated with each other, and the radian of the first guiding groove is larger than that of the second guiding groove. Fig. 6(a) shows a first embodiment of the present application, which is implemented by dividing the wire chute into a first guiding groove, a second guiding groove and a third guiding groove from the distal end to the proximal end, wherein the first guiding groove and the third guiding groove are arc-shaped sections, and the second guiding groove is a straight section, wherein the arc-shaped section has a larger change of the turning angle, but the moment is small, the moment changes non-linearly, and the change range is small, and there is a dead point where the moment is zero; and the straight line characteristic, moment is big, and moment linear stability changes, and the change range is big, does not have the moment dead point, but the change of upset angle is little, consequently, will lead spout 1121 to set gradually curved first guide slot, linear second guide slot and curved third guide slot for the closure member is opened and the required moment of the capture process of maximum opening angle position in the initial position is littleer in comparison with the centre, and the transform rate is faster, and then improve system reliability at the capture section, and the angle change that reaches slowly, makes things convenient for the meticulous operation of operative person.

With reference to fig. 6(a) in conjunction with fig. 6(c), (d), the chute driver 850 is circular shaft shaped and positioned within the guide chute 1121, the width of the guide chute 1121 matches the outer diameter of the chute driver 850, and in the initial unopened position, the chute driver 850 is positioned at the proximal end, i.e., the proximal end of the third channel, and the distance between the chute driver 850 and the closure engagement portion 2320 is h1, as shown in fig. 6(c), during the opening of the closure grip 1110, the chute driver 850 slides distally in the third channel, enters the second channel at the distal end of the third channel, at which time the closure grip 1110 has rotated an angle α 1, the chute driver 850 slides further distally, and at which time the closure grip 1110 has rotated an angle α 2, at which time the chute driver 850 is positioned at the distal end of the second channel, i.e., the end of the straight line segment, the distance between the chute driver 850 and the closure engagement portion 2320 is h2, as shown in fig. 6 (d); when the first guiding groove slides distally to reach the most distal end of the guiding groove 1121, the sliding groove driving member 850 rotates the closing clamping portion 1110 by an angle α 3; in the embodiment, the value ranges of α 1, α 2, α 3, h1, and h2 can be selected according to actual requirements, and preferably, the value range of α 1 is 30 ° to 45 °, further preferably, 35 ° to 40 °, and further preferably, 40 °; the value range of (a) is 55 to 70 degrees, more preferably 60 to 70 degrees, and still more preferably 65 degrees; the value range of alpha 3 is 120-150 degrees, more preferably 125-135 degrees, and still more preferably 130 degrees; preferably, h1 has a value in the range of 15-16mm, more preferably 15.5mm, and h2 has a distance of 5-7mm, more preferably 6 mm; as can be appreciated from the above description, rotation of the closure clamping portion 1110 by an angle α 2 requires a distance h2-h1 to drive the closure engagement portion 2320 relative to the chute drive 850. The closure mating portion 2320 moves 9.5mm when α 2 is 65 °, h1 is 15.5mm, and h2 is 6mm, i.e., when the two closure jaws 1110 are open at 130 ° relative to each other. Because the first guide slot of cooperation cambered, linear second guide slot and the third guide slot of cambered, not only be getting that the closure member is opened and the capture process in the middle is compared in the maximum angle position that opens at initial position, the slew velocity is faster, and then slowed down angle slew velocity at the section of catching for catch more stably, and compare in ordinary straight line spout, this application is reaching to predetermine the required driving distance of catching the angle littleer, and need meticulous position of operation again than to the curve groove more safe and reliable.

Fig. 6(b) shows another embodiment of the present invention, in which the guiding chute 1121 is implemented by dividing from the distal end to the proximal end into a first guiding slot and a second guiding slot, the first guiding slot is an arc-shaped segment, and the second guiding slot is a straight segment, which is mainly considered to be able to be folded rapidly when the guiding slot is opened to the maximum angle to the capturing position, and the angle change speed is slowed down at the capturing segment by the straight segment during the capturing of the tissue, so that the capturing is more stable. Specifically, the angle change of the corresponding slide groove 1121 from the nearest section of the slide groove 1121 to the junction of the first guide groove and the second guide groove is θ 1, the change angle of the straight line segment of the slide groove driving piece 850 in the slide groove 1121 is θ 1, and when the slide groove driving piece further moves to the farthest end, the opening angle of the single closed clamping portion 1110 is θ 2, wherein preferably, θ 1 is in the range of 40 ° to 60 °, and θ 2 is in the range of 120 ° to 140 °.

With reference to fig. 3 and 8, the driving assembly 2200 includes a moving seat 2300, and specifically includes a driving connecting block 2310, the side of the driving connecting block 2310 includes a first mounting surface and a second mounting surface perpendicular to each other, and the driving connecting block 2310 is hinged to the closing connecting portion 1120 through a closing member engaging portion 2320 disposed on the first mounting surface, so as to achieve the movement of the driving closing member engaging portion 2320, and further achieve the relative movement of the guide chute 1121 and the chute driving member 850.

Further, referring to fig. 7 again, in the present application, the capturing member 1200 includes a rigid capturing portion 1210, a flexible connecting portion 1220, and a capturing connecting portion 1230, which are connected in sequence, wherein the flexible connecting portion 1220 is located between the rigid capturing portion 1210 and the capturing connecting portion 1230; the second mounting surface is fixedly connected with the catching connecting part 1230;

in this example, the catch is adapted to cooperate with the closure member to capture the moving leaflets, which will be located between the closure member and the catch. The catching and connecting part is used for being connected with the second mounting surface. The natural state of the catching part presents the unfolded bird wing, the flexible connecting part is a deformable part with certain resilience, an overturning external force is applied to the rigid part of the catching part, the flexible connecting part is elastically deformed, the angle between the rigid part of the catching part and the axial direction is changed, the catching part is overturned, when the movable valve leaf to be caught is positioned above the closing part on one side of the catching part, the overturning external force is only removed, the elastic flexible part can instantly perform the action of restoring the shape of the natural state, and the valve leaf can be caught between the closing part and the rigid part of the catching part. The rigid part in the valve capture is mainly used for fixing the movable valve, and the structure of the rigid part needs to have certain rigidity so as to prevent the captured valve leaflets from pushing away the capture pieces to escape.

Further preferably, the rigid catching part 1210 comprises a rigid surface 1211 and catching burs 1212 arranged outside the rigid surface, the rigid surface 1211 is provided with a uniform thickness and is bent,

the rigid surface 1211 of the capture clip has a rigid cross-sectional feature, and the cross-sectional shape is curved as shown in fig. 7(b) or bent as shown in fig. 7(c), and the curved or bent portion of the structure is similar to the structure in which the reinforcing rib is added to the main body, so that the cross section of the sheet-shaped thin wall has a high bending section coefficient, the rigidity of the rigid portion of the capture clip is improved, and an additional layer of component for reinforcing the rigidity is not needed, and

in this example, the flipping motion of the capture clip is achieved by pushing and pulling the steering wire in the delivery control assembly to cause the steering wire to apply a force to the capture clip at the wire guide hole 1213.

In this example, the two capturing pieces 1200 share one capturing connection portion 1230, and the capturing connection portions 1230 are U-shaped and symmetrical vertical portions are fixedly connected to the second mounting surfaces of the driving connection blocks 2310, which are symmetrically arranged. The catching connection portion 1230 may be hinged, riveted, welded, or the like to the driving connection block 2310, so that the catching member 1200 may move axially along with the driving connection block 2310. With the chute drive 850 as a point of reference, as the drive connection block 2310 is brought axially closer to the chute drive 850, the occluding member 1100 will undergo a deployment flipping motion, while the capture member 1200 as a whole will also have an axial motion in the direction closer to the chute drive 850. If a tipping force is simultaneously applied to the rigid portion of the catch 1200 in the direction of the chute drive 850, the catch 1200 will tip in the direction of the chute drive 850, and when the appropriate leaflet comes into contact with the deployed occlusive member 1100, the tipping force on the catch 1200 is removed and the leaflet is trapped between the occlusive member 1100 and the catch 1200. In one embodiment, the natural state of the capture 1200 is the open state, the steering wire 610 is used to constrain the capture 1200 in the closed state, and the removal of the constraining force of the steering wire 610 may effect the flipping of the capture 1200. In another embodiment, the catch 1200 may also be a flexible member that is directly pushed by the steering wire 610 to effect a flip catch.

Further, as the drive link block 2310 begins to move axially away from the chute drive 850, the closure member 1100 will carry the captured leaflets and the deployed catch 1200 in a closing, everting motion, while at the same time the drive link block 2310 will carry the catch 1200 as a whole in an axial motion in a direction away from the chute drive 850, at which point there will also be relative displacement, or a tendency for relative displacement, between the catch 1200 and the leaflets. And due to the pressure exerted on the leaflets by the elastic deformation of the catch 1200, a frictional force is generated on the contact surface of the catch 1200 and the leaflets which are relatively displaced, and the direction of the frictional force exerted by the catch 1200 on the leaflets is towards the drive connection block 2310, which causes the catch to have a "pull" motion characteristic on the leaflets. The addition of some friction enhancing or spur features to the rigid portion of the capture 1200, such as the capture spurs 1212 in this embodiment, will make the leaflet "pulling" effect more pronounced and the present invention will make the leaflet more securely associated with the fixation device than the background art proximal element which has only a tipping motion.

Further, in this embodiment, referring to fig. 3, the closing clamping portion 1110 includes a free end and a connecting end connected to the closing connecting portion 1120, and an outer surface of the closing clamping portion 1110 at least partially has an inward contraction tendency from the connecting end to the free end. The cupped mouth feature of the closed clamp 1110, due to its concave nature, can increase the contact area with the valve leaflets when clamping the valve. When the valve is clamped and fixed by the matched catching piece 1200, the valve which is clamped in the concave inner part of the cup mouth can limit the radial displacement of the fixing device on the valve leaf. The cuff feature serves to avoid damage to the valve by the edges of the closed clamp 1110. After the fixation device finally closes the leaflets, the inward curved nature of the closing grip 1110 results in a pinch-off at the ends of the closing grip portions on both sides, which makes the leaflets snap more securely in the axial direction.

Further, the structure and principle of the supporting mechanism 2000 are explained with reference to fig. 3 and 8. Specifically, as previously mentioned, the support mechanism 2000 includes a stationary connection assembly 2100 and a drive assembly 2200 that is relatively movable with the stationary connection assembly 2100, the drive assembly 2200 being distally connected with both closure members 1100 such that opening or closing of the closure members 1100 is controlled when the drive assembly 2200 is relatively moved with respect to the stationary connection assembly 2100; specifically, the base housing further includes a base boss 2110 disposed at the distal end, and the chute driver 850 is disposed outside the base boss 2110. The closure member 1100 is controlled to open or close by controlling the relative movement of the drive assembly 2200 with respect to the chute drive 850.

Specifically, the fixed connection assembly 2100 includes a base housing having a base inner cavity 2130 disposed therein, a base threaded portion 2131 disposed therein within the base inner cavity 2130, a driving assembly 2200 including a driving shaft 2230, the driving shaft 2230 including a driving threaded portion 2231 engaged with the base threaded portion 2131, wherein a thread lead angle of the base threaded portion 2131 engaged with the driving threaded portion 2231 is less than a friction angle.

In this example, since the driving screw part 2231 and the base screw part 2131 have the same pitch and the same cross-sectional shape after being engaged with each other, the base housing and the driving shaft 2230 can be moved relative to each other in the axial direction by rotating the base housing or the driving shaft 2230. Because the lead angle of the helical groove is less than the friction angle between the contacting surfaces of the helical grooves, the base housing or drive shaft 2230 will not be axially displaced when the base housing or drive shaft 2230 is stopped, if only an axial force is applied to the base housing or drive shaft 2230. Therefore, the self-locking function is realized, the self-locking is not required to be realized through a spring piece or other structures as in the prior art, and the self-locking can be stopped at any position through threaded matching.

The drive assembly 2200 further includes a drive output shaft 2210 provided at the distal end of the drive shaft 2230 and having a smaller outer diameter than the drive shaft 2230, a drive connecting block 2310 provided with a coupling guide hole 2311 having an inner diameter matched to the drive output shaft 2210, and the drive output shaft 2210 being axially and rotatably fitted into the coupling guide hole 2311. The driving assembly 2200 further includes a positioning sleeve 810 provided at a distal end side of the driving connecting block 2310, and the driving output shaft 2210 is inserted through the coupling guide hole 2311 and then inserted into the positioning sleeve mounting hole 811 of the positioning sleeve 810 to be fixedly coupled with the positioning sleeve 810.

According to the above description, the present embodiment discloses a motion matching manner between the driving output shaft 2210 and the driving connection block 2310, and the output end of the driving output shaft 2210 outputs pushing force and pulling force to the driving connection block 2310 to realize axial movement of the driving connection block 2310, but since there is rotational movement between the driving output shaft 2210 and the base housing and there is no rotational displacement between the driving connection block 2310 and the base housing, the above structure can be adopted to realize the rotation driving process without driving the clamping mechanism to rotate therewith, and the clamping mechanism is moving stably in the axial direction. The locating sleeve 810 can be a tubular part, and the axial end faces at two sides are the end faces of the locating sleeve 810. The fixed connection between the positioning sleeve 810 and the output end of the driving output shaft 2210 can adopt a welding or interference fit mode, and also can adopt a mechanical connection mode. A mechanical connection as disclosed below: the positioning sleeve 810 may be provided with a positioning sleeve positioning hole 812 in the radial direction, and a driving output shaft positioning hole 2211 is provided in the radial direction at the matching position of the output end of the driving output shaft 2210 and the positioning sleeve 810, and the pin 840 is inserted into the positioning sleeve positioning hole 812 and the driving output shaft positioning hole 2211.

To illustrate the specific application of the device of this embodiment to a surgical procedure, the following description will be made of the operation of the system for clamping tissue according to the present application, taking a mitral valve repair procedure as an example, with reference to the structure described in detail in this embodiment:

the first step is as follows: the fixation device to which it is attached is advanced from the left atrium, through the mitral valve, and to the left ventricle by the pusher shaft 600. At this point, the closure member 1100 of the clip mechanism 1000 is in a collapsed state, as shown in fig. 12 (a).

The second step is that: the relative position of the valve fixing device and the mitral valve is adjusted by pushing the shaft 600, so that two closing members 1100 of the fixing device approach to the anterior leaflet and the posterior leaflet of the mitral valve respectively, then the driving shaft 2230 is rotated, the base threaded part 2131 is matched with the driving threaded part 2231 to make the driving connecting block 2310 move towards the far end, taking the chute driving piece 850 as a reference point, when the driving connecting block 2310 approaches axially towards the chute driving piece 850, the closing members 1100 will perform unfolding and overturning motions, so as to achieve the states as shown in fig. 12(b) and (c), the closing members can be further overturned to the state as shown in fig. 12(d), at the moment, the ends of the two closing members 1100 have the maximum distance, after the two closing clamping parts 1110 form an included angle of 180 degrees relatively, the closing members can be further overturned, so as to be relatively opened to an obtuse angle as shown in fig. 13(a), and the situation that the fixing device needs to be withdrawn from the heart due to inaccurate position or other problems can be adapted, because the two closed clamping parts 1110 form an obtuse angle relatively, the contact surface of the two closed clamping parts and the tissue tends to incline outwards in the withdrawing process, the tissue cannot be hooked, and the withdrawing process is smooth and safe.

The third step: after both closure elements 1100 capture the leaflets, the leaflets are clamped between the closure elements 1100 and the capture element 1200 by controlling the manipulation wire 610 to flip the capture element 1200 toward the closed clamp 1110, as shown in fig. 13 (b);

the fourth step: as the drive link block 2310 begins to move away from the slot drive 850, the closure member 1100 will carry the captured leaflets and the deployed catch 1200 in a closing, everting motion, while at the same time the drive link block 2310 will carry the catch 1200 in its entirety in an axial direction away from the slot drive 850, to the condition shown in fig. 13(c), (d), at which time there will also be a tendency for relative displacement, or tendency for relative displacement, between the catch 1200 and the leaflets. And due to the pressure exerted on the leaflets by the elastic deformation of the catch 1200, a frictional force is generated on the contact surface of the catch 1200 and the leaflets which are relatively displaced, and the direction of the frictional force exerted by the catch 1200 on the leaflets is towards the drive connection block 2310, which causes the catch to have a "pull" motion characteristic on the leaflets.

Through the system for clamping tissue of this application comes repair heart valve, closed clamping part has the effect to distal end pulling, make closed process have the motion characteristic of "interlock", under the firm prerequisite of tissue centre gripping, the leaflet on the closed clamping part will obtain the effect of "dragging", the adoption has the wire spout cooperation drive of non-straightway section, the angle of opening and the capture distance of closure member have been improved, it is easier to make and catch the leaflet, longer leaflet contact, make the leaflet of catching more firm.

In this document, the terms front, back, upper and lower are used to define the components in the drawings and the positions of the components relative to each other, and are used for clarity and convenience of the technical solution. It is to be understood that the use of the directional terms should not be taken to limit the scope of the claims.

The embodiments and features of the embodiments described herein above can be combined with each other without conflict.

While the utility model has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the utility model is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

Claims (10)

1. A clutch assembly for a tissue closure device, comprising:

a support mechanism (2000), said support mechanism (2000) comprising a stationary attachment assembly (2100) and a drive assembly (2200) movable relative to said stationary attachment assembly (2100), said stationary attachment assembly (2100) comprising a base engaging end (2120);

a clutch mechanism (3000) including a coupling seat (3300) detachably connected to the base clutch end (2120), a snap member (3200) connecting the base clutch end (2120) to the coupling seat (3300), and an operating lever (3100) capable of providing a driving force to the driving assembly (2200);

the operating lever (3100) comprises an operating lever disengaging end (3120) axially separable from and rotationally fixed to the driving assembly (2200), and an operating lever support portion (3130), the operating lever (3100) being arranged to be movable between a first position and a second position with respect to the snap member (3200), and the operating lever support portion (3130) being capable of bringing the snap member (3200) along with it and moving proximally when the operating lever (3100) is moved proximally in the second position, so that the coupling seat (3300) and the base disengaging end (2120) are relatively separable.

2. The tissue closure device clutch assembly of claim 1,

coupling seat (3300) including coupling seat link end (3310), coupling seat from closed end (3320) and run through coupling seat inner chamber (3330) of coupling seat (3300), joint spare (3200) is located in coupling seat inner chamber (3330), coupling seat from closed end (3320) passes through joint spare (3200) with base from closed end (2120) is connected, coupling seat link end (3310) is used for being connected with conveyor.

3. The tissue closure device clutch assembly of claim 2,

the connecting seat clutch end (3320) is provided with a connecting seat clamping hole (3321), and the base clutch end (2120) is provided with a base clamping hole (2121) corresponding to the connecting seat clamping hole (3321);

the clamping piece (3200) comprises a buckle (3220) which simultaneously penetrates through the connecting seat clamping hole (3321) and the base clamping hole (2121) so that the connecting seat (3300) and the base separation end (2120) are relatively fixed;

and the catch (3220) is configured such that when the catch (3200) is moved proximally with respect to the coupling seat (3300), the catch (3220) disengages from the coupling seat catch hole (3321) and/or the base catch hole (2121) to enable relative separation of the coupling seat (3300) and the base disengaging end (2120).

4. The tissue closure device clutch assembly of claim 3,

the buckle (3220) is made of flexible material, and when the clamping piece (3200) moves towards the proximal end relative to the coupling seat (3300), the buckle (3220) generates deformation.

5. The tissue closure device clutch assembly of claim 3,

the clamping piece (3200) further comprises a claw bottom ring (3230) and claw connecting rods (3210) which are the same in number as the buckles (3220) and are connected with the buckles (3220) and the claw bottom ring (3230), and the claw bottom ring (3230) is provided with a bottom ring opening;

the operating rod (3100) further comprises an operating rod connecting end (3110) connected to a proximal end of the operating rod supporting portion (3130), the proximal end of the operating rod connecting end (3110) passing through the bottom ring opening for connecting to a driving source, and an outer diameter of the proximal end of the operating rod supporting portion (3130) is larger than an inner diameter of the bottom ring opening.

6. The clutched assembly of a tissue closure device according to claim 5, wherein the lever support portion (3130) has a length less than a length of the jaw connection rod (3210), the lever support portion (3130) having an outer diameter configured such that when the lever support portion (3130) is located in the coupling block aperture (3321), the lever support portion (3130) outer surface blocks the catch (3220) from disengaging the coupling block aperture (3321) and the base block aperture (2121).

7. The tissue closure device clutch assembly of claim 5,

the number of the jaw connecting rods (3210) is 3-6, and the jaw connecting rods are uniformly distributed on the side surface of the jaw bottom ring (3230).

8. The tissue closure device clutch assembly of claim 1,

the drive assembly (2200) comprises a transmission rod clutch end (2220), the operating rod clutch end (3120) is connected with the transmission rod clutch end (2220) in a rotation-proof manner, and when the pulling force between the operating rod clutch end (3120) and the transmission rod clutch end (2220) is greater than a preset value, the operating rod clutch end (3120) is separated from the transmission rod clutch end (2220).

9. The tissue closure device clutch assembly of claim 8,

one of the operating lever clutch end (3120) and the driving lever clutch end (2220) is provided with a deformable buckle (3121), the other one of the operating lever clutch end (3120) and the driving lever clutch end (2222) is provided with a clutch connecting groove (2222), a clamping shaft which is matched and connected with the deformable buckle (3121) is arranged in the clutch connecting groove (2222), the operating lever clutch end (3120) and the driving lever clutch end (2220) are connected through the deformable buckle (3121) and the clamping shaft, and when the pulling force between the operating lever clutch end (3120) and the driving lever clutch end (2220) is greater than a preset value, the deformable buckle (3121) is separated from the clamping shaft.

10. The clutched assembly of tissue closure devices of claim 8, wherein a lumen is formed in the lever (3100) that communicates through its proximal end to the lever clutch end (3120).

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