CN215915077U - Delivery system for implantable tissue fixation devices - Google Patents

Abstract

The utility model discloses a conveying system for an implantable tissue fixing device, wherein the tissue fixing device comprises a second connecting part, the conveying system comprises a first connecting part, a limiting part and a separating component, and the separating component comprises a separating part; the limiting part is used for preventing the first connecting part and the separating part from moving relatively when the first connecting part is connected with the second connecting part, so that the conveying system is kept in a locked state; the separating part is used for applying acting force to the first connecting part to deform the first connecting part when the first connecting part is driven to overcome the stopping force of the limiting part to the first connecting part and move towards the separating part, so that the first connecting part is separated from the second connecting part. This conveying system sets up through ingenious structure for when inserting the implantable fixing device in the pipeline connecting pipe and reaching the target location, the pipeline is evacuated safely, and is minimum to the adjacent tissue damage.

Description

Delivery system for implantable tissue fixation devices

Technical Field

The present invention relates to the field of medical devices, and more particularly to a delivery system for an implantable tissue fixation device.

Background

Surgical repair of human tissue typically involves tissue apposition and fixation of these tissues in approximate alignment. When repairing a valve, tissue coaptation involves joining the leaflets during treatment, which can then be maintained by fastening or securing the leaflets. This connection is useful in treating regurgitation, which is most common in the mitral valve.

Mitral regurgitation is characterized by retrograde flow from the left ventricle of the heart through the incompetent mitral valve into the left atrium. During the normal systolic cycle (systole), the mitral valve acts as a one-way valve to prevent oxygenated blood from flowing back into the left atrium. Thus, oxygenated blood enters the aorta through the aortic valve. Valve regurgitation can significantly reduce the efficiency of the heart in delivering oxygenated blood, exposing the patient to the risk of severe, further heart failure.

Mitral regurgitation can be caused by a number of different mechanistic deficiencies of the mitral valve or the left ventricular wall. The leaflets, chordae tendineae connecting the leaflets to the papillary muscles, papillary muscles or left ventricular wall may be damaged or dysfunctional. Often, the annulus may be damaged, dilated or weakened, which limits the ability of the mitral valve to close adequately under high left ventricular pressure.

The most common treatment for mitral regurgitation is valve replacement or repair, including leaflet and annulus reconstruction, the latter commonly referred to as annuloplasty. One recent mitral valve repair technique is suturing together adjacent portions of the contralateral leaflets, known as a "bow-tie" or "edge-to-edge" technique. While all of these techniques are very effective, they typically rely on open-heart surgery, i.e., opening the patient's chest, usually through a sternotomy, and placing the patient in extracorporeal circulation. The need to both open the patient's chest and place it in extracorporeal circulation is painful and is associated with high mortality and morbidity.

The prior art also provides alternative and additional methods, devices or systems that do not require an open thoracic pathway and that can perform mitral and other heart valve repairs intravascularly or by minimally invasive methods, such as valve repair by implantable fixation devices, requiring such devices to be delivered and deployed by a catheter to the desired location for further surgery.

While there are some delivery systems for implantable tissue fixation devices, such as described in chinese patent CN102395331B, the delivery system in this patent relies solely on overcoming the pulling force to disengage by the user pulling proximally on the control handle or access catheter, and since the driving force by the method described in CN102395331B is not easily controlled within a safe and effective range to allow deployment, there may be instances of damage to the tissue in contact with the clip due to excessive pulling force.

Accordingly, there is a great need in the art to develop a delivery system for an implantable tissue fixation device that overcomes at least one of the above-mentioned disadvantages.

Disclosure of Invention

To address one or more of the above concerns, the present invention provides a delivery system for an implantable tissue fixation device, the tissue fixation device including a second coupling portion,

the conveying system comprises a first connecting part, a limiting part and a separating assembly, wherein the separating assembly comprises a separating part;

the limiting part is used for preventing the first connecting part and the separating part from moving relatively when the first connecting part is connected with the second connecting part, so that the conveying system is kept in a locked state;

the separating part is used for applying acting force to the first connecting part to deform the first connecting part when the first connecting part is driven to overcome the stopping force of the limiting part to the first connecting part and move towards the separating part, so that the first connecting part is separated from the second connecting part.

In another preferred example, the conveying system comprises a conveying element, the separation part is positioned at the far end of the conveying element, the conveying element and the separation part jointly limit a conveying inner space, and the limiting part is arranged in the conveying inner space;

the tissue fixation device includes a connector defining a connection interior space in which at least a distal portion of the first connector is disposed when the delivery system is maintained in a locked state.

In another preferred embodiment, the separation assembly further comprises a control rod passing through the transport interior space; the control rod is used for driving the first connecting part to move towards the separating part.

In another preferred embodiment, the limiting part is an elastic part, the proximal end of the elastic part is fixedly connected with the inner wall of the conveying part, and the distal end of the elastic part is fixedly connected with the first connecting part.

In another preferred embodiment, the elastic member is a compression spring, and the compression spring is sleeved on the control rod.

In another preferred embodiment, the first connection portion comprises a first control arm and a second control arm, the first control arm comprises a first control arm proximal end and a first control arm distal end, and the second control arm comprises a second control arm proximal end and a second control arm distal end;

the first control arm proximal end and the second control arm proximal end, the distal end of the elastic element and the distal end of the control rod are fixedly connected together to form a fixed connection point;

the first control arm distal end and the second control arm distal end are distal to each other.

In another preferred example, the second connecting portion includes a first locking groove in which the first control arm distal end is locked and a second locking groove in which the second control arm distal end is locked in the locked state of the delivery system.

In another preferred embodiment, the first control arm distal end comprises a first protrusion and the second control arm distal end comprises a second protrusion, the first protrusion being locked in the first locking groove and the second protrusion being locked in the second locking groove in the locked state of the delivery system.

In another preferred embodiment, the position-limiting part is an elastic part, and when the conveying system is in the locked state, the elastic part is in a natural state, or the elastic part is in a compressed state, so that the first connecting part and the second connecting part are tightly matched, that is, when the elastic part is in the compressed state, a slight acting force is generated to make the first connecting part and the second connecting part be more tightly matched.

In another preferred embodiment, the first connecting portion includes a plurality of control arms, the second connecting portion includes a plurality of locking grooves, the proximal ends of the control arms are fixed together, the distal ends of the control arms are far away from each other, and the distal ends of the control arms and the locking grooves can be clamped.

In another preferred embodiment, the distal ends of the plurality of control arms define a radius of minimum circumcircle that is greater than a radius of minimum circumcircle defined by the locking groove to provide a preload force between the control arms and the locking groove.

In another preferred example, the first connection portion includes a maximum radial dimension and a minimum radial dimension, the radial dimension of the space bounded by the separation portion is between the maximum radial dimension and the minimum radial dimension of the first connection portion, and the first connection portion is configured to pass through the space bounded by the separation portion.

In another preferred embodiment, the separating portion has an annular or cylindrical shape, and the first connecting portion is connected to the second connecting portion after passing through the separating portion.

In another preferred embodiment, the first connection portion comprises a plurality of control arms, the proximal ends of the control arms being fixed together, the distal ends of the control arms being remote from each other, and the inner diameter of the separation portion being smaller than the largest diameter defined by the distal ends of the plurality of control arms.

In another preferred embodiment, the inner diameter of the separation portion is larger than the smallest inscribed circle diameter of the control arm portion in the separation portion when the delivery system is in the locked state.

It is to be understood that within the scope of the present invention, the above-described features of the present invention and those specifically described below (e.g., in the examples) may be combined with each other to form new or preferred embodiments. Not to be reiterated herein, but to the extent of space.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It is to be understood that the drawings in the following description are merely exemplary embodiments of the utility model and that one skilled in the art may, without any inventive step, derive other embodiments from these drawings.

FIG. 1 is a schematic view of a delivery system coupled to a tissue fixation device according to an embodiment of the present invention;

FIG. 2 is a schematic illustration of the delivery system and tissue fixation device upon release according to an embodiment of the present invention;

FIG. 3 is a schematic illustration of a post-release delivery system and a tissue fixation device according to an embodiment of the present invention;

FIG. 4(a) is a schematic structural view of a connecting member of a delivery member and a tissue fastening device of a delivery system according to an embodiment, wherein a separating portion is integrally formed with the delivery member;

FIG. 4(b) is a schematic structural view of a connecting conduit of a delivery member and a tissue fixation device of a delivery system according to another embodiment, wherein the separation section is disposed coaxially with the delivery member and the separation section is adjacent to the connecting conduit;

FIG. 5 is a structural schematic diagram illustrating one state of an implantable tissue fixation device according to the present invention;

FIG. 6 is a schematic structural view showing another state of an implantable tissue fixation device according to the present invention;

FIG. 7 shows a schematic structural view of the delivery system and tissue fixation device of the present invention.

In the drawings, the designations are as follows:

1-conveying system

11-handle

12-transport element

121-conveying inner space

13-compression spring

14-control arm

140-fixed connection point

141-first control arm

1411-first control arm proximal end

1412-first control arm distal end

14121-first projection

142-second control arm

1421 second control arm proximal end

1422-second control arm distal end

14221-second tab

15-separation assembly

151-separation part

152-control lever

5-tissue fixation device

51-grip

52-arm

53-connecting piece

531-connecting the inner space

532-locking groove

5321 first locking groove

5322 second locking groove

6-valve leaflet

Detailed Description

In the following description, numerous technical details are set forth in order to provide a better understanding of the present invention. However, it will be understood by those skilled in the art that the claimed invention may be practiced without these specific details and with various changes and modifications based on the following embodiments.

Term(s) for

Implantable tissue fixation device

For interventional medicine, an interventional tool is needed to achieve minimally invasive therapeutic effects. Generally, an interventional tool includes a delivery system for delivering an implantable tissue fixation device to a target tissue through a natural orifice or artificial pathway of a human body, and an implantable tissue fixation device secured to the target tissue to address or alleviate a condition of the human body. For example, in vascular disease, the tissue fixation device is a stent prosthesis; in structural heart disease, the tissue fixation devices are left atrial appendage occluders, mitral valve clamps, tricuspid valve clamps.

Referring to fig. 3, 5-6, the present invention provides an example of an implantable tissue fixation device comprising a connector 53, the connector 53 defining a connection interior 531, and a second connector disposed in the connection interior for connection to a first connector of a delivery system.

The terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, the use of the verb "comprise a" to define an element does not exclude the presence of another, same element in a process, method, article, or apparatus that comprises the element. In the present patent application, if it is mentioned that a certain action is executed according to a certain element, it means that the action is executed according to at least the element, and two cases are included: performing the action based only on the element, and performing the action based on the element and other elements. The expression of a plurality of, a plurality of and the like includes 2, 2 and more than 2, more than 2 and more than 2.

In the present invention, all the directional indications (such as up, down, left, right, front, rear, etc.) are used only to explain the relative positional relationship between the respective members, the motion situation, etc. in a certain posture (as shown in the drawing), and if the certain posture is changed, the directional indication is changed accordingly.

In the present invention, unless otherwise specified, "distal" refers to a side closer to the patient and farther from the operator, and "proximal" refers to a side closer to the operator and farther from the patient.

The present invention provides a delivery system for delivering an implantable tissue fixation device. The tissue fixation device includes a second connection portion; conveying system includes first connecting portion, spacing portion and separable set. Wherein the separating assembly comprises a separating portion; the limiting part is used for preventing the first connecting part and the separating part from moving relatively when the first connecting part is connected with the second connecting part, so that the conveying system is kept in a locked state; the separating part is used for applying acting force to the first connecting part when the first connecting part is driven to overcome the stopping force of the limiting part to the first connecting part and move towards the separating part, so that the first connecting part is deformed, and the first connecting part is separated from the second connecting part.

In the following embodiments, mitral valve clips for preventing mitral regurgitation are exemplified.

Examples

To treat mitral regurgitation, one interventional procedure is to attach the leaflet section edges of the human mitral valve together by interventional medical devices, similar to a surgical "edge-to-edge" procedure. As shown in fig. 7, the interventional medical device comprises a tissue fixation device 5 for effecting gripping of a leaflet edge of the mitral valve. The tissue fixation device 5 here may be a mitral valve clip. The interventional medical device further comprises a delivery system 1 for delivering the tissue fixation device 5 to the vicinity of the mitral valve, the delivery system 1 comprising a proximal handle 11 and a distal delivery member 12. The handle 11 is used to control the attitude of the distal end of the delivery member 12 so that the delivery member 12 moves along the natural orifice or artificial path of the body to the mitral valve in a desired attitude. The handle 11 is also used to control functional movement of the tissue fixation device 5, such as opening and closing movement to grip the mitral valve leaflets; separation between the tissue fixation device 5 and the delivery system 1, and so forth.

In one aspect, as shown in FIGS. 5-6, tissue fixation device 5 includes a grip 51 and clamp arms 52. The clamping arms 52 and the gripping member 51 can be swung independently to effect the clamping of the leaflets 6. In this embodiment, clip arms 52 include two clip arm extension members extending to opposite sides. The grip member 51 includes two grip extension members extending to both sides. As shown in fig. 5, when gripping leaflets 6, the arm extensions of arms 52 rotate distally and the gripping extensions of gripping members 51 rotate proximally to increase the gripping space between the arm extensions and the gripping extensions for the leaflets to more easily enter. As shown in fig. 6, after the leaflets enter the clamping space, the clip arm extension members of the clip arms 52 are rotated back proximally and the grip extension members of the grip 51 are rotated back distally until the leaflets clamp with the clip arm extension members. In other embodiments, the number of the clamping arm extension part and the gripping extension part can be three, four or more. The number of the clamping arm extending parts and the gripping extending parts can be determined according to the anatomical structure of human tissues and the requirements of the operation type. Further, the tissue fixing device 5 further comprises a connecting piece 53, and the gripping piece 51 and the clamping arms 52 swing around the axis of the connecting piece 53. The specific connection manner of the gripping member 51, the clamping arm 52 and the connecting member 53 is not limited. For example, the gripping member 51 and the clamping arm 52 are directly and rotatably connected to the connecting member 53 to swing the gripping member 51 and the clamping arm 52, or the gripping member 51 and the clamping arm 52 may also be indirectly connected to the connecting member 53 to convert the axial movement of the connecting member 53 into the swing of the gripping member 51 and the clamping arm 52 through a conversion mechanism, or the connecting member 53 is directly inserted through the gripping member 51 and the clamping arm 52 to swing the gripping member 51 and the clamping arm 52 by their own elasticity. Further, the proximal end of the connector 53 includes a second connector portion for detachable connection with the first connector portion of the delivery system. Exemplarily, the second connection portion is a groove, a through hole or a blind hole.

In this embodiment, the material of the clamping arm 52 is not particularly limited as long as it is a biocompatible material, and the material of the clamping arm 52 is preferably cobalt-chromium alloy. Also, the present embodiment has no particular limitation on the material of the grip member 51. Preferably, the material of the gripping member 51 is a nickel titanium alloy material, which has good biocompatibility and resilience.

On the other hand, the conveying system 1 further comprises a first connecting portion, a limiting portion 13 and a separating assembly 15, wherein the separating assembly 15 comprises a separating portion 151. The stopper portion is used to prevent the first connecting portion and the separating portion 151 from moving relative to each other when the first connecting portion is connected to the second connecting portion of the tissue fixing device 5, so that the delivery system 1 is kept in a locked state. The separating portion 151 is used for applying an acting force to the first connecting portion when the first connecting portion is driven to overcome the stopping force of the limiting portion to the first connecting portion to move towards the separating portion 151, so that the first connecting portion is deformed, and the first connecting portion is separated from the second connecting portion.

Referring to fig. 1-3, the first connection is a plurality of control arms 14. The proximal ends of the plurality of control arms 14 are connected and the distal ends are remote from each other. Preferably, the control arm 14 is made of a biocompatible metal, more preferably, a cobalt chromium alloy. In the present embodiment, the number of the control arms 14 is 2, i.e., the first control arm 141 and the second control arm 142. The first control arm 141 includes a first control arm proximal end 1411 and a first control arm distal end 1412, and the second control arm 142 includes a second control arm proximal end 1421 and a second control arm distal end 1422; wherein the first control arm proximal end 1411 of the first control arm 141 and the second control arm proximal end 1421 of the second control arm 142 are fixedly connected to the fixed connection point 140, and the first control arm distal end 1412 and the second control arm distal end 1422 are remote from each other and are adapted to be locked with a locking groove, respectively, in a locked state of the delivery system. As such, the first and second control arms 141 and 142 are arranged in a V-shape. In other embodiments, the control arm 14 may be greater than 2, such as 3, 4. The distal end of the control arm is connected with the locking groove in a clamping manner, so that the delivery system 1 is connected with the tissue fixing device 5. Thereby, the conveying system 1 is in a locked state.

Further, the first control arm distal end 1412 includes a first protrusion 14121 and the second control arm distal end 1422 includes a second protrusion 14221. Accordingly, the second connecting portion is a plurality of locking recesses 532 provided on the inner wall of the proximal end of the connecting member 53. The number of the locking recesses 532 matches the number of the control arms 14, and the relative positions between the locking recesses 532 match the distal end relative positions between the control arms 14. In the present embodiment, the number of the locking grooves 532 is 2, i.e., the first locking groove 5321 and the second locking groove 5322. The first and second protrusions 4121 and 4221 may be locked in the first and second locking grooves 5321 and 5322, respectively. By the cooperation of the two, the connection between the delivery system 1 and the tissue fixation device 5 is achieved, i.e. the delivery system is in a locked state. Preferably, the radius of the minimum circumscribed circle defined by the first and second protrusions 4121 and 4221 is slightly greater than or equal to the radius of the minimum circumscribed circle defined by the first and second locking grooves 5321 and 5322. The stability of the connection between the protrusion and the locking groove 532 is increased by slight deformation of the control arm 14 to increase the preload between the protrusion and the locking groove.

After the delivery system 1 has placed the tissue fixation device 5 near the mitral valve, the delivery system 1 needs to be separated from the tissue fixation device 5. When the first connecting portion moves toward the separating portion 151, the separating portion 151 generates an acting force to the first connecting portion due to contact between the separating portion 151 and the first connecting portion, so that the first connecting portion is deformed and then separated from the second connecting portion. In one embodiment, the separation portion defines a space, the first connection portion is configured to pass through the space defined by the separation portion, the first connection portion includes a maximum radial dimension and a minimum radial dimension, and the radial dimension of the space defined by the separation portion is between the maximum radial dimension and the minimum radial dimension of the first connection portion. Referring specifically to fig. 2, in the present embodiment, the separating portion 151 is a hollow tube. Since the proximal ends of the control arms are fixed, the minimum radial dimension is twice the width of the control arms, and the inner diameter of the tube is configured to be smaller than the minimum circumscribed diameter (i.e., the maximum radial dimension) defined by the first and second protrusions 4121 and 4221, so that the control arms 14 are interfered by the separating part 151 and deformed when moving toward the separating part 151. Meanwhile, the inner diameter of the tubular object cannot be too small, so that the separating portion 151 interferes with the control arm 14 when the first projection 4121 and the second projection 4221 are locked with the first locking groove 5321 and the second locking groove 5322, respectively, that is, when the conveying system 1 is in the locked state. One skilled in the art can obtain the minimum inner diameter of the desired tube by geometric relationships based on the length of the control arms 14, as well as the angle between the control arms 14, and the length of the portion of the control arms 14 in the connecting channel 53. More specifically, when the first and second protrusions 4121 and 4221 are locked with the first and second locking grooves 5321 and 5322, respectively, there is a certain gap between the first and second control arms 141 and 142 and the separating portion 151, i.e., the inner diameter of the tube is greater than the diameter of the smallest circumscribed circle defined by the corresponding position control arm 14. In this manner, there is no unintended disengagement between the delivery system 1 and the tissue fixation device 5 in a locked state due to the separation 151 acting accidentally on the control arm 14 as a result of the rotation between the delivery system and the tissue fixation device to some extent. Preferably, the radial deformation resistance of the separating portion 151 is greater than that of the control arm 14. In an alternative embodiment, the separating portion may also be in the shape of a ring or other similar shape that defines a space. When the control arm 14 is locked with the locking groove 532, at least the distal end portion of the control arm 14 is located within the inner space 531, and the proximal end of the control arm 14 may be located within the delivery inner space 121, within the connection inner space 531, or in the space between the delivery inner space 121 and the connection inner space 531. In this regard, the present embodiment is not particularly limited. In the present embodiment, the separating part 151 is integrally formed with the conveying member 12 (see fig. 4 a). In an alternative embodiment, the detachment portion 151 is provided as a separate component that is assembled directly or indirectly to the distal end of the delivery member 12 (e.g., FIG. 4 b).

Further, the detachment assembly includes a control rod 152, a distal end of the control rod 152 is fixedly connected to the fixed attachment point 140 with the control arm 14, and a proximal end of the control rod 152 is connected to the handle 11 of the delivery system. With this arrangement, when it is desired to separate the delivery system 1 from the tissue fixation device 5, the operator can operate the handle 11 to move the control rod 152 proximally, and thus move the control arm 14 toward the separation portion 151, and due to the interference between the two, the control arm 14 is deformed and folded away to separate from the locking groove 532. In this embodiment, a control rod 152 is disposed in the delivery interior 121 and is connected to the handle 11 along the axis of the delivery member 12 extending from the distal end to the proximal end.

After the delivery system 1 is in the locked state, it is necessary to maintain the delivery system in the locked state while delivering the tissue fixation device 5 to the mitral valve target location and while grasping the mitral valve leaflets with the tissue fixation device 5. When the first connecting portion of the delivery system 1 and the second connecting portion of the tissue fixing device 5 are connected, the limiting portion prevents the first connecting portion from moving toward the separating portion 151, so that the first connecting portion is prevented from being deformed by the separating portion 151, and the first connecting portion and the second connecting portion are separated. As shown in fig. 1-3, the position-limiting part is an elastic member disposed in the conveying inner space 121, and a proximal end of the elastic member is fixed to the conveying inner space 121 and a distal end thereof is fixed to the fixed connection point 140 of the control arm 14. The resilient member is further configured to naturally exert no or a slight force (within 10N) to provide a tighter fit between the control arm 14 and the locking recess 532 when the control arm 14 is locked with the locking recess 532. When the control arm 14 moves toward the separation portion 15, the elastic member generates an elastic force to prevent the control arm 14 from further moving toward the separation portion 15. Preferably, the elastic element is a compression spring 13 and is sleeved on the control rod 3. When the control arm 14 is locked with the locking groove 532, the pressing spring 13 is in a natural length.

The following exemplary brief description is provided of the method of operation of the delivery system in the above embodiments.

The delivery system has two states, a locked state (also referred to as a pre-release state) and a disengaged state (also referred to as a post-release state).

Aligning the distal end of the delivery system with the proximal end of the tissue fixation device, slightly compressing the control arm 14, and then moving the delivery system relative to the tissue fixation device such that the compressed control arm 14 enters the connection interior 531 of the connector 53, aligning the control arm 14 with the locking recess 532 of the connector 53 and releasing the control arm 14 to effect locking of the control arm 14 with the locking recess 532, and thereby placing the delivery system in a locked state, as shown in fig. 1;

performing various surgical operations on the delivery system in the locked state, such as delivering the tissue fixation device 5 to the mitral valve target location and grasping the tissue fixation device 5 against the mitral valve leaflets;

as shown in fig. 2-3, when the delivery system needs to be separated from the tissue fixing device, the separation part is kept still, the control arm 14 is driven by the control rod 152 to move towards the separation part against the elastic force of the elastic member, and the control arm 14 is deformed and gathered together due to the acting force of the separation part on the control arm 14, so that the control arm 14 is separated from the locking groove 532, the delivery system is separated from the tissue fixing device, and the delivery system is in a separated state. Finally, the delivery system is withdrawn from the body to complete the surgical procedure.

Advantages of the utility model include one or more of the following:

(a) the delivery system of the present invention may be used in procedures requiring access to a tissue site or endovascular access, particularly where the instrument used must travel through a narrow and tortuous path to reach a distal treatment site;

(b) the delivery system of the present invention is suitable for withdrawal and removal from any location on a patient, and does not interfere with internal tissue or damage injured tissue;

(c) the delivery system of the present invention can be used in a variety of therapeutic procedures, including vascular and open procedures, and in a variety of anatomical regions, including organs, vessels and tissues such as the abdomen, thorax, cardiovascular system, heart, intestinal tract, stomach, urethra, bladder, lung, etc.;

(d) the conveying system is skillfully arranged, so that the conveying system can be safely evacuated after the implantable fixing device reaches the target position, and the damage to adjacent tissues is minimum;

(e) the delivery system of the utility model does not need to apply tension directly to the implant or the joint tissue by operating the control rod through the handle at the proximal end, and does not only rely on tension (pulling towards the proximal side) to realize the separation of the delivery element, thereby having good stability and easy control, and avoiding damaging the tissue contacted with the tissue fixing device due to excessive tension;

(f) the conveying system of the utility model enables the control arm to be locked in the locking groove of the connecting piece by arranging the limiting part, such as the compression spring, and prevents the control arm from being unfolded accidentally or accidentally.

All documents mentioned in this application are to be considered as being incorporated in their entirety into the disclosure of this application so as to be subject to modification as necessary. Further, it is understood that various changes or modifications may be made to the present application by those skilled in the art after reading the above disclosure of the present application, and such equivalents are also within the scope of the present application as claimed.

Claims (15)

1. A delivery system for an implantable tissue fixation device, the tissue fixation device including a second coupling portion,

the conveying system comprises a first connecting part, a limiting part and a separating assembly, wherein the separating assembly comprises a separating part;

the limiting part is used for preventing the first connecting part and the separating part from moving relatively when the first connecting part is connected with the second connecting part, so that the conveying system is kept in a locked state;

the separating part is used for applying acting force to the first connecting part to deform the first connecting part when the first connecting part is driven to overcome the stopping force of the limiting part to the first connecting part and move towards the separating part, so that the first connecting part is separated from the second connecting part.

2. The delivery system of claim 1, wherein the delivery system includes a delivery member, the separation section is located at a distal end of the delivery member, and the delivery member and the separation section together define a delivery interior space, the retention section being disposed in the delivery interior space;

the tissue fixation device includes a connector defining a connection interior space in which at least a distal portion of the first connector is disposed when the delivery system is maintained in a locked state.

3. The transport system of claim 2, wherein the separation assembly further comprises a control rod passing through the transport interior space; the control rod is used for driving the first connecting part to move towards the separating part.

4. The delivery system of claim 3, wherein the retention element is a resilient member, a proximal end of the resilient member is fixedly coupled to an inner wall of the delivery member, and a distal end of the resilient member is fixedly coupled to the first coupling element.

5. The delivery system of claim 4, wherein the resilient member is a compression spring that is mounted over the control rod.

6. The delivery system of claim 4, wherein the first connection comprises a first control arm comprising a first control arm proximal end and a first control arm distal end and a second control arm comprising a second control arm proximal end and a second control arm distal end;

the first control arm proximal end and the second control arm proximal end, the distal end of the elastic element and the distal end of the control rod are fixedly connected together to form a fixed connection point;

the first control arm distal end and the second control arm distal end are distal to each other.

7. The delivery system of claim 6, wherein the second coupling portion includes a first locking recess in which the first control arm distal end is locked and a second locking recess in which the second control arm distal end is locked in the locked state of the delivery system.

8. The delivery system of claim 7, wherein the first control arm distal end includes a first protrusion and the second control arm distal end includes a second protrusion, the first protrusion being locked in the first locking recess and the second protrusion being locked in the second locking recess in the locked state of the delivery system.

9. The conveying system according to claim 1, wherein the position-limiting part is an elastic member, and when the conveying system is in a locked state, the elastic member is in a natural state, or the elastic member is in a compressed state, so that the first connecting part and the second connecting part are tightly matched.

10. The delivery system of claim 1, wherein the first coupling portion comprises a plurality of control arms and the second coupling portion comprises a plurality of locking recesses, wherein proximal ends of the control arms are secured together and distal ends of the control arms are spaced apart from one another, and wherein the distal ends of the control arms are snapably engageable with the locking recesses.

11. The delivery system of claim 10, wherein a minimum circumscribed circular radius defined by the distal ends of the plurality of control arms is greater than a minimum circumscribed circular radius defined by the locking groove to provide a preload force between the control arms and the locking groove.

12. The delivery system of claim 1, wherein the first connection portion includes a maximum radial dimension and a minimum radial dimension, the radial dimension of the space bounded by the separation portion being intermediate the maximum radial dimension and the minimum radial dimension of the first connection portion, the first connection portion being configured to pass through the space bounded by the separation portion.

13. The conveying system according to claim 12, wherein the separating portion is annular or cylindrical, and the first connecting portion is connected to the second connecting portion after passing through the separating portion.

14. The delivery system of claim 13, wherein the first coupling portion comprises a plurality of control arms having proximal ends secured together and distal ends remote from one another, and wherein the inner diameter of the separation portion is less than a maximum diameter defined by the distal ends of the plurality of control arms.

15. The delivery system of claim 14, wherein the inner diameter of the separation portion is greater than the smallest inscribed circle diameter of the portion of the control arm in the separation portion when the delivery system is in the locked state.

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