CN211723546U

CN211723546U - Valve clamping device and clamping system thereof

Info

Publication number: CN211723546U
Application number: CN201921263270.6U
Authority: CN
Inventors: 戴宇峰; 潘炳跃; 潘文志; 周达新; 葛均波
Original assignee: Shanghai Hanyu Medical Technology Co ltd
Current assignee: Shanghai Hanyu Medical Technology Co ltd
Priority date: 2019-08-06
Filing date: 2019-08-06
Publication date: 2020-10-23
Anticipated expiration: 2029-08-06

Abstract

A valve clip and a clipping system thereof are provided, which can effectively treat Mitral Regurgitation (MR) and Tricuspid Regurgitation (TR) after being implanted into a human body by means of the clipping system. The valve clamping device can shorten the axial operation space of the valve clamping device, change the operation direction, perform capture and clamping operation from the other side (namely, the atrium side) of the valve, reduce the damage risk of the valve clamping device to the atrium and chordae tendineae in the operation process, shorten the length of the valve clamping device, shorten the implanted valve clamping device, reduce the space of the valve clamping device occupying the ventricle side, reduce the damage of the valve clamping device to heart tissues possibly caused, and reduce the risk of forming thrombus.

Description

Valve clamping device and clamping system thereof

Technical Field

The utility model relates to a valve clamping device, in particular to a valve clamping device and a clamping system thereof.

Background

The mitral valve is a two-piece valve attached to the periphery of the ostium of the left ventricle (as shown in fig. 1), attached to the papillary muscles by chordae tendineae, and functions to prevent blood from the left ventricle from flowing back into the left atrium.

Mitral Regurgitation (MR) is a series of pathophysiological changes caused by the organic or functional changes in the mitral leaflets and their associated structures that cause poor coaptation of the anterior and posterior leaflets of the mitral valve, with blood flowing back from the left ventricle to the left atrium. Severe MR causes enlargement of the left ventricle, ultimately leading to left systolic dysfunction and heart failure, while left atrial pressure also increases due to regurgitation, easily leading to enlargement of the left atrium, atrial fibrillation and pulmonary hypertension. The MR prognosis is poor, the annual death rate of patients with symptoms but without operation is about 5 percent, and the annual death rate of 5 patients with severe heart failure reaches 60 percent. Meanwhile, MR is also one of the most common cardiac diseases. The incidence rates of people over 65 and 75 years of age were statistically 6.4% and 9.3%, respectively. With the development of economic society and the aging of population, the incidence rate of mitral regurgitation is in a state of obviously rising.

Surgical valve repair or replacement is considered the standard treatment for this disease. However, the surgical operation has the disadvantages of large trauma, obvious postoperative pain, slow recovery, high risk, etc., and in addition, some patients who are elderly, have a history of chest-open disease, have poor cardiac function and have complicated multi-organ dysfunction are often rejected for surgical operation because of the high surgical risk. Therefore, there is a great social and market need to develop minimally invasive, low-risk interventional therapeutic devices for MR treatment. In recent years, with the breakthrough development of valve interventional therapy technology, MR interventional devices have become one of the key directions for the development of cardiovascular devices at home and abroad.

Among them, the valve forceps 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. The principle of the surgical valve edge-to-edge sewing technology is shown in fig. 2: when the mitral valve is in regurgitation, the edges of two valve leaflets cannot be closed together to form a gap in the systole, so that the blood flow of the left ventricle returns to the left atrium from the gap; surgical edge-to-edge suturing sutures the mitral valve at a point intermediate the two leaflet edges such that the inter-leaflet space disappears or becomes smaller during systole, thereby reducing mitral regurgitation (fig. 2a), while during diastole the mitral valve opens into a bi-porous shape and blood flow into the left ventricle remains unaffected (fig. 2 b). The only minimally invasive interventional instrument internationally approved for treatment of MR on the market is MitraClip, a valve-clamping device, by Evalve.

Patent CN106175986A developed by subsidiary zhongshan hospital of fudan university, which is proprietary to the medical technology limited, discloses a valve clip which performs a capturing clipping operation from the valve ventricular side. The patent is developed and used, and the defects that the device still has overlarge operation space required for capturing the valve, can be operated only through the ventricle side (the entrance wound from the apex of the heart is still large), is easy to wind chordae tendineae, is easy to damage the atrial roof of the heart, and can only capture two sides of the valve simultaneously are found in actual operation.

Therefore, effective innovation of the prior art is needed to address the above drawbacks.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to developing a valve clip and a clipping system thereof, which can effectively treat Mitral Regurgitation (MR) and Tricuspid Regurgitation (TR) after being implanted into a human body by means of the clipping system. The valve clamping device can shorten the axial operation space of the valve clamping device, change the operation direction, perform capture and clamping operation from the other side (namely, the atrium side) of the valve, reduce the damage risk of the valve clamping device to the atrium and chordae tendineae in the operation process, shorten the length of the valve clamping device, shorten the implanted valve clamping device, reduce the space of the valve clamping device occupying the ventricle side, reduce the damage of the valve clamping device to heart tissues possibly caused, and reduce the risk of forming thrombus.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a valve clamping device comprises a clamping component and a fixing component, wherein the clamping component comprises a base, a fixing rod, a first clamping component and a second clamping component, the base is provided with a first connecting structure, the fixed rod, the first clamping part and the second clamping part are arranged on the base, the proximal end of the fixing rod is provided with a second connecting structure, the first clamping part is provided with at least two first clamping arms, the second clamping part is provided with a corresponding number of second clamping arms, the outer sides of the second clamping arms are provided with clamping structures, each first clamping arm and the corresponding second clamping arm form a group of clamps, the fixing part is detachably connected with the base, a third connecting structure and a fourth connecting structure are respectively arranged on the inner side and the near end of the fixing part, and the third connecting structure is matched with the first connecting structure;

correspondingly, the first connecting structure is arranged on the circumferential side of the base, the first connecting structure comprises an external thread, and the base can be screwed into the inner sleeve through the external thread and is sleeved in the fixing part;

correspondingly, the fixing rod is arranged at the center of the near-end side of the base, so that when the base is pushed into the fixing part by the fixing rod, acting force acting on the base is more uniform and stable, the first clamping part and the second clamping part are positioned on the same diameter of the near-end side of the base, the first clamping part and the second clamping part are symmetrically arranged by taking the fixing rod as a symmetric center, and the far ends of the fixing rod, the first clamping part and the second clamping part are all arranged at the near-end side of the base, so that the overall length of the structure can be shortened;

correspondingly, the second connecting structure comprises a threaded hole, and the fixed rod can be quickly connected with and disassembled from the push rod through the threaded hole;

correspondingly, the clamping structure comprises a tooth-shaped structure, and the second clamping arm is clamped by the tooth-shaped structure and a third connecting structure on the fixing part after being pushed into the fixing part along with the base, so that the base and the fixing part are prevented from being disengaged to keep the current fixing state;

correspondingly, the first clamping arm and the second clamping arm are made of elastic materials and comprise nickel-titanium alloy;

correspondingly, a setting included angle is formed between the first clamping arms and between the second clamping arms, the setting included angle between the first clamping arms is larger than that between the second clamping arms, so that the first clamping arms and the second clamping arms can capture valve tissues, preferably, the angle change range of the first clamping arms and the central axis of the valve clamping device is set to be 0-70 degrees, and the included angle difference of the setting included angle between the first clamping arms and the setting included angle between the second clamping arms is 10-20 degrees;

correspondingly, the length of the first clamping arm and the second clamping arm is 5.0-12.0mm, and the width of the first clamping arm and the second clamping arm is 3-8 mm;

correspondingly, the proximal ends of the first clamping arm and the second clamping arm are provided with mutually matched contacts, and the opposite sides of the first clamping arm and the second clamping arm are provided with mutually matched clamping teeth;

correspondingly, the contact of the first clamping arm is provided with a threading hole, pull wires are respectively penetrated in the threading holes, and the size of an included angle between the first clamping arms is controlled by pulling the pull wires;

correspondingly, the contact surfaces of the first clamping arm and the second clamping arm are coated with polymer films or polymer materials, including PET films, so as to promote endothelialization of the clamp after being implanted into a human body;

correspondingly, the outer surface of the fastener part is coated with a polymer film or polymer material, including a PET film, so as to promote endothelialization of the clamp after being implanted into a human body;

correspondingly, the fixing part comprises a fixing ring which is of a hollow structure, the near end of the hollow inner side wall of the fixing ring is provided with the third connecting structure, the third connecting structure comprises an internal thread, and the internal thread is in threaded connection with the first connecting structure;

correspondingly, the fixing part comprises a fixing ring which is of a hollow structure, a fourth connecting structure is arranged at the near end of the fixing ring, the fourth connecting structure comprises a connecting arm and a connecting hole formed in the connecting arm, and the quick connection and disassembly between the fixing part and the conveying pipe are realized through the connecting hole;

correspondingly, the axial length of the fixing ring is 4.0-10.0mm, the inner diameter is 4.0-6.0mm, and the outer diameter is 4.5-7.0 mm.

A valve clipping system comprising, in addition to the aforementioned valve clip,:

the adjustable bending catheter sheath comprises a near-end straight pipe section and a far-end bending adjusting section, and the straight pipe section and the bending adjusting section are provided with continuous first through holes communicated with the two ends;

a dilator, wherein the dilator is suitable for passing through the first through hole, the axial length of the dilator is larger than that of the adjustable bending catheter sheath, the dilator is provided with a second through hole which is communicated with two ends, and the inner diameter of the second through hole is suitable for passing through a guide wire;

a shuttle having a third through-hole communicating the two ends, the third through-hole being adapted to receive the valve clamp and at least a portion of the delivery tube, at least a portion of the third through-hole having an outer wall sized to enter the first through-hole;

a delivery tube, wherein the delivery tube is suitable for passing through the first through hole, the axial length of the delivery tube is larger than the total axial length of the adjustable bending catheter sheath and the loader, the delivery tube is provided with a fourth through hole communicated with the two ends, and the distal end of the delivery tube is detachably connected with the proximal end of the fixing part;

the axial length of the pushing rod is greater than that of the conveying pipe and is suitable for axial movement along the fourth through hole, a fifth connecting structure is arranged at the far end of the pushing rod, and the pushing rod is detachably connected with the second connecting structure of the fixing rod through the fifth connecting structure;

correspondingly, the inner proximal ends of the adjustable bending catheter sheath, the dilator, the delivery pipe and the loader are provided with hemostatic valves;

correspondingly, the conveying pipe and the pushing rod are also provided with elastic sections which can bend along with the bending of the bending section of the catheter sheath;

correspondingly, the far end of the conveying pipe is provided with at least two extension arms which are made of elastic materials, the extension arms are shaped into flaring structures, the near ends of the inner sides of the extension arms are provided with at least two clamping pieces, the two clamping pieces are arranged on the inner side walls of the extension arms in a staggered mode, the two clamping pieces are provided with corresponding pore channels, and the pore channels are used for a pushing rod to pass through;

correspondingly, the extension arm is also provided with clamping blocks, the quantity and the position of the clamping blocks correspond to those of the fourth connecting structure, and the clamping blocks are detachably connected with the fourth connecting structure;

correspondingly, the fifth connecting structure comprises a threaded boss, and the threaded boss is matched with the second connecting structure.

It should be noted that, in the present invention, the terms "proximal end" and "distal end" refer to the relative position of the valve to the operator during the normal operation. Wherein, the proximal end refers to the end close to the operator, and the distal end refers to the end far away from the operator. The term "shape-fixing" refers to the shape or included angle of a structure in a natural structure without external force after an earlier process, for example, the "shape-fixing included angle" refers to the angle naturally formed between a first clamping arm or a second clamping arm without external force. The elastic material is a material which is deformed by the stress of an object and the object restores the original shape after the acting force is removed. The elastic section is elastically deformed under the action of external force, and the pipe section can automatically recover the original shape after the external force is removed.

The utility model has the advantages that:

1) the far ends of the first clamping arm, the second clamping arm and the fixing rod are fixed on the base and are positioned on the same side of the base, so that when the valve clamping device is implanted into a body, the axial length of the valve clamping device is shorter, the occupied space is smaller, the risk of forming thrombus is reduced, and the possibility of damage of the valve clamping device to heart tissues is reduced;

2) the first clamping arm, the second clamping arm, the fixing rod and the base can be integrally arranged, the structure is simpler and more stable, the valve can be captured only by changing the angle of the first clamping arm through the pull wire, the required operation space is smaller, and the requirement of simultaneously capturing the valve on one side or two sides can be met by independently or simultaneously tightening or loosening the pull wire;

3) the delivery system can puncture the interatrial septum after entering the right atrium from the femoral vein and output from the left atrium, so that the existing delivery path is changed, and the surgical trauma is smaller;

4) when valve capture is carried out, the second clamping arm, the base and the fixing ring are positioned in the left ventricle, the first clamping arm is positioned in the left atrium, and during capture, capture of valve tissues can be realized by recovering the shaping angles of the first clamping arm and the second clamping arm, so that the operation range is small, and the risk of damage to chordae tendineae and the top of the left atrium is greatly reduced;

5) conveyer pipe and propelling movement pole can dismantle the connection with solid fixed ring and dead lever respectively, and this connection structure is simple for connection between them is more simple and convenient with the dismantlement.

Drawings

FIG. 1 is a schematic view of a heart anatomy;

in the figure: 1 is superior vena cava, 2 is inferior vena cava, 3 is right atrium, 4 is tricuspid valve, 5 is right ventricle, 6 is pulmonary valve, 7 is pulmonary artery, 8 is pulmonary vein, 9 is left atrium, 10 is mitral valve, 11 is left ventricle, 12 is aortic valve, 13 is aorta, 14 is descending aorta, 15 is oxygenated blood flow direction, 16 is anoxic blood flow direction;

FIG. 2 is a schematic diagram of a surgical mitral valve edge-to-edge suturing technique, wherein 2a is mitral valve closing and 2b is mitral valve opening;

fig. 3a is a schematic front view of a valve clamping device in a released state of a pull wire according to an embodiment of the present invention;

fig. 3b is a schematic side view of the valve clamping device in a released state of the pull wire according to an embodiment of the present invention;

fig. 4a is a schematic front view of a valve clamp according to an embodiment of the present invention in a tightened state of a pull wire;

fig. 4b is a schematic side view of the valve clamping device in a tightened state of the pull wire according to an embodiment of the present invention;

fig. 5a is a schematic front view of a clamping member in a loose state of a pull wire according to an embodiment of the present invention;

fig. 5b is a schematic top view of the clamping member in a released state of the wire according to an embodiment of the present invention;

fig. 6a is a schematic front view of the clamping member in a tightened state of the wire pulling device according to an embodiment of the present invention;

fig. 6b is a schematic side view of the clamping member in a tightened state of the wire pulling device according to an embodiment of the present invention;

fig. 7a is a schematic front view of a fixing ring according to an embodiment of the present invention;

fig. 7b is a schematic side view of a fixing ring according to an embodiment of the present invention;

fig. 8 is a schematic structural view of an adjustable bending sheath according to an embodiment of the present invention;

fig. 9 is a schematic structural view of a dilator according to an embodiment of the present invention;

fig. 10 is a schematic structural view of a loader according to an embodiment of the present invention;

fig. 11a is a schematic view of an overall structure of a conveying pipe according to an embodiment of the present invention;

fig. 11b is an enlarged view of an extension arm of a carrier pipe according to an embodiment of the present invention;

fig. 11c is a schematic view illustrating a state of the push rod inserted into the conveying pipe according to an embodiment of the present invention;

fig. 12a is a schematic structural diagram of a push rod according to an embodiment of the present invention;

fig. 12b is a schematic view of a far-end enlarged structure of a push rod according to an embodiment of the present invention;

FIG. 13 is an assembled schematic view of the adjustable bending sheath, dilator and guidewire;

FIG. 14 is an assembled schematic view of the adjustable bending sheath, the delivery tube and the push rod;

the bending of the structure in fig. 8-14 is merely illustrative to show its flexible nature;

in the figure:

20. a base; 201. an external thread;

30. fixing the rod; 301. a threaded hole;

40. a first clamping arm; 401. clamping teeth; 402. a contact; 403. a pull wire;

50. a second clamping arm; 501. a tooth-shaped structure;

60. a fixing ring; 601. an internal thread; 602. a connecting arm; 603. connecting holes;

701. a straight pipe section; 702. bending section adjustment;

80. a dilator;

90. a guide wire;

100. a loader;

110. a delivery pipe; 1001. an extension arm; 1002. a clamping piece; 1003. a duct; 1004. a clamping block;

120. a push rod; 1201. a threaded boss;

130. a hemostatic valve.

Detailed Description

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In one embodiment of the present invention, the valve clamping system comprises a valve clamp, an adjustable curved catheter sheath, a dilator 80, a loader 100, a delivery tube 110, and a push rod 120; wherein the content of the first and second substances,

as shown in fig. 3a-6b, the valve clamping device comprises a clamping component and a fixing component, the clamping component comprises a base 20, a fixing rod 30, a first clamping component and a second clamping component, the fixing rod 30, the first clamping component and the second clamping component are arranged on the base 20, in this embodiment, the fixing rod 30 is disposed at the center of the proximal side of the base 20, the first clamping member and the second clamping member are located on the same diameter of the proximal side of the base 20, and the first clamping parts and the second clamping parts are respectively arranged symmetrically by taking the fixed rod 30 as a symmetrical center, on one hand, the stability of the fixed rod 30 in the propelling process can be improved, on the other hand, in this embodiment, in order to facilitate the assembly of the valve clamping device, the base 20, the fixing rod 30, the first clamping member and the second clamping member are directly integrated;

the proximal end of the fixation rod 30 has a second attachment structure, which in this embodiment is provided as a threaded bore 301;

the first clamping part is provided with at least two first clamping arms 40, the second clamping part is provided with a corresponding number of second clamping arms 50, each first clamping arm 40 and the corresponding second clamping arm 50 form a group of clamps, the first clamping arms 40 and the second clamping arms 50 are made of elastic materials such as nickel-titanium alloy, a shaping included angle is arranged between the first clamping arms 40 and the second clamping arms 50, and the shaping included angle between the first clamping arms 40 is larger than that between the second clamping arms 50. The proximal ends of the first clamping arm 40 and the second clamping arm 50 are provided with contacts 402 which are matched with each other, and opposite sides of the first clamping arm 40 and the second clamping arm 50 are provided with clamping teeth 401 which are matched with each other, wherein the contacts 402 of the first clamping arm 40 are provided with threading holes in which pull wires 403 are respectively penetrated, and the proximal ends of the pull wires 403 are connected to the outside of the body through the fourth threading holes of the conveying pipe 110, so that the pull wires can be conveniently tightened or loosened outside the body. In addition, a clamping structure is further arranged on the outer side of the second clamping arm 50, and in the embodiment, the clamping structure is a tooth-shaped structure 501;

the base 20 has a first connecting structure, in this embodiment, the first connecting structure is an external thread 201, that is, the external thread 201 is disposed on the circumferential side of the base 20;

as shown in fig. 7a and 7b, the fixing member is detachably connected to the base 20, in this embodiment, the fixing member is configured as a fixing ring 60, the fixing ring 60 is a hollow structure, a third connecting structure is disposed at a proximal end of a hollow inner sidewall of the fixing ring 60, and since the third connecting structure is detachably connected to the first connecting structure, on the premise that the first connection structure is provided with the external thread 201, the third connection structure is provided with the internal thread 601, the internal thread 601 can be matched with the external thread 201 on one hand, so that the base 20 can enter the inner far end of the fixing ring 60 in a spiral mode, as shown in fig. 4a, as the base 20 is screwed in, the second clamping arm 50 also partially enters the fixing ring 60, and at this time, a running-in effect is formed by the tooth-shaped structure 501 and the internal thread 601 outside the second clamping arm 50, so as to prevent the fixing ring 60 from being disengaged after the clamping component is fixed. As shown in fig. 7a and 7b, a fourth connecting structure is disposed at the proximal end of the fixing ring 60, and in this embodiment, the fourth connecting structure is configured as a connecting arm 602 and a connecting hole 603 formed on the connecting arm 602;

the proximal ends of the adjustable bending sheath, dilator 80, delivery tube 110, and shuttle 100 are each provided with a hemostasis valve 130, wherein,

as shown in fig. 8, the adjustable bending catheter sheath further comprises a proximal straight pipe section 701 and a distal bending section 702, and the straight pipe section 701 and the bending section 702 have a continuous first through hole communicating the two ends. The bending adjusting section 702 is a bendable conduit section, and is made of an elastic material, and the bending adjusting principle is as follows: through a traction wire, the one end of this traction wire is fixed in the port department of transferring curved section 702 through the stay wire ring, and the other end is worn out from adjustable curved pipe sheath near-end, through the elasticity operation to the traction wire, realizes adjusting the crookedness of curved section, for example, can refer to the adjustable curved sheath pipe that patent number is 201310397312.6 and have this adjustable curved sheath pipe's conveying system, because of the structure of transferring curved of adjustable curved pipe sheath and operation have been prior art, the utility model discloses in just not explaining too much. The utility model adopts the adjustable bending conduit sheath as the conveying device of the valve clamping device, and the reason is that the conveying direction of the valve clamping device is not consistent with the position of the mitral valve because the valve clamping device is conveyed from the right atrium to the left atrium, and the output direction of the valve clamping device is adjusted to the position of the mitral valve through the adjustment of the bending section 702;

as shown in fig. 9, the dilator 80 is adapted to pass through the first through hole, the axial length of the dilator 80 is greater than that of the adjustable bending catheter sheath, and the dilator 80 has a second through hole communicating with both ends, the inner diameter of the second through hole is adapted to pass through the guide wire 90;

as shown in FIG. 10, the cartridge 100 has a third aperture therethrough adapted to receive the valve clamp and at least a portion of the delivery tube 110, at least a portion of the third aperture having an outer wall sized to enter the first aperture, the cartridge 100 acting as a transfer structure for the valve clamp;

as shown in fig. 11a-11c, the delivery tube 110 is adapted to pass through the first throughbore, the delivery tube further having a flexible section, the axial length of the delivery tube 110 being greater than the total axial length of the adjustable bending catheter sheath and the shuttle 100, and the delivery tube 110 has a fourth through hole communicating both ends, the distal end of the delivery tube 110 and the fourth coupling structure of the proximal end of the fixing ring 60 are detachably coupled, whereas in the present embodiment, the fourth coupling structure is composed of the coupling arm 602 and the coupling hole 603, therefore, the distal end of the delivery tube 110 needs to have a coupling structure adapted to the coupling hole 603, and for this purpose, in this embodiment, at least two extension arms 1001 are disposed at the distal end of the delivery tube 110, and the extension arms 1001 are disposed with latches 1004, so that the number and the positions of the latches 1004 and the connection holes 603 correspond to each other, thereby ensuring that the latches 1004 can be latched into the connection holes 603, and realizing the connection between the delivery tube 110 and the fixing ring 60. Meanwhile, considering that after the conveying pipe 110 conveys the fixing ring 60 to the right position, the connection relationship between the conveying pipe 110 and the fixing ring 60 needs to be released, therefore, on the premise of the aforementioned structure, the extension arm 1001 is made of an elastic material, for example, the elastic material includes nickel-titanium alloy, spring steel, etc., and the extension arm 1001 is shaped as a flaring structure, at least two clamping members 1002 are arranged at the proximal end of the inner side of the extension arm 1001, the two clamping members 1002 are arranged on the inner side walls of the extension arm 1001 in a staggered manner, corresponding hole channels 1003 are arranged on the two clamping members 1002, the hole channels 1003 are used for the push rod 120 to pass through, therefore, the extension arm 1001 is connected with the push rod 120 by means of the clamping members 1002, so that the two extension arms 1001 are kept at a certain distance and the clamping blocks 1004 can be stably clamped in the connecting holes 603, but when the connection relationship between the conveying pipe 110 and the fixing ring 60, so as to remove the connection relationship between the push rod 120 and the delivery pipe 110, the extension arm 1001 recovers the shape of the extension arm, and then the fixture block 1004 is driven to be disengaged from the connection hole 603, thereby realizing the disassembly work;

as shown in fig. 12a and 12b, the push rod 120 also has an elastic section, and the axial length of the push rod is greater than the axial length of the conveying pipe 110, and is suitable for performing axial movement along the fourth through hole, the distal end of the push rod 120 has a fifth connection structure, the push rod 120 is detachably connected with the second connection structure of the fixing rod 30 through the fifth connection structure, and in this embodiment, the second connection structure is a threaded hole 301, so that the fifth connection structure is set as a threaded protrusion 1201, the threaded protrusion 1201 is matched with the threaded hole 301, and the threaded connection and the detachment of the push rod 120 and the threaded hole 301 are achieved in a spiral manner.

In addition, it should be particularly noted that, in this embodiment, for convenience of description, the fixing ring 60 and the delivery tube 110, and the fixing rod 30 and the pushing rod 120 are all connected by threads, but the connection is not limited to threaded connections, for example, the connecting end of the fixing ring 60 and the delivery tube 110, and the connecting end of the fixing rod 30 and the pushing rod 120 are provided with connecting holes, and connecting wires are inserted into the connecting holes, when the connection between the two is required to be maintained, the connecting wires are in a tightened state, when the connection between the two is required to be released, the connecting wires are cut off, or both ends of one of the two connected parts are connected by threads, and both ends of the other connected part are connected by connecting wires, which are specific examples only for the purpose that the two parts can be detached in the heart.

According to the valve clamping system of the embodiment, the following embodiments can be obtained:

1) assembly of push rod 120, delivery tube 110 and loader 100: as shown in fig. 14, the push rod 120 is inserted from the distal end of the delivery tube 110 through the proximal end of the delivery tube 110 into the fourth through hole, and the delivery tube 110 is inserted from the distal end of the delivery tube 110 through the proximal end of the loader 100 into the third through hole;

2) assembly between the base 20 and the fixing ring 60: the threaded connection between the base 20 and the fixing ring 60 is realized by the external thread 201 on the base 20 and the internal thread 601 on the fixing ring 60;

3) assembly between the fixing ring 60 and the delivery tube 110: after the positions of the fixture block 1004 on the extension arm 1001 of the delivery pipe 110 correspond to the positions of the connection hole 603 on the fixing ring 60, the push rod 120 penetrates through the fourth through hole of the delivery pipe 110, and the push rod 120 is ensured to simultaneously penetrate through the through hole 1003 of the clamping piece 1002, so that the extension arm 1001 in the flaring state is restricted by necking, and the fixture block 1004 is just clamped into the connection hole 603;

4) assembling the fixing rod 30 and the pushing rod 120: the pushing rod 120 is continuously pushed along the axial direction of the conveying pipe 110 until the threaded bulge 1201 on the pushing rod 120 is completely screwed into the threaded hole 301 of the fixing rod 30;

5) introducing an adjustable curved catheter sheath into the left atrium: as shown in fig. 13, the distal end of the guide wire 90 is first introduced into the body by using a puncture tool such as a puncture needle, the distal end of the guide wire 90 is continuously introduced into the left atrium, then the puncture needle is removed, the dilator 80 is inserted into the first through hole of the adjustable bending sheath, the proximal end of the guide wire 90 is passed through the second through hole from the distal end of the dilator 80, so that the dilator 80 can introduce the adjustable bending sheath into the left atrium under the guidance of the guide wire 90 (the distal end of the adjustable bending sheath is the adjustable bending section 702, which is made of a flexible material and has low hardness, and cannot be directly passed through the femoral vein, so that the dilator 80 with a conical head and high hardness is required to guide, which is a conventional medical operation), and then the distal end of the guide wire 90 is pulled into the dilator 80, and the guide wire 90 and the dilator 80 are withdrawn from the adjustable;

6) transfer operation of the loader 100: the valve clamping device is completely retracted into the loader 100, the distal end of the loader 100 is inserted into the first through hole of the adjustable bending catheter sheath, and the valve clamping device is pushed into the first through hole of the adjustable bending catheter sheath through the loader 100 (the reason why the valve clamping device is not directly pushed into the adjustable bending catheter sheath is that since the proximal end of the inner side of the adjustable bending catheter sheath is provided with vulnerable components such as the hemostatic valve 130, and the outer side of the second clamping arm 50 is provided with the tooth-shaped structure 501, the tooth-shaped structure 501 easily scratches the hemostatic valve 130 to damage the hemostatic valve 130);

7) delivering a valve clip to the mitral valve and performing capture of valve tissue: the valve clamping device is pushed into the left atrium along the adjustable bending catheter sheath, the bending section 702 of the adjustable bending catheter sheath is operated to bend towards the mitral valve, the delivery pipe 110 and the push rod 120 are bent along with the valve clamping device, the delivery pipe and the push rod are continuously pushed, meanwhile, the pull wire 403 penetrating through the first clamping arm 40 is tightened, the fixing ring 60, the base 20 and the second clamping arm 50 are ensured to enter the left ventricle, at the same time, at least a part of the first clamping arm 40 is positioned in the left atrium, at the same time, the pull wire 403 is loosened (the two pull wires 403 penetrating through the two first clamping arms 40 can be independently tightened or loosened, and can also be simultaneously tightened or loosened), so that the first clamping arm 40 can be in a natural shaping state as the second clamping arm 50, in the embodiment, the clamping angle difference between the shaping included angle between the first clamping arms 40 and the shaping included angle between the second clamping arms 50 is 10 degrees-20 degrees, and then, by means of the matching of the contact 402 and the clamping teeth 401, so that the first and second clamping arms 40 and 50 can better capture valve tissue;

8) further clamping of the captured valve tissue: keeping the current position of the delivery pipe 110 unchanged, keeping the fixing ring 60 connected with the delivery pipe 110 still, continuing to push the push rod 120, pushing the clamping component to the far end of the inner side of the fixing ring 60 under the pushing force of the push rod 120, greatly reducing the included angle between the first clamping arm 40 and the second clamping arm 50 under the action of the ring diameter of the fixing ring 60, greatly increasing the clamping force on valve tissues, and preventing the clamping component and the fixing ring 60 from being disengaged by utilizing the clamping action between the tooth-shaped structure 501 and the internal thread 601 so as to keep the current fixing state;

9) the connection state between the pushing rod 120 and the fixing rod 30 and between the delivery tube 110 and the fixing ring 60 is released: the pushing rod 120 is rotated reversely, the thread lug 1201 of the pushing rod 120 is screwed out of the thread hole 301 of the fixing rod 30 and then retreats out of the delivery pipe 110, meanwhile, after the acting force of the extension arm 1001 on the limiting delivery pipe 110 is removed, the extension arm 1001 immediately restores the flaring structure thereof, then the clamping block 1004 is driven to be separated from the connecting hole 603 of the fixing ring 60, then the delivery pipe 110 and the pushing rod 120 are together retreated from the adjustable bent conduit sheath, and finally the adjustable bent conduit sheath is retreated.

It should be noted that the order of the above-described operational steps is not exclusive, as long as it is feasible according to industry operational standards or common general knowledge.

The foregoing has described in detail preferred embodiments of the present invention. It should be understood that numerous modifications and variations can be devised by those skilled in the art in light of the teachings of the present invention without undue experimentation. Therefore, the technical solutions that can be obtained by a person skilled in the art through logic analysis, reasoning or limited experiments based on the prior art according to the concepts of the present invention should be within the scope of protection defined by the claims.

Claims

1. A valve clip, comprising: comprises a clamping part and a fixing part, wherein the clamping part comprises a base, a fixing rod, a first clamping part and a second clamping part, the base is provided with a first connecting structure, the fixed rod, the first clamping part and the second clamping part are arranged on the base, the proximal end of the fixing rod is provided with a second connecting structure, the first clamping part is provided with at least two first clamping arms, the second clamping part is provided with a corresponding number of second clamping arms, the outer sides of the second clamping arms are provided with clamping structures, each first clamping arm and the corresponding second clamping arm form a group of clamps, the fixed part with the base can be dismantled the connection, the inboard and the near-end of fixed part are provided with third connection structure and fourth connection structure respectively, just third connection structure with first connection structure looks adaptation.

2. The valve clip of claim 1, wherein: the first connection structure is disposed at a circumferential side of the base, and includes an external thread.

3. The valve clip of claim 1, wherein: the fixed rod is arranged at the center of the near end side of the base, the first clamping part and the second clamping part are positioned on the same diameter of the near end side of the base, and the fixed rod is symmetrically arranged between the first clamping part and the second clamping part by taking the fixed rod as a symmetric center.

4. The valve clip of claim 1, wherein: the second attachment structure includes a threaded aperture.

5. The valve clip of claim 1, wherein: the clamping structure comprises a tooth-shaped structure.

6. The valve clip of claim 1, wherein: the first clamping arm and the second clamping arm are made of elastic materials.

7. The valve clip of claim 1, wherein: and a shaping included angle is formed between the first clamping arms and between the second clamping arms, and the shaping included angle between the first clamping arms is larger than that between the second clamping arms.

8. The valve clip of claim 7, wherein: the angle change range of the first clamping arms and the central shaft of the valve clamping device is set to be 0-70 degrees, and the clamping angle difference between the shaping included angle between the first clamping arms and the shaping included angle between the second clamping arms is 10-20 degrees.

9. The valve clip of claim 1, wherein: the first clamping arm and the second clamping arm are 5.0-12.0mm in length and 3-8mm in width.

10. The valve clip of claim 1, wherein: the near ends of the first clamping arm and the second clamping arm are provided with contacts matched with each other, and the opposite sides of the first clamping arm and the second clamping arm are provided with clamping teeth matched with each other.

11. The valve clip of claim 10, wherein: the contact of the first clamping arm is provided with a threading hole, and the threading holes are respectively penetrated with a stay wire.

12. The valve clip of claim 10, wherein: the contact surfaces of the first clamping arm and the second clamping arm are coated with polymer films or polymer materials.

13. The valve clip of claim 1, wherein: the outer surface of the fixed part is coated with a polymer film or a polymer material.

14. The valve clip of claim 1, wherein: the fixed part is including solid fixed ring, gu fixed ring is hollow structure, in gu fixed ring's cavity inside wall near-end sets up third connection structure, third connection structure includes the internal thread, the internal thread with first connection structure threaded connection.

15. The valve clip of claim 1, wherein: the fixing part comprises a fixing ring, the fixing ring is of a hollow structure, a fourth connecting structure is arranged at the near end of the fixing ring, and the fourth connecting structure comprises a connecting arm and a connecting hole formed in the connecting arm.

16. A valve clip according to claim 14 or 15, wherein: the axial length of the fixing ring is 4.0-10.0mm, the inner diameter is 4.0-6.0mm, and the outer diameter is 4.5-7.0 mm.

17. A clamping system for clamping a valve according to any one of claims 1 to 15, characterised in that it further comprises:

the axial length of propelling movement pole is greater than the axial length of conveyer pipe to be suitable for along the fourth through hole carries out axial motion, the distal end of propelling movement pole has fifth connection structure, the propelling movement pole passes through fifth connection structure with the connection can be dismantled to the second connection structure of dead lever.

18. The valve clamping system of claim 17, wherein: hemostatic valves are arranged at the inner proximal ends of the adjustable bending catheter sheath, the dilator, the delivery pipe and the loader.

19. The valve clamping system of claim 17, wherein: the delivery tube and the push rod also have a flexible section that can flex following the bending of the curved section of the catheter sheath.

20. The valve clamping system of claim 17, wherein: the distal end of conveyer pipe sets up two at least extension arms, the extension arm adopts elastic material, just the extension arm is stereotyped for the flaring structure, in the inboard near-end of extension arm is provided with two at least joint spare, two the joint spare stagger set up in on the inside wall that the extension arm is relative, two be provided with corresponding pore on the joint spare.

21. The valve clamping system of claim 20, wherein: the extension arm is further provided with clamping blocks, the quantity and the position of the clamping blocks correspond to those of the fourth connecting structures, and the clamping blocks are detachably connected with the fourth connecting structures.

22. The valve clamping system of claim 17, wherein: the fifth connecting structure comprises a threaded protrusion, and the threaded protrusion is matched with the second connecting structure.