WO2017121194A1 - Transcatheter aortic valve device having positioning ring - Google Patents

Abstract

A transcatheter aortic valve device (100), comprising: a main support; valve leaflets (104) fixed inside the middle part of the main support; and a skirt (102) that is fixed along the inner periphery of the main support and that is fixed to the valve leaflets (104). An upper flared structure (105) in a three-lobe pattern is formed on the upper end of the main support. Three top circular connection jaws (106) used for loading the main support are provided at the top of the upper flared structure (105). An outwardly-expanding lower flared structure (101) used for reducing paravalvular leak is provided on the lower end of the main support. Three bottom circular connection jaws (110) are provided at the bottom of the lower flared structure (101). The aortic valve device further comprises a positioning ring (103) that is located on the lower side of the main support and that is used for positioning. The positioning ring (103) comprises three V-shaped or U-shaped arc sections. The end portions of the V-shaped or U-shaped arc sections are connected to each other to form a ring, and three circular positioning connection jaws (111) are formed on the end portions. The bottom circular connection jaws (110) are respectively connected to the corresponding circular positioning connection jaws (111) by means of flexible positioning lines (107).

Description

Transcatheter delivery aortic valve device with positioning ring Technical field

The present invention relates to the field of medical devices, and more particularly to a transcatheter delivery aortic valve device having a positioning ring.

Background technique

With the aging of the population, valvular disease caused by senile valvular disease and coronary heart disease and myocardial infarction is also becoming more and more common. Surgical treatment, such as prosthetic heart valve replacement or valvuloplasty, is the cure for valvular heart disease. However, for some patients with advanced age, multiple comorbidities, or history of surgical thoracotomy, the mortality rate of surgical thoracotomy is very high. high. In recent years, with the advancement of interventional techniques, the epoch-making technique of transcatheter prosthetic valves has pushed interventional surgery to the peak of technology and tried to solve all the deficiencies of surgical valve replacement. In 2002, the success of the first transcatheter prosthetic valve replacement surgery marked the beginning of this revolutionary interventional medical technology into a feasible stage. After 10 years of development, more than 100,000 people have rebuilt heart function through this technology. Get a new life.

However, the existing aortic valve device may be released for recovery; or the positioning may be accurate but not recyclable; or the release may be released and the positioning is accurate, but the indication is limited.

Summary of the invention

It is an object of the present invention to provide a transcatheter delivery aortic valve device having a positioning ring for implantation into an in situ subject due to aortic stenosis or regurgitation or regurgitation In the arterial valve, to solve the problem of accurate positioning of the aortic valve device; further, to solve the problems of adapting to various diseases, such as aortic stenosis or regurgitation or reflux or two-valve.

The present invention provides a transcatheter delivery aortic valve device having a positioning ring, the aorta The valve device includes: a main bracket; a leaflet fixed inside the middle portion of the main bracket; and a skirt fixed along the inner periphery of the main bracket and fixed to the leaflet; wherein the upper end of the main bracket Forming an upper bell mouth structure in the form of a three-lobed; at the upper end of the upper bell mouth structure, there are three upper end circular connecting claws for loading the main bracket; the bottom end of the main bracket is used for reducing the leakage of the valve a downwardly flared lower bell mouth structure; the lower bellows structure has three lower end circular connecting claws at a lower end thereof; the aortic valve device further includes a positioning ring for positioning on a lower side of the main bracket The positioning ring includes three V-shaped or U-shaped circular arc segments, and ends of each of the V-shaped or U-shaped circular arc segments are connected to each other to form an annular shape, and three positioning circular connecting claws are formed on the end portions. The lower circular connecting claws and the corresponding positioning circular connecting claws are respectively connected by a flexible positioning line.

Optionally, the main bracket and/or the positioning ring is a Nitinol material; the middle portion is a vertical section, and the lower bell mouth structure has a degree of opening smaller than a degree of opening of the upper bell mouth structure. Further, the lower bell mouth structure is a flat flare structure that is slightly expanded outward. The lower bell mouth structure height is 3mm to 8mm.

Optionally, the main bracket is a grid structure formed by a diamond-shaped grid unit; and an inclination of an end of the upper bell mouth structure and the lower bell mouth structure from the central axis of the main bracket is 1° to 15°.

Optionally, the center of the upper end circular connecting claw is a circular or square through hole or a non-porous shape, and the upper end circular connecting claw and the upper bell mouth structure are connected by a short connecting rod.

Alternatively, the intermediate portion of the main bracket and the upper bell structure of the main bracket are connected to each other by a short link. Preferably, the short link has a length of 1.5 mm to 4 mm and a width of 0.25 mm to 1 mm.

Optionally, a short connecting rod is used between the adjacent grid units of the main bracket connection. The minimum width of the left and right concave short links is 0.25 mm to 0.5 mm.

Optionally, the left and right concave short links are a concave structure formed by two left and right circular arcs or a concave structure formed by a short straight line segment and left and right circular arcs.

Optionally, the middle of the lower end connecting claw is a circular hole or a square hole, and the bottom end of the lower end connecting claw is a concave arc structure; the lower end connecting claw is evenly distributed at the bottom end of the main bracket. .

The middle of the positioning circular connecting claw is a circular hole or a square hole, and the top end of the positioning circular connecting claw is a concave circular arc structure.

Preferably, the concave arc of the bottom end of the lower end circular connecting claw has a radius of 0.3 mm to a radius of 1 mm. The circular arc of the concave end of the positioning circular connecting claw has a radius of 0.3 mm to a radius of 1 mm.

Optionally, the material of the leaflet is pig pericardium, bovine pericardium, horse pericardium or polymer material polytetrafluoroethylene; the material of the skirt is pig pericardium, bovine pericardium, horse pericardium, polymer material polytetrafluoroethylene Ethylene or polyester cloth.

Optionally, the positioning line is a filament material such as a polymer material thread or a nickel-titanium wire such as a general medical suture or a degradable medical suture.

Alternatively, the positioning ring is composed of 3 to 12 V-shaped or U-shaped structural units having a rod width of 0.3 mm to 1 mm, and the positioning ring has a height of 7 mm to 15 mm.

Preferably, the length of the positioning line is increased by 5 mm to 12 mm than the height of the positioning ring.

The invention has the advantages that the loading and recovery of the aortic valve device is achieved by three circular connecting claws arranged at the upper end of the main stent of the aortic valve as a flared structure; the straight horn passing through the bottom end of the main stent The shape of the mouth reduces the leakage of the valve; the positioning of the aortic valve device is achieved by the positioning line and the positioning ring at the lower end of the main stent, so that the surgical procedure is safer and more reliable.

DRAWINGS

Figure 1 is a schematic view showing the unfolded state of an aortic valve device of the present invention;

2 is a schematic view showing the positioning of an aortic valve device of the present invention;

Figure 3 is a schematic view showing the structure of a positioning ring of an aortic valve device of the present invention;

Figure 4 is a schematic illustration of the loading of the aortic valve device of the present invention into a delivery system;

Figure 5 is a schematic illustration of the semi-release of the positioning ring of the aortic valve device of the present invention;

Figure 6 is a schematic view showing the complete release of the positioning ring of the aortic valve device of the present invention;

Figure 7 is a schematic view showing the position of the aortic valve device of the present invention delivered to the heart;

Figure 8 is a schematic view showing the semi-release of the aortic valve device of the present invention in a cardiac position positioning ring;

Figure 9 is a schematic view showing the complete release of the aortic valve device of the present invention at the cardiac position positioning ring;

Figure 10 is a schematic view showing the positioning of the main stent of the aortic valve device of the present invention at the heart position;

Figure 11 is a schematic illustration of the complete release of the aortic valve device of the present invention at the heart position.

detailed description

The present invention provides a transcatheter delivery aortic valve device having a positioning ring for implantation into an in situ aortic valve resulting from aortic stenosis or regurgitation or regurgitation To solve the problem of accurate positioning of the aortic valve device; further, to solve problems that adapt to a variety of conditions, such as aortic stenosis or regurgitation or reflux or two-valve.

The embodiments of the present invention are further described in detail below with reference to the accompanying drawings.

An aortic valve device 100, as shown in Figures 1 through 3, for implantation into an orthotopic aortic valve resulting from a lesion of the aortic stenosis or regurgitation, the aortic valve device comprising a main bracket; a leaflet 104 fixed inside the intermediate portion of the main bracket; and a skirt 102 fixed along the inner periphery of the main bracket and fixed to the leaflet 104; further, the skirt 102 is along the main bracket surrounding In a circle, and sutured with sutures; the leaflets 104 are three pieces, which are sewn in the middle part of the main frame and fixedly stitched with the skirt 102.

Referring to FIG. 1, the upper end of the main bracket forms an upper bell mouth structure 105 in the form of three lobes; at the upper end of the upper bell mouth structure 105, there are three upper end circular connecting claws 106 for loading the main bracket, It may be hollow or solid; the bottom end of the main bracket has an outwardly flared lower bell structure 101 for reducing the leakage of the valve; the lower end of the lower bell structure 101 has three lower end circular connecting claws 110; The aortic valve device further includes a positioning ring 103 for positioning on a lower side of the main bracket, the positioning ring 103 including three V-shaped or U-shaped arc segments, each of the V-shaped or U-shaped arcs The ends of the segments are connected to each other to form an annular shape, and three positioning circular connecting claws 111 are formed on the end portions; the lower circular connecting claws 110 and the corresponding positioning circular connecting claws 111 respectively pass through flexible positioning lines 107 connections.

The main bracket and the positioning ring 103 may be a Nitinol material; the middle portion is a vertical section, and the opening of the lower bell mouth structure 101 is smaller than the opening degree of the upper bell mouth structure 105. Further, the lower bell mouth structure 101 is an outwardly slightly expanded flat bell structure. The lower bell mouth structure 101 has a height of 3 mm to 8 mm.

The main bracket may be a grid structure formed by a diamond-shaped grid unit; and the inclinations of the ends of the upper bell mouth structure 105 and the lower bell mouth structure 101 deviating from the central axis of the main bracket are respectively 1° to 15 °. The middle portion of the main bracket smoothly transitions with the lower bell mouth structure 101 and the upper bell mouth structure 105.

The center of the upper end circular connecting claw 106 is a circular or square through hole or a non-porous shape, and the upper end circular connecting claw 106 and the upper bell mouth structure 105 are connected by a short link.

Referring to FIG. 2, the middle portion of the main bracket and the upper bell mouth structure 105 of the main bracket pass The short links 108 are connected to each other. Preferably, the short link has a length of 1.5 mm to 4 mm and a width of 0.25 mm to 1 mm.

A short link connection 109 that is concave in the left and right may be used between adjacent grid cells of the main bracket. The minimum width of the left and right concave short links is 0.25 mm to 0.5 mm.

The left and right concave short links may be a concave structure formed by two left and right circular arcs or a concave structure formed by adding a small straight line segment and a left and right circular arc.

The middle of the lower end connecting claw 110 may be a circular hole or a square hole, and the bottom end of the lower end circular connecting claw 110 is a concave arc structure; the lower end circular connecting claw 110 is evenly distributed at the bottom end of the main bracket. .

The middle of the positioning circular connecting claw 111 is a circular hole or a square hole, and the top end of the positioning circular connecting claw 111 has a concave circular arc structure 112 (see FIG. 3).

The circular arc of the bottom end of the lower end circular connecting claw 110 has a radius of 0.3 mm to a radius of 1 mm. The circular arc of the top end of the positioning circular connecting claw 111 has a radius of 0.3 mm to a radius of 1 mm.

The material of the leaflet may be a pig pericardium, a bovine pericardium, a horse pericardium or a polymer material polytetrafluoroethylene; the material of the skirt is pig pericard, bovine pericardium, horse pericard, polymer material polytetrafluoroethylene or polyester cloth.

The positioning line 107 may be a filament of a polymer material such as a general medical suture or a degradable medical suture or a nickel wire.

In addition, the positioning ring 103 may also be composed of 3 to 12 V-shaped or U-shaped structural units having a rod width of 0.3 mm to 1 mm, and the positioning ring 103 has a height of 7 mm to 15 mm.

The length of the positioning line 107 may be increased by 5 mm to 12 mm than the height of the positioning ring 103.

In addition, the middle portion of the upper bell mouth structure 105 may be expanded in a diamond shape, and the upper bell mouth structure 105 is evenly distributed around the main bracket.

Transcatheter delivery aortic valve device with positioning ring according to an embodiment of the invention The process is as follows:

The aortic valve device 100 (including the main stent and the positioning ring 103) is first loaded into the loading sheath 202 of the delivery system 200 by a certain device (refer to FIG. 4), and the delivery system 200 includes a head end 201, loading The sheath 202 and the handle 203 and the like. The delivery system 200 is delivered to the human lesion site by intervention (see Figure 7). The loading sheath 202 of the delivery system 200 is then moved back to the fixed position by the handle 203, and the positioning ring 103 of the aortic valve device 100 is released halfway (please refer to Figures 5 and 8), at this time The shape and memory characteristics of the aortic valve device 100, the positioning ring 103 automatically expands to form a bell mouth shape (please refer to FIG. 5 and FIG. 8), and then slowly pushes the delivery system 200 toward the ventricle, so that the positioning ring 103 contacts the human body naturally. At the bottom of the leaflet tissue 300, the push delivery system 200 is stopped. The loading sheath 202 of the delivery system 200 is again moved back to the fixed position by the handle 203, so that the positioning ring 103 is completely released from the loading sheath 202, at which time the positioning ring 103 is fully automatically expanded to the maximum size due to the material shape memory property. (Please refer to Figures 6 and 9). Continue to push the delivery system 200 toward the ventricle so that the loading sheath 202 passes over the human natural leaflet tissue 300 until the positioning line 107 is in a taut state, and the delivery system 200 is also in a limit state (refer to Figure 10), and then through the handle 203 slowly moves the loading sheath 202 rearwardly such that the lower bellows structure 101 of the main stent is slowly released from the loading sheath 202 of the delivery system 200, due to the material shape memory characteristics of the aortic valve device 100, the lower bell mouth The structure 101 automatically expands to the maximum, and the human natural leaflet tissue 300 is opened. At this time, the human natural leaflet tissue 300 is between the lower bell structure 101 and the positioning ring 103 of the aortic valve device 100 (refer to the figure). 11) The aortic valve device 100 performs precise positioning. The loading sheath 202 is again moved rearwardly by the handle 203 of the delivery system 200, releasing the upper flare structure 105 and the upper circular connecting jaw 106 of the aortic valve device 100 from the loading sheath 202, as described Aortic valve device 100 The shape memory characteristic of the material, the upper bell mouth structure 105 automatically expands to the maximum, and is fixed to the blood vessel wall (refer to FIG. 11), the conveying system 200 and the upper end circular connecting claw 106, and finally the delivery system 200 is withdrawn, the main The anastomotic valve device 100 is implanted.

The above embodiments are merely illustrative of the present invention and are not intended to be limiting of the invention, and various modifications and changes can be made without departing from the spirit and scope of the invention. Equivalent technical solutions are also within the scope of the invention, and the scope of the invention is defined by the claims.

Claims (10)

A transcatheter delivery aortic valve device having a positioning ring, the aortic valve device comprising: a main stent; a leaflet fixed to an inner side of the intermediate portion of the main stent; and fixed along an inner periphery of the main stent And a skirt fixed to the leaflet; characterized in that: the upper end of the main bracket forms an upper bell mouth structure in the form of three petals; and the upper end of the upper bell mouth structure has three loadings for the main bracket Upper end circular connecting claw; the bottom end of the main bracket has an outwardly flared lower bell structure for reducing the leakage of the valve; the lower end of the lower bell structure has three lower end connecting claws; the aorta The valve device further includes a positioning ring for positioning on a lower side of the main bracket, the positioning ring including three V-shaped or U-shaped arc segments, ends of each of the V-shaped or U-shaped arc segments Connected to each other to form an annular shape, and three positioning circular connecting claws are formed on the end portion; the lower circular connecting claws and the corresponding positioning circular connecting claws are respectively connected by a flexible positioning line. The aortic valve device according to claim 1, wherein the main bracket and/or the positioning ring are made of a nickel-titanium alloy material; the intermediate portion is a vertical section, and the opening of the lower bell mouth structure The extent is less than the degree of opening of the upper bell mouth structure. The aortic valve device according to claim 1, wherein the main support is a mesh structure formed by a diamond-shaped mesh unit; and the ends of the upper bell structure and the lower bell structure are deviated The inclination angle of the central axis of the main bracket is 1° to 15°, respectively. The aortic valve device according to claim 1, wherein the center of the upper end circular connecting claw is a circular or square through hole or a non-porous shape, and the upper end circular connecting claw and the upper bell mouth structure Connected by a short link. The aortic valve device according to claim 1, wherein the intermediate portion of the main bracket and the upper bell structure of the main bracket are connected to each other by a short link. The aortic valve device according to claim 3, wherein adjacent grid members of said main stent are connected by short and left concave links. The aortic valve device according to claim 6, wherein the left and right concave short links are concave structures formed by two left and right circular arcs or a small straight segment formed by left and right circular arcs. structure. The aortic valve device according to claim 1, wherein the middle of the lower circular connecting claw is a circular hole or a square hole, and the bottom end of the lower circular connecting claw is a concave circular arc structure. ; The middle of the positioning circular connecting claw is a circular hole or a square hole, and the top end of the positioning circular connecting claw is a concave circular arc structure. The aortic valve device according to claim 1, wherein the material of the leaflet is a pig pericardium, a bovine pericardium, a horse pericardium or a polymer material polytetrafluoroethylene; and the material of the skirt is a pig pericardium. , bovine pericardium, horse heart bag, polymer material PTFE or polyester cloth. The aortic valve device according to claim 1, wherein the positioning line is a polymer material thread or a nickel titanium wire material.

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