CN202892148U - Support valve and conveying device thereof - Google Patents

Abstract

The utility model discloses a support valve and a conveying device thereof. The support valve comprises a support and a valve leaflet, the support is in an intersected and closed grid structure, the grid structure comprises three sections of grids, a first section of grids, a second section of grids and a third section of grids are sequentially combined to form an integrity, the second section of grids are in a column shape, the first section of grids extend down from the second section of grids to form a horn opening shape, and the third section of grids extend upwards from the second section of grids to form a horn opening shape and sequentially form three top ends with connection holes. A valve seal ring is sewn on the inner sides of the first section of grids and the second section of grids of the support, the valve leaflet is fixed on the second section of grids, and an arc line of the valve leaflet is sewn on the seal ring. According to the support valve and the conveying device of the support valve, the support valve can be rearranged through the conveying device if the position is improper during the arranging process, the support valve can be recovered through the conveying device if the size is improperly selected, difficulties in the operation process are reduced for doctors, and operation successful rate is improved.

Description

A kind of stent valve and conveyer device thereof

Technical field

This utility model relates to medical instruments field, specifically belongs to the intervention therapeutic apparatus field; Relate to the cardiac valve technology, particularly a kind of stent valve and conveyer device thereof.

Background technology

Along with the development trend of China's aging society, old valve degeneration sickness rate constantly increases, and wherein aortic stenosis becomes the modal valvular heart disease of this crowd gradually.To the narrow patient of severe aortic lobe, the surgery aortic valve replacement once was unique treatment means that can extending life, its concrete grammar is to cut the thoracic cavity under general anesthesia, first aorta and the caval vein that connects heart is carried out intubate, sets up the extracorporeal circulation path that connects the heart-lung machine.Make cardiac arrest with special method, then cut heart, the cardiac valve of excision pathological changes, again artificial valve's (mechanical prosthetic valve or bioprosthetic valve) is sewn on the valvular position of original excision, substitute original valvular function with the artificial valve, guarantee the unobstructed of intracardiac blood, prevent that it from backflowing.Make again recovering beat of heart after operation is finished, finish subsequent operation.Surgery prosthetic valve replacement operation wound is large, and patient's recovery time is long, therefore to the gerontal patient often because of a little less than advanced age, the body constitution, pathological changes is heavy or merge Other diseases avoids operation.

The statistics of developed country shows, approximately 1/3 severe aortic stenosis in patients is because operation risk is high or contraindication is arranged and can't accept traditional surgery open chest surgery.High-risk for these or have cardiac surgery operation to avoid patient then can be used as a kind of effective treatment means through conduit aortic valve implantation (Transcatheter Aortic Valve Implantation, TAVI) now.This technology is sent into interposing catheter by femoral artery or other roads through (apex of the heart microtrauma puncture, clavicle tremulous pulse), Cardiac valve prosthesis is delivered to the aortic area opens, and inserts thereby finish the artificial valve, recovers valvular function.Operation need not out breast, thereby wound is little, post-operative recovery is fast.TAVI finishes the implantation of first case percutaneous intervention valve by the Alain Cribier doctor of France the earliest on April 16th, 2002.Recently studies show that, to the narrow patient of inoperable severe aortic lobe, TAVI compares with Drug therapy can reduce case fatality rate 46%, and significantly improves Quality of Life.

Through conduit aortic valve implantation conduct the third pattern after surgery aortic valve replacement, Drug therapy, because it uses the cardiac catheter less invasive techniques, need not out breast, wound is little, operating time is short, the patient recovers the characteristics such as fast, can not prolong its life or alleviate its painful aortic stenosis in patients for those present conventional therapy means, a kind of new solution is provided.But because this technology time of occurrence is shorter, also be faced with more problem at present.

US 2008/0071366 A1 discloses a kind of intervention valve and conveyer device thereof of deciding function with riveting, the lobe frame of this intervention valve adopts the nickel-titanium alloy material laser engraving to make, support at proximal part is designed with several agnails of deciding function with riveting, stent valve can thrust cardiac muscle after placing, prevent that stent valve from being rushed in the aorta vessel by blood when LV Diastolic, support at distal end is designed with three support bars that can block original lobe leaf, prevents that stent valve valve pressurized when left ventricular contraction from slipping into left ventricle.But the maximum shortcoming of this invention be stent valve in case after discharging from induction system, if placement location is undesirable, stent valve can't be reorientated, in practical operation, greatly increased the difficulty of operation.

WO 2006/124649 A2, CN 101623217A patent disclose a kind of eject and have got involved valve, adopt the Nitinol laser engraving to make, the two ends size of support is greater than intermediate sizes, in the middle of valve is fixed on, support can effectively be fixed on the valve annulus, considered on the structural design of simultaneously this invention that stent valve does not discharge fully from conveyer device before, can readjust the position of placement or be contracted in the conveyer device.But the maximum shortcoming of this invention is: owing to the restriction of supporting structure, there is obvious defective in the stress of lobe leaf and support suture site on the one hand, and in the valve running, the lobe leaf is easily torn; Though consider on the other hand recovery, the function of reset of stent valve, but because stent valve does not discharge fully, the kinestate of lobe leaf, adherent performance have a lot of differences with the state that discharges fully, and easy error in judgement in put procedure causes the situations such as position slippage, perivalvular leakage of stent valve.

U.S. Patent No. 6,454,799 disclose a kind of intervention valve of balloon expandable, the lobe frame of this valve adopts rustless steel or the cochrome of plasticity to form by cut, valve is sewn to the inboard, hold device by pressure before implanting the valve pressure is held on the sacculus of conveyer device, by the sacculus pressurization valve is expanded behind the arrival implant site.The problem that this invention faces equally is that in a single day sacculus is opened, and is improper such as placement location, and valve can't be reorientated, and brings very large risk for patient's life.

The utility model content

In view of this, the purpose of this utility model is to provide a kind of stent valve and conveyer device thereof, can realize through conduit mode minimally-invasive treatment aortic stenosis, stent valve position in put procedure is improper can reset by conveyer device, size Selection is improper can be reclaimed by conveyer device, reduce the difficulty of doctor in operation process, improve success rate of operation.

For reaching above-mentioned purpose, this utility model provides a kind of stent valve, comprise: support and lobe leaf, wherein, the close-network lattice structure of described support for intersecting, this network comprises three segment mesh, the first paragraph grid, the second segment grid, the 3rd segment mesh is successively in conjunction with forming an integral body, the second segment grid is column, the horn mouth shape of described first paragraph grid for extending to form downwards from the second segment grid, the 3rd segment mesh is for to extend upward the horn mouth shape of formation and to form successively three with the top of connecting hole from the second segment grid, described support first paragraph grid and second segment grid inboard are sewed with the valve sealing ring, described lobe leaf is fixed on the second segment grid, and the camber line of lobe leaf is sewn on the sealing ring.

Described support first paragraph has nine to 15 grid cells.

Preferably, described support first paragraph has 15 grid cells.

Every the grid top of four grid cells lobe leaf sewing hole is arranged on the grid of described support second segment, per two grids of four grid cells of being cut apart by lobe leaf sewing hole shorten a grid into.

Grid cell between the lobe leaf sewing hole that described support is the 3rd section shortens a grid into, and there is connecting hole on the top of grid, and each connecting hole is connected by connecting rod with adjacent lobe leaf sewing hole.

Described support grid is comprised of cradling piece, and the cradling piece of every segment mesh unit is long, the wide difference of bar.

Preferably, described support first paragraph grid has agnail upwards, and the 3rd segment mesh has downward agnail.

Described timbering material is Nitinol.

Described valve sealing ring is fixed on the support inboard, and the material of sealing ring can be macromolecular material, such as PET, e-PTFE etc., also can be biological tissue, such as bovine pericardium, Cor Sus domestica bag etc.

Described lobe leaf material is the biological tissue that calcification was processed, such as Cor Sus domestica bag, bovine pericardium, Cor Sus domestica lobe etc.

Described lobe leaf has three, is the semilune structure, and lobe leaf both sides are sewed up in twos and are fixed on the lobe leaf sewing hole, and the camber line of lobe leaf is sewn on the valve sealing ring.

The conveyer device of a kind of stent valve that this utility model also provides comprises:

Import head, its distal diameter is less than proximal diameter;

Inner tube, its far-end are connected to an importing near-end and its inside has the thread eye that is through to the importing head;

Push pipe, its far-end is connected with three arc connection tubes, and connecting line is arranged in the tube chamber, and has the inner chamber that can supply inner tube to penetrate;

Outer tube, it has the inner chamber that can accommodate above-mentioned stent valve, and its far-end can insert the hole that imports head from importing a near-end;

Outer tube socket, it is located at proximal outer tube and has and can penetrate to the hole of the inner chamber of outer tube for pushing pipe.

Described outer tube bore is far longer than the diameter that described outer tube bore is used for accommodating the rear end part that pushes pipe for the diameter of the fore-end of accommodating described stent valve.

Described far-end refers in the operating process away from operator's a end herein, near-end depends near operation person's a end

Described propelling movement pipe is multi-cavity structure, and inner tube, three connecting lines are distributed in the different tube chambers, and described propelling movement pipe near-end has helicitic texture.

The in the same size of opening of opening size and three connecting holes of stent valve of three arc connection tubes on the described propelling movement pipe.

Three control pieces are arranged on the described base, be connected respectively with connecting line in three arc connection tubes that push pipe.

In the described base screw thread is arranged, with the threaded engagement that pushes on the pipe, described propelling movement pipe by helicitic texture relatively outer tube seesaw.

As seen from the above technical solution, the utility model has the advantage of, three connecting holes on the described stent valve are connected by connecting line with the connection tube on the described propelling movement pipe, described connecting line links to each other with control piece on the described outer tube socket respectively, by the helicitic texture on the outer tube socket with the stent valve distal outer tube of packing into, after being delivered to diseased region, by the helicitic texture on the outer tube socket stent valve is discharged fully, by the control piece on the base stent valve and conveyer device are broken away from.The profile of the stent valve in this utility model and size and Human left ventricle efferent tract, aortic valve and aortic root anatomical structure match, make support firmly be fixed in left ventricular outflow tract, aortic valvular ring and aorta, do not affect coronary flow and mitral function; The suture way of lobe leaf and support is firm, can effectively avoid the risk that suture is torn in the long-time running of lobe leaf; A kind of conveyer device of stent valve is provided, stent valve is not before breaking away from conveyer device, stent valve is opened fully, but the performances such as the size matching of assessment of stent valve, lobe leaf running status, perivalvular leakage, if placement location is improper, can stent valve be contracted in the conveyer device by conveyer device, the adjustment position reapposes, if size Selection is improper, can cross conveyer device is contracted to stent valve in the conveyer device, stent valve is withdrawn from external, selected suitable size, reappose.

Description of drawings

Fig. 1 is supporting structure expanded view of the present utility model;

Fig. 2 is another kind of supporting structure expanded view of the present utility model;

Fig. 3 a-c is support stitch points partial enlarged drawing of the present utility model;

Fig. 4 is schematic diagram behind the rack forming of the present utility model;

Fig. 5 is schematic diagram behind the another kind of rack forming of the present utility model;

Fig. 6 is lobe impeller structure schematic diagram of the present utility model;

Fig. 7 is that lobe leaf of the present utility model is sewed up schematic diagram;

Fig. 8 is that lobe leaf of the present utility model is sewed up the film schematic diagram;

Fig. 9 is that lobe leaf of the present utility model and lobe leaf are sewed up the film connection diagram;

Figure 10 a-c is that the stitch points of this utility model lobe leaf and support is sewed up schematic diagram;

Figure 11 is that stent valve of the present utility model is opened schematic diagram;

Figure 12 is that stent valve of the present utility model is closed schematic diagram;

Figure 13 is conveyer device schematic diagram of the present utility model;

Figure 14 is conveyer device of the present utility model and stent valve connection diagram;

Figure 15 is pack into schematic diagram behind the conveyer device of stent valve of the present utility model;

Figure 16 is stent valve operation process schematic diagram of the present utility model;

Figure 17 is stent valve dispose procedure schematic diagram of the present utility model;

Figure 18 is the complete release conditions schematic diagram of stent valve of the present utility model.

1, support first paragraph grid 2, support second segment grid 3, support the 3rd segment mesh 4, first paragraph net grid support bar 5, second segment net grid support bar 6, the hole 7 of strip, connecting hole 8, agnail 9 upwards, downward agnail 10, aperture 11, aperture 12, lobe leaf 13, lobe leaf stitching thread 14, valve sealing ring 15, stitching thread 16, seal wire 17, import 18, inner tube 19, connection tube 20, push pipe 21, outer tube 22, ascending aorta 23, left coronary artery mouth 24, right arteria coronaria mouth 25, aortic valve 26, left ventricular outflow tract

The specific embodiment

The utility model discloses a kind of stent valve and conveyer device thereof, can realize through conduit mode minimally-invasive treatment aortic stenosis, stent valve position in put procedure is improper can reset by conveyer device, size Selection is improper can be reclaimed by conveyer device, reduce the difficulty of doctor in operation process, improve success rate of operation.

Below in conjunction with the accompanying drawing among this utility model embodiment, the technical scheme among this utility model embodiment is described particularly, obviously, described embodiment only is this utility model part embodiment, rather than whole embodiment.Based on the embodiment in this utility model, those of ordinary skills are not making the every other embodiment that obtains under the creative work prerequisite, all belong to the scope of this utility model protection.

See also Fig. 1-5, it has provided the holder part of stent valve of the present utility model.Figure 1 shows that the supporting structure expanded view, supporting structure is the network of sealing, is divided into three sections.The cradling piece of each section is long, the wide equal difference of bar, and the grid cell of support first paragraph grid 1 is greater than the grid cell of support second segment grid 2, and the grid cell of support the 3rd segment mesh 3 is greater than the NE of support first paragraph grid 1, support second segment grid 2.The bar of first paragraph net grid support bar 4 is wide large than second segment net grid support bar 5, can provide larger radial support power after making first paragraph grid typing.The grid cell of support second segment grid 2 has lobe leaf sewing hole every the grid top of four grid cells, and per two grids of four grid cells of being cut apart by lobe leaf sewing hole shorten a grid into.The lobe leaf is sewed up pore structure and is consulted Fig. 3 a, Fig. 3 b, Fig. 3 c, Fig. 3 a, Fig. 3 b, Fig. 3 c have provided respectively three kinds of different designs, the structure of Fig. 3 a is the hole 6 of a strip, the design of Fig. 3 b is to have increased respectively several apertures 10 in the both sides in the hole 6 of strip, and the design of Fig. 3 c is the hole 6 that several apertures 11 replace the strip of Fig. 3 a.Grid cell between the 3rd section the lobe leaf sewing hole is concentrated into a grid, and there is connecting hole 7 on the top of grid, and each connecting hole 7 is connected by connecting rod with adjacent lobe leaf sewing hole.

Fig. 2 has provided another kind of scheme of the present utility model, and support first paragraph grid 1 has agnail 8 upwards, and agnail can be to arrange on each grid, also can arrange every several grids; Support the 3rd segment mesh 3 has downward agnail 9.The length of agnail between 1～5mm, 3mm preferably.

The material of support is Nitinol, and Nitinol is a kind of marmem, the plastic deformation of self can be reverted to automatically the special alloy of original-shape under a certain specified temp.Its corrosion resistance is better than at present best medical stainless steel, therefore can satisfy application demand medically, is a kind of very outstanding functional material.Memorial alloy also has the excellent characteristics such as wear-resistant, anticorrosive, high damping and super-elasticity except having unique shape memory function.

The NiTi pipe becomes the network of hollow out through laser engraving, such as Fig. 1 or shown in Figure 2, through techniques such as heat treatment shaping, sandblast, polishings, be made into large, the middle little support in two ends, such as Fig. 4, shown in Figure 5; The grid of the support first paragraph after the typing is the horn mouth shape, and the grid of support second segment is column, and the grid that support is the 3rd section is concentrated into successively three with the top of connecting hole and is the horn mouth shape.According to the anatomical structure of aortic valve and in conjunction with the materialogy characteristics of Nitinol, the diameter at this place because support first paragraph net grid support bar 4 is wider, can provide larger radial support power after the typing between 23～35mm, can effectively strut the valve of calcification, and be fixed on the valve annulus place.The grid of second segment is column, and the lobe leaf is sewn to this position, and according to the size of human aortic valve, the diameter at this place and has preferably radial support power between 20～31mm, can guarantee that the lobe leaf keeps preferably shape in running.Outer horn mouth shape after the 3rd section the grid typing, large than first paragraph, according to the size of ascending aorta, the diameter at this place is between 40～45mm, and the radial support power of this layer is less, can comply with the size of different ascending aortas, reduces the stimulation to blood vessel wall.The height of whole support is between 35～55mm.

Fig. 5 provides is shape after the support typing of this utility model band agnail.

It will be understood by those skilled in the art that, the present embodiment has only been listed two kinds of supporting structures, can adopt similar network about other supporting structures, or with the structure of agnail, as long as guarantee that the network of opening is maximum, the network of straight tube end is minimum to be got final product, and this utility model is not only limited to above-mentioned two kinds of supporting structures.

Fig. 6-9 has provided lobe leaf and valve sealing structure of rings and connected mode thereof.Lobe leaf 12 materials are Cor Sus domestica bag or bovine pericardium, carry out collagen by chemical treatment and fix, and carry out calcification and process, and lobe leaf 12 shapes are seen Fig. 6, are the semilune structure.Three identical lobe leaf 12 both sides are sewed up in twos by lobe leaf stitching thread 13, see Fig. 7.Fig. 8 has provided the shape of valve sealing ring 14, and this shape is consistent with the geometry of support inboard.The camber line of lobe leaf 12 is sewn on the valve sealing ring 14, sees Fig. 9.The tissue of lobe leaf 12 both sides is seen Figure 10 with being connected of lobe leaf sewing hole, the suture way of Figure 10 a, Figure 10 b, the respectively corresponding three kinds of different designs lobe leaf sewing holes of Figure 10 c.After Fig. 9 mesopetalum leaf stitches in twos and is incorporated in lobe leaf 12 sealing rings and sews up lobe leaf 12 both sides are passed the stitch points on the support, be fixed on the support with stitching thread.Below the camber line of lobe leaf 12, valve sealing ring 14 and the bar of each grid of support are sewed up.

Figure 11 is that stent valve is opened schematic diagram, and lobe leaf 12 opens fully, and Figure 12 is that stent valve is closed schematic diagram, and lobe leaf 12 is closed fully.

Figure 13 is the conveyer device schematic diagram, conveyer device mainly is comprised of inner tube 18, propelling movement pipe 20, outer tube 21, the inner tube front end connects soft importing 17, distal diameter is less than proximal diameter, when intravasation, avoid abrading blood vessel wall, the inner tube far-end is connected to an importing near-end and its inside has the thread eye that is through to the importing head, but admittance silk 16; The head end that pushes pipe 20 is connected with and the supporting arc connection tube 19 that is connected of three connecting holes of stent valve, and there is the connecting line of metal these connection tube 19 inside, pushes pipe 20 and has the inner chamber that can supply inner tube to penetrate; Outer tube 21 inner chambers are far longer than the diameter that described outer tube 21 inner chambers are used for accommodating the rear end part that pushes pipe 20 for the diameter of the fore-end of accommodating described stent valve.

Outer tube socket is located at proximal outer tube and is had and can penetrate to the hole of the inner chamber of outer tube for pushing pipe.

Preferably, pushing pipe 20 is multi-cavity structure, and inner tube 18, three connecting lines are distributed in the different tube chambers, and pushing pipe 20 near-ends has helicitic texture.

Preferably, push the in the same size of opening of opening size and three connecting holes 7 of stent valve of three arc connection tubes 19 on the pipe 20.

Three control pieces are arranged on the outer tube socket, be connected respectively with connecting line in three the arc connection tubes 19 that push pipe 20.

Screw thread is arranged in the base, with the threaded engagement that pushes on the pipe, push pipe 20 by helicitic texture relatively outer tube 21 seesaw.

Figure 14 is the connection diagram of stent valve and conveyer device, and the control piece on the operation base is connected the connecting hole 7 on the stent valve respectively with arc connection tube 19.By pushing pipe 20 stent valve is drawn in the outer tube 21, seen Figure 15, stent valve is forced to be shrunk to elongate.

Figure 16 is stent valve operation process schematic diagram, Figure 17 stent valve dispose procedure schematic diagram.

The complete release conditions schematic diagram of Figure 18 stent valve, support first paragraph grid 1 is fixed on left ventricular outflow tract 26, block the aortic valve 25 of pathological changes, stent valve is avoided left coronary artery mouth 23, right arteria coronaria mouth 24, lobe leaf 12 is opened, the closed blood confession that does not affect arteria coronaria, and support the 3rd segment mesh 3 is fixed in ascending aorta 22 blood vessels.The another kind of structure of stent valve, the agnail 8 of support first paragraph grid thrusts left ventricular outflow tract 26, can prevent that when valve is opened blood flow from impacting the next stent valve of stent valve cornice and being shifted to ascending aorta; The agnail 9 of support the 3rd segment mesh, the blood vessel wall of thrusting ascending aorta can be placed blood flow and be impacted the stent valve that stent valve lobe leaf brings and be shifted to left ventricle when valve is closed, thoroughly avoid the perivalvular leakage risk of bringing because of the stent valve displacement.

Embodiment 1

Referring to Figure 16,17, Figure 16 is stent valve operation process schematic diagram, Figure 17 stent valve dispose procedure schematic diagram.Conventional femoral artery puncture, at DSA (Digital subtraction angiography, digital subtraction angiography) guiding is lower, first-selection penetrates seal wire 16 to left ventricle from femoral artery, the conveyer device that stent valve is housed enters aortic valve 25 along seal wire, with 21 recession of conveyer device outer tube, stent valve is opened the narrow aortic valve of rear distraction 25, and fixing behind the location.Running status by the ultrasound detection stent valve, the hydrodynamic performance of blood flow and backflow, the perivalvular leakage situation, meet the requirements such as properties, control piece on the operation base, connecting line in the arc connection tube 19 is separated with the connecting hole 7 of stent valve, realize the disengaging of conveyer device and stent valve, and withdraw from conveyer device, finish operation.

Embodiment 2

After pressing the first releasing bracket valve of method among the embodiment 1, running status by the ultrasound detection stent valve, the hydrodynamic performance of blood flow and backflow, the perivalvular leakage situation, such as stent valve location on the upper side or on the lower side, fail effectively to be fixed on the valvular calcification diseased region, this moment is because the fully disengaging of stent valve and conveyer device, can stent valve be taken in the outer tube 21 by the opposite program of releasing bracket valve, reorientate the placing rack valve, locate suitable rear method of pressing among the embodiment 1 and discharge valve, finish operation.

Embodiment 3

After pressing the first releasing bracket valve of method among the embodiment 1, running status by the ultrasound detection stent valve, the hydrodynamic performance of blood flow and backflowing, the perivalvular leakage situation, less than normal such as the stent valve size Selection, cause the serious perivalvular leakage of stent valve, fail effectively to be fixed on the valvular calcification diseased region, this moment is because the fully disengaging of stent valve and conveyer device, can stent valve be taken in the outer tube 21 by the opposite program of releasing bracket valve, and conveyer device is withdrawn from external, select the stent valve of suitable dimension, reappose stent valve by the method among the embodiment 1, finish operation.

Claims (17)

1. stent valve, comprise: support and lobe leaf, it is characterized in that, the close-network lattice structure of described support for intersecting, this network comprises three segment mesh, the first paragraph grid, the second segment grid, the 3rd segment mesh is successively in conjunction with forming an integral body, the second segment grid is column, the horn mouth shape of described first paragraph grid for extending to form downwards from the second segment grid, the 3rd segment mesh is for to extend upward the horn mouth shape of formation and to form successively three with the top of connecting hole from the second segment grid, described support first paragraph grid and second segment grid inboard are sewed with the valve sealing ring, described lobe leaf is fixed on the second segment grid, and the camber line of lobe leaf is sewn on the sealing ring.

2. stent valve as claimed in claim 1 is characterized in that, described support first paragraph grid has nine to 15 grid cells.

3. stent valve as claimed in claim 2 is characterized in that, described support first paragraph grid has 15 grid cells.

4. stent valve as claimed in claim 3 is characterized in that, every the grid top of four grid cells lobe leaf sewing hole is arranged on the described support second segment grid, and per two grids of four grid cells of being cut apart by lobe leaf sewing hole shorten a grid into.

5. stent valve as claimed in claim 3 is characterized in that, the grid cell between the lobe leaf sewing hole that described support is the 3rd section shortens a grid into, and there is connecting hole on the top of grid, and each connecting hole is connected by connecting rod with adjacent lobe leaf sewing hole.

6. stent valve as claimed in claim 3 is characterized in that, described support grid is comprised of cradling piece, and the cradling piece of every segment mesh is long, the wide difference of bar.

7. stent valve as claimed in claim 3 is characterized in that, the first paragraph grid of described support has agnail upwards, and the 3rd segment mesh has downward agnail.

8. stent valve as claimed in claim 1 is characterized in that, described timbering material is Nitinol.

9. stent valve as claimed in claim 1 is characterized in that, described valve sealing ring is fixed on the support inboard, and the material of sealing ring is macromolecular material or biological tissue.

10. stent valve as claimed in claim 1 is characterized in that, described lobe leaf material is the biological tissue that calcification was processed.

11. stent valve as claimed in claim 10 is characterized in that, described lobe leaf has three, is the semilune structure, and lobe leaf both sides are sewed up in twos and are fixed on the lobe leaf sewing hole, and the camber line of lobe leaf is sewn on the valve sealing ring.

12. a conveyer device that is used for stent valve as claimed in claim 1 is characterized in that, comprising:

Import head, its distal diameter is less than proximal diameter;

Inner tube, its far-end are connected to an importing near-end and its inside has the thread eye that is through to the importing head;

Push pipe, its far-end is connected with three arc connection tubes, and connecting line is arranged in the tube chamber, and has the inner chamber that can supply inner tube to penetrate;

Outer tube, it has can accommodate the as claimed in claim 1 inner chamber of stent valve, and its far-end can insert the hole that imports head from importing a near-end;

Outer tube socket, it is located at proximal outer tube and has and can penetrate to the hole of the inner chamber of outer tube for pushing pipe.

13. conveyer device as claimed in claim 12 is characterized in that, described outer tube bore is far longer than the diameter that described outer tube bore is used for accommodating the rear end part that pushes pipe for the diameter of the fore-end of accommodating described stent valve.

14. conveyer device as claimed in claim 12 is characterized in that, described propelling movement pipe is multi-cavity structure, and inner tube, three connecting lines are distributed in the different tube chambers, and described propelling movement pipe near-end has helicitic texture.

15. conveyer device as claimed in claim 12 is characterized in that, the in the same size of opening of opening size and three connecting holes of stent valve of three arc connection tubes on the described propelling movement pipe.

16. conveyer device as claimed in claim 12 is characterized in that, three control pieces are arranged on the described outer tube socket, is connected respectively with connecting line in three arc connection tubes that push pipe.

17. conveyer device as claimed in claim 12 is characterized in that, in the described outer tube socket screw thread is arranged, with the threaded engagement that pushes on the pipe, described propelling movement pipe by helicitic texture relatively outer tube seesaw.

Images