CN210158738U - A kind of artificial valve delivery catheter and delivery device - Google Patents

Abstract

The utility model provides a conveying catheter and a conveying device for an artificial valve. The conveying catheter includes a first component and a second component. The first component includes a sheath tube that can accommodate the artificial valve, a guide head fixedly connected with one end of the sheath tube, and a The guide head is fixedly connected and is located in the inner core tube of the lumen of the sheath tube; the second assembly includes the outer tube, the inner tube located in the cavity of the outer tube and the fixing head fixedly connected with the inner tube, the inner core tube is arranged on the inner tube of the inner tube In the cavity, the sheath tube or the inner core tube and the fixed head form a circumferential positioning cooperation, so that the inner core tube drives the guide head, the sheath tube and the fixed head to rotate in a coordinated manner as a whole, so as to adjust the circumferential direction of the release of the artificial valve. angle of purpose. Keeping the inner tube and the outer tube stationary, maintaining the three-dimensional configuration required for positioning, and improving the accuracy of the prosthetic valve release positioning. After being adjusted in place, the inner core tube can move axially in the fixed head, thereby driving the guide head and the sheath tube to move axially to achieve the purpose of releasing the artificial valve.

Description

Conveying catheter and conveying device for artificial valve

Technical Field

The utility model relates to the technical field of medical equipment, concretely relates to artificial valve's conveying pipe and conveyor.

Background

With the development of socioeconomic and the aging of population, the incidence rate of valvular heart disease is obviously increased, and researches show that the incidence rate of valvular heart disease of the old people over 75 years old is up to 13.3%. At present, the traditional surgical treatment is still the first treatment method for patients with severe valvular diseases, but for the patients with advanced age, complicated multiple organ diseases, chest-open operation history and poor cardiac function, the traditional surgical treatment has high risk and high death rate, and some patients even have no operation chance. Transcatheter heart valve replacement has the advantages of no need of thoracotomy, small wound, quick recovery of patients and the like, and is widely concerned by experts and scholars.

In heart valve replacement surgery, precise release of the prosthetic valve is required. Due to the complex anatomy of the human body, prosthetic valves are often designed with irregular shapes. For example, to achieve anchoring of the prosthetic valve, it is designed to conform to the shape of the anatomy, and the cross-section of the stent is designed to be D-shaped, polygonal, etc. In order to accurately release the irregular-section prosthetic valve to the anatomical site, a transporter is required to be able to adjust the angle of the prosthetic valve. However, because the delivery paths of the femoral artery and vein are not linear and the final configuration of the delivery device is not on a plane, the conventional delivery system cannot simultaneously realize circumferential rotation and keep the configuration unchanged.

Disclosure of Invention

In view of the above-mentioned shortcomings of the prior art, the present invention provides a delivery catheter and a delivery device for a novel artificial valve, so as to solve the problem that the artificial valve with irregular cross section is difficult to release precisely.

According to one aspect of the present invention, a delivery catheter for a prosthetic valve is provided, comprising a first component and a second component, wherein the first component comprises a sheath tube capable of accommodating a prosthetic valve, a guide head fixedly connected to one end of the sheath tube, and an inner core tube fixedly connected to the guide head and located in a cavity of the sheath tube; the second assembly comprises an outer pipe, an inner pipe located in the cavity of the outer pipe and a fixing head fixedly connected with the inner pipe, the inner core pipe is arranged in the cavity of the inner pipe, and the sheath pipe or the inner core pipe is matched with the fixing head in a circumferential positioning mode.

Further, in the delivery catheter of the artificial valve, the inner wall of the fixing head and the outer wall of the inner core tube form a nested structure.

Further, in the delivery catheter for the artificial valve, the inner wall of the fixing head is provided with the protrusion or the groove, and the outer wall of the inner core tube is provided with the groove or the protrusion matched with the protrusion or the groove of the inner wall of the fixing head.

Further, in the delivery catheter of the artificial valve, the inner wall of the sheath tube and the outer wall of the fixing head form a nested structure.

Further, according to the delivery catheter of the artificial valve, the inner wall of the sheath tube is provided with the protrusion or the groove, and the outer wall of the fixing head is provided with the groove or the protrusion matched with the protrusion or the groove of the inner wall of the sheath tube.

Further, in the delivery catheter for the artificial valve, at least one section of the embedding section is arranged on the outer wall or the inner wall of the fixing head, and the friction force generated between the embedding section and the sheath tube or the inner core tube is larger than the friction force generated between the valve and the sheath tube or the inner core tube.

Further, in the delivery catheter of the artificial valve, the static friction coefficient between the embedding section and the sheath tube or the inner core tube ranges from 0.1 to 1.5.

Further, the delivery catheter of the above artificial valve, the embedding section comprises a first strip unit and a second strip unit, and a first spring and a second spring are connected between the first strip unit and the second strip unit.

Further, the delivery catheter of the artificial valve further comprises a pull wire, and the pull wire is arranged at the connecting position of the first strip-shaped unit and the second strip-shaped unit and the first spring or the second spring.

Further, in the delivery catheter for the artificial valve, the pull wire is positioned between the inner tube and the inner core tube, and the inner tube is a multi-cavity tube.

Further, in the delivery catheter of the artificial valve, the pull wire is positioned in the inner core tube, and the inner core tube is a multi-cavity tube.

Further, in the delivery catheter for the artificial valve, the first strip-shaped unit and the second strip-shaped unit are axially symmetrically distributed on the outer wall or the inner wall of the fixing head.

Further, the fixing head and the inner tube of the delivery catheter of the artificial valve are connected through a bearing or an elastic material.

Further, in the delivery catheter for the artificial valve, the outer tube is a polymer tube or a composite tube of metal and polymer.

Further, the guide head of the delivery catheter of the artificial valve has a streamline outline structure.

According to another aspect of the utility model, a conveyor of artificial valve is provided, including the handle and with the delivery conduit that the handle is connected, the handle includes inner core pipe movable part and fixed connector, inner core pipe movable part and inner core pipe are connected, are used for control the axial or the circumferential motion of inner core pipe, fixed connector and inner tube fixed connection.

Further, in the delivery device for a prosthetic valve, the pull wire is located between the inner tube and the inner core tube and connected to the handle, or the pull wire penetrates through the inner core tube and is connected to the handle.

Compared with the prior art, the utility model discloses prosthetic valve's conveying pipe forms circumference location cooperation between sheath pipe or inner core pipe and the fixed head, can realize that the inner core pipe drives guide head, sheath pipe and fixed head when circumferential direction rotates and wholly do rotation in coordination, has reached the purpose of adjustment prosthetic valve release circumference angle. At the moment, the inner tube and the outer tube are kept still, the three-dimensional configuration required by positioning is maintained, and the accuracy of releasing and positioning the artificial valve is improved. After the artificial valve is adjusted in place, the inner core tube can move axially in the fixing head, so that the guide head and the sheath tube are driven to move axially, and the purpose of releasing the artificial valve is achieved. The utility model provides a prosthetic valve delivery catheter can release the prosthetic valve of irregular cross section in pathological change position accurately, has improved the release precision of the prosthetic valve of irregular cross section.

Drawings

FIG. 1 is a schematic view of a delivery catheter for a prosthetic valve according to an embodiment of the present invention;

fig. 2 is a sectional view of a circumferential fitting structure of a sheath tube or an inner core tube and a fixing head according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of a delivery device for artificial valve according to an embodiment of the present invention;

FIG. 4 is a schematic view of the handle structure according to the embodiment of the present invention;

FIG. 5 is a cross-sectional view of the fixing head and inner core tube nesting structure of the embodiment of the present invention;

fig. 6 is a schematic view of a concave-convex shape matching structure of the fixing head and the inner core tube according to the embodiment of the present invention;

fig. 7 is a cross-sectional view of a nested structure of a sheath tube and a fixed head according to an embodiment of the present invention;

fig. 8 is a schematic view of a concave-convex shape matching structure of the sheath tube and the fixing head according to the embodiment of the present invention;

fig. 9 is a schematic view of a three-dimensional structure of an embedding section arranged on the outer wall of the fixing head in the embodiment of the present invention;

fig. 10 is a schematic view of a structure of the embedded section and the spring in a state where the sheath tube is separated from the fixing head according to the embodiment of the present invention;

fig. 11 is a schematic view of a structure of the embedded section and the spring in a locked state of the sheath tube and the fixing head according to the embodiment of the present invention;

FIG. 12 is a schematic view showing a state of a sheath tube and a fixing head separated from each other when a tension wire is pulled according to an embodiment of the present invention;

FIG. 13 is a schematic view of the locking structure of the sheath and the fixing head when the pulling wire is released according to the embodiment of the present invention;

FIG. 14 is a sectional view of the locking structure of the fixing head and the inner core tube when the pulling wire is tightened according to the embodiment of the present invention;

fig. 15 is a schematic view of a structure of the embedded section and the spring in a locked state of the fixing head and the inner core tube according to the embodiment of the present invention;

FIG. 16 is an enlarged view of the locking structure of the fixing head and the inner core tube in the case of the tension of the wire of FIG. 14;

FIG. 17 is a sectional view of the structure of the embodiment of the present invention showing the separation of the fixing head from the core tube when the pulling wire is released;

fig. 18 is a schematic view of a structure of the embedded section and the spring in a state where the fixing head is separated from the inner core tube according to the embodiment of the present invention;

FIG. 19 is an enlarged view of the structure of FIG. 17 showing the separation of the fixing head from the inner core tube when the pulling wire is released;

FIG. 20 is a schematic view of a loading procedure of a prosthetic valve according to an embodiment of the present invention;

fig. 21 is a schematic structural view illustrating a release process of a prosthetic valve according to an embodiment of the present invention;

fig. 22 is a schematic structural view illustrating a release process of a prosthetic valve according to an embodiment of the present invention;

1-a delivery catheter; 2-a handle; 3-a prosthetic valve; 11-a guide head; 12-sheath tube; 13-an outer tube; 14-a fixed head; 15-inner tube; 16-inner core tube; 21-inner core tube movable parts; 22-fixed connection; 141-an embedding section; 1411-first stripe cells; 1412-second stripe unit; 1421 — first spring; 1422 — second spring; 142-a pull line.

Detailed Description

In order to make the creation features, technical means and achievement objects of the present invention easily understood and appreciated, the present invention will be further described with reference to the following embodiments.

As shown in fig. 1, a delivery catheter for a prosthetic valve provided by an embodiment of the present invention includes a first component and a second component, wherein the first component includes a sheath 12 capable of accommodating a prosthetic valve 3, a guide head 11 fixedly connected to one end of the sheath 12, and an inner core tube 16 fixedly connected to the guide head 11 and located in a cavity of the sheath 12; the second assembly comprises an outer tube 13, an inner tube 15 located in the lumen of the outer tube 13, and a fixing head 14 fixedly connected to the inner tube 15, the inner core tube 16 being arranged in the lumen of the inner tube 15.

Preferably, the sheath tube 12 of the present invention is connected with the guide head 11 in a smooth and fixed manner. The guide head 11 has a streamline shape structure, so that the inner wall of a blood vessel can be prevented from being scratched, and the whole conveying catheter can be guided to advance along a blood vessel channel.

As shown in fig. 2, the sheath tube 12 or the inner core tube 16 of the present invention forms a circumferential positioning fit with the fixing head 14. When the inner core tube 16 moves axially, the guide head 11 and the sheath tube 12 are driven to move axially, so as to load and release the artificial valve. When the inner core tube 16 moves in the circumferential direction, the guide head 11, the sheath tube 12 and the fixing head 14 can be driven to rotate in cooperation with each other, so that the purpose of adjusting the release circumferential angle of the prosthetic valve 3 is achieved. At this point, the inner tube 15 and the outer tube 13 remain stationary to maintain the desired three-dimensional configuration for positioning of the delivery device, improving the accuracy of the release positioning of the prosthetic valve 3.

As shown in fig. 3, the delivery device for a prosthetic valve provided by the embodiment of the present invention includes a handle 2 and a delivery catheter 1 connected to the handle 2. In practice, the present invention will be referred to as distal end in the direction of the delivery catheter 1 and proximal end in the direction of the handle 2.

As shown in fig. 4, the handle 2 of the present invention includes an inner core tube movable part 21 and a fixed connecting part 22, the inner core tube movable part 21 is connected to the inner core tube 16 for controlling the axial or circumferential movement of the inner core tube 16, and the fixed connecting part 23 is fixedly connected to the inner tube 15.

In the concrete implementation, the utility model discloses a 2 drive bearings of handle drive the circumferential direction that drives inner core pipe movable part 21, and then make inner core pipe 16 drive guide head 11, sheath pipe 12 and fixed head 14 wholly do and rotate in coordination, adjust the matching of artificial valve 3 and native valve ring. After the valve prosthesis 3 is adjusted in place, the handle 2 drives the bearing to drive the fixed connecting piece 22 to axially move, so that the inner core tube 16 drives the guide head 11 and the sheath tube 12 to axially move relative to the inner tube 15, and loading and releasing of the valve prosthesis 3 are realized.

Optionally, the embodiment of the present invention provides a handle driving method that can be performed by an electric driving method or a manual driving method.

The embodiment of the utility model provides a, form circumference location complex implementation mode specifically includes following four kinds between sheath pipe 12 or inner core pipe 16 and fixed head 14:

the first embodiment is as follows: as shown in fig. 5 to 6, the inner wall of the fixed head 14 and the outer wall of the inner core tube 16 form a nested structure, which can fix the fixed head 14 and the inner core tube 16 in the circumferential direction. Specifically, the inner wall of the fixed head 14 is provided with a protrusion or a groove (C), and the outer wall of the inner core tube 16 is provided with a groove or a protrusion which is matched with the protrusion or the groove of the inner wall of the fixed head 14.

Alternatively, the shape of the projections or recesses on the inner wall of the fixing head 14 and the outer wall of the inner core tube 16 may be square, triangular, circular, or other irregular patterns. Moreover, the number of the projections or the recesses may be 1 or more.

Alternatively, the plurality of protrusions or grooves may have the same shape or different shapes, and may be uniformly distributed in the circumferential direction of the inner wall of the fixing head 14 and the outer wall of the inner core tube 16, or may be non-uniformly distributed in the circumferential direction of the inner wall of the fixing head 14 and the outer wall of the inner core tube 16. Preferably, the plurality of protrusions or grooves are symmetrically distributed on the inner wall of the fixed head 14 and the outer wall of the inner core tube 16.

Although the concave-convex shape matching between the fixing head 14 and the inner core tube 16 of the embodiment of the present invention can be changed, the outer wall of the inner core tube 16 is made into a convex structure because the wall thickness of the pipe is smaller, which is a more excellent choice.

Example two: as shown in fig. 7 to 8, the inner wall of the sheath 12 and the outer wall of the fixed head 14 form a nested structure, which can fix the sheath 12 and the fixed head 14 in the circumferential direction. Specifically, the inner wall of the sheath tube 12 is provided with a protrusion or a groove (C'), and the outer wall of the fixing head 14 is provided with a groove or a protrusion which is matched with the protrusion or the groove of the inner wall of the sheath tube 12.

Alternatively, the shape of the protrusions or grooves on the inner wall of the sheath 12 and the outer wall of the fixing head 14 may be square, triangular, circular, or other irregular patterns. Moreover, the number of the projections or the recesses may be 1 or more.

Alternatively, the plurality of protrusions or grooves may be in the same shape or different shapes, and may be uniformly distributed on the outer wall of the fixing head 14 and the inner wall of the sheath 12 in the circumferential direction, or may be non-uniformly distributed on the outer wall of the fixing head 14 and the inner wall of the sheath 12 in the circumferential direction. Preferably, the plurality of protrusions or grooves are symmetrically distributed on the outer wall of the fixing head 14 and the inner wall of the sheath 12 in the circumferential direction.

The embodiment of the present invention provides a convex-concave shape matching between the sheath 12 and the fixing head 14, which can be converted, but because the wall thickness of the pipe is smaller, the inner wall of the sheath 12 is made into a convex structure, which is a more excellent choice.

Example three: as shown in fig. 9, the outer wall of the fixing head 14 is provided with at least one insertion section 141. The friction force generated between the embedding section 141 and the sheath 12 is greater than the friction force generated between the valve and the sheath 12, so that the friction force generated between the fixing head 14 and the sheath 12 is greater than the valve releasing force and the recovering force. The sheath 12 and the fixation head 14 are frictionally locked for cooperative rotation in this embodiment.

Specifically, one or more sections of material with high friction coefficient are embedded in the outer wall of the fixing head 14, and the outer diameter of the embedded section 141 can be changed to realize the friction locking and unlocking with the sheath 12.

Preferably, in the above delivery device for a prosthetic valve, the static friction coefficient between the insertion section 141 and the sheath 12 is in the range of 0.1-1.5.

Further, as shown in fig. 10-11, the embedding section 141 of the present invention includes two parts, namely a first strip-shaped unit 1411 and a second strip-shaped unit 1412, and a first spring 1421 and a second spring 1422 are further connected between the first strip-shaped unit 1411 and the second strip-shaped unit 1412.

Further, the embodiment of the present invention further includes a pulling wire 142, wherein the pulling wire 142 is disposed at a connection portion between the first strip unit 1411 and the second strip unit 1412 and the first spring 1421 or the second spring 1422.

In operation, as shown in fig. 10 and 12, when the pulling wire 142 is pulled, the first spring 1421 (or the second spring 1422) is compressed, the two portions of the first strip-shaped unit 1411 and the second strip-shaped unit 1412 of the embedded section 141 are forced to approach each other, and the fixing head 14 is separated from the sheath 12, and the movement of the two is not influenced by each other. As shown in fig. 11 and 13, when the pulling wire 142 is loosened, the two portions of the first strip-shaped unit 1411 and the second strip-shaped unit 1412 of the embedding section 141 are pressed outwards against the sheath 12, and the fixing head 14 and the sheath 12 are locked by the friction force of the embedding section 141 to realize the cooperative rotation.

Preferably, in the delivery device for a prosthetic valve of the present invention, the first strip-shaped unit 1411 and the second strip-shaped unit 1412 are disposed on the outer wall of the fixing head 14 in an axisymmetric distribution, so as to facilitate the connection of the pull wire 142 with all single-sided embedded sections.

Example four: as shown in fig. 14 to 19, the inner wall of the fixing head 14 is provided with at least one section of the insertion section 141, and the friction force generated between the insertion section 141 and the inner core tube 16 is greater than the friction force generated between the valve and the inner core tube 16, so that the friction force generated between the fixing head 14 and the inner core tube 16 is greater than the valve releasing force and the valve recovering force. The fixed head 14 and the inner core tube 16 are locked by friction force to realize cooperative rotation in the embodiment.

Specifically, a section or sections of material with a high coefficient of friction are embedded in the inner wall of the fixing head 14, and the outer diameter of the embedded section 141 can be changed to realize frictional locking and unlocking with the outer wall of the inner core tube 16.

Preferably, in the above delivery device for a prosthetic valve, the static friction coefficient between the insertion section 141 and the inner core tube 16 is in the range of 0.1-1.5.

Further, as shown in fig. 15 and 18, the embedding section 141 of the present invention includes two portions, namely a first strip unit 1411 and a second strip unit 1412, and a first spring 1421 and a second spring 1422 are further connected between the first strip unit 1411 and the second strip unit 1412.

Further, the embodiment of the present invention further includes a pulling wire 142, wherein the pulling wire 142 is disposed at a connection portion between the first strip unit 1411 and the second strip unit 1412 and the first spring 1421 or the second spring 1422.

In practice, as shown in fig. 14-16, when the pulling wire 142 is pulled, the first spring 1421 (or the second spring 1422) is compressed, the two portions of the first strip-shaped element 1411 and the second strip-shaped element 1412 of the insertion section 141 are forced to approach each other, the insertion section 141 of the fixing head 14 abuts against the outer wall of the inner core tube 16, and the fixing head 14 and the inner core tube 16 are locked by the friction force of the insertion section 141 and can move cooperatively. As shown in fig. 17-19, when the pulling wire 142 is released, the two ends of the embedded section 141 are separated by the force of the spring, and the first strip unit 1411 and the second strip unit 1412 are far away from the outer wall of the inner core tube 16, while the movement of the two is not affected.

Preferably, in the delivery device for a prosthetic valve of the present invention, the first strip-shaped unit 1411 and the second strip-shaped unit 1412 are disposed on the inner wall of the fixing head 14 in an axisymmetric distribution, so as to facilitate the connection of the pull wire 142 with all single-sided embedded sections.

Further, in the above delivery device for the artificial valve, the pull wire 142 is located between the inner tube 15 and the inner core tube 16 and connected to the handle 2. In this case, the inner tube 15 is preferably a multi-lumen tube. Alternatively, the pull wire 142 may be connected to the handle 2 through the inner core tube 16. In this case, the inner core tube 16 is preferably a multi-lumen tube.

Preferably, the pull wire 142 may be a single wire or a multi-wire, including but not limited to a single solid wire, a multi-stranded wound metal cord, or the like. In implementation, the utility model discloses axial pulling acts as go-between 142, can adjust the external diameter of embedding section 141.

Optionally, the fixing head 14 and the inner tube 15 are connected by a bearing or an elastic material. The elastic material includes but is not limited to silicone material, PU material, Pebax nylon elastomer engineering polymer, etc. Preferably, the fixed head 14 is connected with the inner tube 15 through a bearing, and circumferential unlimited rotation can be realized. The connection between the fixed head 14 and the inner tube 15 is made by a spring or an elastic material, and the circumferential rotation has a limit angle, which will be determined according to the characteristics of the spring or the elastic material itself.

The embodiment of the utility model provides a drive the axial displacement that bearing drove inner core pipe movable part 21 through handle 2, and then make inner core pipe 16 drive guide head 11 and sheath pipe 12 and do axial displacement for inner tube 15, realize loading and release to artificial valve 3. In addition, the handle 2 drives the bearing to drive the inner core tube movable part 21 to rotate in the circumferential direction, so that the inner core tube 16 drives the guide head 11, the sheath tube 12 and the fixing head 14 to rotate in a coordinated manner, and the release angle of the artificial valve 3 is adjusted to achieve the purpose of accurate release.

Optionally, the outer tube 13 of the present invention may be a polymer tube or a controllable bending tube such as a metal and polymer composite tube. In an embodiment, the outer tube 13 is a polymer composite tube having a metal structure on an inner surface thereof, at least one metal wire is embedded in the outer tube 13, and the bending angle, position, and direction of the outer tube 13 are controlled by drawing different metal wires. Preferably, in order to improve the bending control accuracy, a plurality of metal wires are embedded in the controllable bent pipe.

The embodiment of the utility model provides a prosthetic valve loading process as follows: as shown in fig. 20, the driving handle 2 drives the inner core tube 16 to drive the guiding head 11 and the sheath tube 12 to integrally move to the far end to expose the fixing head 14, then the self-expandable artificial valve 3 is clamped in the fixing head 14, the artificial valve 3 can be stabilized by means of an auxiliary loading tool, after the artificial valve 3 is stabilized, the driving inner core tube 16 moves to the near end until the sheath tube 12 completely covers the artificial valve 3, and the far end face of the artificial valve 3 abuts against the end face of the guiding head 11, so that the artificial valve 3 is completely loaded.

The embodiment of the utility model provides a prosthetic valve delivery process as follows: the whole artificial valve conveying device is stretched into the puncture along the guide wire and enters the human body. The catheter assembly 1 is then passed through the atrial septum following the vascular access of the femoral vein and the sheath 12 is delivered to the diseased annulus.

The embodiment of the utility model provides a prosthetic valve release process as follows: as shown in fig. 21, the bending is controlled by the outer tube 13, and after the outer tube 13 is adjusted to the position, the outer tube 13 is fixed. At this time, the inner core tube 16 is driven by the handle 2 to rotate in the circumferential direction, and the circumferential rotation of the inner core tube 16 can simultaneously drive the guide head 11, the sheath tube 12 and the fixing head 14 to rotate in coordination, so that the relative position of the artificial valve 3 and the native valve annulus is adjusted, and the artificial valve is ensured to be better attached to the native valve annulus. After the artificial valve 3 is circumferentially adjusted to the proper position, the handle 2 drives the inner core tube 16 to drive the guide head 11 and the sheath tube 12 to move towards the far end, and the artificial valve 3 starts to be released until the artificial valve 3 is completely released to the designated position and separated from the conveying system.

Specifically, as shown in fig. 22, during the distal movement of the sheath 12, the inflow channel 32 of the prosthetic valve 3 is released first, and as the sheath 12 moves, the outflow channel 33 of the prosthetic valve 3 is slowly released until the proximal end of the sheath 12 moves to the fixing head 14, exposing the fixing head 14, and the prosthetic valve 3 is completely released.

Preferably, the embodiment of the present invention can suspend the release of the prosthetic valve 3 at any time during the release of the prosthetic valve, and switch to the rotation action of circumferential alignment of the inner core tube 16, so as to better realize the real-time alignment and accurate release of the prosthetic valve 3.

To sum up, the inner core tube 16 of the present invention can drive the sheath 12 and the fixing head 14 to move freely in the circumferential direction, so as to adjust the position of the prosthetic valve 3 with irregular cross section. Meanwhile, the inner core tube 16 can drive the sheath tube 12 to move freely in the axial direction, and the fixing head 14 is kept stationary in the axial direction, so that loading and releasing of the artificial valve 3 are achieved, and the beneficial effects that the inner core tube 16 and the fixing head 14 move in a circumferential direction in a coordinated mode and do not interfere with each other in the axial direction, and the fixing head 14 is fixed by the inner tube 15 in the axial direction and does not interfere with the circumferential direction are achieved.

The embodiment of the utility model provides an at conveyor's overall configuration remain unchanged, curved at outer management and control promptly, under the circumstances that keeps motionless, the artificial valve can circumferential motion to the accurate release problem of irregular cross-section artificial valve has been solved.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (17)

1. A delivery catheter for a prosthetic valve, comprising a first component and a second component, wherein the first component comprises a sheath (12) capable of accommodating a prosthetic valve (3), a guide head (11) fixedly connected with one end of the sheath (12), and an inner core tube (16) fixedly connected with the guide head (11) and positioned in the cavity of the sheath (12); the second assembly comprises an outer pipe (13), an inner pipe (15) located in the cavity of the outer pipe (13) and a fixing head (14) fixedly connected with the inner pipe (15), the inner core pipe (16) is arranged in the cavity of the inner pipe (15), and a circumferential positioning fit is formed between the sheath pipe (12) or the inner core pipe (16) and the fixing head (14).

2. The delivery catheter for prosthetic valves according to claim 1, wherein the inner wall of the fixation head (14) forms a nested structure with the outer wall of the inner core tube (16).

3. The delivery catheter for the artificial valve according to claim 2, wherein the inner wall of the fixing head (14) is provided with a projection or a groove, and the outer wall of the inner core tube (16) is provided with a groove or a projection which is matched with the projection or the groove of the inner wall of the fixing head (14).

4. The delivery catheter for prosthetic valves according to claim 1, wherein the inner wall of the sheath (12) forms a nested structure with the outer wall of the fixation head (14).

5. The delivery catheter for the artificial valve according to claim 4, wherein the inner wall of the sheath (12) is provided with a protrusion or a groove, and the outer wall of the fixing head (14) is provided with a groove or a protrusion which is matched with the protrusion or the groove of the inner wall of the sheath (12).

6. The delivery catheter for the prosthetic valve according to claim 1, wherein the outer wall or the inner wall of the fixing head (14) is provided with at least one section of the embedding section (141), and the friction force generated between the embedding section (141) and the sheath (12) or the inner core tube (16) is larger than the friction force generated between the valve and the sheath (12) or the inner core tube (16).

7. The delivery catheter of the prosthetic valve according to claim 6, wherein the static friction coefficient between the insertion section (141) and the sheath (12) or the inner core tube (16) is in the range of 0.1-1.5.

8. The delivery catheter of the prosthetic valve according to claim 6 or 7, wherein the embedding section (141) comprises a first strip-shaped unit (1411) and a second strip-shaped unit (1412), and a first spring (1421) and a second spring (1422) are connected between the first strip-shaped unit (1411) and the second strip-shaped unit (1412).

9. The delivery catheter of the prosthetic valve according to claim 8, further comprising a pull wire (142), wherein the pull wire (142) is disposed at the connection of the first strip-shaped unit (1411) and the second strip-shaped unit (1412) with the first spring (1421) or the second spring (1422).

10. The delivery catheter of the prosthetic valve according to claim 9, wherein the pull wire (142) is located between an inner tube (15) and an inner core tube (16), the inner tube (15) being a multi-lumen tube.

11. The delivery catheter of the prosthetic valve according to claim 9, wherein the pull wire (142) is located within an inner core tube (16), the inner core tube (16) being a multi-lumen tube.

12. The delivery catheter of the artificial valve, which is characterized in that the first strip-shaped unit (1411) and the second strip-shaped unit (1412) are distributed in an axisymmetric manner on the outer wall or the inner wall of the fixing head (14).

13. The delivery catheter of the prosthetic valve according to claim 1, characterized in that the connection between the fixing head (14) and the inner tube (15) is made by means of a bearing or an elastic material.

14. The delivery catheter of the prosthetic valve according to claim 1, wherein the outer tube (13) is a polymer tube or a composite tube of metal and polymer.

15. The delivery catheter of a prosthetic valve according to claim 1, characterized in that the guiding head (11) has a streamlined profile.

16. A delivery device for a prosthetic valve, comprising a handle (2) and a delivery catheter according to any one of claims 1 to 15 connected to the handle (2), wherein the handle (2) comprises a core tube movable part (21) and a fixed connecting member (22), the core tube movable part (21) is connected to the core tube (16) for controlling the axial or circumferential movement of the core tube (16), and the fixed connecting member (22) is fixedly connected to the inner tube (15).

17. The prosthetic valve delivery device of claim 16, wherein the delivery catheter further comprises a pull wire (142), wherein the pull wire (142) is located between the inner tube (15) and the inner core tube (16) and is connected to the handle (2), or wherein the pull wire (142) is connected to the handle (2) through the inner core tube (16).

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