CN211534995U - Plug protection device - Google Patents

Abstract

The utility model provides a plug protection device, which comprises a plug deflector and a pushing pipe, wherein the plug deflector comprises a first support frame and a first filter element arranged on the first support frame; the pushing tube comprises a tube body, and the tube body is connected with the embolus deflector and used for pushing, positioning and adjusting the embolus deflector; the body still includes the sea wave cutting structure of setting at the distal end. The utility model discloses a propelling movement pipe makes the embolus deflector of protection upstream blood vessel have good adherence performance, the body is still including setting up the sea wave cutting structure at the distal end department for the propelling movement pipe is moulding by inside seal wire, thereby realizes self-adaptation patient's aortic arch anatomical structure's performance, and then can make embolus deflector have better adherence.

Description

Plug protection device

Technical Field

The utility model relates to the technical field of medical equipment, in particular to an embolism protection device for preventing vascular embolism in an operation process.

Background

During cardiac or aortic surgery, such as cardiac surgery, cardiopulmonary bypass, catheter-based interventional cardiology, and ascending aorta, platelet polymers such as thrombi, lipid droplets, bacterial clots, tumor cells, and embolic material such as atherosclerotic debris broken off of the artery wall can be generated. These substances, when introduced into the brain with blood, block small arteries, leading to local cerebral vascular embolization, which has become a significant complication of cardiac and aortic surgery. At the same time, embolic material entering the downstream blood circulation can also cause embolization of downstream organs, thereby causing the function of the downstream organs to decline and even fail.

Taking TAVR (transcatheter aortic valve replacement) surgery as an example, out of 10 patients undergoing the surgery, 1 results in clinically significant stroke due to the surgery, with most of the stroke occurring during the surgery or within 72 hours of the surgery. It has been found that the reason for this may be cerebral vascular embolism caused by loose debris on the heart valve or aortic wall migrating to the brain.

In order to prevent complications from embolic material, embolic protection devices are often used during surgery. Embolic protection devices benefit the patient by diverting or collecting embolic material, such as plaque, debris, or thrombus, that flows anteriorly to prevent the embolic material from entering the brain, thereby preventing the formation of a vascular embolism. However, the existing anti-embolism protection device has the problems of complex instrument operation, poor adherence of the instrument, escape of embolus and the like.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a embolism protection device to solve the whole poor scheduling problem of adherence of embolism protection device.

In order to solve the technical problem, the utility model provides a plug protection device, include:

an embolic deflector comprising a first support frame and a first filter element disposed on the first support frame;

a pushing tube comprising a tube body connected to the embolic deflector for pushing, positioning and adjusting the embolic deflector; the body still includes the sea wave cutting structure of setting at the distal end.

Optionally, the push tube further comprises a first connection portion disposed on the tube body, and the tube body is connected to the embolus deflector through the first connection portion.

Optionally, the first connection portion has a through hole through which the proximal end of the first support frame or the first filter element passes to enable connection of the embolus deflecting device with the push tube.

Further, the through hole penetrates through the pipe body along a direction perpendicular to the axial direction of the pipe body.

Further, the first connecting portion comprises a first tubular structure, a first connecting rod and a second tubular structure which are sequentially arranged along the direction from the far end to the near end of the tube body, the first tubular structure and the second tubular structure are coaxially arranged with the tube body and sleeved on the tube body, and the first tubular structure and the second tubular structure are connected through the first connecting rod.

Furthermore, the first connecting rod is in an arched long strip shape and arched towards the direction far away from the pipe body, so that the through hole is formed between the first connecting rod and the pipe body.

Further, first connecting portion include along third tubular structure, second connecting rod and the fourth tubular structure that the distal end to the near-end direction of body arranged in proper order, the fourth tubular structure with the body is coaxial to be set up and the cover is established on the body, third tubular structure and fourth tubular structure pass through the second connecting rod is connected, and the axial of third tubular structure is perpendicular to the axial of body, the inner chamber of third tubular structure forms the through-hole.

Optionally, the length of the cutting structure along the axial direction of the pipe body is between 80mm and 350 mm.

Optionally, the sea wave cutting structure includes a plurality of cutting units, a plurality of cutting units are followed the axial of body is the heliciform and arranges.

Optionally, the sea wave cutting structure includes a plurality of cutting portions arranged at intervals along an axial direction of the pipe body, and each cutting portion includes at least one cutting unit arranged at intervals along a circumferential direction of the pipe body.

Optionally, the sea wave cutting structure includes a plurality of cutting portions arranged at intervals along a circumferential direction of the pipe body, and each cutting portion includes at least one cutting unit arranged at intervals along an axial direction of the pipe body.

Further, the cutting unit comprises at least one groove.

Further, the groove comprises at least one annular groove located at the end part and a strip-shaped groove connected with the annular groove.

Further, the strip-shaped groove comprises at least one V-shaped structure, and the annular groove is communicated with the strip-shaped groove.

Further, the pushing pipe is provided with an inner cavity, the inner cavity penetrates through the pushing pipe along the extending direction of the pushing pipe, and the groove penetrates through the outer part of the pipe body and the inner cavity.

Further, the cutting unit comprises at least two grooves which are arranged at intervals along the extending direction of the cutting unit.

Further, the extending direction of the cutting unit and the axial direction of the pipe body form an included angle of 60-90 degrees.

Further, the ratio of the length of the cutting unit extending along the outer surface of the pipe body to the circumferential length of the outer surface of the pipe body is between 0.08 and 0.90.

Optionally, the embolic protection device further comprises an embolic collector comprising a second support frame and a second filter element attached to the second support frame; the push tube further comprises a second connecting portion disposed on the tube body, the second connecting portion being disposed between the first connecting portion and the proximal end of the tube body; the embolus collector is connected with the pushing pipe through the second connecting part.

Further, the second connecting portion include the recess that encircles the circumference of body, embolus collector cover is established recess department, in order to realize with the connection of propelling movement pipe.

Optionally, the pushing tube has a uniform diameter structure with a uniform outer diameter from the proximal end to the distal end, or the pushing tube has a diameter-variable structure with a thick proximal end and a thin distal end.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model provides a plug protection device, which comprises a plug deflector and a pushing pipe, wherein the plug deflector comprises a first support frame and a first filter element arranged on the first support frame; the pushing pipe comprises a pipe body, the pipe body is connected with the embolus deflector, and the pushing pipe is used for pushing, positioning and adjusting the embolus deflector; the tube body further includes a sea wave cutting structure disposed at the distal end. The utility model discloses a propelling movement pipe makes the embolus deflector of protection upstream blood vessel have good adherence performance, the body is still including setting up the sea wave cutting structure at the distal end department for the propelling movement pipe is moulding by inside seal wire, thereby realizes self-adaptation patient's aortic arch anatomical structure's performance, and then can make embolus deflector have better adherence. The push tube further includes a first connector having a through hole through which the proximal end of the first support frame or the first filter element passes to enable connection of the embolic deflection device to the push tube. First connecting portion make the propelling movement pipe obtain better propelling movement power and control power for embolic protection device obtains better degree of freedom, and this embolic protection device design is simple, and is multiple functional, the simple operation.

Drawings

FIG. 1 is a schematic view of a blood vessel at the aortic arch;

FIG. 2 is a schematic diagram of an embolic protection device according to an embodiment of the present invention;

fig. 3 is a schematic view of the placement of an embolic protection device according to an embodiment of the present invention at the aortic arch of fig. 1;

fig. 4a-4c are schematic structural views of a second supporting frame according to an embodiment of the present invention;

fig. 5a to 5e are schematic structural views of a tube according to an embodiment of the present invention;

fig. 6a to 6e are schematic structural views of a connecting portion according to an embodiment of the present invention.

Description of reference numerals:

11-ascending aorta; 12-descending aorta; 13-aortic arch;

21-brachiocephalic trunk artery; 22-left common carotid artery; 23-left subclavian artery;

100-an embolic deflector; 110-a first support frame; 120-a first filter element;

200-an embolus collector; 210-a second support frame; 220-a second filter element;

300-pushing the pipe; 310-a tube body; 310 a-a cutting section; 311-a cutting unit; 320-a first connection; 321-a through hole; 322-a first tubular structure; 323-a second tubular structure; 324-a first connecting rod; 325-a third tubular structure; 326-a fourth tubular structure; 327-a second connecting rod;

400-a delivery sheath;

500-guide.

Detailed Description

A embolic protection device of the present invention will be described in further detail below. The present invention will now be described in more detail with reference to the accompanying drawings, in which preferred embodiments of the invention are shown, it being understood that those skilled in the art may modify the invention herein described while still achieving the beneficial results of the invention. Accordingly, the following description should be construed as broadly as possible to those skilled in the art and not as limiting the invention.

In the interest of clarity, not all features of an actual implementation are described. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. It will of course be appreciated that in the development of any such actual embodiment, numerous implementation-specific details must be set forth in order to achieve the developer's specific goals, such as compliance with system-related and business-related constraints, which will vary from one implementation to another. Moreover, it will be appreciated that such a development effort might be complex and time-consuming, but would nevertheless be a routine undertaking for those of ordinary skill in the art.

In order to make the objects and features of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings. It is to be noted that the drawings are in a very simplified form and are not to be construed as precise ratios as are merely intended to facilitate and distinctly illustrate the embodiments of the present invention.

Herein, the terms "distal" and "proximal" are all relative orientations, relative positions, and directions of elements or actions with respect to one another from the perspective of a clinician using the medical device, and although "distal" and "proximal" are not intended to be limiting, distal generally refers to the end of the medical device that is first introduced into a patient, and proximal generally refers to the end of the medical device that is closer to the clinician during normal operation. The term "or" is generally employed in its sense including "and/or" unless the content clearly dictates otherwise. The terms "inner", "outer", and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Fig. 1 is a schematic view of a blood vessel at the aortic arch. As shown in fig. 1, the embolic protection device provided in this embodiment can be placed in ascending aorta 11, aortic arch 13 and/or descending aorta 12 before or during a transcatheter operation that may generate embolic material, and plays a role in filtering the ascending blood flow of the side branch vessels, i.e. brachiocephalic trunk artery 21, left common carotid artery 22 and left subclavian artery 23, and the blood flow of the downstream vessels, so as to prevent the embolic material generated during the operation from entering the brain and the downstream vessels, thereby avoiding stroke and downstream organs, causing sequelae such as acute kidney injury. The embolic protection device is accessed, for example, through a femoral artery path, which can reduce the access path of the operation, thereby reducing the complexity of the operation.

Fig. 2 is a schematic structural view of the embolic protection device of the present embodiment. As shown in fig. 2, the embolic protection device can include an embolic deflector 100, an embolic collector 200, a pusher tube 300, and a delivery sheath 400. The embolus deflector 100 is connected to the embolus collector 200 and a delivery sheath 400 via the pushing tube 300, wherein the delivery sheath 400 is connected to the side of the embolus collector 200 remote from the embolus deflector 100 for accommodating the embolus deflector 100, embolus collector 200 and pushing tube 300 after compression. The pushing tube 300 is used for pushing, positioning and adjusting the embolus deflector 100 and the embolus collector 200, and particularly, the proximal end of the pushing tube 300 enables the embolus deflector 100 and the embolus collector 200 to be released or recovered.

Fig. 3 is a schematic view illustrating the placement of the embolic protection device of the present embodiment at the aortic arch of fig. 1. As shown in fig. 3, the embolic protection device is located between the proximal end of the ascending aorta and the distal end of the descending aorta so that it fits on the arch wall of the aortic arch, and specifically, the embolic deflector 100 is placed at the aortic arch to filter the ascending blood flow of the brachiocephalic trunk artery 21, the left common carotid artery 22 and the left subclavian artery 23, so as to prevent the thrombus generated during the operation from entering the brain and to avoid stroke; the embolus collector 200 is positioned between the aortic arch and the distal end of the descending aorta 12, and plays a role in filtering blood flow of downstream blood vessels, so as to prevent sequela such as acute kidney injury and the like caused by embolus substances generated in the operation process from entering downstream organs.

With continued reference to fig. 2, the embolic deflector 100 can comprise a first support frame 110 and a first filter element 120. The push tube 300 is shaped against the first support frame 110 and the first filter element 120 under the shape of the guide wire to improve adherence of the embolic deflector 100, thereby reducing interference of the embolic deflector 100 with subsequent medical devices.

The first support frame 110 serves to support the first filter element 120 and defines a circumferential coverage area of the first filter element 120 such that the vascular ostium area of a side branch vessel at the aortic arch can be covered. The first support frame 110 may be woven by wires or cut. The first support frame 110 may be a circumferentially closed ring-shaped structure. In this embodiment, the first support frame 110 may be a three-dimensional structure, such as an arch structure, that is, the surface defined by the first support frame 110 is an arc surface. The first support frame 110 has a three-dimensional arch structure, so that the first filter element 120 attached to the first support frame can be more attached to the inner wall of the blood vessel at the aortic arch, and embolic material is prevented from being missed. In other embodiments, the first support frame 110 may also be a planar structure, i.e., the plane defined by the first support frame 110 is a plane. The first support frame 110 may have a polygonal, elliptical, or elliptical-like structure. The first support frame 110 may have a symmetrical structure or an asymmetrical structure. In this embodiment, the first supporting frame 110 has an oval structure, and the oval structure has the characteristics of good elasticity and easy compression.

The first filter element 120 may be a first filter net attached to the first support frame 110 for filtering embolic materials, such as thrombus, etc., in blood flowing through the first filter element 120. In particular, the first filter element 120 may wrap around the first support frame 110 to filter thrombus from blood flowing through the embolic deflector 100. The first filter element 120 may be a three-dimensional structure, such as an arch structure, i.e. the face of the first filter element 120 is a curved face. The first filter element 120 adopts a three-dimensional arch structure, and can be more attached to the inner wall of the blood vessel at the aortic arch, so as to avoid missing embolic materials. In other embodiments, the first filter element 120 may also be a planar structure, i.e., the surface of the first filter element 120 is a plane. The first filter element 120 may be attached to the first support frame 110 on one or both sides, wherein the perimeter of the first filter element 120 is attached to the first support frame 110. The first filter element 120 attached to the first support frame 110 at one side may have a smaller pore size than the first filter element 120 attached to the first support frame 110 at both sides. The mesh pore size of the first filter element 120 may be 60 μm to 250 μm, and the mesh open area of the entire first filter element 120 may occupy 40% to 70% of the total area of the first filter element 120, so that it can both block the passage of emboli and ensure that the blood flow rate is not affected. The first filter element 120 may be made of a biocompatible material such as nickel-titanium wire, polymer, inorganic nonmetal, or the like, and may be woven or pre-processed into a membrane and perforated. The first filter element 120 may be an elastic first filter element or a non-elastic first filter element.

Optionally, the first filter element 120 may be covered with a coating layer, which may be heparin, anticoagulant, etc., to prevent thrombus from accumulating to block the mesh of the first filter element 120 during the operation; alternatively, the first filter element 120 may be made of a material having an anticoagulant such as an antithrombotic drug.

The embolus collector 200 is positioned between the proximal end of the aortic arch and the proximal end of the descending aorta, so that the embolus collector can collect the embolus flowing into the downstream blood vessel from the aortic arch, and the sequela of acute renal injury and the like caused by the fact that embolus generated in the operation process enters the downstream organs is prevented.

Fig. 4a to 4c are schematic structural views of the second supporting frame of this embodiment. As shown in fig. 4a-4c, the embolic collector 200 can comprise a second support frame 210 and a second filter element 220. The second support frame 210 may be shaped as a "claw" (as shown in fig. 4 a), a "petal" (as shown in fig. 4 b), or a "lantern" (as shown in fig. 4 c) with at least a proximal end having a tapered configuration to facilitate movement of the embolic collector 200 within the blood vessel while avoiding damage to the blood vessel wall by the embolic collector 200. The second filter element 220 may be a second filter net attached to the second support frame 210 for filtering embolic material, such as thrombus, etc., in the blood flowing through the second filter element 220. Specifically, the second filter element 220 at least partially covers the second support frame 210, for example, to filter thrombus in blood flowing through the embolic collector 200. The second filter element 220 may be single-sided attached to the second support frame 210, wherein the perimeter of the second filter element 220 is attached to the second support frame 210. The second filter element 220 may be a flexible second filter element or a non-flexible second filter element. Optionally, the surface of the second filter element 220 may be covered with a coating, which may be heparin, anticoagulant, etc., to prevent thrombus from accumulating to block the second filter element 220 during the operation; alternatively, the second filter element 220 may be made of a material having an anticoagulant such as antithrombotic property.

The portion of the second support frame 210 that is covered by the second filter element 220 is generally funnel-shaped, and the push tube 300 passes through the second support frame 210 of the embolus collector 200 via the funnel mouth, and is connected to the embolus collector at the funnel mouth. That is, the second supporting frame 210 is sleeved on the pushing pipe 300, and the pushing pipe 300 and the second supporting frame 210 may be connected by a laser, a stamping method, or a heat setting method, or may be connected by a chemical method (for example, by using glue). The second support frame 210 serves to support the second filter element 220 and defines a circumferential coverage area of the second filter element 220 such that a radial cross-section of a downstream blood vessel can be completely covered.

The push tube 300 has a lumen extending through the push tube 300 in the direction of extension of the push tube 300, which may be used to traverse a corresponding guide wire, such as that used during TAVR procedures to match the guide wire used during TAVR procedures delivery, so that the guide wire may guide the push tube 300 to a predetermined location, such as the aortic arch 13. The push tube 300 may be made of metal (e.g., stainless steel or nitinol), polymer, or a composite of the two. The push tube 300 may have a uniform diameter structure with a uniform outer diameter from the proximal end to the distal end, or the push tube 300 may have a variable diameter structure with a thick proximal end and a thin distal end. Further, the distal end or the proximal end of the push tube 300 is provided with a special shaping or stamping structure forming treatment, so that the push tube 300 is shaped at different bending angles, and when a medical instrument enters the aortic arch region along the guide wire, the medical instrument can actively match the aortic arch anatomical structure, so that the instrument is not turned over, and the instrument can be stably released. The distal end of the push tube 300 can be connected to the distal or proximal end of the first support frame 110 or the first filter element 120, or can be connected to both the distal and proximal ends of the first support frame 110 or the first filter element 120. Preferably, the distal end of the push tube 300 can be connected to both the distal end and the proximal end of the first support frame 110 or the first filter element 120, which facilitates the good adherence of the push tube 300 supported by the guide wire, and also ensures that both ends of the first support frame 110 are also well adhered.

Fig. 6a is a schematic structural diagram of a connecting portion according to this embodiment. As shown in fig. 6a, the pushing tube 300 includes a tube body 310, a first connecting portion 320 and a second connecting portion disposed on the tube body 310. The first connection portion 320 is connected to the tube 310, and specifically, the tube 310 and the first connection portion 320 may be connected by a laser, a punching method, or a heat setting method, or may be connected by a chemical method (e.g., using glue), so that the embolic deflector 100 is connected to the tube 310 through the first connection portion 320. The first connection 320 is near the distal end of the push tube 300, and the push tube 300 is connected to the embolic deflector 100 by the first connection 320. The tube 310 further includes a hypotube cutting structure disposed at the distal end that can be shaped by a guidewire inside the pusher tube 300 to achieve adaptive patient aortic arch anatomy, which can result in better adherence of the first support frame 110 and/or the first filter element 120. The second connection portion is disposed between the first connection portion 320 and the proximal end of the tube body 310; the embolic collector 200 can be connected to the push tube 300 by the second connection. The second connecting portion includes a groove around the circumference of the tube body 310, and the embolus collector 200 is sleeved at the groove of the second connecting portion to realize the connection with the pushing tube 300.

Fig. 5a-5d are schematic structural diagrams of several types of sea wave cutting structures of the pipe body according to the present embodiment. As shown in fig. 5a to 5d, the length of the sea wave cutting structure extending along the axial direction of the pipe body 310 is between 80mm and 350mm, and preferably, the length of the sea wave cutting structure extending along the axial direction of the pipe body 310 is between 100mm and 230 mm.

As shown in fig. 5a, the sea wave cutting structure includes a plurality of cutting units 311, and the plurality of cutting units 311 are spirally arranged along the axial direction of the pipe body 310. The cutting unit 311 may include at least one groove. When the cutting unit 311 includes at least two grooves, the at least two grooves are arranged at intervals along the extending direction of the cutting unit 311. The distance a between the cutting units 311 (i.e., the distance between adjacent cutting units 311 in the axial direction of the tube 310) is, for example, in a range of 0.7mm to 2.5mm, and preferably, the distance a between the cutting units 311 is, for example, in a range of 1.2mm to 2.2 mm. The angle α of the cutting unit 311 (i.e., the included angle between the cutting unit 311 and the axial direction of the pipe body 310) is, for example, between 0 ° and 90 °, and preferably, the angle of the cutting unit 311 is, for example, between 60 ° and 90 °.

As shown in fig. 5b and 5d, the sea wave cutting structure includes a plurality of cutting portions 310a arranged at intervals in an axial direction of the pipe body 310, and each of the cutting portions 310a includes at least one cutting unit 311 arranged at intervals in a circumferential direction of the pipe body 310. The distance B between the cutting portions 310a (i.e., the distance between adjacent cutting portions 310a in the extending direction of the tube 310) is, for example, in the range of 0.7mm to 2.5 mm. Preferably, the distance B between the cutting portions 310a ranges from 1.2mm to 2.2mm, for example. The angle β of the cutting portion 310a (i.e., the included angle between the extending direction of the cutting portion 310a and the axial direction of the tube 310) is, for example, between 0 ° and 180 °. When the angle β of the cutting portion 310a is 90 °, the cutting portion 310a is a circle of disconnected annular cutting units 311 arranged on the pushing tube 300 along the axial direction of the pushing tube 300. When the angle β of the cutting portion 310a is 0 ° or 180 °, the extending direction of the cutting portion 310a is parallel to the axial direction of the tube 310. Preferably, the angle β of the cutting portion 310a ranges from 40 ° to 65 °, or from 115 ° to 140 °, for example. In other embodiments, the cutting structure further includes a plurality of cutting portions arranged at intervals along the circumferential direction of the pipe body, each cutting portion includes at least one cutting unit arranged at intervals along the axial direction of the pipe body, and the structure of a single cutting portion may be the same as that of the plurality of cutting portions 310a arranged at intervals along the axial direction of the pipe body 310.

The angle α of the cutting unit 311 is an axial included angle between the cutting unit 311 and the pipe body 310. The angle α of the cutting unit 311 is, for example, in the range of 0 ° to 90 °, and preferably, the angle α of the cutting unit 311 is, for example, in the range of 60 ° to 90 °. The width of the cutting unit 311, that is, the width of the groove, that is, the length of the cutting unit 311 perpendicular to the extending direction thereof, may range from 0.01mm to 2.00mm, and preferably, the width of the cutting unit 311 may range from 0.02mm to 1.50 mm. The pitch b of the cutting units 311 is the distance between adjacent cutting units 311. The range of the distance b between the cutting units 311 may be 0.05mm to 0.50mm, and preferably, the range of the distance b between the cutting units 311 may be 0.05mm to 0.30 mm. The length L of the cutting unit 311 is the length of the cutting unit 311 extending along the outer surface of the pipe body. The length L of the cutting unit 311 is determined according to the outer wall perimeter M of the pipe body 310, specifically, a ratio P that is satisfied by the length L of the cutting unit 311 and the outer wall perimeter M of the pipe body 310, that is, P is equal to L/M, and the ratio P is, for example, in a range of 0.08 to 0.90, and preferably, the ratio P is, for example, in a range of 0.10 to 0.85. At least one of the angle α of the cutting unit 311, the angle β of the cutting portion 310a, the width a of the cutting unit 311, the distance B of the cutting unit 311, the distance a of the cutting unit 311, and the distance B of the cutting portion 310a may be gradually or sectionally changed within a value range thereof, so as to achieve the purpose of gradual or sectionally changing the hardness of the pipe body 310, so that the push pipe may not only be molded by an internal guide wire, but also may not have an obvious or strong stress concentration point in a process of bearing and transmitting a pushing force or a pulling force, thereby reducing a possibility of bending the push pipe due to stress concentration.

As shown in fig. 5e, the cross-section of the cutting unit 311 (i.e., the section of the cutting unit 311 perpendicular to the extending direction thereof) has a shape including, but not limited to, a trapezoid, a semicircle, a rectangle, a triangle, etc., to further change the hardness of the pipe body 310.

The cutting unit 311 includes at least one groove, and when the cutting unit 311 includes at least two grooves, the at least two grooves are arranged at intervals along an extending direction of the cutting unit. The groove may or may not pass through the exterior of the tube 310 and the lumen. As shown in fig. 5d, the cutting unit 311 may further include two annular grooves at two ends, and a bar groove connecting the two annular grooves, the bar groove may further include at least one V-shaped groove structure, and the annular groove and the bar groove may or may not be communicated.

Fig. 6a is a schematic structural diagram of a first connecting portion according to the present invention. As shown in fig. 6a, the first connection portion 320 extends in the same axial direction as the tube body 310, and the first connection portion 320 is integrally formed with the tube body 310. The first connection portion 320 has a through hole 321, the through hole 321 penetrates the tube 310 in a direction perpendicular to the axial direction of the tube 310, and the diameter of the through hole 321 is smaller than the diameter of the cross section (i.e., the section perpendicular to the axial direction of the tube 310) of the first connection portion 320. The first support frame 110 is, for example, fitted in the through hole 321 to connect the embolic deflector 100 with the push tube 300. The through hole 321 has two opposite openings, which are a first opening and a second opening, respectively, and a maximum distance between the first opening and the second opening (i.e., a maximum length of the through hole) is, for example, in a range of 2.5mm to 7mm, and preferably, the maximum length of the through hole is, for example, in a range of 3mm to 5 mm. The minimum distance between the first opening and the second opening (i.e. the minimum length of the through hole) is, for example, in the range of 0.2mm to 1 mm.

Fig. 6b-6c are schematic structural views of a second connecting portion according to the present invention. As shown in fig. 6b to 6c, the first connection portion 320 may also be an H-shaped connection element, and the first connection portion 320 extends in the same axial direction as the tube body 310. The first connection portion 320 includes a first tubular structure 322, a first connection rod 324 and a second tubular structure 323 sequentially arranged along a distal end to a proximal end direction of the tube 310, the first tubular structure 322, the first connection rod 324 and the second tubular structure 323 are coaxially disposed and sleeved on the tube 310, and the first tubular structure 322 and the second tubular structure 323 are connected by the first connection rod 324. Specifically, the distal end of the first connecting rod 324 is, for example, an opening connected to the first tubular structure 322 at the proximal end, and the proximal end of the first connecting rod 324 is, for example, an opening connected to the second tubular structure 323 at the distal end. The proximal end of the first connecting rod 324 may be attached by, for example, laser, stamping, or heat setting, or may be chemically (e.g., with glue) attached to the distal opening of the second tubular structure 323. The first connecting rods 324 are, for example, long, and may be plane long and also be arched long, and preferably, the first connecting rods 324 may be arched long, and the first connecting rods 324 are arched away from the tube 310 to form the through holes 321 between the first connecting rods and the tube, so as to facilitate relieving pressure from the first tubular structures 322 and the second tubular structures 323. The first support frame 110 and/or the first filter element 120 are sleeved in the first tubular structure 322, and the proximal end of the second tubular structure 323 is connected to the distal end of the tube body 310, specifically, the inner diameter of the second tubular structure 323 is larger than the outer diameter of the distal end of the tube body 310, for example, so that the proximal end of the second tubular structure 323 can be sleeved outside the distal end of the tube body 310 to connect the embolic deflector 100 with the push tube 300. The length of the first tubular structure 322 (i.e., the length of the first tubular structure 322 in the extending direction) and the length of the second tubular structure 323 may be the same or different, the length of the first tubular structure 322 and the length of the second tubular structure 323 may both be in a range of 0.5mm to 5mm, and preferably, the length of the first tubular structure 322 and the length of the second tubular structure 323 may both be in a range of 1mm to 3 mm. The distance between the first tubular structure 322 and the second tubular structure 323 can be, for example, in the range of 2.5mm to 7mm, and preferably, the distance between the first tubular structure 322 and the second tubular structure 323 can be, for example, in the range of 3mm to 5 mm. The width of the first connecting rod 324 (i.e., the length of the first connecting rod 324 perpendicular to the axial direction of the pipe body) ranges, for example, from 0.2mm to 1mm, the height of the first connecting rod 324 (the height of the arch of the first connecting rod 324) ranges, for example, from 0.5mm to 3mm, and preferably, the height of the first connecting rod 324 ranges, for example, from 0.8mm to 2.5 mm.

Fig. 6d-6e are schematic structural views of a third connecting portion according to the present invention. As shown in fig. 6d-6e, the first connection portion 320 may also be an H-shaped connection element, the first connection portion 320 includes a third tubular structure 325, a second connection rod 327, and a fourth tubular structure 326 sequentially arranged along a distal end to a proximal end direction of the tube body, the fourth tubular structure 326 is coaxially disposed with the tube body 310 and sleeved on the tube body 310, the third tubular structure 325 and the fourth tubular structure 326 are connected by the second connection rod 327, an axial direction of the third tubular structure 325 is perpendicular to an axial direction of the tube body 310, and an inner cavity of the third tubular structure 325 forms the through hole 321. The third tubular structure 325 and the fourth tubular structure 326 are connected by the second connecting rod 327, specifically, a proximal end of the second connecting rod 327 is connected to a distal end of the fourth tubular structure 326, and a distal end of the second connecting rod 327 is connected to the outer wall of the third tubular structure 325, so that the extending direction of the fourth tubular structure 326 is perpendicular to the axial direction of the tube body 310, and the distal end of the second connecting rod 327 can be connected by, for example, laser, stamping, or heat setting, or can be connected to the outer wall of the third tubular structure 325 by chemical means (for example, by using glue). The first support frame 110 or the first filter element 120 is sleeved in the third tubular structure 325, and the inner diameter of the fourth tubular structure 326 is larger than the outer diameter of the tube body 310, so that the fourth tubular structure 326 is sleeved outside the distal end of the tube body 310. The outer diameter of the third tubular structure 325 may range from 1mm to 3mm, and the length of the third tubular structure 325 may range from 0.6mm to 1.5 mm. The length of the fourth tubular structure 326 may range from 0.5mm to 5mm, and preferably, the length of the fourth tubular structure 326 may range from 1mm to 3 mm. The second connecting rod 327 is, for example, a straight bar shape, a width of the second connecting rod 327 may range from 0.2mm to 1mm, a length of the second connecting rod 327 may range from 1mm to 6mm, and preferably, the length of the second connecting rod 327 may range from 2mm to 4 mm.

The first connection portion 320 may be made of metal, polymer or ceramic material to enhance the manipulation force (including the control of release and movement) of the embolic protection device by the operator, which provides stronger pushing and pulling force to enable the operator to quickly and quickly adjust the position of the deflected first support frame 110, improve the positioning accuracy of the deflected first support frame 110, enable the first support frame 110 to freely rotate within a range of 180 ° around the penetrating direction of the through hole 321, and freely rotate within a range of 360 ° around the axial direction of the push tube 300, and further help improve the adherence of the embolic deflector 100.

The delivery sheath 400 is a hollow tubular structure, and the delivery sheath 400 has a cavity penetrating through the extension direction thereof to accommodate the compressed embolus deflector 100, embolus collector 200, and pushing tube 300. The conveying sheath 400 may be woven from a polymer material or a metal material, or may be woven from a mixture of a polymer material and a metal material.

Optionally, the embolic protection device further comprises a plurality of visualization elements to enable clear identification of the position of the embolic deflector 100, as well as the open or retracted state, during the procedure. The developing element can be a developing point or a developing wire. The developing elements are disposed on the tap deflector 100, for example, and specifically, the developing elements may be disposed at both ends of the first support frame 110, or may be disposed continuously on the first support frame 110. Further, the developing element may be further provided on the conveying sheath 400, and specifically, the developing element may be further provided at a distal end of the conveying sheath 400. The developing element may also be disposed on the push tube 300, and in particular, the developing element may also be disposed at the distal end of the push tube 300. The visualization element may facilitate an operator in confirming placement of the embolic protection device during a surgical procedure, such as delivery, placement, release, etc. The developing element can be tantalum, platinum, gold, tungsten and the like.

Optionally, the embolic protection device further comprises a guide member 500, wherein the guide member 500 is connected to the proximal end of the embolic deflector 100, and the proximal end of the guide member 500 has a reduced structure to assist the embolic deflector 100 to be fixed at the aortic arch to avoid its movement, while avoiding the damage of the guide member 500 to the vessel wall.

In summary, the present invention provides a embolic protection device, comprising an embolic deflector and a push tube, the embolic deflector comprising a first support frame and a first filter element disposed on the first support frame; the pushing pipe comprises a pipe body, the pipe body is connected with the embolus deflector, and the pushing pipe is used for pushing, positioning and adjusting the embolus deflector; the tube body further includes a sea wave cutting structure disposed at the distal end. The utility model discloses a propelling movement pipe makes the embolus deflector of protection upstream blood vessel have good adherence performance, the body is still including setting up the sea wave cutting structure at the distal end department for it is moulding to promote the inside seal wire, thereby realizes the performance of self-adaptation patient's aortic arch anatomical structure, and then can make embolus deflector have better adherence. The push tube further includes a first connector having a through hole through which the proximal end of the first support frame or the first filter element passes to enable connection of the embolic deflection device to the push tube. First connecting portion make the propelling movement pipe obtain better propelling movement power and control power for embolic protection device obtains better degree of freedom, and this embolic protection device design is simple, and is multiple functional, the simple operation.

Furthermore, unless otherwise specified or indicated, the descriptions of the terms "first," "second," "third," "fourth," and the like in the specification are only used for distinguishing various components, elements, steps, and the like in the specification, and are not used for indicating a logical relationship or a sequential relationship between various components, elements, steps, and the like.

It is to be understood that while the present invention has been disclosed in terms of the preferred embodiment, it is not intended to limit the invention to the disclosed embodiment. To anyone skilled in the art, without departing from the scope of the present invention, the technical solution disclosed above can be used to make many possible variations and modifications to the technical solution of the present invention, or to modify equivalent embodiments with equivalent variations. Therefore, any simple modification, equivalent change and modification made to the above embodiments by the technical entity of the present invention all still fall within the protection scope of the technical solution of the present invention, where the technical entity does not depart from the content of the technical solution of the present invention.

Claims (21)

1. An embolic protection device, comprising:

an embolic deflector comprising a first support frame and a first filter element disposed on the first support frame;

a pushing tube comprising a tube body connected to the embolic deflector for pushing, positioning and adjusting the embolic deflector; the body still includes the sea wave cutting structure of setting at the distal end.

2. The embolic protection device of claim 1, wherein the push tube further comprises a first connection disposed on the tube, the tube being connected to the embolic deflector through the first connection.

3. The embolic protection device of claim 2, wherein the first connector portion has a through-hole through which the proximal end of the first support frame or the first filter element passes to enable connection of the embolic deflection device to the pusher tube.

4. An embolic protection device as in claim 3, wherein the through-hole extends through the tubular body in a direction perpendicular to the axial direction of the tubular body.

5. The embolic protection device of claim 3, wherein the first connector comprises a first tubular structure, a first connecting rod, and a second tubular structure arranged in sequence from the distal end to the proximal end of the tubular body, wherein the first tubular structure and the second tubular structure are coaxially arranged with the tubular body and are sleeved on the tubular body, and the first tubular structure and the second tubular structure are connected by the first connecting rod.

6. An embolic protection device as in claim 5, wherein the first connecting rod is elongated in the shape of an arch and is arched away from the body to form the through-hole between the first connecting rod and the body.

7. The embolic protection device of claim 3, wherein the first connecting portion comprises a third tubular structure, a second connecting rod and a fourth tubular structure sequentially arranged along a distal end to a proximal end direction of the tubular body, the fourth tubular structure is coaxially arranged with the tubular body and sleeved on the tubular body, the third tubular structure and the fourth tubular structure are connected through the second connecting rod, an axial direction of the third tubular structure is perpendicular to an axial direction of the tubular body, and an inner cavity of the third tubular structure forms the through hole.

8. An embolic protection device as in claim 1, wherein the length of the marine wave cutting structure along the axial extension of the tubular body is between 80mm and 350 mm.

9. An embolic protection device as in claim 1, wherein the sea wave cutting structure comprises a plurality of cutting units arranged helically along the axial direction of the tubular body.

10. The embolic protection device of claim 1, wherein the marine wave cutting structure comprises a plurality of cutting portions spaced axially along the tubular body, each cutting portion comprising at least one cutting unit spaced circumferentially along the tubular body.

11. The embolic protection device of claim 1, wherein the marine wave cutting structure comprises a plurality of cutting portions spaced circumferentially along the tubular body, each cutting portion comprising at least one cutting unit spaced axially along the tubular body.

12. Embolic protection device as in claim 9, 10 or 11, wherein the cutting unit comprises at least one groove.

13. An embolic protection device as in claim 12, wherein the grooves comprise at least one annular groove at an end, and a strip groove connecting the annular grooves.

14. An embolic protection device as in claim 13, wherein the strip shaped groove comprises at least one V-shaped structure, the annular groove communicating with the strip shaped groove.

15. The embolic protection device of claim 12, wherein the push tube has an inner lumen extending therethrough in the direction of extension of the push tube, the groove extending through the outer portion of the tubular body and the inner lumen.

16. The embolic protection device of claim 12, wherein the cutting unit comprises at least two grooves spaced apart along the direction of extension of the cutting unit.

17. An embolic protection device as in claim 9, 10 or 11, wherein the cutting element extends at an angle of between 60 and 90 degrees to the axial direction of the tubular body.

18. An embolic protection device as in claim 9, 10 or 11, wherein the cutting unit extends along the outer surface of the tubular body at a ratio of between 0.08 and 0.90 to the circumferential length of the outer surface of the tubular body.

19. The embolic protection device of claim 2, further comprising an embolic collector comprising a second support frame and a second filter element, the second filter element attached to the second support frame; the push tube further comprises a second connecting portion disposed on the tube body, the second connecting portion being disposed between the first connecting portion and the proximal end of the tube body; the embolus collector is connected with the pushing pipe through the second connecting part.

20. The embolic protection device of claim 19, wherein the second coupling portion comprises a groove around the circumference of the tubular body, the embolic collector sleeve fitting over the groove to effect the connection with the push tube.

21. The embolic protection device of claim 1, wherein the pusher tube is of a uniform diameter structure with a uniform outer diameter from the proximal end to the distal end, or the pusher tube is of a variable diameter structure with a thick proximal end and a thin distal end.

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