CN113693675B - Thrombolysis stent and manufacturing method thereof - Google Patents

Abstract

The invention provides a thrombus taking support and a manufacturing method thereof, wherein the thrombus taking support comprises a support main body which can be radially self-expanded and axially stretched, the support main body comprises an outer support and an inner support, the inner support is arranged in the outer support, the outer support is respectively connected with the axial proximal end and the axial distal end of the inner support, and the inner support provides axial supporting force for the outer support; the side of the outer layer bracket is also provided with a first opening for thrombus or clot to enter the outer layer bracket. The thrombus taking bracket provided by the invention adopts an inner-outer double-layer design, and can immediately open the embolic tissue by means of strong supporting force of the inner-layer bracket after the intracranial embolism blood vessel is released, so that the blood supply of the embolism blood vessel is restored, and the effect of immediately restoring the blood flow is achieved.

Description

Thrombolysis stent and manufacturing method thereof

Technical Field

The invention relates to the technical field of medical instrument design, in particular to a thrombus taking bracket and a manufacturing method thereof.

Background

Acute ischemic cerebral apoplexy, acute pulmonary embolism and deep venous embolism are diseases caused by blood vessel distal ischemia and hypoxia due to blockage of blood vessel by thrombus, clot and the like. The diseases have high mortality and disability rate. Wherein, intracranial blood vessels are thinner, blood paths are more tortuous, and embolic blood vessels are shorter in length. Pulmonary embolism and deep venous embolism are thicker in blood vessels and are gentle in blood paths, but the clot and thrombus of embolism are more generally, and the blood vessels of the embolism section are longer.

Acute ischemic stroke (Cerebral Ischemic Stroke, CIS) is a damage to nerve tissue caused by ischemic necrosis of local brain tissue due to sudden blockage of cerebral blood flow. From 70% to 80% of patients with severe symptoms who need angiography can see emboli or blockage of thrombus. The mortality rate of the larger vascular embolism is 53-92%.

Pulmonary arterial embolism (PE) refers to the clinical and pathophysiological syndrome in which an endogenous or exogenous embolic obstruction of a pulmonary artery or its branches causes pulmonary circulatory dysfunction. Among the most common types are pulmonary arterial thromboembolism (PTE), and those with pulmonary hemorrhage or necrosis following pulmonary arterial embolism are called pulmonary infarction. Pulmonary embolism is an acute condition with a high clinical morbidity and mortality, most commonly caused by pulmonary thromboembolism. According to incomplete statistics, 35.5 ten thousand cases of pulmonary embolism patients exist in China at present.

Vascular recanalization is the key to treating acute ischemic stroke and acute pulmonary embolism. Current conventional methods for treating acute ischemic stroke include interventional thrombolysis and mechanical thrombolysis, wherein mechanical thrombolysis is further divided into stent thrombolysis and aspiration thrombolysis.

At present, the bracket thrombus taking and the suction thrombus taking of the intracranial vascular embolism are clinically accepted, have the same effect as the intervention thrombus taking, and have the advantages that the time window is long, and compared with 3 hours of the intervention thrombus taking, the bracket thrombus taking and the suction thrombus taking are expanded to 24 hours. And the treatment technology of the stent thrombolysis and the suction thrombolysis is also widely popularized.

The thrombus taking bracket similar to the intracranial thrombus taking bracket structure can also be applied to interventional thrombus taking operation of pulmonary embolism and deep vein embolism.

Intracranial interventional embolectomy stents have evolved for many years, and have undergone the procedures of Merci spring ring-type structures, catch basket structures, cutting stent structures with two closed ends of the Redevice SE, cutting stents with two open ends of the Trevo, solitaire FR side single-sided opening with two open ends, versi three-section sectional, eric multisection filter combination, punamer 3D multisection interception, phonex multisection hairbrush types, inner and outer double layers of Embotagap II, double-sided opening, distal basket type structures, aperio distal opening, proximal closing, open flaps on the stent, inner layer guide wire development type structures, tigertriever-13 outer braided stents, inner layer movable guide wires, and adjustable stent length and diameter by controlling the guide wires through handles.

From the aspect of processing technology, the thrombus taking bracket mainly comprises the following steps of: the first step, braiding or cutting a bracket, wherein main raw materials are respectively NiTi alloy wires and NiTi alloy tubes; secondly, heat treatment shaping, namely shaping the bracket into a target shape and size; polishing, namely removing oxide skin on the surface of the bracket to form smooth inner and outer surfaces; fourth, assembling, and connecting the bracket and the pushing rod together.

The main working principle of the intracranial thrombus taking support is to capture thrombus or clot, take the thrombus or clot out of the body, smooth the blood vessel which is originally plugged, restore blood flow, and not cause the damage of the blood vessel and plug the far-end blood vessel which is finer. In order to achieve the effect of restoring the blood flow of the embolic vessel, the thrombus removal stent needs to solve the problem in aspect 3: first, the thrombolytic stent is capable of reaching the vascular embolization site, which requires a sufficiently small outer diameter and proper radial support force for the thrombolytic stent; secondly, the thrombus taking stent captures thrombus and clot as much as possible, so that embolic materials can enter the stent and be taken out; thirdly, when a doctor withdraws the pushing rod to pull the thrombus and clot captured by the thrombus-taking bracket as a recovered sheath, the thrombus and clot do not fall off when passing through a tortuous intracranial vessel;

the ideal intracranial thrombus taking stent can reach the far-end thinner intracranial blood vessel without damaging the blood vessel, capture thrombus and/or clot as much as possible, and the captured thrombus and/or clot is firmly captured by the thrombus taking stent and does not fall off through the tortuous blood vessel in the process of withdrawing the thrombus taking stent.

The existing on-market thrombus taking bracket products can only reach thicker blood vessels, collect emboli or clots with smaller size, softer texture and short clotting time, the positions of the blood vessels where the emboli are located are not too tortuous, or one thrombus taking can not lead the blood vessels to be unobstructed, only a small amount of thrombus can be taken out at a time, and repeated thrombus taking is needed. These thrombolytic stents have more or less drawbacks, are too large in size to be placed in the finer distal vessels; the radial supporting force is too large, the pushing in the microcatheter is not easy, and the vascular injury is caused after the release; failure to capture large-size, high-viscosity thrombi or clots; in the process of withdrawing, the thrombus or clot is seriously fallen off through the tortuous blood vessel, and the fallen thrombus floats to the farther and finer blood vessel to generate embolism again, thereby influencing the prognosis effect of a patient. Therefore, there is a need for a thrombolytic stent that can specifically address the above-described problems for both the patient and the physician.

Disclosure of Invention

Aiming at the problems in the background technology, the invention provides a thrombus taking support, which comprises a support main body which can be radially self-expanded and axially stretched, wherein the support main body comprises an outer support and an inner support, the inner support is arranged in the outer support, the outer support is respectively connected with the axial proximal end and the axial distal end of the inner support, and the inner support provides axial supporting force for the outer support; the side of the outer layer bracket is also provided with a first opening for thrombus or clot to enter the outer layer bracket.

Preferably, the outer layer support is of an elongated network-shaped cylindrical structure with two folded ends.

Preferably, the outer layer bracket is formed by sequentially connecting a plurality of bracket units, and the two symmetrical sides of each bracket unit are respectively provided with the first openings.

Preferably, each support unit has a structure symmetrical up and down and left and right.

Preferably, on each of the holder units, the area of the first opening portion is 0.8 to 1.5 times the area of the non-opening portion.

Preferably, each support unit has the same structure, and two adjacent support units are connected by a rotation angle alpha in the circumferential direction.

Preferably, the value range of the angle alpha is 0-90 degrees.

Preferably, the connection points of the two adjacent bracket units are discontinuous on the same connecting line parallel to the axial direction.

Preferably, the inner layer support comprises at least one support section and at least one telescopic section connected, and the telescopic section is used for compensating the whole length of the inner layer support.

Preferably, the inner stent comprises a support section and a telescoping section, the support section being at the proximal end and the telescoping section being at the distal end.

Preferably, the inner layer support comprises a plurality of support sections, and one telescopic section is arranged between every two adjacent support sections.

Preferably, the telescopic section is a spring tube which is telescopic in the axial direction.

Preferably, the telescopic section is of a cross-shaped structure with adjustable size along the length direction of the inner layer bracket.

Preferably, the support section is an expandable network-like structure.

Preferably, the proximal end of the stent body tapers in a proximal direction from the distal direction.

Preferably, the bracket main body is provided with a first developing part.

Preferably, the device further comprises a catching structure for intercepting thrombus or clot escaping from the stent body, the catching structure being connected to the distal end of the stent body and having a second opening at its end facing the stent body.

Preferably, the catching structure adopts a fusiform network structure.

Preferably, the catch structure is connected to the distal end of the outer stent.

Preferably, the catching structure is provided with a second developing part.

Preferably, an extension rod is arranged at one end of the catching structure, which is away from the bracket main body, and the second developing part is arranged on the extension rod.

Preferably, the device further comprises a push rod, wherein the push rod is connected with the proximal end of the bracket main body.

Preferably, the push rod is provided with a third developing part.

The invention also provides a manufacturing method of the thrombus taking bracket, which is used for processing the thrombus taking bracket, and comprises the following steps:

s1, respectively and independently processing each component part on the thrombus taking support;

s2, performing heat treatment shaping on the processed components;

s3, carrying out acid washing and electrochemical polishing treatment on each component;

s4, arranging developing materials on the component parts;

s5, assembling and connecting all the forcing parts to form the complete thrombus taking support.

Preferably, step S1 further comprises: the laser cutting of the metal structure or the laser engraving of the metal structure or the braiding of the metal wires are adopted to respectively process each component part.

Preferably, step S1 further comprises: each component part comprises an outer layer bracket, an inner layer bracket, a catching structure and a push rod.

Preferably, step S2 further comprises: the outer layer stent and the fishing structure are subjected to heat treatment to form the expanded diameter together, the inner layer stent is subjected to heat treatment to form the expanded diameter independently, and the expansion amount of the inner layer stent is smaller than that of the outer layer stent;

preferably, step S2 further comprises: the outer layer bracket, the catching structure and the inner layer bracket need to be subjected to heat treatment shaping for multiple times, so that the diameters of the outer layer bracket, the catching structure and the inner layer bracket are gradually expanded to the target values.

Preferably, step S2 further comprises: in the heat treatment shaping process of each component part, the original air in the heat treatment space is firstly exhausted, and then inert gas is filled into the heat treatment space, so that the airtight state of the heat treatment space is ensured in the treatment process.

Compared with the prior art, the invention has the following advantages and positive effects due to the adoption of the technical scheme:

1. the thrombus taking bracket provided by the invention adopts an inner-outer double-layer design, and can immediately open the embolic tissue by means of strong supporting force of the inner-layer bracket after the intracranial embolism blood vessel is released, so that the blood supply of the embolism blood vessel is restored, and the effect of immediately restoring the blood flow is achieved;

2. The outer layer stent side opening of the thrombus taking stent provided by the invention can be better embedded into thrombus or clot after the thrombus taking stent is released, and when the thrombus taking stent is retracted, the thrombus or clot positioned outside the whole stent can roll in, slide in and squeeze into the inside of the thrombus taking stent in the sliding process, and is wrapped between the inner layer stent and the outer layer stent, so that the thrombus or clot wrapping rate is higher;

3. when the whole bracket receives a pulling force during the withdrawing of the thrombus taking bracket, the inner-layer double-layer bracket design of the thrombus taking bracket can maintain the original length without generating larger axial deformation due to the stronger axial supporting force of the inner-layer bracket. This reduces the pulling forces experienced by the integral stent, and in particular the outer stent, without significant axial deformation. The thrombus collecting rack has the advantages that the shape of the original rack can be maintained unchanged when the rack is pulled, so that the internal space is kept unchanged, thrombus which is captured by the original thrombus collecting rack can be firmly clamped in the space formed by the inner and outer double-layer rack, falling or escaping does not occur, and the thrombus collecting rack has higher thrombus collecting rate and collecting stability in recovery;

4. When the thrombus taking support is withdrawn, the inside and outside double-layer design of the thrombus taking support can be necessarily extruded by the inner wall of a tortuous blood vessel when the thrombus taking support passes through the tortuous intracranial blood vessel. At this time, due to the double-layer design of the stent, the inner stent is close to the side wall of the blood vessel, and the outer stent is pushed out to the outer side of the blood vessel wall to form an expansion arc, so that the advantages of the design are that the stent is prevented from being integrally flattened to obviously reduce the space in the stent, so that captured thrombus or clot is extruded from the stent, falls off and escapes, and the stent has the capability of resisting the pressure of the side wall of the tortuous blood vessel and maintaining the space in the thrombus taking stent;

5. the thrombus taking bracket provided by the invention is also provided with a catching structure for intercepting thrombus or clot escaping from the bracket main body; in the process of withdrawing and retracting the thrombus taking support into the sheath, if the condition that thrombus is crushed and falls off occurs, the catching structure is used as a protection tool, so that the fallen thrombus or clot can be captured again, the escape of the thrombus is reduced, the risk that the intracranial distal blood vessel is blocked again due to the falling thrombus is reduced, and the thrombus taking support is an effective protection tool.

Drawings

The above and other features and advantages of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings, in which:

fig. 1 is a front view of a thrombolytic stent according to embodiment 1 of the present invention;

fig. 2 is a top view of a thrombolytic stent according to embodiment 1 of the present invention;

FIG. 3 is a front view of the outer bracket of embodiment 1 of the present invention connected to a fishing structure;

FIG. 4 is a top view of the attachment of the outer bracket to the fishing structure according to embodiment 1 of the present invention;

FIG. 5 is a schematic structural view of an inner stent according to embodiment 1 of the present invention;

FIG. 6 is a front view of the thrombolytic device according to example 2 of the present invention;

fig. 7 is a schematic structural diagram of an inner stent in embodiment 2 of the present invention.

Detailed Description

The invention will be described in more detail hereinafter with reference to the accompanying drawings showing embodiments of the invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. In the drawings, the size and relative sizes of layers and regions may be exaggerated for clarity.

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the present invention are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicator is changed accordingly.

The invention provides a thrombus taking bracket which is used for collecting clots and thrombus in blood vessels, dredging the blood vessels and recovering blood flow, is mainly used for intracranial blood vessels, pulmonary artery blood vessels, deep vein blood vessels and the like, solves the problems that the clots are difficult to capture, easy to fall off and escape when collecting the clots, and can better meet clinical use requirements.

Specifically, the thrombus taking support comprises a support main body which can be radially self-expanded and axially stretched, wherein the support main body comprises an outer support and an inner support, the inner support is arranged in the outer support, the outer support is respectively connected with the proximal end and the distal end of the inner support in the axial direction, and the inner support provides supporting force for the outer support in the axial direction; the side of the outer layer bracket is also provided with a first opening for thrombus or clot to enter the outer layer bracket.

Before use, the thrombus taking support is folded in a loading sheath; when in use, the thrombus taking support is pushed into the micro-catheter through the loading sheath and then pushed out to the embolism position in the blood vessel from the distal end of the micro-catheter, the thrombus taking support slowly self-expands and is embedded into thrombus or clot, and the thrombus or clot slides into the thrombus taking support from the first opening. The compression degree or the self-expansion degree of the thrombus taking stent is mainly influenced by the thickness of the blood vessel at the position, and the thinner the blood vessel is, the larger the compression degree is, and the smaller the self-expansion degree of the thrombus taking stent is; the degree of expansion of the thrombus taking stent is also influenced by the texture of the thrombus or clot at the position, and the softer and the looser the texture of the thrombus or clot is, the greater the degree of expansion of the thrombus taking stent is; the harder the texture of the thrombus or clot, the denser the thrombus-removal stent will have a lesser degree of distraction; after being released, the thrombus taking stent stays for 3-5 min, so that the thrombus taking stent is spread as much as possible, and is further embedded into thrombus or clot tissues to be fully combined with the thrombus taking stent.

When the thrombus taking support is recovered, the thrombus taking support is subjected to the traction force of the near end and gradually withdraws from the intracranial blood vessel with the thinner far end to the carotid artery blood vessel with the thicker and thicker far end, and at the moment, the thrombus taking support is gradually unfolded from a compressed state to a complete self-expanding state, and the thrombus or clot captured by the thrombus taking support is wrapped and clamped, so that the thrombus taking support is completely unfolded. Finally, the thrombus taking support is pulled to take out the captured thrombus or clot and pull the thrombus or clot into the recovery sheath (balloon catheter) integrally, and the thrombus or clot is taken out of the body. In the process of thrombus and clot capturing and recovering by the thrombus-taking stent, the whole stent is subjected to the traction force of the near end, if the thrombus-taking stent is a single-layer stent at the moment, the traction force is concentrated on the single-layer stent, the whole stent is lengthened and thinned, and the stent is extruded to be flattened and bent through the extrusion action of the side wall of a blood vessel when the blood vessel is bent, so that the internal space of the stent is obviously reduced, and the captured thrombus and clot are easy to fall off and escape; the stent main body adopts a double-layer structure, the axial supporting force of the inner stent is strong, the inner stent can provide stronger resistance when being dragged, and the length and the diameter of the outer stent are kept almost unchanged, so that the thrombus taking stent is ensured not to be deformed obviously even being extruded by the pulling force and the side wall of a blood vessel when being retracted, the internal space of the thrombus taking stent is unchanged, and the captured thrombus is not easy to fall off and escape.

The thrombus taking bracket provided by the invention has the following advantages:

1. the thrombus taking bracket provided by the invention adopts an inner-outer double-layer design, and can immediately open the embolic tissue by means of strong supporting force of the inner-layer bracket after the intracranial embolism blood vessel is released, so that the blood supply of the embolism blood vessel is restored, and the effect of immediately restoring the blood flow is achieved;

2. the outer layer stent side opening of the thrombus taking stent provided by the invention can be better embedded into thrombus or clot after the thrombus taking stent is released, and when the thrombus taking stent is retracted, the thrombus or clot positioned outside the whole stent can roll in, slide in, squeeze in and be embedded into the inside of the thrombus taking stent in the sliding process, and is wrapped between the inner and outer layer stents, so that the thrombus or clot wrapping rate is higher;

3. the design of the inner and outer double-layer stent of the thrombus taking stent provided by the invention can ensure that when the thrombus taking stent is retracted and the whole stent receives the pulling force, because the inner layer bracket has stronger axial supporting force, the original length can be maintained without larger axial deformation. This reduces the pulling forces experienced by the integral stent, and in particular the outer stent, without significant axial deformation. The thrombus collecting rack has the advantages that the shape of the original rack can be maintained unchanged when the rack is pulled, so that the internal space is kept unchanged, thrombus which is captured by the original thrombus collecting rack can be firmly clamped in the space formed by the inner and outer double-layer rack, falling or escaping does not occur, and the thrombus collecting rack has higher thrombus collecting rate and collecting stability in recovery;

4. When the thrombus taking support is withdrawn, the inside and outside double-layer design of the thrombus taking support can be necessarily extruded by the inner wall of a tortuous blood vessel when the thrombus taking support passes through the tortuous intracranial blood vessel. At this time, because the double-deck design of this support, inlayer support is pressed close to the vascular lateral wall, and outer support is pushed out to the vascular lateral wall outside and forms a bulge arc, and the advantage of this design has avoided the support to be flattened by whole and is showing the space that reduces the support inside, causes that thrombus or the clot that has caught to extrude from the support, drops, escapes, has the ability of resisting tortuous vascular lateral wall pressure, maintains the interior space of thrombus taking support.

The following is a further description of specific embodiments:

example 1

Referring to fig. 1-5, the present embodiment provides a thrombus taking stent, which comprises a radially self-expandable and axially stretchable stent body, wherein the stent body comprises an outer stent 1 and an inner stent 2, the inner stent 2 is arranged in the outer stent 1, the outer stent 1 is respectively connected with the proximal end and the distal end of the inner stent 2 in the axial direction, and the inner stent 2 provides supporting force for the outer stent in the axial direction; the outer stent 1 is also provided with a first opening on the side for the entry of thrombus or clot into the outer stent.

In this embodiment, the outer layer support 1 is an elongated network-shaped cylindrical structure with two folded ends, and the distal end of the outer layer support 1 is closed, that is, the proximal end and the distal end of the outer layer support 1 are folded, so the design is beneficial to enabling the distal end to be used as a fishing net structure, that is, when the first opening on the side edge of the outer layer support 1 is large enough, the closed design of the distal end can play a role of the fishing net. Further, the proximal end of the preferred outer stent 1 may also be closed; of course, in other embodiments, the proximal end of the outer stent 1 may be in an open state, i.e., not folded, and in an open state.

Specifically, the outer stent 1 is formed by sequentially connecting a plurality of stent units, for example, the outer stent 1 shown in fig. 3 to 4 includes five stent units, which are respectively a stent unit 101, a stent unit 102, a stent unit 103, a stent unit 104, and a stent unit 105, and the five stent units are sequentially connected to each other to form a continuous segmented structure. The number of the stent units included in the outer stent 1 is not limited, and can be adjusted according to specific conditions, and generally includes 2-5 stent units; wherein, each bracket unit is integrally manufactured to form a complete outer bracket.

Further, each support unit has the same structure, and each support unit has a structure which is symmetrical up and down and left and right.

Further, the two adjacent bracket units are connected by rotating an angle alpha in the circumferential direction; the value range of the angle alpha is 0-90 degrees; the preferred angle alpha is 90 deg. so that the connection points at the connection of two adjacent stent units are discontinuous on the same line parallel to the axial direction, as shown in fig. 3-4. In this embodiment, a plurality of repeated stent units in the outer stent are designed into an alternate 90-degree rotating structure instead of a continuous repeated unit, so that the flexibility of the outer stent is improved, and when the outer stent passes through a tortuous blood vessel, the designed thrombus taking stent can better adapt to the 3D structure bending configuration of the blood vessel, and the blood vessel cannot be damaged by forcibly straightening the blood vessel due to the rebound effect of the stent, so that the postoperative instant recanalization effect is good, and the condition of poor healing effect occurs.

Of course, in other embodiments, the connection manner of the brackets of each bracket unit is not limited to the above, and may be adjusted according to the specific situation, which is not limited herein.

Further, the first openings are provided on both symmetrical sides of each of the holder units, respectively, and the area of the preferred first opening portion is 0.8 to 1.5 times the area of the non-opening portion. The above design allows for a larger first opening in each stent unit, thereby making it easier for a thrombus or clot to fall into the outer stent 1.

In this embodiment, the material of the outer stent 1 is preferably a NiTi alloy material, the NiTi alloy has superelasticity and shape memory, and the shape after being shaped by heat treatment can be remembered, so the outer stent 1 made of the NiTi alloy also has superelasticity and shape memory, and when the outer stent is contracted into a very fine sheath tube to push for a certain distance, the NiTi alloy can be restored to the original shape as long as the applied external force is removed.

Furthermore, the outer layer bracket can be made of a NiTi alloy pipe integrally by a processing technology of laser engraving or laser cutting; or, the outer layer bracket 1 is made of NiTi alloy wires integrally by using a braiding processing technology; alternatively, the material of the outer layer support 1 can be made of a combination of a NiTi alloy tube and a NiTi alloy wire by using a combined processing technology of laser engraving, hand knitting and laser cutting. The processing method of the outer stent 1 can be selected according to specific needs, and is not limited herein.

Of course, in other embodiments, the outer stent 1 may be supported by other materials having elastic and shape memory properties, which are not limited.

In this embodiment, referring to fig. 4-5, the inner stent 2 comprises a connected support section 201 and a telescoping section 202, the support section 201 being at the proximal end, the telescoping section 202 being at the distal end, and the proximal end of the support section 201 being open to facilitate collection of a thrombus or clot.

The present embodiment mainly uses the supporting section 201 to mainly exert the effect of strengthening and the effect of stretching resistance. When the thrombus taking support is released, the strong supporting force of the inner support can instantly open a blood flow passage at the embolism position to restore the blood flow, and the telescopic section 202 has the effect, but the effect of restoring the blood flow by the telescopic section 202 is inferior to that of the supporting section 201. The telescopic section 202 mainly plays a role in length compensation when the thrombus taking support is retracted into the sheath; the diameter of the outer stent is particularly thick, the diameter of the outer stent is obviously changed when the outer stent is taken in the sheath, the outer stent is obviously reduced in radial dimension in order to be taken in the sheath, but is obviously increased in axial dimension, because the inner stent and the outer stent are connected with each other at the proximal end and the distal end, at the moment, in order to keep the consistency of the axial dimensional change, the expansion section 202 of the inner stent is obviously lengthened when being pulled, the same elongation as the outer stent is kept, and finally the thrombus taking stent is smoothly taken in the sheath.

In this embodiment, the support section 201 preferably adopts an expandable network-like structure, and the expansion section 203 preferably adopts an axially expandable spring tube; of course, in other embodiments, the segments 201 and 203 may be formed by other structural designs, which are not limited herein.

In this embodiment, the support section 201 and the telescopic section 202 are integrally made, and the specific support section 201 and the telescopic section 202 are in natural transition and tightly connected, and are in different cutting or braiding forms of the same material, and no splicing processing exists.

The support section 201 and the telescopic section 202 have larger diameter difference, the support section 201 is thicker, the diameter is generally (1-1.5) mm, the diameter of the telescopic section 202 is thinner, and the diameter is (0.2-0.3) mm.

Further, the length of the telescopic section 202 occupies the length of the whole thrombus taking support in a ratio of (1/2-1/4). Since the outer stent and the inner stent are ultimately assembled together, the lengths of the two are consistent in the expanded state and the lengths of the two are consistent in the contracted state. The diameter of the outer layer support in the expansion state is obviously larger than that of the inner layer support, and if the inner layer support and the outer layer support are identical in length in the expansion state under the condition that the inner layer support is not specially designed for length compensation, the outer layer support is longer than the inner layer support due to large deformation in the contraction state. The solution is to add a telescopic section to the inner layer bracket. In the contracted state, the length of the inner layer bracket is compensated by the extension of the telescopic section, so that the length of the inner layer bracket is consistent with that of the outer layer bracket.

However, the length of the telescoping section 202 cannot be too long because the inner stent 2 does not function to limit the overall length of the outer stent 1 during retraction and when traversing tortuous vessels after the telescoping section 202 has a ratio of more than 1/2 over the entire inner stent. That is, the elastic force of the expansion section 202 is slightly greater than the traction force applied when the stent is retracted, so as to limit the deformation of the outer stent. At the same time, the telescoping section 202 must not be too short, and the stent must be deformed too much by the spring when contracted, and the larger deformation requires more traction, while the thrombus-withdrawing stent is deployed in the vessel, with a sheath operating in a distance of about 2 meters from the proximal end to the distal end of the guidewire, and it is very difficult for the user to overcome the larger force to retrieve the stent, which would likely result in the stent not being retrieved. Therefore, the length of the expansion section 202 is designed to occupy the whole length of the thrombus taking support with the ratio of (1/2-1/4).

Of course, in other embodiments, the diameters and lengths of the supporting section 201 and the telescopic section 202 can be adjusted according to the specific situation, which is not limited herein.

In this embodiment, the inner stent 2 may also be made of NiTi alloy material.

Specifically, the inner stent 2 may be a multi-strand NiTi wire braided structure, the number of NiTi wires is n, and n ranges from 1 to 10, preferably, n=3/4/5/6. The inner support 2 may also be a wire wrap spring structure, such as: the NiTi wire winding spring, the platinum iridium alloy wire or the platinum tungsten alloy wire, the stainless steel wire, the Huang Jinsi and the like provide tensile force and have certain elasticity. Because the deformation of the NiTi wire is large, the deformation force is small, larger length compensation can be achieved through a small duty ratio, and meanwhile, the traction force is not obviously increased.

The inner layer bracket 2 can also be an assembly of a NiTi alloy tube cutting bracket and a NiTi wire winding yellow spring, the support end is a NiTi alloy tube cutting bracket, the telescopic section is a NiTi wire winding Huang Danhuang, and the combination mode of the two combination positions can be mechanical riveting, joggling, glue bonding, laser welding or combination of a plurality of combination modes.

Of course, in other embodiments, the processing method of the inner support 2 may be selected according to specific needs, which is not limited herein.

Of course, in other embodiments, the inner stent 2 may alternatively be supported by other materials having elastic and shape memory properties, which are not limited.

In this embodiment, the proximal end of the outer stent 1 is connected to the proximal end of the inner stent 2, and the distal end of the outer stent 1 is connected to the distal end of the inner stent 2 to form a stent body; and only the proximal end and the distal end are connected with each other between the outer layer stent 1 and the inner layer stent 2, and the middle section has no point of mutual combination, so that the inner layer stent can realize length compensation.

The connection mode between the outer layer support 1 and the inner layer support 2 can be nesting of a mechanical structure, physical press-holding connection, metal lantern ring, laser welding, adhesive bonding and the like, one of the connection modes, or a combination of a plurality of connection modes, is not limited, and can be adjusted according to specific needs.

In the embodiment, the proximal end of the whole stent body gradually tapers from the distal end direction to the proximal end direction to make the stent body smooth and slender, so that the pulling force required by an operator in the process of recovering the thrombus taking stent is gradually increased instead of the cliff type abrupt increase, and the thrombus taking stent, thrombus and clot are smoothly recovered; instead of being clamped at the sheath orifice, larger force is required to be made, the force suddenly breaks through a threshold value, and the thrombus taking support is suddenly pulled into the sheath; the condition that the suddenly broken threshold value is recovered can cause the following 2 adverse effects, (1) the weak supporting rod of the thrombus taking bracket cannot bear gradually accumulated tensile force, and is broken by pulling to puncture blood vessels, so that intracranial or carotid artery hemorrhage is caused; (2) The thrombus taking support and the blood vessel wall are rapidly rubbed to damage the inner wall of the blood vessel, or clamp the inner wall of the blood vessel when crowded, and tear the inner wall of the blood vessel when suddenly breaking through a threshold value; these adverse consequences can be surgical failure, or serious complications.

In this embodiment, the thrombus-taking stent further comprises a catching structure 2 for intercepting thrombus or clot escaping from the stent body, and the catching structure 2 is connected to the distal end of the stent body. In the process of withdrawing and retracting the thrombus taking support into the sheath, if the condition that thrombus is crushed and falls off occurs, the catching structure 2 is used as a protection tool, so that the fallen thrombus or clot can be captured again, the escape of the thrombus is reduced, the risk that the intracranial distal blood vessel is blocked again due to the falling thrombus is reduced, and the thrombus taking support is an effective protection tool.

The catching structure 3 adopts a fusiform network structure, has compact meshes and is used for intercepting tiny thrombus and clots which fall off and escape from the main body part of the thrombus taking bracket in the dragging process; the proximal end of the catching structure 3 is open and the distal end is closed, i.e. the end of the catching structure 3 facing the stent body has a second opening.

Wherein the fishing structure 3 is connected with the far end of the outer layer bracket 1; specifically, the distal end fishing net of the thrombus-taking bracket is in natural transition and tight connection with the outer bracket of the main body part, and is in different cutting or braiding modes of the same material, and no splicing processing is adopted. Furthermore, the connecting end between the fishing structure 3 and the outer layer bracket 1 adopts a hypotube design.

Of course, in other embodiments, the fishing structure 3 may be connected to the distal end of the inner stent 2, or both the inner stent 2 and the outer stent 1, and may be adjusted according to specific needs without limitation.

Wherein, the maximum diameter of the catching structure 3 is consistent with the outer layer bracket 1 of the bracket drawing and is (3-6) mm. The outer diameter of the main body bracket of the thrombus taking bracket with the same model specification is the same as that of the catching structure 3, and the outer diameter dimension tolerance is not more than 0.25mm.

Of course, in other embodiments, the arrangement of the catching structure 3 may be omitted, without limitation.

In this embodiment, the thrombus taking support further includes a push rod, and the push rod is connected to the proximal end of the support body, so as to realize pushing or taking out of the support body.

The connection mode between the pushing rod and the bracket main body can be nesting of a mechanical structure, physical press-holding connection, a metal lantern ring, laser welding, adhesive bonding and the like, one of the connection modes can be adopted, the combination of multiple connection modes can be adopted, the selection can be carried out according to specific conditions, and the connection mode is not limited.

The push rod is made of NiTi alloy wires (rods), can be a single thicker metal rod, can be a metal rope woven by a plurality of thinner metal wires, and can be 2/3/5/7/9 in number; alternatively, the pushing rod can be made of single or multi-strand stainless steel wires; or the pushing rod can be made of a plurality of NiTi alloy wires and stainless steel wires which are mixed and woven; or the pushing rod can be made of a single metal pushing rod formed by butt welding and splicing a single NiTi alloy rod and a stainless steel rod.

Further, the push rod can be divided into an outer layer and an inner layer, the inner layer is a single metal rod, the outer layer is a plurality of strands of metal wires, and the plurality of strands of metal wires can be of a woven structure or a coiled spring structure.

In this embodiment, the specific materials and manufacturing methods of the pushing rod can be adjusted according to specific needs, and the pushing rod is not limited herein.

In this embodiment, one end of the push rod is connected with the bracket main body in a cylindrical shape, a round rod shape or a sphere shape, and is used for being inserted and matched with an opening on the bracket main body, one end of the specific push rod is directly ground into a cylindrical structure by adopting a NiTi wire, or is welded into a sphere by adopting a laser fusion mode, or is sleeved at the end of the NiTi wire by adopting a biocompatible heat shrinkage sleeve, and a round rod is obtained by heat shrinkage; the forming manner of the pushing rod end is not limited to the above, and can be adjusted according to the specific situation.

Of course, in other embodiments, one end of the push rod connecting support body is of a ring structure, and is used for being inserted and matched with an insert on the support body, and the specific ring structure can be of a ring structure made of stainless steel or platinum or other materials, or can be a biocompatible polymeric ring, which is not limited herein.

In this embodiment, the thrombus taking support is further provided with developing parts at a plurality of positions, so that the use process of the thrombus taking support can be observed conveniently.

Wherein, the main body bracket is provided with a first developing part; specifically, the proximal ends, the middle sections and the distal ends of the outer layer support 1 and the inner layer support 2 are uniformly provided with first developing parts.

Wherein, the catching structure 3 is provided with a second developing part; specifically, the fishing structure 3 is provided with the extension rod on the one end that is away from the support main part, and the second development portion sets up on the extension rod, and this extension rod has the function of developing except that still has the function of direction simultaneously, and further this extension rod still has soft characteristic. The extension rod can be of a multi-layer structure, the inner layer is a single NiTi rod or a plurality of NiTi wires, the outer layer is at least provided with one layer of developing wire spring winding shaft, and the inner layer of the optimized thin extension rod can also be made of stainless steel materials; the choice of materials and the construction of the extension rod can be adjusted according to the specific circumstances, and are not limited herein.

Of course, in other embodiments, the extension rod may be omitted, and the developing units may be directly disposed at two ends of the capturing structure, and may be adjusted according to the specific situation, which is not limited herein.

The pushing rod is provided with a third developing part, and the specific third developing part is arranged at the connection position of the distal end of the pushing rod and the bracket main body.

In this embodiment, the first developing portion, the second developing portion, and the third developing portion may specifically be one or more of a developing wire, a developing point, a developing sheet, a developing lever, or a developing ring; when the first developing part, the second developing part and the third developing part are developing wires, the developing wires can be connected to the thrombus taking support in a braiding mode; when the first developing part, the second developing part and the third developing part adopt developing points, developing films, developing rods or developing rings, one or a combination of a plurality of connecting modes of winding springs, nesting of mechanical structures, physical pressing and holding connection, metal lantern rings, laser welding, adhesive bonding (the adhesive can be selected from the le-Tai 4011 glue, the le-Tai 4031 glue and the like) and the like can be adopted for connecting to the thrombus taking support.

Further, the materials of the first developing part, the second developing part and the third developing part can be platinum-tungsten alloy, can be platinum-tungsten alloy sheets and/or platinum-tungsten alloy wires, can be gold, platinum-iridium alloy, tungsten gold, tantalum gold and the like, can be metal sheets, and can also be metal dots formed by adding adhesives such as glue into metal powder; the developing material is specifically selected according to the difference in the position and the developing effect, and is not limited here.

Example 2

Referring to fig. 6-7, this embodiment is an adjustment made on the basis of embodiment 1.

In this embodiment, the inner support 2 'includes a plurality of support sections 201', and a telescopic section 202 'for compensating the overall length of the inner support 2' is provided between adjacent support sections.

The lengths of the supporting sections 201' may be the same or different, and may be adjusted according to specific situations without limitation.

Wherein the support section 201' preferably adopts an expandable network-like structure; of course, in other embodiments, the segments 201 and 203 may be formed by other structural designs, which are not limited herein.

The telescopic section 202 'is a structure with adjustable size along the length direction of the inner layer bracket 2'; in this embodiment, the expansion section 202 'has a "cross-shaped" structure, which has a smaller radial dimension and an increased axial dimension when the inner stent 2' is stretched in the longitudinal direction. Of course, in other embodiments, the expansion section 202' may be implemented by a spring tube, etc., and may be adjusted according to the specific situation without limitation.

In the same embodiment, the supporting section 201 and the telescopic section 202 are integrally formed, and the specific supporting section 201 and the telescopic section 202 are in natural transition and are in tight connection, and are in different cutting or braiding modes of the same material, and no splicing processing exists.

Example 3

The present embodiment provides a method for manufacturing a thrombus-taking stent, which is used for processing the thrombus-taking stent described in embodiment 1.

The manufacturing method of the thrombus taking bracket in the embodiment specifically comprises the following steps:

s1, respectively and independently processing each component part on the thrombus taking support.

Wherein each component comprises an outer layer bracket, an inner layer bracket, a catching structure and a push rod; when the fishing structure and the push rod are not arranged, the processing process can be omitted;

wherein, the laser cutting of the metal structure or the laser engraving of the metal structure or the braiding of the metal wire are adopted to respectively process each component part. Furthermore, the femtosecond laser engraving machine is needed for laser engraving, which is beneficial to ensuring the processing process of the high precision of the thrombus taking support.

S2, performing heat treatment shaping on the processed components.

Wherein, the outer layer bracket and the catching structure are heat-treated together to shape and expand the diameter, and the expansion section in the inner layer bracket is not required to expand, so the inner layer bracket is heat-treated separately to shape and expand the diameter,

Wherein, the expansion amount of the inner layer stent is smaller than that of the outer layer stent; specifically, the diameters of the outer stent and the distal fishing structure need to be expanded from the size of the cutting tube to the target size, the expansion multiple of the diameter is 6-12 times, and the expansion quantity is large; the inner layer support only needs diameter expansion of the support section, the expansion section does not need expansion, the diameter of the support section needs to be expanded from the size of the cutting pipe to the target size, the expansion multiple of the diameter is 3-6 times, and the expansion quantity is smaller than that of the outer layer.

Wherein, the outer layer bracket, the catching structure and the inner layer bracket need to be subjected to heat treatment shaping for a plurality of times, so that the diameter of the outer layer bracket and the inner layer bracket gradually expands to the target value.

Specifically, as the expansion amount of the outer layer stent and the far-end fishing net is larger, the diameter of the stent is gradually expanded to the target size by multiple times of heat treatment, and the number of times of heat treatment setting is 3-6 times; and the temperature and time are different for each heat treatment setting, and the specific heat treatment parameters are shown in table 1.

Table 1 shows the heat treatment parameters of the outer stent of the thrombus-taking stent and the distal fishing net:

the inner layer bracket only needs heat treatment for shaping the expansion diameter of the support section, and the cutting pipe can be supported to the target size by 1-3 times of heat treatment for shaping due to the small expansion quantity. The specific heat treatment parameters are shown in Table 2.

Table 2 shows the heat treatment parameters of the inner stent of the thrombus removal stent:

of course, in other embodiments, the number of heat treatments of the inner and outer stent is not limited to the above; the number of times of heat treatment of the inner and outer layer brackets can be determined according to the model specification of an actual sample, and the principle is that the larger the expansion amount of the bracket diameter is, the more times of heat treatment shaping are, and vice versa. Preferably, no matter how many times the heat treatment is carried out on the bracket for shaping, the technological parameters of the last heat treatment shaping are as follows: the heat treatment temperature is 500-650 ℃, the heat treatment time is 5-35 min, and the argon flow is 5-20 mL/min.

In the heat treatment shaping process of each component part, the original air in the heat treatment space is firstly exhausted, and then inert gas is filled into the heat treatment space, so that the airtight state of the heat treatment space is ensured in the treatment process.

Specifically, the furnace chamber can be vacuumized and then filled with inert gas for protection, such as argon and the like, in the heat treatment process, and the furnace chamber is kept in a closed state in the whole heat treatment process. Considering that the pressure in the hearth is increased after the gas is heated, when the gas is introduced after vacuumizing, the hearth is in a negative pressure state, and the pressure in the hearth is about 1/3-2/3 of the atmospheric pressure.

Or, inert gas such as argon is introduced for a period of time in the heat treatment process, the ventilation time is (10-30) min, and after the air in the furnace is completely discharged, the inert gas is introduced into the furnace while the air is discharged outwards, so that the air in the furnace is mainly inert gas and cannot enter, the pressure in the furnace is required to be higher than the atmospheric pressure, and the pressure in the furnace is about 1.2-1.5 atmospheres.

S3, carrying out acid washing and electrochemical polishing treatment on each component;

among them, the purpose of the acid cleaning polishing process is to remove an oxide film generated on the metal surface during the heat treatment.

Specifically, the process firstly uses acid solution to remove oxide skin on the metal surface, but the bracket surface is dark silver gray at the moment, so as to make the metal surface bright silver white; or in order to achieve the purpose of smoothing the surface of the bracket, reducing friction force, removing burrs and the like in the laser engraving process; or to achieve increased corrosion resistance of the stent, to improve biocompatibility; or in order to make all the net-shaped struts of the stent become more round, elliptical in cross section, one or more or all of the purposes of enhancing the supporting force, reducing the stress concentration, and the like. And removing the dark silver gray metal film on the surface of the metal bracket by using an electrochemical polishing process to form a new bright silver white surface and even enable the mirror surface.

S4, arranging developing materials on the component parts;

s5, assembling and connecting all the forcing parts to form the complete thrombus taking support.

It will be appreciated by those skilled in the art that the invention can be embodied in many other specific forms without departing from the spirit or scope thereof. Although embodiments of the present invention have been described, it is to be understood that the present invention should not be limited to these embodiments, but that variations and modifications can be made by one skilled in the art within the spirit and scope of the present invention as hereinafter defined in the appended claims.

Claims (7)

1. A thrombus taking stent, comprising a radially self-expandable, axially stretchable stent body which tapers in a proximal direction from a distal direction to a smooth elongate shape; the main body of the stent comprises an outer stent and an inner stent, wherein the inner stent is arranged in the outer stent, the proximal end of the outer stent is connected with the proximal end of the inner stent in the axial direction, the distal end of the outer stent is connected with the distal end of the inner stent in the axial direction, the outer stent and the inner stent are only connected with each other at the proximal end and the distal end, and the inner stent provides supporting force for the outer stent in the axial direction, so that the thrombus taking stent can provide stronger resistance when being dragged, the length and the diameter of the outer stent are kept almost unchanged, and simultaneously, by virtue of the supporting force, embolic tissues can be instantly opened to recover blood supply of embolic blood vessels; the side surface of the outer layer bracket is also provided with a first opening for a clot to enter the outer layer bracket;

The outer layer bracket is formed by sequentially connecting a plurality of bracket units, and each bracket unit is of a structure which is symmetrical up and down and left and right; the two symmetrical sides of each bracket unit are respectively provided with the first opening, and the area of the first opening part of each bracket unit is 0.8-1.5 times of the area of the non-opening part;

the inner layer bracket comprises at least one supporting section and at least one telescopic section which are connected, and the telescopic section is used for compensating the whole length of the inner layer bracket; the length of the telescopic section accounts for 1/4-1/2 of the length of the thrombus taking support, the diameter of the supporting section is 1mm-1.5mm, and the diameter of the telescopic section is 0.2mm-0.3mm;

the bracket units have the same structure, and every two adjacent bracket units are connected by rotating by 90 degrees in the circumferential direction; the connection points of the two adjacent bracket units are discontinuous on the same connecting line parallel to the axial direction.

2. The thrombolytic stent of claim 1, wherein said inner stent comprises a support section and a telescoping section, said support section being at a proximal end and said telescoping section being at a distal end; or, the inner layer support comprises a plurality of support sections, and a telescopic section is arranged between every two adjacent support sections.

3. The thrombolytic stent of claim 2, wherein said telescoping section is an axially telescoping spring tube; or the telescopic section is of a cross-shaped structure with adjustable size along the length direction of the inner layer bracket; the support section is an expandable network-like structure.

4. The thrombolytic stent of claim 1, further comprising a catch structure for intercepting clots escaping from said stent body, said catch structure being attached to a distal end of said stent body and having a second opening at an end thereof facing said stent body;

the fishing structure is connected with the distal end of the outer layer bracket;

the fishing structure adopts a fusiform network structure.

5. The thrombolytic stent of claim 4, wherein a first developing portion is provided on said stent body; an extension rod is arranged at one end of the catching structure, which is opposite to the bracket main body, and a second developing part is arranged on the extension rod; the device also comprises a push rod, wherein the push rod is connected with the proximal end of the bracket main body, and a third developing part is arranged on the push rod.

6. A method for manufacturing a thrombus taking support, which is characterized in that the method is used for manufacturing the thrombus taking support as claimed in any one of claims 1 to 5, and comprises the following steps:

S1, respectively and independently processing each component part on the thrombus taking support;

s2, performing heat treatment shaping on the processed components;

s3, carrying out acid washing and electrochemical polishing treatment on each component;

s4, arranging developing materials on the component parts;

s5, assembling and connecting all the components to form a complete thrombus taking bracket;

step S2 further comprises: the outer layer stent and the fishing structure are subjected to heat treatment to form the expanded diameter together, the inner layer stent is subjected to heat treatment to form the expanded diameter independently, and the expansion amount of the inner layer stent is smaller than that of the outer layer stent;

wherein, the outer layer bracket, the catching structure and the inner layer bracket are all required to be subjected to heat treatment shaping for a plurality of times, so that the diameters of the outer layer bracket, the catching structure and the inner layer bracket are gradually expanded to the target values;

in the heat treatment shaping process of each component part, the original air in the heat treatment space is firstly exhausted, and then inert gas is filled into the heat treatment space, so that the airtight state of the heat treatment space is ensured in the treatment process.

7. The method of claim 6, wherein step S1 further comprises: laser cutting of the metal structure or laser engraving of the metal structure or braiding of the metal wire are adopted to respectively process each component part; each component part comprises an outer layer bracket, an inner layer bracket, a catching structure and a push rod.