WO2010006786A1 - Implant with a braided mesh structure and method for producing such an implant - Google Patents

Abstract

The invention relates to an implant having a braided mesh structure (20), comprising wire elements (11) proximate to cells (14), wherein at least two wire elements (11) are disposed in an intersecting manner forming an intersection area (10). The implant according to the invention is characterized in that the braided mesh structure (20) comprises an elastically deformable support means (12) locally limited to the intersection area (10), said support means connecting the wire elements (11) in the intersection area (10) such that an elastic reset force acting on the braided mesh structure (20) can be adjusted by way of a relative movement of the wire elements (11) forming the intersection area (10). The invention further relates to a method for manufacturing such an implant, wherein at least two wire elements (11) braided into a mesh structure (20) are disposed in intersecting fashion for forming an intersection area (10) and are provided with a supporting means (12) that is locally limited to the intersection area (10).

Description

 MEISSNER BCDLTE

PO Box 860624 81633 Munich

Acandis GmbH & Co. KG July 15, 2009

Kolpingstraße 5 M / CAN-053-PC

76327 Pfinztal MB / JK / MP / hb

A braided mesh implant and method of making such an implant

description

The invention relates to an implant with a braided grid structure according to the preamble of patent claim 1. Such an implant is known from WO 2006/124541 A2. Furthermore, the invention relates to a method for producing such an implant.

The aforementioned WO 2006/124541 A2 discloses a stent which is formed from a wire mesh. The wire mesh comprises wire elements which are alternately guided over and under each other and form intersection areas. The wire elements are freely movable in the crossing areas, i. that the wire elements can slide on each other. In order to avoid open wire ends, the stent has closed wire loops, which are formed by welding the wire ends. The welded wire ends are positioned between two adjacent intersections or nodes. The known stent may additionally be provided with a cover or coating of a polymeric material.

The expansion or radial force of the stent according to WO 2006/124541 A2 or generally braided stents is low compared to other known stents with comparable dimensions.

The radial force corresponds to the force that acts in the radial direction in the implanted state of the stent perpendicular to the vessel wall and arises from the fact that the stent MEISSNER, BOLTE & PARTNER M / CAN-053-PC

initially deformed upon compression into a delivery system (catheter), with the maximum amount of deformation force stored in the form of potential elastic energy. Upon discharge from the delivery system into the vessel, the stent expands, releasing some of its potential energy. The expansion does not take place to the original diameter, but to the smaller vessel diameter, so that a residual deformation with respect to the set diameter of the stent remains. The remaining force with which the stent tries to return to the original diameter corresponds to the radial force.

In braided stents, a change in the cross-sectional diameter of the stent, for example, when compressed into a delivery system, results in a sliding of the wire elements in the intersection regions. The frictional force between the wire elements caused by the sliding action counteracts the radial force of the stent so that the radial force is reduced. When increasing the fine mesh of the stent, i. by providing a higher number of thinner wire elements, the total frictional force between the stent wire elements is further increased while the radial elastic restoring force decreases due to the relatively thin wires. There is a risk that the stent will not expand sufficiently after discharge from the delivery system because the frictional force between the wire elements is greater than the return or radial force. Such an implant is not suitable for stabilization of a blood vessel.

Furthermore, a stent is known from US 2005/0055081 A1 which has a cover or coating made of polytetrafluoroethylene (PTFE), in particular expanded PTFE (ePTFE). The coating can be applied both on the outside of the stent, as well as on the inner side. Preferably, the coating is applied on both sides in the known stent, so that the grid structure of the stent is completely embedded in the ePTFE coating. The material ePTFE is biocompatible, water repellent and inelastic.

Above all, due to the inelastic properties, there is the disadvantage that the stent according to US 2005/0055081 A1 has a relatively low flexibility. The radial force acting on the vessel wall in the implanted state is limited by the inelastic coating, so there is a risk that the stent is not securely and firmly fixed in the vessel. This risk is further increased by the low coefficient of friction of the material ePTFE. MEISSNER, BOLTE & PARTNER M / CAN-053-PC

The complete coating of a stent also has the disadvantage that a large volume of material, in particular plastic volume, is necessary, which must be compressed when introducing the stent or implant into the delivery system. The increased footprint of the coating prevents compression of the stent to the small diameter of the delivery system.

The invention is therefore based on the object to provide an implant with a braided grid structure that can be securely fixed in the body. Furthermore, the object of the invention is to provide a simple and cost-effective production of such an implant.

According to the invention, this object is achieved with regard to the implant by the subject matters of claims 1 and 19 and with regard to the manufacturing method by the subject-matter of claim 20.

The invention is based on the idea of specifying an implant with a braided grid structure comprising cell-limiting wire elements, wherein at least two wire elements are arranged crossed and form a crossing area. In this case, the braided lattice structure has a locally deformable on the crossing region, elastically deformable holding means which connects the wire elements in the crossing region such that a force acting on the braided grid structure elastic restoring force is adjustable by a relative movement of the intersection region forming wire elements.

In general, the structure of braided implants, in particular stents, can be set very finely with respect to other stents known from the prior art by the choice of the wires. Due to the fine mesh, the flow conditions can be significantly influenced, for example, in aneurysms. For example, when placing a stent on a plaque deposit, the fine structure prevents plaque particles from peeling off and entering the bloodstream. In addition, the (re) growing or the (re) closure of the vessel is made more difficult by the fine meshes of the stent. Rather, the fine mesh structure causes the surface of the implant to be covered by endothelial cells, forming a thin layer of tissue that restores the natural vascular properties. MEISSNER, BOLTE & PARTNER M / CAN-053-PC

The elastically deformable holding means in the crossing region offers the advantage that the restoring force, in particular expansion force or radial force, of the implant according to the invention is increased in comparison to known implants. This will provide better fixation and stabilization of the implant in use, i. in the implanted state within a body, such as a blood vessel, achieved. It is due to the fact that the elastically deformable holding means is deformed in the compression of the implant by an external force in the elastic region and thus stores potential energy. During implantation and elimination of the external compression constraint, the stored potential energy in the retention means results in enhanced expansion force or radial force, resulting in improved and more stable fixation of the implant. In this way, it is possible to reduce the cross-sectional diameter of the wire elements, so that the number of wire elements for forming a braided grid structure can be increased. Due to the elastically deformable holding means, a sufficient expansion force is nevertheless achieved for secure fixation of the implant. The increase in the number of wire elements is advantageous in that in this way an increased fine mesh and flexibility of the braided grid structure is achieved.

In general, in this way an implant with a braided lattice structure is provided, which is characterized by a particularly high degree of fine mesh, flexibility and expansion or radial force. Unlike implants that have a complete coating, the holding means limited locally to the crossing area allows the implant, particularly stents, to be compressed to a relatively small cross-sectional diameter, since the space requirement of the locally limited holding means is smaller than that of a complete coating.

As elastic in the context of the invention compounds are referred to, which differ from inelastic connection types such as cold working, welding or brazing. In particular, the elastic holding means according to the invention has comparable properties as plastics or superelastic shape memory materials. This does not exclude that the deformation of the holding means is also partially plastic, that is, that the deformation energy is also partially converted into thermal energy. However, mainly the elastic properties of the holding agent lead to the success of the invention. MEISSNER, BOLTE & PARTNER M / CAN-0S3-PC

In a preferred embodiment of the implant according to the invention, the holding means substantially completely surrounds the wire elements in the crossing region. In this way, the fixation of the two wire elements in the crossing region is improved and stabilized. Furthermore, the complete covering of the node or the wire elements in the crossing region has the advantage that all spaces between the wires are filled by the holding means. When using the implant in blood vessels, the risk of coagulation is thereby reduced, since the blood is not stowed by unevenness of the lattice structure. In this way, the risk of clot formation and subsequent vascular occlusion can be reduced. Furthermore, it is achieved by the complete covering of the knot or the wire elements in the crossing region that abrasion of the material of the wire elements is prevented by slipping on of the wire elements or can not get into the bloodstream.

Preferably, the retaining means extends at least partially along the wire elements. As a result, the node or the intersection region and the wire elements themselves are additionally stabilized. In particular, when using wire elements with a very small cross-sectional diameter, the overall stability of the implant is increased in this way.

The holding means may connect the wire elements substantially cohesively. The cohesive connection is particularly easy to manufacture and ensures a permanent and firm connection of the wire elements in the crossing area.

In a preferred embodiment of the implant according to the invention, the holding means has a wall thickness of at most 80 μm, in particular at most 60 μm, in particular at most 40 μm, in particular at most 20 μm, in particular at most 15 μm, in particular at most 10 μm, in particular at most 8 μm, in particular at most 6 μm, in particular at most 5 μm, in particular at most 4 μm, in particular at most 3 μm. The choice of the wall thickness of the holding means meets the expert in the context of his expert knowledge depending on the material properties and the cross-sectional diameter of the underlying lattice structure and the intended use. The wall thickness can vary within a holding means. MEISSNER, BOLTE & PARTNER M / CAN-053-PC

The holding means may partially and / or completely cover the cells of the braided grid structure. Preferably, the braided lattice structure comprises at least two, in particular a plurality, intersection regions, each having locally limited holding means.

Advantageously, the locally limited holding means are arranged in edge regions of the grid structure. In this way, an increased expansion or radial force is effected in the edge regions of the implant or the lattice structure. In this way, the risk is minimized that the edge regions of the grid structure does not expand sufficiently due to the high frictional forces between the wire elements. In the case of stents, for example, this leads to a cigar form which can result in at least partial blockage of the blood vessel by the stent ends protruding into the bloodstream. Due to the elastic properties of the holding means this effect is avoided.

Furthermore, different holding means, in particular with different moduli of elasticity or dimensions or shapes, can be arranged in the longitudinal and / or circumferential direction of the grid structure. The usually homogeneously braided lattice structure holds in this way different areas of force, that is, areas that apply different expansion or radial forces in the implanted state, so that the implant can be well adapted to specific anatomical events.

Holding means with different elastic properties are preferably arranged in a middle area of the grid structure than in an edge area of the grid structure. The holding means in a central area of the grid structure may have different shapes or dimensions than other areas of the grid structure in order to produce a higher expansion or radial force with the same deformation of the grid structure. This can also be achieved by means of adhesive in the middle region of the lattice structure, which have a higher modulus of elasticity than the retaining means in the edge regions. As a result, the compliance of the implant or stent is increased, ie a fluid transition is provided between the edge regions of the lattice structure and the adjacent body tissue, for example a blood vessel wall. In particular, with stent-like implants, the load on the vessel walls is reduced in this way, since essentially MEISSNER, BOLTE & PARTNER M / CAN-053-PC

shear stresses at the stent ends occurring by a blood vessel, as the elastic stent ends follow the pulsating vessel.

The expansion force of the implant can also progressively and / or continuously decrease gradually from a central region of the lattice structure to the edge regions. In general, all known to the expert options for a variation of the expansion force along the implant are possible.

In a particularly preferred embodiment of the implant according to the invention, the braided grid structure has a tubular shape, which can be converted from an expanded state having a relatively large cross-sectional diameter into a compressed state having a relatively smaller cross-sectional diameter. The tubular, braided grid structure or the stent is particularly suitable for use in body vessels, preferably in blood vessels. The ability to compress the stent to a smaller cross-sectional diameter, it is achieved that the stent can be easily and minimally invasively by means of a delivery system, in particular a catheter, brought to the treatment site.

The cross-sectional diameter of the tubular braided lattice structure may be at least 10%, in particular at least 20%, in particular at least 30%, in particular at least 40%, in particular at least 50%, in particular at least 60%, in particular at least 70%, during the transition from the expanded to the compressed state. , in particular at least 80%, in particular at least 90%, be changeable. A change in the diameter of 90% means that the tubular lattice structure or the stent in the compressed state has a diameter of 10% of the original cross-sectional diameter in the expanded state. The percentage change in the cross-sectional diameter Δd is calculated from d " ^{p ~ dkomp-} l00%

wherein dexp corresponds to the cross-sectional diameter of the stent in the expanded state and dkomp the cross-sectional diameter of the stent in the compressed state. MEISSNER, BOLTE & PARTNER M / CAN-053-PC

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The braided lattice structure preferably has a braiding angle which is at least 40 °, in particular at least 45 °, in particular at least 50 °, in particular at least 55 °, in particular at least 60 °, in particular at least 65 °, in particular at least 70 °. The braiding angle of the grid structure is defined as the angle formed between a wire element and the projection of the longitudinal axis onto the plane of the wire element.

The braiding angle of the braided lattice structure may be at least 10 °, in particular at least 15 °, in particular at least 20 °, in particular at least 25 °, in particular at least 30 °, in particular at least 35 °, in particular at least 40 °, when the lattice structure changes from the expanded to the compressed state , in particular at least 45 °, in particular at least 50 °, in particular at least 55 °, in particular at least 60 °, in particular at least 65 °, in particular at least 70 °, be changeable. This ensures the necessary flexibility to implant the stent or the implant in general through a small delivery system minimally invasive.

The cells preferably have a longitudinal extent along a longitudinal axis of the lattice structure, which at the transition of the tubular, braided lattice structure from the expanded to the compressed state by at least 40%, in particular at least 50%, in particular at least 60%, in particular at least 70%, in particular at least 75 %, in particular at least 80%, in particular at least 90%, in particular at least 100%, in particular at least 125%, in particular at least 150%, in particular at least 175%, in particular 200% is changeable. The longitudinal extent of the cells is essentially defined by the distance between two intersections or nodes of the lattice structure, which are arranged in the same plane as a longitudinal axis of the tubular lattice structure.

In a preferred embodiment of the implant according to the invention, the ratio of the wall thickness of the holding means to the cross-sectional diameter of the wire elements is at most 50%, in particular at most 40%, in particular at most 30%, in particular at most 20%, in particular at most 10%, in particular at most 8%, in particular at most 5 %.

The holding means and / or the wire elements may in a preferred embodiment of the implant according to the invention a biocompatible plastic MEISSNER, BOLTE & PARTNER M / CAN-053-PC

and / or a superelastic shape memory material. The elastic properties of plastics are particularly suitable for use as elastically deformable holding means. Particularly preferred is the use of the plastic polyurethane (PU). PU is characterized by biocompatibility and elasticity in a wide range of expansion. Further advantages of the material PU are that the hardness of the plastic can be adjusted so that the holding means formed from PU do not stick together when compressing the grid structure, in particular when folding the holding means. Further, PU has a low tear propagation, that is, a high tear strength. Alternatively or additionally, the holding means may comprise other plastics, for example silicones or Teflon. The use of superelastic shape memory materials is preferred to provide an implant having a self-expanding lattice structure. Such materials include, for example, nickel titanium alloys, especially nitinol.

The holding means may further comprise a biodegradable and or drug-bearing material. The additionally caused by the holding means expansion or radial force is guaranteed until the degradation of the material. When using the implant as a stent can be expanded in this way, for example, stenoses in blood vessels with the increased expansion or radial force. After the successful expansion of the blood vessel, it has proven to be advantageous if the expansion or radial force subsides, in order to promote the healing of the vessel walls and thus to reduce the risk of restenosis. The reduction of the expansion or radial force is achieved in this embodiment of the implant according to the invention in that the holding means is degraded in the implanted state. Suitable biodegradable materials are, for example, chitin, chitosan and / or cellulose. By alternative or additional use of medicament-containing materials, anticoagulant substances, for example, can be dispensed over an extended period of time in a region of a blood vessel to be treated, thereby reducing the risk of re-formation of blood clots.

The invention is further based on the idea of specifying an implant with a braided grid structure comprising cell-limiting wire elements, wherein at least two wire elements are arranged crossed and form a crossing area. In this case, the braided grid structure a locally limited to the crossing region holding means which connects the wire elements in the crossing region. By locally limited to the crossing area holding means is achieved MEISSNER, BOLTE & PARTNER M / CAN-053-PC

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the wire elements in the crossing region are essentially fixed in position in relation to known implants with braided lattice structure, so that a sliding movement of the wire elements is prevented or at least restricted from one another.

The connection of the wire elements can be done by gluing, i. that the holding means comprises, for example, epoxy resin, polyurethane adhesive or silicone adhesive. Furthermore, the wire elements can be connected to each other by cold forming, laser or ultrasonic welding or soldering. Other connection types are also possible.

Furthermore, the invention is based on the idea to provide a method for producing an implant, wherein at least two wire elements, which are braided into a lattice structure, crossed arranged to form a crossing region and provided with a locally limited to the crossing region holding means.

The locally limited holding means preferably comprises an elastic material. Furthermore, the locally limited holding means can be produced by a spraying or dipping method. Thereby, a particularly simple method is provided to connect the wire elements in the crossing area by an elastic holding means with each other.

The invention is explained in more detail below on the basis of embodiments with reference to the accompanying schematic drawings. Show in it

1 shows a crossing region of an implant according to the invention according to a preferred embodiment in the expanded state of the lattice structure.

FIG. 2 shows an intersection region according to FIG. 1 in the compressed state of the lattice structure; FIG.

3 shows a cross section through an intersection region according to FIG. 2;

4 shows a plan view of an implant according to the invention in a preferred embodiment in the expanded state of the lattice structure; MEISSNER, BOLTE & PARTNER M / CAN-0S3-PC

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5 shows a plan view of an implant according to the invention according to FIG. 4 in the compressed state of the lattice structure;

6 shows a cross section through an intersection region of an implant according to the invention according to FIG. 5;

7 shows a plan view of an implant according to the invention according to a further preferred embodiment in the compressed state of the lattice structure;

8 shows a plan view of a cell of an implant according to the invention according to a further preferred embodiment in the expanded state of the lattice structure; and

9 shows a plan view of a cell according to FIG. 8 in the compressed state of the lattice structure.

1 shows an intersection region 10, which is formed by two wire elements 11 arranged one above the other and at an angle. In the context of the invention, intersection regions 10 are understood to be those regions of a braided lattice structure 20 which are to be assigned directly to intersecting wire elements 11. This means, above all, that neighboring crossing regions 10 do not touch or overlap. Between adjacent intersection regions 10, the lattice structure 20 therefore has free wire element sections 13. The intersection region 10 comprises at least the contact point 16 or overlapping region of the intersecting wire elements 11. The extent of the intersection region 10 along a wire element 11 is less than half the distance between two adjacent contact points 16. In this case, the intersection region 10 can also comprise a plurality of wire elements 11, which overlap in a cross or star shape and abut each other. For example, three wire elements 11 may cross each other in a star shape in a contact point 16 or a plurality of mutually parallel, contacting wire elements 11 may cross a single or a plurality of (parallel arranged, contacting) wire elements 11, so that a substantially diamond-shaped crossing region 10 is formed.

In the crossing region 10, a holding means 12 is arranged, which is connected to the wire elements 11. The holding means 12 comprises a film or coating which MEISSNER, BOLTE & PARTNER M / CAN-0S3-PC

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is elastically deformable. The elastic deformability can be visible, especially visible to the naked eye. For this purpose, the holding means 12 on a material which is at least comparable to a plastic. The material for the holding means 12 particularly preferably has an E modulus which is at most 110 MPa, in particular at most 100 MPa, in particular at most 90 MPa, in particular at most 75 MPa, in particular at most 50 MPa, in particular at most 20 MPa, in particular at the highest 18 MPa, in particular at most 16 MPa, in particular at most 14 MPa, in particular at most 12 MPa. Advantageously, the holding means 12 has an E modulus of at most 10 MPa, in particular at most 9 MPa, in particular at most 8 MPa, in particular at most 7 MPa, in particular at most 6 MPa, in particular at most 5 MPa, in particular at most 4 MPa, in particular at most 3 MPa, in particular at most 2 MPa, up. Other materials with an E-modulus of at most 5000 MPa can also be used. Basically, plastics such as polyurethane, silicone, polyurethane-silicone mixtures, polyphosphazenes, PTFE, generally bioabsorbable materials and / or adhesives are provided as the material for the holding means 12. Polyphosphozene, for example, are characterized by biocompatible, anti-inflammatory, bacteria-resistant properties and promote the growth of endothelial cells. In addition, it is easily moldable, allows high mechanical strains and has good adhesive properties, which allows a simple coating. Furthermore, the holding means 12 may comprise shape memory materials, in particular superelastic shape memory materials or materials with a high elastic elongation, such as β-titanium alloys or cobalt-base alloys, or materials with comparable properties.

The retaining means 12 according to FIG. 1, in expanded relation to the compressed state of the lattice structure 20, causes substantially no or at least minimal elastic prestressing force and is of rectangular design. Other shapes, for example round coating forms for fixing the wire elements 11 are conceivable. The holding means 12 or the coating can also be adapted to the shape of the crossing region 10. For example, the holding means 12 may be formed like a spider web or a tent roof. Adjacent to the crossing region 10, the wire elements 11 continue in the form of free wire element sections 13.

2 shows the intersection region 10 in the compressed state of the lattice structure 20, wherein the holding means 12 is elastically deformed, since the wire elements 11 are in complex MEISSNER, BOLTE & PARTNER M / CAN-053-PC

13

As a result, the holding means 12 is compressed in the longitudinally opposed angular regions between the wire elements 11, while the other two sides of the holding means 12 are elastically stretched. Thereby, a biasing force in the crossing region 10 is effected.

In Fig. 3 it can be seen that the holding means 12 in the crossing region 10, the wire elements 11 completely surrounds or encloses, so that also formed between the wire elements 11 spaces are closed.

4 shows a further exemplary embodiment of the implant according to the invention, wherein the holding means 12 extend beyond the crossing regions 10 along the wire elements 11 and furthermore protrude into the cells 14b. The cells 14b are partially closed by the holding means 12. The illustrated lattice structure 20 shows a diamond-shaped lattice pattern, wherein differently shaped lattice structures 20 are also claimed within the scope of the invention. The lattice structure 20 is formed by interwoven wire elements 11, wherein a wire element 11 is alternately guided over or under a crossing wire element 11. It is also possible for a plurality of wire elements 11 to intersect in an intersection area 10. For example, two or more parallel arranged wire elements 11 may overlap each other in a cross shape or alternately be guided over or under each other. In this case, the parallel wire elements 11 can touch.

FIG. 5 shows the lattice structure 20 according to FIG. 4 in the compressed state, wherein the cells 14b have an increased longitudinal extension I and a smaller crossing angle β compared to the expanded state.

FIG. 6 shows a cross section through an intersection region 10 of the lattice structure 20 according to FIG. 5. The holding means 12 completely surrounds the wire elements 11 and forms covering regions 15 which extend like a wing into the cell 14 formed by the wire elements 11. The cover regions 15 are arranged in a plane with the contact point 16 of the wire elements 11. It is possible that the cover regions 15 are arranged in a different plane. For example, the covering regions 15 can be assigned only to one wire element 11 or can be assigned in different directions. MEISSNER, BOLTE & PARTNER M / CAN-053-PC

14

be arranged. By covering regions 15, the fluidic behavior of the implant is favored.

FIG. 7 shows a further exemplary embodiment of an implant according to the invention, wherein some cells 14a of the lattice structure 20 are completely closed by the cover regions 15. Other cells 14b are partially closed by the cover portions 15. It is possible that a part of the cells 14 of the lattice structure 20 is closed. Alternatively, all of the cells 14 of the grid structure 20 may be partially closed or open. The grid structure 20 may also include a combination of open, closed and / or partially closed cells 14.

Figs. 8 and 9 illustrate the change in the braiding angle α at the transition of the lattice structure 20 from the expanded to the compressed state. For reasons of clarity, the holding means 12 are not shown in FIGS. 8 and 9. During the compression of the lattice structure 20, the length l of a cell 14, which is delimited by four wire elements 11, is increased. At the same time, the braiding angle α decreases. In the illustrated FIGS. 8 and 9, the longitudinal axis of the entire lattice structure 20 or the longitudinal axis of the stent extends in the vertical of the plane of the drawing. In general, the parameters stent diameter, cell length I and braiding angle α are changed by the compression of the lattice structure 20 or of the stent. The ratio of the three parameters with each other is determined by the geometry of the implant.

The implant according to the invention is preferably used as a stent for implantation in blood vessels and has the following features and properties:

In a preferred embodiment, the holding means 12 is formed of plastic and encloses the entire crossing region 10 or node region, ie runs on the inside and outside of the stent. As a result, the node area or crossing point is optimally held together. Such a casing has the additional advantage that the spaces between the wire elements 11 in the region of the node are filled with plastic. This reduces the risk of coagulation because the blood is less jammed. Especially on the inner surface of the stent, which is surrounded by the blood, this feature is of considerable importance. The formation of clots there or, due to separation of particles, in the downstream vessels would occlude the vessel lumen. In addition, this type of wrapping ensures optimum anchoring to the wire elements 11. MEISSNER, BOLTE & PARTNER M / CAN-053-PC

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Another advantage of the complete enclosure is that it avoids possible wear (wear) of the crossing points and the associated release of metal ions (e.g., nickel).

The grid or the grid structure 20 may consist of round wire elements 11, of flat bands and / or elongated elements with different profiles. The braid can consist of elements with different profile and / or dimensions. It is possible for the holding means 12 or the plastic alone to encase the wire elements 11 without plastic films protruding beyond the wire elements 11 or wires (i.e., as plastic tongues project into the cells). The coating can cover all or only a portion of the wires in the area of the nodes.

In a preferred embodiment, portions of the holding means 12 and the coating extend into the braid cells 14, respectively. Thereby, the force of the coating stored in elastic form is increased in the deformed state, i. There is also an expansion of the plastic of the holding means 12 within the cell 14. In addition, it is achieved that is reduced by the partially coated cells 14, the porosity of the stent. This has a positive effect, e.g. in the coverage of aneurysms, as in this way a decoupling of the aneurysm from the flow in the blood vessel takes place and a targeted coagulation in the aneurysm and control of bleeding is made possible. When treating stenoses, the partially coated cells 14b ensure that any detaching particles are trapped by the smaller cell openings and are not flushed into downstream blood vessels. The protrusion of coating areas into the cell 14b may be e.g. made by the surface tension of the plastic in the production by dipping or spraying. By choosing the material, the composition of the solution of plastic and solvent and other process parameters such as temperature or time, the coating can either adhere only to the wire elements 11 or even protrude into the cells 14. The intrusion of the plastic into the cell 14 results in a flow-optimized cross-sectional profile. The flow path of the blood is favored and storage areas are avoided.

It is possible that the holding means 12 completely closes the cell 14a. Thereby, the force is maximized, which exerts the holding means 12 in the compressed state on the lattice structure 20. The elongation of the holding means 12 is in direct MEISSNER, BOLTE & PARTNER M / CAN-053-PC

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with the deformation of the cell 14, i. the angle change of the cell 14 upon compression of the lattice structure 20. By fully coated cells 14a it is e.g. possible to interrupt bleeding or to protect particularly critical aneurysms.

The braid angle α of the lattice structure is preferably in the implanted state, i. within a blood vessel by at least 5 °, in particular at least 10 °, in particular at least 15 °, in particular at least 20 °, in particular at least 25 °, in particular at least 30 °, in particular at least 35 °, smaller than in the resting state, i. expanded state.

The extension of the cell 14 or the stretching of the holding means 12 along the stent axis between the resting state and the implanted state is at least 5%, in particular at least 10%, in particular at least 20%, in particular at least 30%, in particular at least 40%, in particular at least 50%, in particular at least 70%, in particular at least 90%.

The largest deformation undergoes the holding means 12 when introduced into a small catheter system. Common stent catheters have an inside diameter between 0.6 mm and 2 mm. The elongation of the cell 14 or the elongation of the holding means 12 along the stent axis from rest to compressed or crimped state is at least 40%, in particular at least 50%, in particular at least 60%, in particular at least 75%, in particular at least 80%, in particular at least 100%, in particular at least 125%, in particular at least 150%, in particular at least 175%, in particular at least 200%.

In one embodiment, the plastic of the holding means 12 has a porous structure to store medicines or anticoagulant substances.

It is possible to store radiopaque substances, for example barium sulfate, in the holding means 12.

The properties of the coating can vary along the stent. This changes the force properties of the stent. For example, the holding means 12 or the plastic coating in some crossing regions 10 or at some MEISSNER, BOLTE & PARTNER M / CAN-053-PC

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Knots thinner than at others. In addition, differently soft or hard plastics can be used in different areas. As a result, different force ranges can be set in a homogeneously braided stent. Furthermore, the grid mesh can have variable braiding angles α along the stent axis. As a result, different angular changes are achieved during the expansion of the implant, so that the holding means 12 cause different expansion or radial forces.

It is also possible that the outer coating of the stent, for example by a thinner plastic film, applying a lower force than in the middle of the stent. As a result, the compliance of the stent or the lattice structure 20 is increased and the load on the vessel wall is reduced. When the stent is stiff at the ends, the elasticity of the stent causes it to pulsate outside the stent more than in the stent area, where it is held in place by the stent force. It comes to high local stresses with significant shear stresses at the edge of the stent. This can lead to injury and inflammation and, consequently, excessive stent cell growth (in-stent stenosis), which can result in occlusion of the stent. The stiffer the stent, the higher the load on the vessel walls in the transition area. With the invention, an implant is provided, which allows a smoother transition.

Further possibilities of a variable force distribution are that, for example, the central region of the lattice structure 20 has holding means 12 adapted in such a way that a lower force is applied in this region and the stent does not project into the aneurysm during the aneurysm treatment. At the stent ends, the force for anchoring in the vessel can be greater.

The properties of the coating or holding means 12 may also vary along the circumference of the stent. For example, the force could be greater in one region on the circumferential surface of the stent than in other peripheral regions. As a result, the stent automatically assumes a curved shape, which has the smallest radius of curvature where the coating has a higher wall thickness or the adhesive has a higher modulus of elasticity. Such a stent allows positioning in vessels with particularly complex geometries. MEISSNER, BOLTE & PARTNER M / CAN-053-PC

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The coated portion of cells 14 may also vary along the stent. In some areas, the cells 14 may be open or partially coated or fully coated. As a result, both the force and the degree of coverage of the stent along its axis or on the circumference is varied. Targeted areas (such as aneurysms) are thereby covered, while other areas (e.g., at the level of branching vessels) remain relatively free.

In general, the holding means 12 are limited locally to the crossing region 10. This does not exclude that the holding means 12 form covering regions 15 which extend at least partially into the cell 14 and / or along the wire elements 11. It has proved to be particularly advantageous if the covering regions 15 are arranged along the wire elements such that the holding means 12 or the crossing regions 10 are connected by the covering regions 15, as shown in FIGS. 4 and 5. The cover regions 15 form a tapering cross-sectional shape which runs out in the direction of the cell 14 or toward the center of the cell 14. The cover regions 15 may be formed substantially beak-like, as shown in Fig. 6. The intersecting or intersecting wire elements 11 in the crossing region 11 are therefore preferably completely encased by the holding means 12, in particular a plastic material, wherein the holding means 12 expires in the manner of a wing in the adjacent cells 14 or extends like a wing. In this way partially closed cells 14b are formed. In particular, the covering regions 15 have a rounded, preferably concavely rounded shape. The rounded or wing-like or tapering shape of the cover regions 15 promotes the flow behavior of the stent. The cover regions 15 preferably extend in a circumferential plane of the lattice structure 20, in which the contact points 16 of the wire elements 11 are also arranged. The cover regions 15 are thus formed in a circumferential plane of the lattice structure 20, which essentially comprises the common tangents of the wire elements 11 touching in the intersection regions 10. In other words, the covering regions 15 are aligned with the common contact tangent of the wire elements 11 in the crossing regions 10, specifically in the contact points 16.

It is possible that individual retaining means 12 form the covering regions 15. This means that, for example, two out of four crossing regions 10 which delimit a cell 14 have holding means 12 which form wing-like covering regions 15. Two further crossing regions 10 may have holding means 12 which are locally on the MEISSNER, BOLTE & PARTNER M / CAN-053-PC

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Junction 10 are limited and no coverage areas 15 form. In this way, a substantially asymmetrically partially opened cell or asymmetric, partially closed cell 14b is formed.

It is advantageous if the cover regions 15 extend along the wire elements 11 and into the cell 14. The lattice structure 20 can therefore be completely covered with the holding means 12 or covering areas 15, wherein recesses 17 or openings are kept free within the cells 14. Since the cover regions 15 are preferably designed like a wing, the lattice structure 20 essentially has a structured outer circumferential surface and / or inner circumferential surface. In particular, 14 depressions or crater-like structures are formed in the region of the cells, with the covering regions 15 tapering away to the cell openings or recesses 17. The cover regions 15 preferably have a wall thickness which is at most 80 μm, in particular at most 60 μm, in particular at most 40 μm, in particular at most 20 μm, in particular at most 15 μm, in particular at most 10 μm, in particular at most 8 μm, in particular at most 6 μm. in particular at most 5 μm, in particular at most 4 μm, in particular at most 3 μm. The wall thickness is advantageously determined in the tapered section of the covering region 15, in particular in the surface section of the covering region 15 delimiting the cell opening 14 directly.

It has proved to be particularly advantageous if the covering regions 15 have a wall thickness which, relative to the cross-sectional diameter of the wire elements 11, has a ratio of at most 50%, in particular at most 40%, in particular at most 30%, in particular at most 20%, in particular at most 10%, in particular not more than 8%, in particular not more than 5%. The wall thickness of the cover regions 15 is thus preferably half or less of the wall thickness of the wire elements 11. The wall thickness of the wire elements 11 substantially corresponds to the radial extent or thickness of the wire elements 11 starting from a central longitudinal axis of the lattice structure 20.

The extension of the cover regions 15 into the cell 14 can be designed in such a way that different geometric shapes result for the recesses 17 formed in the cells 14. For example, the recesses 17 delimited by the cover regions 15 may have a circular shape. It is not excluded that the recesses 17 in the cells 14 other forms, for example MEISSNER, BOLTE & PARTNER M / CAN-0S3-PC

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an oval surface shape or an angular surface shape include. It is possible for the recesses 17 in the cells 14 to be delimited by the cover regions 15 in such a way that polygonal or other, in particular irregular, opening surfaces or opening shapes are formed.

It can also be formed several recesses 17 in a cell 14. For example, the cell 14 has a substantially perforated structure. Preferably, this perforation is formed in the manufacture of the lattice structure 20 by leaving the recesses 17 in the cell 14. A subsequent incorporation of recesses 17 or openings in the cells 14 is essentially not provided, but also not excluded.

To form a plurality of recesses 17 or openings within a cell 14, the cover regions 15 can be connected diagonally or diametrically to each other. The covering regions 15 can thus form elastic webs or bridges which extend between two intersection regions 10. The cover regions 15 preferably form elastic bridges which extend between two diametrically opposite or not immediately adjacent, in particular spaced-apart, intersection regions 10 or holding means 12. The elastic bridges can be straight. A meandering or different course of the elastic bridges is also possible. Generally, at least two recesses 17 within a cell 14 are formed by the elastic bridges. It is also possible to form a plurality of recesses, in particular at least 3, in particular at least 4, in particular at least 6, in particular at least 8 recesses per cell 14. It is also not excluded that over the entire lattice structure 20 differently shaped cells 14 are formed by the cover portions 15.

In general, a part of the cells 14 partially closed cells 14b and another part of the cells 14 may be formed as completely closed cells 14a. It is also possible that a part of the cells 14 has a plurality of recesses 17. Another part of the cells 14 may in this case form partially closed cells 14b, which comprise a single recess 17, or completely closed cells 14a. In addition, individual cells 14 or a part of the cells 14 can also form completely open cells 14. The open cells 14 are limited at least in sections by free wire element sections 13. Combinations of the aforementioned cover or MEISSNER, BOLTE & PARTNER M / CAN-053-PC

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Coating variants, in particular of partially or completely covered or partially or completely free or open cells 14, are possible.

In principle, it has proven to be advantageous if the lattice structure 20 is provided with holding elements 12 or covering areas 15 such that between the open area or the total area of the recesses 17 within the cells 14 and the entire circumferential surface of the lattice structure 20 or cell surface sets a ratio not exceeding 80%, in particular not more than 60%, in particular not more than 40%, in particular not more than 20%, in particular not more than 10%, in particular not more than 5%, in particular not more than 3%, in particular not more than 2%, in particular not more than 1%, in particular not more than 0.5%.

Furthermore, it is preferred if the wire elements 11 have a round, in particular circular, cross-sectional profile. In contrast to angular, in particular rectangular, cross-sectional profiles have round profiled wire elements 11 in combination with locally limited to the crossing region 10 holding means 12 advantages.

In particular, when using an elastic plastic as a holding means 12 has been found that the holding member 12 adapts due to its own surface tension of the shape of the wire elements 11 in the crossing region 10. This can result in wire elements 11 with angular cross-sectional profile that the wall thickness of the holding means 12 is reduced in the region of the edges. In the area of the edges or the thinner wall thickness, the holding element 12 is therefore susceptible to cracking. Moreover, by the smaller wall thickness of the holding means 12 in the region of the edges of the wire elements 11, the elastic restoring force, which is exerted by the support member 12 in the crossing region 10 on the lattice structure 20, reduced.

In the case of wire elements 11 with a round cross-sectional profile, on the other hand, the wall thickness is constant at least over the outer regions of the wire elements 11. In the region of the contact point 16 of the round wire elements 11, however, a concave region is formed, in which the holding means 12 or the material of the holding means 12 collects due to their own surface tension. The material of the holding means 12 thus flows between the round wire elements 11, so that the function of acting on the wire elements 11 in the crossing region 10 restoring force is ensured. Moreover, the round cross-sectional profile prevents the wire elements 11 from being cut into the plastic coating or the retaining element 12. MEISSNER, BOLTE & PARTNER M / CAN-053-PC

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dent, whereby the elastic restoring force could be impaired. By the round wire elements 11 damage to the holding means 12 and a related detachment of holding agent particles is avoided.

LIST OF REFERENCE NUMBERS

10 crossing area

11 wire element

12 holding means

13 free wire element section

14 cell

14a completely closed cell

14b partially closed cell

15 coverage area

16 touch point

17 recess 20 grid structure

α braiding angle ß crossing angle I cell length

Claims

MEISSNER, BOLTE & PARTNER M / CAN-0S3-PC23 claims

An implant comprising a braided lattice structure (20) comprising wire elements (11) delimiting cells (14), wherein at least two wire elements (11) are crossed and form an intersection region (10), which means that the braided lattice Lattice structure (20) has a locally deformable on the crossing region (10), elastically deformable holding means (12) which connects the wire elements (11) in the crossing region (10) such that by a relative movement of the crossing region (10) forming wire elements (11 ) an elastic restoring force acting on the braided lattice structure (20) is adjustable.

2. Implant according to claim 1, characterized in that the holding means (12) substantially completely surrounds the wire elements (11) in the crossing region (10).

3. Implant according to claim 1 or 2, characterized in that the holding means (12) extends at least partially along the wire elements (11).

4. Implant according to at least one of claims 1 to 3, characterized in that the holding means (12) connects the wire elements (11) essentially in a materially bonded manner.

5. The implant according to claim 1, wherein the holding means (12) has a wall thickness of at most 80 μm, in particular at most 60 μm, in particular at most 40 μm, in particular at most 20 μm, in particular at most 15 μm, in particular at most 10 μm, in particular at most 8 μm, in particular at most 6 μm, in particular at most 5 MEISSNER, BOLTE & PARTNER M / CAN-053-PC

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μm, in particular at most 4 μm, in particular at most 3 μm.

6. Implant according to at least one of claims 1 to 5, characterized in that the holding means (12) covers the cells (14) of the braided lattice structure (20) partially and / or completely.

7. Implant according to at least one of claims 1 to 6, characterized in that the braided lattice structure (20) comprises at least two, in particular a plurality, crossing regions (10) each having locally limited holding means (12).

8. Implant according to at least one of claims 1 to 7, characterized in that locally limited retaining means (12) are arranged in edge regions of the lattice structure (20).

9. The implant according to claim 1, wherein in the longitudinal and / or circumferential direction of the lattice structure, different holding means are arranged, in particular with different moduli of elasticity or dimensions or shapes.

10. The implant according to claim 1, wherein holding means (12) with different elastic properties are arranged in a central region of the lattice structure (20) than in an edge region of the lattice structure (20).

11. The implant according to at least one of claims 1 to 10, characterized in that the braided mesh structure (20) has a tubular shape that can be converted from an expanded state having a relatively large cross-sectional diameter into a compressed state having a relatively smaller cross-sectional diameter. MEISSNER, BOLTE & PARTNER M / CAN-053-PC

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12. Implant according to claim 11, dadurchge ke nnzeichnet that the cross-sectional diameter of the tubular braided lattice structure (20) in the transition from the expanded to the compressed state by at least 10%, in particular at least 20%, in particular at least 30%, in particular at least 40%, in particular at least 50%, in particular at least 60%, in particular at least 70%, in particular at least 80%, in particular at least 90%, is changeable.

13. Implant according to at least one of claims 1 to 12, dadurchge ke nnzeichnet that the braided grid structure (20) has a braid angle (α), the at least 40 °, in particular at least 45 °, in particular at least 50 °, in particular at least 55 °, in particular at least 60 °, in particular at least 65 °, in particular at least 70 °.

14. The implant according to at least one of claims 1 to 13, dadurchge ke nnzeichnet that the braided grid structure (20) has a braid angle (α), the transition of the lattice structure from the expanded to the compressed state by at least 10 °, in particular at least 15 ° , in particular at least 20 °, in particular at least 25 °, in particular at least 30 °, in particular at least 35 °, in particular at least 40 °, in particular at least 45 °, in particular at least 50 °, in particular at least 55 °, in particular at least 60 °, in particular at least 65 ° , in particular at least 70 °, is changeable.

15. Implant according to at least one of claims 1 to 14, dadurchge ke nnzeichnet that the cells (14) along a longitudinal axis of the grid structure (20) have a longitudinal extent (I), which in the transition of the tubular, braided grid structure from the expanded into the compressed State by at least 40%, in particular at least 50%, in particular at least 60%, in particular at least 70%, in particular at least 75%, in particular at least 80%, in particular at least 90%, in particular at least 100%, in particular MEISSNER, BOLTE & PARTNER M / CAN-0S3-PC

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especially at least 125%, in particular at least 150%, in particular at least 175%, in particular at least 200%, is changeable.

16. Implant according to claim 1, characterized in that the ratio of the wall thickness of the holding means (12) to the cross-sectional diameter of the wire elements (11) is at most 50%, in particular 40%, in particular at most 30%, in particular at most 20%, in particular at most 10%, in particular at most 8%, in particular at most 5%.

17. Implant according to at least one of claims 1 to 16, characterized in that the holding means (12) and / or the wire elements (11) comprise a biocompatible plastic and / or a superelastic shape memory material.

18. Implant according to at least one of claims 1 to 17, characterized in that the holding means (12) comprises a biodegradable and / or medicament-carrying material.

19. An implant having a braided lattice structure (20), the cell (14) delimiting wire elements (11), wherein at least two wire elements (11) are arranged crossed and form an intersection region (10), that is said that the braided Grid structure (20) has a locally on the crossing region (10) limited holding means (12) which connects the wire elements (11) in the crossing region (10).

20. A method for producing an implant according to claim 1 or 19, wherein at least two wire elements (11), which are braided into a lattice structure (20), crossed to form a crossing region (10) arranged and with a on the crossing region (10) locally limited holding means (12) are provided. MEISSNER, BOLTE & PARTNER M / CAN-053-PC

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21. Method according to claim 20, characterized in that the locally limited holding means (12) comprises an elastic material.

22. The method according to claim 20 or 21,

23. d a n e c o v e n c e s that the localized holding agent (12) is prepared by a spraying or dipping process.