FR2993451A1 - ENDOLUMINAL VASCULAR PROSTHESIS FOR SMALL VESSELS - Google Patents

Abstract

The invention relates to a vascular prosthesis for insertion into a vessel with stenosis or narrowing. To prevent early restenosis and late thrombosis, such a prosthesis comprises a substantially tubular main member consisting of a wire mesh (11) cooperating with its bioabsorbable means (12) comprising one or more medicinal agents and a biocompatible monomer or polymer stimulating cell growth around said lattice.

Description

The invention relates to an endoluminal vascular prosthesis, also referred to as an endovascular prosthesis, or more generally to a device intended to be introduced into a vessel presenting a stenosis or narrowing of the vessel lumen. The installation of such an endovascular prosthesis makes it possible to recover a satisfactory arterial lumen conducive to normal circulation within said vessel. The invention relates more particularly but not limited to a prosthesis for small veins or arteries, coronary arteries or small vessels of the lower or upper limbs. As described by way of example in Figures 1a and 1b, a stenosis generally results from an accumulation of fat deposits on the inner wall or intima 3 of a vessel 1 thus forming one or more plates 2. These deposits may be consisting of cholesterol, calcium or other substances carried by the blood. The formation of said plaques may eventually occlude vessels, especially small arteries such as coronary arteries, making them rigid and irregular. To treat this condition, the interventional cardiologist may use transluminal angioplasty to introduce a balloon, which when inflated, pushes out the plates formed against the intima. The balloon is subsequently removed and the arterial lumen 4 is restored. However, the effect can be short-lived. To prolong this, a therapeutic gesture may consist in placing an endovascular prosthesis or a stent in the form of a flexible metal cylinder whose mesh provides, like a scaffold, a reactive force to the collapse of the inner wall of the vessel. At the level of the lesion, the stent remains present in the vessel in the long term. It thus keeps the vessel open enough for the blood to circulate normally. There are different types of endovascular prosthesis. The oldest consist of a mesh or bare metal mesh (stent). The wire mesh is directly applied in contact with the vessel wall. More recent, as exemplified by US 6,010,530, prostheses may consist of a wire mesh - such as a wire constrained to materialize zigzags - which optionally includes a polymer type coating. The stent (for example nitinol-based) can be self-expanding when placed with a catheter and a retractable sheath. It can alternatively be deployed using a balloon. In the latter case, the stent is crimped onto said balloon as the interventional cardiologist inflates within the vessel to repel the plaques and restore the arterial lumen. The balloon is then deflated and removed. Once the plates are pushed against the inner wall of the vessel, the stent is a scaffolding supporting the wall of said vessel. The stent remains in the vessel to keep it open. The therapeutic effects of stent placement are relatively long-lasting thanks to the scaffolding provided by said stent. However, it has been found that the body can react following the stent placement by rejecting this foreign body. The metallic structure of the stent seems to have a major role in this reaction, which can result in restenosis, ie a new formation of stent narrowing at the level of the stent limiting the arterial lumen of the vessel. This phenomenon can appear in a period of 6 months to two years depending on the patient, his lifestyle or diet, etc. The prevalence at 6 months is estimated at 20 to 30% of patients who received a bare coronary stent, compared to 30 to 60% of patients who had balloon angioplasty alone. To delay the occurrence of restenosis, US 6,010,530 teaches that the coating (if any) of the endovascular prosthesis may be impregnated with a drug substance or agent - for example Rapamycin or Paclitaxel - which is gradually released into the body after placement of the endovascular prosthesis may have effects among the breast of a vessel. This particular effect substance or a plurality of which we may mention anti-inflammatory, antimicrobial, antibacterial, anti-thrombotic or anti-coagulant effects. In particular, it makes it possible to limit the formation of thrombosis and / or the excessive proliferation of smooth muscle cells thus preventing early restenosis. Alternatively, the metal mesh may be directly coated with a substance equivalent to that impregnated with the coating of the preceding stent or with a plurality of substances whose combined effects slow down the occurrence of restenosis. Such prostheses having an additional assimilable substance are commonly referred to as "drug-eluting stents". Thus, restenosis can be delayed for several years compared to a bare stent. The prevalence at 6 months is then estimated between 3 and 20% of the patients having received a drug-eluting coronary stent according to the types of stent and drug agents used. Although having a remarkable progress, such endovascular prostheses nevertheless raise some disadvantages.

An endovascular prosthesis with a coated stent does not promote "uptake" of the stent by the treated vessel. Once the effect induced by the substance or substances fades, the coating, which is permanent, contributes to the "rejection" effect of the endovascular prosthesis. US 6,010,530 teaches that to limit this disadvantage, the coating may have holes or be made using a porous material. Thus, endothelial cells can infiltrate into said wall and form a new intima which, like a filter, allows blood to feed the vessel wall again.

Other known embodiments of drug-eluting stents use a non-coated prosthesis. The mesh is thus directly applied against the inner wall of the treated vessel. In order for the prosthesis to prevent early restenosis, the substances making it possible to constitute a drug-eluting stent are directly deposited in successive layers on the metal mesh of the stent. Alternatively, the substance or substances may be deposited in a single layer by spraying or dipping. Thus, in addition to its scaffolding function, this metal mesh fulfills the role of "substance carrier". In order that a sufficient quantity of substances can be diluted within the treated vessel, it is necessary that the mesh of the stent is particularly dense to convey said substances. This high metal density comes at the expense of the flexibility and flexibility of the whole (very useful depending on the tortuosity of the vessel treated), the cost of the endovascular prosthesis and the desired effect to prevent restenosis associated with a presence. too much metal compounds. After the dilution of the substances, a high density of the mesh can thus reinforce a risk of restenosis requiring a new therapeutic intervention. The use of drug-eluting stents may further promote late thrombosis. Indeed, while a bare metal stent does not cause this secondary complication following the implantation of the wire mesh because of a sufficient endothelization, the recent drug-eluting stents slow the endothelization of the wire mesh. Thus, the use of such stents results in a deleterious prolongation of oral post-operative platelet treatment to prevent any risk of thrombosis in the long term. By using broad-spectrum drug agents such as Rapamycin or Paclitaxel, current stents prevent the proliferation of smooth muscle cells and reduce the risk of re-stenosis, but also prevent proliferation and colonization of the coating or wire mesh by the endothelial cells. Thus, even in the long term, certain portions of the lattice remain in direct contact with the blood, which potentially induces thrombus formation, if the blood is not anticoagulated sufficiently. The invention makes it possible to meet all the disadvantages raised by the known solutions.

The invention mainly consists in providing a prosthesis with a radial force or a minimum but sufficient permanent crushing reaction to sustainably maintain a nominal arterial lumen while preventing risks of re-stenosis and thrombosis in the short term. and in the long run. The invention makes it possible to improve the tolerance of the stent by the body thanks to a particularly innovative design and to the presence of bioabsorbable means carrying primarily but not limited to substances with virtues conducive to cell development to form a new cell. intima imprisoning the prosthesis. These substances may have a particular effect or a plurality of effects, among which may be mentioned anti-inflammatory, antimicrobial, antibacterial, anti-thrombotic or anticoagulant effects or promoting adhesion and proliferation of endothelial cells. Among the many advantages provided by the invention, we can mention that the invention makes it possible: to promote the healing response of the vascular wall; 20 to improve the growth and homogeneity of the intima recreated after prosthesis placement and promote controlled cell growth to limit the risk of late thrombosis; to slow down or even to prevent restenosis after placement of an endovascular prosthesis and thus to reduce the occurrences of therapeutic gestures to maintain a satisfactory and perennial arterial lumen in a treated vessel; To facilitate tolerance by arranging prostheses by the optimized and minimal presence of metallic material and bioabsorbable means; To this end, firstly there is provided an endovascular prosthesis comprising a substantially tubular main member consisting of a wire mesh. To prevent early restenosis, such an endovascular prosthesis comprises bioabsorbable means cooperating with said metal mesh, said bioabsorbable means comprising one or more medicinal agents and a biocompatible monomer or polymer stimulating cell growth around said mesh. A short-term bioabsorbable coating, also having one or more drug agents, may advantageously cover said wire mesh and said bioabsorbable means to prevent initial inflammation and acute thrombosis. According to this variant, said one or more medicinal agents may be chosen from a group consisting of anticoagulant, antiplatelet, antithrombotic, anti-inflammatory or antiproliferative agents.

Among several advantageous embodiments, the lattice may consist of a structure forming a plurality of rings respectively comprising vertices connected in pairs by substantially rectilinear uprights and having a flexible portion having one or more curvatures. To preserve the flexibility of the trellis, two adjacent crowns can advantageously cooperate via a flexible connector connecting two vertices respectively of said crowns.

To allow the introduction of the prosthesis via a catheter and the expansion of its main limb and bioabsorbable means, said expansion may be automatic or assisted by a balloon, the wire mesh and the bioabsorbable means may have a configuration allowing the contraction or crimping on a balloon and the expansion of the prosthesis. In order to promote the flow of blood in contact with the prosthesis and to reduce the recirculation and high shear zones, the crown posts may have a substantially trapezoidal section whose internal base intended to be in contact with the blood is less than the outer base intended to be in contact with the wall of a vessel. According to a preferred embodiment, the bioabsorbable means may consist of a polymer. To prevent re-stenosis and late thrombosis, the drug agent of said bioabsorbable means may advantageously be an agent of a group consisting of anti-inflammatory, anti-proliferative or adhesion promoting, growth and the maturation of endothelial cells. More specifically, said bioabsorbable means 20 may consist of polymer fibers interwoven with the wire mesh to homogeneously distribute said bioabsorbable means along the main member. Alternatively and to facilitate the assembly of the prosthesis, the absorbable means may consist of a substantially tubular structure forming a plurality of rings respectively having vertices connected in pairs by substantially rectilinear uprights and having a flexible portion having one or 30 several curvatures. To improve the flexibility of the prosthesis, two adjacent crowns - the substantially tubular structure of the absorbable means - can cooperate via a flexible connector connecting two vertices respectively of said crowns. According to the variant for which the bioabsorbable means are made from a tubular structure and to facilitate the assembly of the prosthesis, the respective tubular structures of the metal mesh and bioabsorbable are preferably arranged to cooperate mutually. To make the assembly of the prosthesis more reliable, the flexible portion of an amount of the bioabsorbable structure may comprise a recess for partially accommodating the flexible portion of an amount of the wire mesh. To facilitate the therapeutic gesture and control the positioning of a prosthesis according to the invention in the vessel, said prosthesis may comprise radiopaque means located at the ends of the main member of the prosthesis. In a preferred configuration, a prosthesis may comprise a quantity of bioabsorbable means substantially equivalent to that of the wire mesh constituting the main member of said prosthesis. Other features and advantages will become more apparent upon reading the following description and examining the accompanying figures, of which: FIGS. 1a and 1b (already described) show a partial view of the vascular system of a patient with arterial stenosis; FIG. 2 describes a first prosthesis according to the invention; Figures 3a and 3b depict a partial view of the vascular system of a patient with arterial stenosis immediately after application of a prosthesis according to the invention; FIGS. 3c and 3d describe a partial view of the vascular system of a patient presenting with an arterial stenosis after the application of a prosthesis according to the invention once the bioabsorbable means are completely degraded several months after implantation of the prosthesis; Figure 4 describes the wire mesh of a second prosthesis according to the invention; FIGS. 4A and 4B more precisely respectively describe two rings of the wire mesh presented in connection with FIG. 4; Figures 5 and 5A describe a section advantageously arranged with an amount of a crown of a prosthesis according to Figure 4; FIGS. 6 and 6A respectively describe global and partial views of a prosthesis according to the invention having bioabsorbable means crimped onto a wire mesh as described with reference to FIG. 4. FIG. 2 shows a first embodiment preferred embodiment of an endovascular prosthesis 10 according to the invention when it is deployed. This comprises a main member or substantially tubular stent consisting of a mesh, preferably in the form of a continuous wire 11 and folded into a configuration allowing the contraction (or crimping of the member if the deployment of the latter is assisted by balloon) and expansion of the prosthesis. Such a lattice is preferably made based on cobalt chromium or nitinol. As shown in Figure 2, the lattice has a zigzag or chisel configuration. This configuration is particularly advantageous because, when the prosthesis is deployed, scissors or crowns materialized by the wire mesh prevent excessive cell growth in regions in contact with said mesh. The invention would however be limited to this preferred configuration. The invention provides that the stent may be self-expanding when the stent is released from a catheter sheath or alternatively may be expanded by means of a balloon. According to the embodiment chosen, the mesh is designed according to well-known techniques to ensure such automatic deployment or assisted by a balloon. The density of the mesh is further determined to deliver, after deployment, a radial force or a crush-responsive force sufficient to maintain an open vessel. The function of the wire mesh is reduced to a scaffolding role to sufficiently support the inner wall of the treated vessel. To limit the risk of occurrence of restenosis, the invention provides that the metal mesh is reduced to its simplest expression simply sufficient to enable it to sustainably maintain the vessel. In addition, to prevent the risk of re-stenosis following the installation of a prosthesis according to the invention, bioabsorbable means 12 cooperate with said wire mesh 11. These means can be preferably made in the form of one or more polymers comprising one or more medicinal agents. Thus, as indicated by way of example in FIG. 2, one or more bioabsorbable fibers 12 is (are) interlaced with the wire mesh 11. The fibers 12 appear in fine lines in FIG. lattice 11 shown in thick lines. The carriers are - non-exhaustively - an anticoagulant to limit clot formation or a monomer whose role is to catalyze or promote cell growth of tissues in contact with the prosthesis. The tissues can thus interfere within the mesh to constitute after a few weeks or months a new intima imprisoning the mesh metal. The latter - in addition to its role of scaffolding provides a role of trellis. The function of the agents is temporary. The means carrying the agents are therefore intended to be bioabsorbable. Several weeks or months after the insertion of the endovascular prosthesis, said means 12 are completely resorbed. Only remains the metal mesh 11 which continues its role of scaffolding and trellis. The density of foreign body remaining present can thus be reduced in view of the prior art. Different configurations of bioabsorbable means are possible. For example, fibers 12 may be interwoven cooperating with the mesh 11 to diffuse the agents along the tubular member in a homogeneous and equitably distributed manner. Said medicinal agents and / or biocompatible monomer (s) can thus be regularly distributed along the wire mesh 11 (mainly on one of the inner or outer parts of the mesh or equitably on said parts). For a self-expanding prosthesis of which a metal stent is calibrated to exert a determined radial force, the density of bioabsorbable means can be adjusted to determine the amount and dynamics of elution of the carriers regardless of the density of metal compounds. . The invention thus reduces the risk of restenosis and promotes the assimilation of the prosthesis by organizing the patient. According to a preferred embodiment, a prosthesis according to the invention is substantially composed (before its application within a vessel) of 50% metal elements 11 and 50% bioabsorbable means 12. Other proportions could be considered according to the desire to strengthen or reduce the radial force exerted by the mesh 11 or the degree and distribution of the drug agents carried by the bioabsorbable means 12. Figures 3a and 3b describe a vessel 1 as illustrated in conjunction with Figures la or lb. This has a stenosis in the form of a plate 2. After having dilated the vessel and pushed out the plate 2, a prosthesis 10 according to the invention has been applied. Whether its expansion is automatic or assisted by inflating a balloon, the metallic mesh 11 bears against the intimal 3 of the vessel and exerts either a radial force for a self-expanding stent or a resistance to pressure. crushing for a balloon expandable stent against said intima. This force or resistance is sufficient to keep the vessel open so that the arterial lumen 4 of the latter is satisfactory. Bioabsorbable means 12 cooperating with the mesh 11 appear in fine lines with regard to the wire mesh 11 shown in thick lines. The presence of anticoagulants carried by said means 12 or other medicinal substances prevent the risk of re-stenosis and acute or late thrombosis by promoting the healing response of the vascular wall. Figures 3b and 3c describe the same vessel, a few months to a few years after the application of the prosthesis 10. The bioabsorbable means are resorbed. The presence of a monomer carried by the bioabsorbable means 12 (present in FIGS. 3a and 3b), a monomer promoting cell growth of the tissues in contact with the tubular member of the prosthesis, has favored the creation of a new intimal 3 imprisoning the mesh 11 represented by transparency in FIG. 3c in dotted lines. It continues its function of scaffolding but the new intima 3 'perfectly irrigated and having a smooth surface facilitates the blood circulation and prevents any risk of late thrombosis. The arterial lumen 4 is thus durably preserved. The invention provides a second embodiment of a prosthesis which in particular reduces the density of the wire mesh while preserving the flexibility of the assembly. FIG. 4 thus describes a wire mesh, no longer preferably made from a wire, but from a substantially tubular structure 11 that has been cut beforehand (for the perforation), for example by means of a LASER beam or any other technique. The cut or molded structure is advantageously based on cobalt-chromium or nitinol. In connection with the example illustrated in Figure 4, the mesh 11 comprises one or more rings 110A, 110B and 110C. In the same way as a woven wire mesh described in connection with Figure 2, this technique allows for a wire mesh 11 whose configuration provides a good contraction capacity, a crimp on a balloon or an automatic expansion or assisted by the balloon of the main limb of the prosthesis. To reduce the metal density, it is possible to reduce the number of crowns by "stretching" them. A ring (for example one of the rings 110A or 110B) has vertices connected in pairs by substantially rectilinear amounts. Thus, in FIG. 4, two vertices 111A and 114A connected by an amount 112A can be distinguished. To better distinguish the different elements, FIG. 4A shows a partial enlargement of the mesh 11. This view corresponds to the portion symbolized by the circle A represented in FIG. 4. FIG. 4A thus describes the apex 111A from which two substantially rectilinear amounts 112A start. and 113A. To maintain good flexibility and maintain the ability of the prosthesis to conform to the anatomy of a patient, the invention provides that said uprights comprise a non-rectilinear portion. Thus the amount 112A comprises two substantially rectilinear portions ll2Ax and ll2Az and a central portion ll2Ay having one or more curvatures. In conjunction with Figures 4 and 4A, this portion advantageously and substantially describes an 'S' or a "Z" in the plane of the surface of the mesh (the radius of curvature of the tubular structure 11). Other curvatures could be provided at the portion ll2Ay. Similarly, other positions of the portion ll2Ay relative to the portions ll2Ax and ll2Az and other ratios of lengths between these different portions may be provided. It suffices that said configuration of portions ll2Ax, ll2Ay and ll2Az offers the desired flexibility and conformability. In addition to flexibility recovered, the configuration of such a lattice reduces the "spring" effect that is to say the "springback" and "shortening" of the stent particularly sensitive after the expansion of the prosthesis. The lattice 11 described in connection with FIGS. 4 and 4A thus comprises the uprights 112A and 113A starting from the apex 111A having a non-rectilinear portion 112Ay. Such amounts could alternatively comprise a plurality of portions having one or more curvatures instead of one. This variant allows for example to further stretch the crowns by extending the length of the amounts of a crown.

In the same way as for FIG. 4A, FIG. 4B illustrates a second ring 110B of the lattice 11 described in connection with FIG. 4. This enlargement (corresponding to the portion of said lattice 11 surrounded by the oval B in FIG. 4) shows that the crown 110B comprises in particular two vertices 111B and 114B connected by a substantially rectilinear amount 112B. This amount comprises a substantially central portion ll2By which has - like the amount 112A of the crown 110A - one or more curvatures. It is the same for a second amount 113A connecting the top 112B to a third crown of the crown 110B. To ensure the connection between the various crowns while maintaining the flexibility of the mesh 11 and the conformability of the prosthesis to a pathological vessel, the distal peaks of a crown can be connected respectively to the proximal vertices of a neighboring ring by means of connectors. flexible. Thus, in connection with the embodiment illustrated in FIG. 4B, a flexible connector 132 connects the vertex 111B of the crown 110B to one of the apices of the adjacent ring 110A. It is the same for the top 111C of the adjacent ring 110C which is connected to a crown of the crown 110B by the flexible connector 133. FIG. 4A also illustrates a connector 131 connecting the crown 110A (the crown 111A) to a crown neighbor. According to a particularly advantageous embodiment, such a connector can describe a double 'S'. Other forms of connections could, however, be envisaged to connect the crowns of the same lattice 11. Preferably, the flexible connector links two neighboring crown peaks (vertex-vertex configuration) but other junctions could also be envisaged. such as a summit-up junction, summit-valley (the valley being the inner side of the summit), valley-valley or any other combination or place of junction between two neighboring crowns by a flexible connector. The use of a lattice made from a cut or molded tubular structure makes it possible to promote the cellular colonization of the wire mesh. Indeed, according to a preferred embodiment, the trellis (mainly the amounts of the crowns) may have a trapezoidal section so that the base Be of the outer wall intended to be in contact with the vascular wall of the vessel (or external base ) a mesh amount is greater than the base Bi of the inner wall of said upright (or internal base) intended to be in contact with the blood. This result can for example be obtained by cutting a beam through the tubular metal structure non-normally to the outer surface of the tube. An inclination of the firing angle of the LASER beam (ALPHA angle) makes it possible to remove additional material ll2Ba at a normal normal cut at the surface to form an amount 112B of substantially trapezoidal section as described by way of example. 5. Similarly the other side of the upright can be cut with a BETA angle and a material withdrawal ll2Bb, equal or not to the angle ALPHA. It is therefore possible to machine the structure so that the amounts are thinner towards the central axis of the structure. While Figure 5 shows an embodiment of the section of a profiled post after cutting LASER (angles ALPHA and BETA equal), Figure 5a describes this same section once polished by a preferred electropolishing technique. The sharp edges are smoothed and the thickness of material removed is adjustable during the polishing operation. This possibility can be applied to single amounts or to the entire trellis. This configuration makes it particularly advantageous to reduce, in particular, the local stasis or recirculation zones around the uprights by reducing the disturbances created by the trellis on the flow of blood to the wall of the vessel. As a result, the risk of thrombosis formation is reduced after application of the prosthesis. This configuration further promotes the colonization of endothelial cells by reducing the shear stresses generated by the fluid against the wall of the prosthesis. Adhesion and growth of endothelial cells is thus favored, eventually producing a better recovery of the lattice by the new intima and thus a reduction in the risk of late thrombosis. The mesh 11 of a prosthesis made according to this second embodiment - illustrated in FIGS. 4, 4A or 4B) cooperates with bio-absorbable means such as, for example, a polymer in the same way as the prosthesis described in connection with FIG. 2. The tubular metal structure 11 can thus receive bioabsorbable means which consist of polymer fibers interwoven with said wire mesh. Alternatively, the invention provides that said bioabsorbable means can be obtained by molding or cutting a substantially tubular structure whose configuration is close to or identical to that of the wire mesh. According to this variant, a second substantially resorbable tubular structure 12 (based on a polymer or a biodegradable ceramic) is thus formed of a plurality of crowns respectively comprising vertices connected in pairs by substantially rectilinear uprights and comprising minus a flexible portion having one or more curvatures. Figures 6 and 6A illustrate this particularly advantageous variant. In the same way as the variant described in connection with FIG. 2, the bioabsorbable means may be impregnated with one or more medicinal agents. To prevent re-stenosis and late thrombosis, the drug agent (s) of said bioabsorbable means are advantageously one or more agents of a group consisting of anti-inflammatory, anti-proliferative or adhesion promoting agents, growth and maturation of endothelial cells. FIG. 6 shows a metal mesh 11 around which bioabsorbable means 12 are applied. The two elements 11 and 12 are mutually arranged to cooperate perfectly, for example during a crimping operation of the means 11 and 12 on a balloon or contraction in a sheath of a catheter prior to the application of the prosthesis within a pathological vessel. According to Figure 6, the two lattices (metal for one 11 and resorbable for the second 12) are similar and symmetrical (or inverted) so that the two lattices cooperate substantially at the non-rectilinear flexible portions of the crowns amounts. FIG. 6A is an enlargement of a portion A of the prosthesis illustrated in FIG. 6. Among the rings 120A, 120B of the polymer mesh 12 and the rings 110A, 110B of the wire mesh 11, FIG. 6A describes a particularly advantageous mutual arrangement. . The ring 110A of the mesh 11 has a top 111A from which a substantially rectilinear upright 112A which however comprises at least a non-rectilinear portion 112Ay. This ring 110A cooperates with the ring 120A of the polymer mesh 12 mainly at the 123Ay portion of the amount 123A of said ring 120A. This portion 123Ay has secant curvatures with respect to the curvatures of the portion ll2Ay. The respective portions 123Ay and 112Ay of substantially rectilinear amounts 123A and 112A, substantially describe a 'S' or 'Z' respectively symmetrical or inverted. The superposition of said non-rectilinear portions describes an 'X' or an open alpha whose intersection constitutes a point of support and pivot. According to an advantageous embodiment, the 123Ay portion may comprise a cavity 123Ayr or a 123Ayr arranged for - that audit point of contact - the amount 123A enchased the amount 112A. The holding of all, the crimping and expansion of the two lattices can be improved. Alternatively or additionally, an outer recess on a flexible portion 112Ay or a post 112A of the wire mesh may be considered to partially encase an amount of the polymer mesh. The mutual arrangement of the trellises 11 and 12 is particularly advantageous because it does not interfere with the expansion of the prosthesis when it is implanted in the vessel and provides the latter with great flexibility while minimizing the "elastic return" and "shortening" effects. ". The invention however can not be limited - according to this second embodiment - to this preferred example of mutual arrangement. Thus a variant may consist of a bioabsorbable means 12 identical to that of Figure 6 and which covers a thin thickness of the wire mesh 11 on its outer surface. Thus, no metal part is in contact with the vessel wall, which can reduce the inflammatory reaction during the first post-operative time, depending on the type of drug impregnated in said bioabsorbable means. To facilitate the therapeutic gesture, the invention provides that radio-opaque markers can be positioned on the main member of the prosthesis regardless of the structure of the prosthesis according to the invention braided or tubular trellis). By way of example and with reference to FIG. 2, markers 13 and 14 may be positioned at the extremities of the limb. The practitioner can thus control his gesture positioning perfectly - using a catheter carrying the prosthesis - the latter prior to its automatic expansion or assisted.

The invention further provides that an abluminal coating preferably or all over the stent and bioabsorbable can cover the assembly constituted by the wire mesh and resorbable after they have been assembled. Said coating is in a preferred embodiment a bioabsorbable polymer which degrades completely in a few weeks to a few months. To reduce initial inflammation and acute thrombosis, this coating may include substances having a particular effect or a plurality of effects, among which we can mention anti-inflammatory, anti-platelet, anticoagulant, antithrombotic and antiproliferative effects. .

The invention has been described in a preferred manner in connection with an endovascular prosthesis for small vessels such as small veins or arteries, coronary arteries or veins or arteries of the lower limbs (femoral, tibial, popliteal arteries) or upper limbs. The invention applies naturally to any other endovascular prosthesis having a persistent metallic mesh cooperating with bioabsorbable means.

Claims (20)

REVENDICATIONS1. An endovascular prosthesis (10) comprising a substantially tubular main member constituted by a wire mesh (11), characterized in that said endovascular prosthesis comprises bioabsorbable means (12) cooperating with said wire mesh, said bioabsorbable means comprising one or a plurality of medicinal agents and a biocompatible monomer or polymer stimulating cell growth around said lattice and a wire mesh (11) comprises a structure forming a plurality of rings (110A, 110B, 110C) respectively having vertices (111A, 114A, 111B, 114B) connected in pairs by uprights (112A, 113A, 112B, 113B) substantially rectilinear and having a portion (112Ay, 112By) flexible having one or more curvatures. 2. Prosthesis according to the preceding claim, wherein said wire mesh is based on chromium-cobalt or nitinol. The prosthesis of any one of the preceding claims, wherein the flexible portion (112Ay, 112By) substantially describes an 'S' or a 'Z'. 4. Prosthesis according to any one of the preceding claims, wherein two adjacent crowns cooperate via a flexible connector (131, 132, 133) connecting two vertices respectively of said crowns. that the 5. Prosthesis according to the preceding claim, wherein the flexible connector substantially describes a double 'S'. 6. Prosthesis according to any one of the preceding claims, wherein the amounts of crowns and / or vertices and / or connectors have a substantially trapezoidal section whose inner base (Bi) is lower than the outer base (Be). 7. Prosthesis according to the preceding claim, wherein the cutting angles of the section of the amounts of crowns and / or vertices and / or connectors are different. The prosthesis of any one of the preceding claims, wherein the bioabsorbable means (12) is a biodegradable polymer or ceramic. A prosthesis according to any one of the preceding claims, wherein the bioabsorbable means (12) consists of polymer fibers interwoven with the wire mesh (11). 10. Prosthesis according to any one of claims 1 to 8, wherein the absorbable means (12) consist of a substantially tubular structure forming a plurality of rings (120A, 1208) respectively having vertices (121A) connected in pairs by uprights (122A, 123A) substantially rectilinear and having a flexible portion (123Ay) having one or more curvatures. 11. Prosthesis according to the preceding claim, wherein the flexible portion (123Ay) - an amount of the substantially tubular structure of the absorbable means - substantially describes an 'S' or a 'Z'. 12. Prosthesis according to any one of claims 10 or 11, wherein two adjacent rings - the substantially tubular structure of the absorbable means - cooperate via a flexible connector (141) connecting two vertices respectively of said rings. 13. Prosthesis according to the preceding claim, wherein the flexible connector (141) substantially describes a double 'S'. The prosthesis of any one of claims 10 to 13, wherein the respective tubular structures of the metal and bioabsorbable meshes are arranged to cooperate with one another. 15. Prosthesis according to the preceding claim, wherein the flexible portion (123Ay) of an amount (123) of the bioabsorbable structure (12) comprises a recess (123Ayr) to partially accommodate the flexible portion (112Ay) of a amount (112A) of the wire mesh (11). 16. Prosthesis according to any one of the claims. wherein the bioabsorbable means are impregnated with one or more drug agents from a group consisting of anti-inflammatory, antiproliferative, or promoting endothelial cell adhesion, growth, and maturation. A prosthesis according to any one of the preceding claims, comprising a bioabsorbable polymer coating which covers the assembly consisting of the wire mesh (11) and the resorbable mesh (12) after the latter have been assembled. 18. Prosthesis according to the preceding claim, wherein the coating is arranged to degrade completely in a few weeks to a few months by emitting substances having a particular effect or a plurality of effects, among which anti-inflammatory, anti-inflammatory and anti-inflammatory effects. platelet, anticoagulant, anti-thrombotic and anti-proliferative. 19. Prosthesis according to any one of the preceding claims, comprising radio-opaque means (13, 14) located at the ends of the main member of the prosthesis. 20. Prosthesis according to any one of the preceding claims, comprising a quantity of bioabsorbable means (12) substantially equivalent to that of the wire mesh (11) constituting the main member of said prosthesis.