DE202008009610U1 - Prosthetic heart valve system - Google Patents

Abstract

Prosthetic heart valve system (10; 40) for implantation in the body of a mammal, with a flap (16) attached to a stent member (18) is to form a stent-flap element (12), and with a Anchoring element (14) inside the aorta of the mammal is arranged, and the stent-flap element (12) apart is located, characterized in that the anchoring element (14) a cylindrical tube member having a Fabric structure (22) which is supported by a metal net is, and that the stent-flap element (12) and the anchoring element (14) represent two structurally separated elements by band-shaped Connecting means (30; 50) are interconnected such that a between the stent-flap element (12) and the anchoring element (14) formed connecting portion (28) in general free of Foreign material is.

Description

The The present invention relates to a heart valve prosthesis system for Implantation in the body of a mammal, with a flap attached to a stent member for formation a stent-flap element, as well as an anchoring element, the within the aorta, and that of the valve element with stent located spatially away.

Valve prostheses systems of this kind are usually used to exchange injured, bad or non-functioning heart valves. heart valves hold in your heart the unidirectional bloodstream upright, depending on the pressure difference open and close on each side.

Next the valves of the coronary sinus and the valve of the inferior vena cava there are four heart valves: the two atrio-ventricular (AV) valves, to make sure that the blood from the atria into the Herzkammern flows, and not the other way, as well as the two Semilunar (SL) flaps into the arteries leaving the heart, so in the pulmonary artery and the aorta, and prevent blood flows back from the arteries into the heart chambers. The aortic valve, one of the semilunar valves, lies between the left ventricle and aorta. Consist of the mitral valve the heart valves from three heart valve sails that serve the heart valves seal in the closed state.

The Aortic valve can be affected by various diseases, whereby their exchange may be necessary, which in turn means that the aortic valve of a patient replaced by another flap becomes. The flap can either be leaking, d. H. a reflux allow or work inefficiently, in which case the aortic valve is not functional, and blood passively to the heart and flows back in the wrong direction. About that In addition, the flap may partially close, d. H. be stenotic, in which case the flap will not open completely which in turn hinders blood flow from the heart. Both states often occur simultaneously.

One Heart valve replacement usually involves an anterior sternotomy necessary, and thus an intervention on the open heart, which a heavy Intervention on the patient to be treated means: the sternum becomes cut in half and the patient becomes, after the pericardium was opened, connected to a heart lung bypass machine. Once the patient is connected to the bypass, the diseased Aortic valve of the patient removed and a mechanical or tissue flap put in their place. In addition to the physical burden associated with This operation is connected beyond the risks that the patient dies or serious complications from the open heart suffers, which in particular of depends on the health and age of the patient.

In More recently, valves have been developed using a catheter implanted without an open heart procedure can be.

Currently There are two basic types of artificial heart valves, mechanical valves and tissue valves. Tissue heart valves consist usually from tissues of animals, either from Heart valve tissue of animals or of animal pericardial tissue, the two are treated in such a way that a repulsion and calcification is prevented. While mechanical flaps are generally designed to extend the life of a patient To survive, they have the disadvantage of being due Their material increases the risk of blood clots that exists only through a constant anti-coagulation therapy can be prevented, which makes the patient stronger Bleeding tends. Mechanical heart valves generally exist all made of synthetic or non-biological materials, whereas heart valves made of tissue (or bioprostheses) of synthetic and biological materials. Heart valve bioprostheses can either represent xenografts taken from a species, which differs from the recipient, or homografts, represent the donor flaps of the same species as the were taken from the recipient.

The EP 0 592 419 describes a heart valve prosthesis having a collapsible resilient flap attached to an elastic / self-expanding stent. The commissure points of the elastic flap are attached to the cylindrical surface of the elastic / self-expanding stent made of a radially collapsible and re-expandable cylindrical support member. The prosthesis is inserted into the body by catheterization.

Further, the US 6,652,578 a prosthetic heart valve stent consisting of an expandable stent body member and a graft member, the latter consisting of biologically-derived membranes or biocompatible synthetic materials.

A major disadvantage of the valves known in the art, however, is that they are inadequate at the point where the flap with the art union flap to be replaced, can be safely anchored. In addition, many heart valve replacement elements have no elements with which the artificial valve can be attached sufficiently securely to the place of the natural flap to be replaced. Therefore, with such prior art heart valves there is a risk that the valve will migrate into the vessel and thereby no longer be able to meet the requirement of a replacement valve.

On on the other hand, some of the heart valve replacement devices, that are known in the art, stiff and bulky great devices for them to safely in a vessel can be anchored, which is why such heart valve replacement devices often to a modification of the vascular anatomy lead, and consequently to a malfunctioning Flap.

In front This is the object of the present invention, a new one To provide heart valve prosthesis system with which the disadvantages of the prior art can be overcome and which makes it possible, the valve replacement device safely anchor without risk of blood flow in the neighboring vessels are blocked or blocked becomes.

The The object underlying the invention is achieved by a heart valve prosthesis system solved the type mentioned, wherein the anchoring element has a cylindrical tubular element, that from a metal net supported fabric structure and wherein the stent-flap element and the anchoring element represent two structurally separate elements by means of band-like Connection means are connected, in such a way that between the stent-flap element and the anchoring element a connecting portion is generally free of foreign material.

With the heart valve replacement system according to the invention It is therefore possible to put the system in a jar of one Safely Secure Patients: The Stent-Valve Element of the Replacement System, which is to replace the affected native flap, is about the native flap released, for example by compression of the stent-valve element within a catheter and releasing the stent flap element above the flap to be replaced. simultaneously is the anchoring element of the replacement system, with the stent-flap element over Connecting means is connected in the aorta near the stent-valve element released, which causes the stent-flap element in place the native flap as well as the whole system in the vessel safely anchored.

About that In addition, because the connecting portion between the Stent flap element and the anchoring element in general free of foreign material is, the perfusion of the vessels, the over half the flap, especially the coronary arteries, ensured.

To the release expands the anchoring element, for example placed in the lower section of the ascending aorta, such that it rests securely against the vessel wall, thereby its cylindrical tubular member, the formed from a supported by a metal mesh fabric structure is anchored in the aorta. Due to the fact that the Stent flap element and the anchoring element by the connecting means are separated, in such a way that between a Connecting portion is generally free of Material is, the vessels that can in the area of the lower section of the ascending aorta and branch off in the area of the heart valve, still supplied with blood become.

The The object underlying the invention is therefore complete solved.

in the For the purposes of the present invention, the term "im Generally free of material "mean that in addition to the band-like Lanyards no other materials are provided to to connect the stent flap element and the anchoring element, in such a way that between the stent-flap element and the Anchoring element sections are formed, free of any Material are, and thereby quasi-free openings in make up the replacement system.

Further In the present case, the term "band-like" is meant to be any Form of connecting means between the stent-valve element and the anchoring element, which is a strip, strand, web or rod-like or another similar shape has, and therefore a thin or fine connecting element represents between the two elements, free of any Cover is.

Of the The term "anchoring element" is intended to mean any element mean, which is designed such that by its concerns to the vessel walls the system safely Place and place of the release site is held.

The expression "apart" or "separated from each other" is intended to mean that the anchoring element and the stent flap element do not lie directly against one another but are separated from one another. In the context of the present invention, the two elements the replacement system by the connecting means at a distance from each other, and therefore separated.

Under A "stent" will generally be a radially expandable one Endoprosthesis understood that a typical intravascular Implant implanted transluminal, and the radially enlarged or expanded after it was introduced. Stents can be self-expanding be expanded or expanded by means of an applied from the inside radial force for example, when applied to a balloon and be introduced.

In a preferred embodiment of the invention the bridge-like connecting means of the heart valve prosthesis system or mechanical means by which the stent-valve element is connected to the anchoring element.

Thereby, in that the connecting means comprise suture means or mechanical means, or sewn, the two elements, so the stent-flap element and the anchoring element effectively and simply connect with each other while being at the same time stay separated from each other and between them a connecting section which is generally free of material. As part of of the present invention, the term "suture means" generally materials that are not rigid but rather flexible Represent filaments or fibers.

In In this connection, it is preferred if the stitching means are thread-like Represent structures. Under "thread-like structures" become filaments, filaments or fibers or the like meant, which are suitable, a seam connection of the two To form elements of the valve prosthesis. For example, a biocompatible thread to be used, the two elements to connect, while maintaining a certain distance between the two elements is provided, whereby the connecting portion which is generally free of material.

The sutures or sutures used in connection with the present invention as connecting means may in particular be suture means such as threads currently used in the medical field, for example for surgical sutures, which are biocompatible and made of natural or synthetic material. Exemplary materials that can be used as a suture means, polypropylene, polyester, polyethylene terephthalate, polybutylene terephthalate, polyamide, nylon materials, Goretex ^®, or stainless steel, nitinol, or any other metal alloy. In principle, any biocompatible, nonabsorbable suture that has been found to be suitable for implantable medical devices or that seems very suitable for such purposes may be employed.

According to one another preferred embodiment of the invention the band-like connecting means flexible, web-shaped Structures on, each over their ends with the stent flap element and connected to the anchoring element.

in the In the context of the present invention, the expression "bar-shaped" any element that means a solid and ordinary makes straight length of any material that to implant is suitable in the human body, and that, for example a metal, etc. can be. The expression "formed as a bridge" can also be a narrow band or strip of a rather stiff Material, such as metal mean.

By the use of web-shaped and rather strong fasteners a certain length is possible, the two Elements, so the stent-flap element and the anchoring element keep apart, in such a way that a connecting portion which is generally free of material. It understands itself, that any material can be used that meets the requirement the above definition of the term "bridge-shaped" Lanyard meets as long as it is biocompatible.

About that In addition, the connecting means make it possible, in particular the suturing means, the distance between the two elements of the valve prosthesis individually, which means that the prosthesis is very specific for a patient to be treated can. This is of particular advantage since the individual states and conditions of the heart, the heart valve and the aorta as well the branching vessels from patient to patient can vary greatly.

In a development of the invention is the stent-flap element with the anchoring element over the three sails of the flaps connected.

With the term "sail of the flap" is the training of the Heart valve meant, namely with three sails, the 120 ° in the circumferential edge of the stent are separated from each other which the seams are attached to the flap sails.

In a further development of the invention, it is preferred if the metal net of the cylindrical tubular element of the anchoring element consists of at least two meandering metal rings extending in the longitudinal direction of the Anchoring element are arranged successively, and that the fabric structure of the cylindrical tubular member consists of a fabric material which is fixed to the rings, and thereby connecting, wherein the fabric material forms a hollow cylindrical body.

This embodiment has the advantage that prefabricated stents or stent graft elements can be used as an anchoring element in the heart valve prosthesis system. Such stent elements or stent graft elements are known in the art, and are for example in the German patent application DE 100 65 824.5 whose contents are hereby explicitly referred to.

In In this context, it is preferred if the metal rings Z-shaped Profiles have, with pointed arches, alternating with the have proximal and distal end of the anchoring element.

In a development of the invention is preferred when the number the pointed arches of the last ring of the proximal end of the anchoring element is smaller than the number of pointed arches in the rings following the last ring towards the distal end of the anchoring element are arranged.

in this connection is particularly preferred when the last ring of the proximal end has three pointed arches that are in the direction of the proximal Have the end of the anchoring element, and in particular, if the three sails of the stent flap element over the connecting means associated with the three pointed arches.

In a preferred embodiment of the invention is that Stent element of the stent flap element self-expanding Stent member. It is particularly preferred if the stent element of the stent-valve element is a shape memory material ("Shape-memory"), including at least a shape memory or shape memory metal, especially nitinol.

Such self-expanding stent elements contain an elastic material, that can expand outward, ie radially, as soon as forces are introduced to compress the material of the stent member exerted in a vessel be removed, for example by means of a shell. Nitinol is preferably used for this purpose, which may also possess shape memory properties. Of the Frame of the stent is made of this material, and owns preferably a tubular structure, usually has a slightly larger diameter than the vessel, into which it is to be implanted. The advantage of this measure is that the stent is due to its superelasticity after its release from a compressed state leading to the introduction the prosthesis is used, automatically its original shape takes up again.

Similar it is preferred if the metal mesh of the anchoring element Rings exists, which have a shape memory material, including at least one shape memory polymer or a shape memory metal, in particular nitinol.

In another preferred embodiment of the invention the fabric structure of the anchoring element comprises a material, which is selected from the group of polymers, preferably polyester.

Such Tissue structures used with stents to stent grafts are generally known in the art, and can be any natural or synthetic polymer which is biocompatible and which serves as a "mantle" for the stent frame within the scope of the present invention is. In addition, the polymers can with a medically active substance or any other substance coated be a condition of a patient at the site of implantation to influence and / or treat the prosthesis. This measure is known per se, and the medical active substances can For example, to prevent a stenosis, the healing of wounds within the Accelerate wall of a vessel, or development prevent inflammation. In addition, can the mesh of the anchoring element and / or the stent flap element coated or treated with a medically active substance be.

In a development of the invention, it is preferred if the flap is a heart valve which has a material which is selected from human, bovine, porcine or horse pericardial tissue. The flap can therefore be either a xenograft or a homograft. In particular, it is preferred if the materials are treated, for example, with glutaraldehyde. The biocompatible material to be used as a valve replacement is usually made by fixing the material in a glutaraldehyde solution which acts as a tissue preservative. Although fixation into glutaraldehyde may have disadvantages in terms of biomaterial calcification, glutaraldehyde fixation remains the method of choice for preserving tissue and preparing it for implantation as a biomaterial. In this context, it is preferable if the Valve prosthesis is treated with a substance that prevents calcification, for example with dimethyl sulfoxide, or the like.

• – Bereitstellen einer auf einem Stentelement angebrachten Klappe, um ein Stent-Klappen-Element zu bilden,
• – Bereitstellen eines Verankerungselements mit einem zylindrischen röhrenförmigen Element aus einer Gewebestruktur, die von einem Metallnetz getragen wird, und
• – Verbinden des Stent-Klappen-Elements und des Verankerungselements durch Band-ähnliche Verbindungsmittel, derart, dass ein Verbindungsabschnitt zwischen dem Stent-Klappen-Element und dem Verankerungselement gebildet wird, der im Allgemeinen frei von Fremdmaterial ist.

The present invention further relates to a method of making a heart valve prosthesis as disclosed herein, the method comprising the steps of:

• Providing a valve mounted on a stent member to form a stent-flap member,
• Providing an anchoring element having a cylindrical tubular element of a fabric structure supported by a metal net, and
• - Connecting the stent-flap element and the anchoring element by band-like connecting means, such that a connecting portion between the stent-flap element and the anchoring element is formed, which is generally free of foreign material.

It is particularly preferred when the tape-like connecting means, for connecting the stent flap element and the anchoring element used, suture means and / or mechanical means are.

• – Transfemoral, d. h. auf eine retrograde Art und Weise, unter Verwendung eines langen Katheters, der über die Oberschenkelarterie, Hüftkranzarterie und Aorta eingeführt wird, wodurch das Stent-Klappen-Element über den nativen Klappensegeln freigesetzt wird, und nachfolgend das Verankerungselement in der aufsteigenden Aorta freigesetzt wird.
• – Über eine transapikale, d. h. auf eine anterograde Art und Weise mit einem Katheter mittlerer Größe, der mittels einer kleinen Thoraktomie und einer Punktur im Apex der linken Herzkammer zugeführt wird, und mittels dessen zunächst das Verankerungselement in der aufsteigenden Aorta und nachfolgend das Stent-Klappen-Element über die ursprüngliche Klappe freigesetzt wird, oder auf entgegengesetzte Art und Weise, indem zuerst die Stent-Klappe und nachfolgend das Verankerungselement freigesetzt wird.
• – Schließlich in einem Eingriff am offenen Herzen mit einem Herzlungenbypass; bei diesem Eingriff wird die Aortenwurzel seziert, die ursprünglichen Segel der Herzklappe entnommen, d. h. herausgeschnitten, und nachfolgend die Klappenprothese direkt in den Anulus platziert, und zwar mittels eines kurzen flexiblen Katheters, und einem nachfolgenden Vernähen des Stentgrafts an die aufsteigende Aorta. Der letztere Weg ist jedoch, aufgrund der oben erwähnten Nachteile, der am wenigsten bevorzugte; nichtsdestotrotz kann unter bestimmten Umständen eine solche Operation notwendig sein.

The valve prosthesis according to the invention is placed in the heart using an endovascular catheter. The site of release can be achieved in three different ways:

• Transfemoral, ie, in a retrograde manner, using a long catheter inserted through the femoral artery, femoral artery, and aorta, thereby releasing the stent-valve element over the native valve leaflets, and subsequently the anchoring element in the ascending aorta is released.
• - Via a transapical, ie in an anterograde manner with a medium-sized catheter, which is supplied by means of a small thoracic and a puncture in the apex of the left ventricle, and by means of which first the anchoring element in the ascending aorta and then the stent flaps Element is released via the original flap, or in the opposite manner, by first releasing the stent flap and subsequently the anchoring element.
• - finally in an open heart surgery with a cardiopulmonary bypass; In this procedure, the aortic root is dissected, the original leaflets are removed from the heart valve, ie excised, and subsequently the valve prosthesis placed directly into the annulus, by means of a short flexible catheter, and subsequent suturing of the stent graft to the ascending aorta. The latter approach, however, is least preferred because of the drawbacks mentioned above; nevertheless, under certain circumstances such an operation may be necessary.

It it is understood that the features mentioned below be discussed in more detail, not only in the respectively specified Combination but also in isolation or in other combinations can be used without the scope of the present To leave invention.

The Invention is covered by the description and the attached Figures described in more detail. These show:

1 a schematic representation of the heart;

2a a perspective schematic representation of an embodiment of the valve prosthesis according to the invention;

2 B an enlarged view of the connecting means of in 2a shown valve prosthesis;

3a a perspective schematic representation of another embodiment of the valve prosthesis according to the invention; and

3b an enlarged view of the connecting means of the valve prosthesis 3a ,

In 1 denotes the reference numeral 100 Overall, the human heart as a whole, with the aorta 102 , the left ventricle 104 and the right ventricle 106 , The four flaps of the heart 100 are the aortic valve 108 that exist between the left ventricle 104 and the aorta 102 lies, the Pulmonarklappe 110 that is between the right ventricle 106 and the pulmonary artery 107 lies, the mitral valve 112 that exist between the left ventricle 104 and the left atrium 111 lies, and the tricuspid valve 114 that is between the right atrium 113 and the right ventricle 106 lies.

If during the ventricular systole the pressure in the left ventricle 104 about the pressure in the aorta 102 rises, opens the aortic valve 108 , causing the blood to enter the left ventricle 104 in the direction of Aorta 102 leaves. When the ventricular systole is over, the pressure in the left ventricle sinks 104 quickly, causing the aortic pressure the aortic valve 108 for closing forces.

In patients with a diseased and / or malfunctioning aortic valve 108 have to shut up 108 be replaced with a valve prosthesis.

In 2a denotes the reference numeral 10 a heart valve prosthesis according to the invention with a stent flap element 12 and an anchoring element 14 , The stent flap element 12 has a flap material 16 which preferably consists of a human, bovine, porcine or horse pericardial tissue. The valve material 16 is inside a cylindrical stent 18 sutured. The stent is preferably self-expanding and constitutes a highly elastic metal stent, preferably a laser-cut nitinol.

In the embodiment shown, the anchoring element 14 a stent graft, which is a cylindrical stent 20 and a graft 22 having. The graft 22 covers the stent 20 fixing on its outer side, similar to a shell or a coat. The graft 22 is preferably of a natural or synthetic polymer. The stent is made of metal springs, preferably Nitinol. The feathers make two metal rings 24 which are meandering, and which are consecutive in the longitudinal direction of the anchoring element 14 are arranged. The graft 22 or the tissue structure of the cylindrical stent is fixed to the rings and connects them.

As further out 2a can be removed, have the metal rings 24 a z-shaped profile with pointed arches 25 alternating towards the proximal end 15 and distal end 17 of the anchoring element 14 point.

In 2a are connecting means 30 shown the anchoring element 14 with the stent flap element 12 connect. The connecting means 30 are also in 2 B shown in an enlarged view. In the in 2 embodiment shown have the connecting means 30 a bar-shaped training: they put sticks with a loop or eyelet 31 at each of its ends, as in 2 B is shown. For example, the rod-shaped connecting means may be made of any metal that is biocompatible with respect to the human body. As in 2a shown connect the connecting means 30 or their eyelets 31 , on each side the metal ring 24 of the anchoring element 14 ; In particular, they connect the metal ring 24 of the anchoring element 14 that concerning the other rings 24 of the anchoring element close to the stent flap element 12 is positioned, and more precisely on the bows 25 of the metal ring 24 pointing in the direction of the stent-valve element 12 point. With their other side, or rather with the eyelet on this side, the connecting means with the stent portion of the stent-flap element 12 connected, at the top of the stent-flap sail, wherein the connection through a physical element, such as through a hole in the sail. By varying the length of the connecting means 30 lie the anchoring element 14 and the stent-valve element 12 apart, creating a connecting section 28 between the stent-valve element 12 and the anchoring element 14 form, being the region 28 is generally free of foreign material, in particular free of material 16 or 22 ,

As 2a can also be removed, is the anchoring element 14 over the connecting means 30 and over its proximal end 15 with the stent flap element 12 connected, with only the pointed arches 25 of the last ring 24 of the proximal end 15 towards the proximal end 15 of the anchoring element 14 wise, through the graft 22 or a tissue structure material 22 are covered. Through the meandering circumferential last ring 24 and because of the last ring 24 , from the proximal end 15 of the anchoring element 14 points away, sections are formed that are not from the graft or the tissue structure material 22 are covered.

How further 2a can be taken is the number of pointed arches 25 of the last ring 24 of the proximal end 15 of the anchoring element 14 smaller than the number of pointed arches 25 The Rings 24 , following each other on the last ring 24 towards the distal end 17 of the anchoring element 14 are arranged, and in particular, that the last ring 24 of the proximal end 15 three pointed arches 25 which points towards the proximal end 15 of the anchoring element 14 point.

Referring to 3 are the same features of this embodiment with the same reference numerals as the corresponding features of FIG 2 illustrated embodiment. Consequently, the embodiment of the valve prosthesis 40 , in the 3a is shown, an anchoring element 14 and a stent-valve element 12 , both elements being connected by connecting means 50 are connected. The formation of the anchoring element 14 and the stent flap element 12 correspond to the anchoring element 14 and the stent-valve element 12 out 2a , Briefly explained, the stent-flap element has 12 a flap material 16 that within a cylindrical, preferably self-expanding stent 18 sewn, which is preferably made of a laser-cut nitinol.

In the in 3a illustrated embodiment further provides the anchoring element 14 a stent graft, which is a cylindrical stent 20 features, with feathers and a graft 22 who is the stent 20 covering fixed on the outer side. The springs make two metal rings 24 meandering are circular. The graft 22 or the tissue structure of the cylindrical stent is fixed to the rings and connects them.

In 3a are connecting means 50 shown the anchoring element 14 with the stent flap element 12 connect. The connecting means 50 are also in 3b shown in an enlarged view. In the in 3 illustrated embodiment, the connecting means 50 three suture means in the form of filaments or fibers having a filamentary structure. The three sutures are passed through the stent arches 25 of the anchoring element 14 led and will sail to the flap 16 of the stent flap element 12 sutured. Due to the length of the threads are the anchoring element 14 and the stent-valve element 12 each other. In addition, a connection section 28 between the stent-valve element 12 and the anchoring element 14 formed, this section is generally free of foreign material, in particular free of materials 16 or 22 ,

Therefore, with the exemplary in the embodiments of 2 and 3 illustrated heart valve prostheses, the connecting portion free of any foreign material, which in turn ensures the perfusion of the coronary arteries. This is due to the fact that the connecting portion is placed within the mouth portion of the coronary arteries so that blood flow into these vessels is not blocked by the heart valve prosthetic material.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 0592419 [0008]
• - US 6652578 [0009]
• - DE 10065824 [0034]

Claims (15)

Heart valve prosthesis system ( 10 ; 40 ) for implantation in the body of a mammal, with a flap ( 16 ) attached to a stent element ( 18 ) is used to form a stent flap element ( 12 ), and with an anchoring element ( 14 ) located within the aorta of the mammal and that of the stent-valve element ( 12 ), characterized in that the anchoring element ( 14 ) has a cylindrical tube member made of a fabric structure ( 22 ), which is supported by a metal mesh, and that the stent-flap element ( 12 ) and the anchoring element ( 14 ) represent two structurally separate elements which are provided by band-shaped connecting means ( 30 ; 50 ) are connected to each other in such a way that a between the stent-flap element ( 12 ) and the anchoring element ( 14 ) formed connecting section ( 28 ) is generally free of foreign material. Heart valve prosthesis system ( 10 ; 40 ) according to claim 1, characterized in that the band-like connecting means ( 30 ; 50 ) Suture ( 50 ) or mechanical means ( 30 ), by means of which the stent flap element ( 12 ) with the anchoring element ( 14 ) is connected. Heart valve prosthesis system ( 10 ; 40 ) according to claim 2, characterized in that the suture means ( 50 ) are thread-like structures. Heart valve prosthesis system ( 10 ; 40 ) according to one of claims 1 to 3, characterized in that the band-shaped connecting means ( 30 ) have flexible, rod-shaped structures which, via their ends, in each case with the stent-flap element ( 12 ) and the anchoring element ( 14 ) are connected. Heart valve prosthesis system ( 10 ; 40 ) according to one of claims 1 to 4, characterized in that the stent-flap element ( 12 ) with the anchoring element ( 14 ) over three sails of the flap ( 16 ) connected is. Heart valve prosthesis system ( 10 ; 40 ) according to one of claims 1 to 5, characterized in that the metal net of the cylindrical tubular element consists of at least two meandering metal rings ( 24 ) which follow one another in the longitudinal direction of the anchoring element ( 14 ) and that the tissue structure ( 22 ) of the cylindrical tubular element is made of a fabric structure material which is attached to the rings ( 24 ) and which connects them, the fabric structure material forming a hollow cylindrical body. Heart valve prosthesis system ( 10 ; 40 ) according to claim 6, characterized in that the metal rings ( 24 ) a Z-shaped profile with pointed arches ( 25 ) which alternate in the direction of the proximal end ( 15 ) and the distal end ( 17 ) of the anchoring element ( 14 ) point. Heart valve prosthesis system ( 10 ; 40 ) according to one of claims 6 or 7, characterized in that the number of pointed arches ( 25 ) of the last ring ( 24 ) of the proximal end ( 15 ) of the anchoring element ( 14 ) smaller than the number of pointed arches ( 25 ) The Rings ( 24 ) following the last ring ( 24 ) in the direction of the distal ring ( 17 ) of the anchoring element ( 14 ) are arranged. Heart valve prosthesis system ( 10 ; 40 ) according to one of claims 7 or 8, characterized in that the last ring ( 24 ) of the proximal end ( 15 ) three pointed arches ( 25 ), which in the direction of the proximal end ( 15 ) of the anchoring element ( 14 ) point. Heart valve prosthesis system ( 10 ; 40 ) according to claim 9, characterized in that the three sails of the flap ( 16 ) via the connecting means ( 30 ; 50 ) with the three pointed arches ( 25 ) are connected. Heart valve prosthesis system ( 10 ; 40 ) according to one of claims 1 to 10, characterized in that the stent element ( 18 ) of the stent flap element ( 12 ) is a self-expanding stent element. Heart valve prosthesis system ( 10 ; 40 ) according to one of claims 1 to 11, characterized in that the stent element ( 18 ) of the stent flap element ( 12 ) has a shape memory material, including at least one polymer or shape memory metal, in particular nitinol. Heart valve prosthesis system ( 10 ; 40 ) according to one of claims 1 to 12, characterized in that the fabric structure ( 22 ) of the anchoring element ( 12 ) has a material selected from the group of polymers, preferably the polyester. Heart valve prosthesis system ( 10 ; 40 ) according to one of claims 1 to 13, characterized in that the metal net of the anchoring element ( 14 ) from rings ( 24 ) having a shape memory material, including at least one polymer or shape memory metal, in particular nitinol. Heart valve prosthesis system ( 10 ; 40 ) according to one of claims 1 to 14, characterized gekennzeich net, that flap ( 16 ) is a heart valve comprising a material selected from the group of human, bovine, porcine or equine pericardial tissues.