RU2425657C2 - In-wall supporting frame of heart valve bioprosthesis and heart valve bioprosthesis - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: group of inventions relates to cardiosurgery. In-wall supporting frame (1) for integration into heart valve bioprosthesis (10) has comissures (13) and cusps (11a, b, c), determining valve plane. Cusps are attached to external tubular wall (12) and branch from it in lateral direction along comissures (13). Frame consists of base (3) and stabilising part (2), installed on base and containing, at least, two in-wall rods (2a, 2b), installed on base (3) with possibility of travel aside along circumference arch relative point of intersection of line on which external tubular wall (12) intersects with comissures (13), with valve plane (10). Described is bioprosthesis of heart valve, which contains in-wall supporting frame.

EFFECT: ensuring bioprosthesis rigidity.

12 cl, 4 dwg

Description

FIELD OF THE INVENTION

This invention relates to an intramural, or intra-wall stiffening reinforcing framework, designed for integration into a bioprosthesis of a heart valve, the basis of which is a heart valve of biological origin, in which the valve plane is defined by the valves laterally attached, along with commissures, to the external tubular wall. The frame is designed to accommodate such a heart valve in organic tissue; it consists of a support and a stabilizing part attached to it, intended for insertion into the external tubular wall of the heart valve in order to increase the rigidity of its structure, which ensures that the heart valve retains its shape after implantation. The invention also relates to a valve bioprosthesis reinforced with such a framework.

State of the art

In the field of cardiac surgery associated with the replacement of heart valves, mainly artificial valve prostheses, usually metal valves, the surface of which is covered with synthetic tissue, or bioprostheses, usually valves of animal origin, prepared for implantation in the human body, are currently used. Bioprostheses can be divided into two groups: dentures with a stent and dentures without a stent.

For prostheses belonging to the category of bioprostheses, the authors of this invention propose a new approach to strengthening the biological part of the prosthesis, usually representing the heart valve of the animal; this approach consists in introducing a stiffening reinforcing (support) framework into the tissue of the heart valve and differs both from the method in which the valve of animal origin is used without strengthening its stiffness (in the case of prostheses without a stent), and from the method of strengthening the stiffness of the valve by fixing the stent on the surface of the valve (in the case of dentures with a stent). A framework that allows the manufacture and use of a bioprosthesis of this new type has, in general terms, a short support on which rods are inserted into the tissue of the external tubular wall of the biological valve parallel to the lines of intersection of this wall with the planes of the valve commissures. The proposed support frame allows the manufacture of reinforced valve bioprostheses that combine the advantages of valveless bioprostheses with a stent and traditional bioprostheses with a stent. Indeed, on the one hand, such a framework makes it possible to obtain bioprostheses of a maximum area (and, therefore, a maximum volume characterizing the main function of the heart valve), which is typical of prostheses without a stent (due to the fact that there is no device occupying a significant volume similar to a traditional stent ) On the other hand, this framework allows, without using a traditional stent, to strengthen the stiffness of the prosthesis and thereby ensure that it maintains its desired shape, which allows the use of a relatively simple and fast implantation technique for this new type of reinforced bioprosthesis, used in the case of traditional bioprostheses with a stent; this is achieved due to the increased stiffness of the bioprosthesis of the heart valve and the fact that in this case only one seam is needed in the valve plane, and not two seams, as for prostheses without a stent.

In this context, however, it turned out that, in introducing said support frame into the external wall of the biological valve, problems may arise in some cases. It turned out that the area around the point of intersection of the line along which the plane of the commissure of the valve of the heart intersects with the outer tubular wall, and the plane of the valve of the prosthesis is distinguished by a special structure of its constituent fibers, exhibiting reduced strength (hereinafter, this point will be called a "special point of commissure" or " intersection point "). The introduction of the rod into this area can lead to dissection of the fibers and weakening of the organic tissue, which can adversely affect the stability and quality of the prosthesis made in this way; in particular, these lesions may subsequently initiate rupture or exfoliation of the cardiac valve commissure.

In addition, since the core of such a support frame is fixed on a relatively short support, the implantation of a prosthesis equipped with such a frame is relatively more difficult, and therefore requires a great deal of experience from the implant surgeon.

Disclosure of invention

The present invention is the solution of these problems and the creation of such a supporting frame for a bioprosthesis valve, which does not damage the organic tissue of the biological valve and allows for simple and quick implantation of a prosthetic heart valve obtained in this way.

The present invention describes an intra-wall support frame for a valve bioprosthesis; the stabilizing part of the frame includes at least two intra-wall rods adapted for insertion into the organic tissue of the biological valve of the heart; these intra-wall rods are located on the base in such a way that when the frame is placed in the biological valve, the rods are laterally displaced along an arc of a circle from the point at which the line of intersection of the tubular external wall with the commissure plane intersects the prosthesis valve plane; the invention also describes a valve bioprosthesis reinforced with at least one such framework.

The frame, further, may have a base, which is a closed ring or an open ring, that is, a ring on the circumference of which there is an arc that is not included in the base of the frame.

The base and / or fastening link that fastens to the opposite ends of the rods of the support frame may be coated with biological material, such as pericardial tissue.

Using these tools, you can get the frame, giving the bioprosthesis of the heart valve sufficient stability and rigidity necessary to maintain the valve after implantation of the desired shape, not damaging the organic tissue of the biological valve of the heart and avoiding the use of a traditional stent, occupying a significant volume. In this case, the framework can be implanted, especially when the base is an arc of a circle, using a relatively simple and quick implantation technique that ensures (provided that all the metal elements of the framework are covered with biological material) that after implantation with the patient’s body only the biological tissue of the bioprosthesis will touch.

Other advantages of the invention arise from its features set forth in the dependent claims and the following description, in which the invention is described in more detail using the drawings.

Brief Description of the Drawings

The accompanying drawings schematically illustrate several ways of applying the invention, taken as examples.

1 and 2 schematically show the principle of the device and two different ways of using the intra-wall support frame for a valve bioprosthesis.

Figure 3 shows in perspective projection a diagram of a third method for using an intra-wall support frame for a valve bioprosthesis.

Figure 4 schematically shows in perspective a bioprosthesis of a valve equipped with an intra-wall support frame used in accordance with the fourth method of application; in the above example, the prosthesis is located between the aortic root and the ascending aorta.

The implementation of the invention

The invention will now be described in detail with reference to the accompanying drawings. The subject of the invention is an enhanced valve bioprosthesis prepared to replace a heart valve. Such a heart valve prosthesis can be implanted in the position of the lunate (aortic), in the position of the mitral (bicuspid) or in the position of the tricuspid (tricuspid) valve and should be oriented in accordance with the direction of the blood flow. The invention relates primarily to a supporting frame device necessary for the manufacture and implantation of such a heart valve prosthesis.

Before proceeding with the description of the intraparietal supporting frame and the heart valve prosthesis strengthened by it, it seems useful to give a brief description of the structure of the natural valve of the human heart, starting from the structure of the replacement biological valve. Such a description will contribute to a better understanding of the functioning of the support frame and methods for introducing the frame into the valve bioprosthesis in order to enhance its rigidity.

Such a valve (an animal’s aortic valve or even a valve bioprosthesis shown schematically in FIG. 4 can be considered as an example) is located in the aorta 20 between the aortic root 21 and the ascending aortic arch 22. The heart valve 10, in general, has three flaps 11a, 11b and 11c defining a valve plane, and an external tubular wall 12, which is part of the tubular wall of the aorta of the animal, and now surrounds the valve plane; the flaps are attached to the outer tubular wall 12 at the edges. In addition, for each pair of valves 11a, 11b and 11c, there are triangular (in general view) vertical walls called commissures (13) extending from the outer tubular wall in the direction of the valve center or, for the mitral and tricuspid position, in the valve - in the direction of the middle of the corresponding cavity of the heart. Commissures 13 are connected, on the one hand, with two edge portions of the cusps 11a, 11b and 11c directed to the inner region of the valve or, for the mitral and tricuspid position, to the middle of the corresponding cavity of the heart, and on the other hand, they are connected to the outer tubular wall 12. Therefore, blood can flow from the aortic root 21 to the ascending aortic arch 22 (or from the atrium to the cavity of the corresponding ventricle), as shown by the arrows in FIG. 4, while blood flow in the opposite direction is not possible. The biological valve, which serves as the biological component of the reinforced bioprosthesis, usually takes their animal aorta and, in the case of replacement of the aortic valve, considered here as an example, the boundary of the outer tubular wall 12 to which the commissures 13 are attached (this boundary is located relative to the valve plane in the direction blood flow), usually has a shape close to a sinusoid. This form allows, on the one hand, to include in the prosthesis points belonging to the sinotubular connection 14, which are the highest (with respect to the valve plane) points of contact between the outer tubular wall 12 and commissures 13, and on the other hand, leave enough space for the right coronary arteries 23a or the left coronary artery 23b, the border of which passes near the right sinus of Valsalva 24a or the left sinus of Valsalva 24b, respectively. The side of the tubular wall 12 corresponding to the non-coronary sinus of Valsalva 24 s, may also have a sinusoidal border.

Having examined the structure of the natural aortic valve, which in general terms is also the structure of the biological heart valves 10 used for the manufacture of bioprostheses of the heart valves, we can better understand the structure of the supporting intra-wall skeleton of the present invention, an example of which is shown in Figs. 1 and 2.

Figure 1 illustrates the essence of the first method of application according to the invention of the supporting intra-wall frame 1, intended for integration into the bioprosthesis of a valve including a biological valve of the heart 10 having the structure described above. This supporting intra-wall frame 1 is adapted to accommodate, at least partially, within the organic tissue of such a heart valve 10, as long as it has a base 3 and a stabilizing part 2 attached to the base 3. The stabilizing part 2 is intended to be inserted into the tissue the outer tubular wall 12 of the heart valve 10 in order to enhance the rigidity of its structure, which is necessary to preserve the shape of the heart valve 10 after implantation.

In order to avoid damage to the areas of reduced strength surrounding the singular points of the commissures 13, which were mentioned in the introduction, in the stabilizing part 2 of the support frame there are at least two intra-wall rods 2a, 2b adapted for insertion into the organic tissue of the heart valve 10; these intra-wall rods 2a, 2b are fixed on the base 3 so that after the insertion of the frame into the heart valve 10, these rods are displaced along the circular arc in the lateral direction from the point of intersection of the line along which the plane of the commissure 13 of the heart valve 10 intersects with the outer tubular wall 12, and the plane of the valve 10 of the valve prosthesis.

Due to the lateral displacement of the intra-wall rods 2a, 2b to the sides of the intersection point, it is possible to avoid damage to the fiber structure in the region of reduced strength surrounding this point, as a result of which the stability and quality of the reinforced valve bioprosthesis are increased. If the heart valve 10 intended for an adult patient has an external tubular wall 12 with a circumference of about 3-4 cm, the lateral displacement from the intersection point is at least about 2 mm and can be increased to about half the height distance between the sinotubular connection 14 and the lowest points of the sinusoid, which is the boundary of the outer tubular wall 12, located between (along an arc of a circle) the highest points 14 belonging to the synotubular connection. In fact, outside the region of reduced strength surrounding the intersection point, the rigidity of the outer tubular wall 12 is fairly constant, and the location of the intra-wall rods 2a, 2b introduced outside this sensitive region is chosen so that the rods of the support frame 1 are far enough from this region, but at this would still provide the desired shape stability of the heart valve prosthesis.

When the frame 1 is placed in the heart valve 10, it is preferable that the intra-wall rods 2a, 2b forming the stabilizing part 2 are located on the base 3 so that their lateral displacements from the point on the base 3 corresponding to the intersection point are equal to each other. This is schematically shown in FIGS. 1 and 2; the latter shows a second method of using the support frame 1 according to the invention, having more than two rods; in this example, there are six intra-wall rods 2a-2f. In configurations that are very different from those described, the number of rods 2 and the lateral displacements with respect to the intersection point can, of course, be chosen other than in the configurations taken as examples; in particular, irregular lateral displacements are possible. In particular, when more than two intra-wall rods 2 are used, the displacements of the rods can be chosen larger than the aforementioned half of the height distances between the sinotubular connection 14 and the lowest points of the sinusoid, which is the boundary of the outer tubular wall 12, located between the points belonging to the sinotubular connection 14.

Preferably, the intra-wall rods 2 form a right angle with the base 3. Then, after the frame 1 is placed in the heart valve 10 in the reinforced valve prosthesis obtained, the rods 2 will be laterally displaced and parallel to each of the lines of intersection of the outer tubular wall 12 with the planes of the commissures 13 of the valve prosthesis heart 10. Essentially, the perpendicular connection between the rods 2 and the base 3, in which both rods 2 are parallel to the axis of the heart valve 10, simplifies the introduction of the frame 1 into the heart valve 10.

Preferably, the intra-wall rods 2 of the support frame 1 of the invention are straight. They can also take the form of a helix, forming miniature “corkscrews”; in this case, their surface will include a portion that is a helix, which can contribute to the stable fixation of the frame 1 in the position in which it is inserted into the tissue of the heart valve 10. In addition, the ends of the intra-wall rods 2 that are not attached to the base 3, - that is, opposite to the ends attached to the base 3, can be pointed, and therefore penetrate into the organic tissue of the heart valve without significant damage to this tissue.

The base 3 of such an intra-wall support frame 1 can be made of a bent rod 3a, as shown in FIGS. 1 and 2, or, possibly, of a straight rod, if the displacement of the rods 2 relative to each other is insignificant.

It is also preferable that the base 3 be made of a closed ring 3b (see Fig. 4) or an open ring 3c (which has a free circle), which allows you to slightly vary the position of the frame in the heart valve 10, as shown in Fig.3. In the case of a base 3 having the shape of an arc of a circle (3a), a ring (3b) or an open ring (3c), the positioning of the reinforced valve prosthesis by the implant surgeon is greatly simplified and accelerated due to the rigidity of the structure that the heart valve prosthesis base possesses.

The intra-wall support frame 1 according to the invention may also include at least one part remote from the base, which is a fastening link 4, which can be attached to the ends of the rods 2 that are farthest from the base to secure them more securely in the outer tubular wall 12. For example, the fastening link may be useful, in particular, when the ends of the rods 2 that are farthest from the base are pointed; in this case, the fastening link can play the role of a protective cover covering these pointed ends and guaranteeing the stability of the position of the frame 1 and the invariance of the position in which it was inserted into the organic tissue of the heart valve 10. The fastening link 4 can be straight or curved, having a curvature corresponding to the curvature of the outer circumference of the heart valve 10 in the area where the fastening link should be placed. Regarding the position of such a fastening link on the support frame 1 of the present invention, the fastening link 4 can be oriented parallel to a segment of the base 3 or obliquely following the shape of a sinusoid, which is the boundary of the outer tubular wall 12 located relative to the valve plane in the direction of blood flow. The fastening link can be fastened with a single or, if necessary, with several intra-wall rods 2, as shown in figure 2.

The intra-wall support frame 1 according to the invention may be made of materials capable of providing sufficient shape stability and, at the same time, sufficient elasticity, such as elastic, semi-rigid and / or rigid polymers, as well as from an elastic metal, for example titanium. Support frames of various sizes should be manufactured in order to have sets of support frames 1, which allow reinforcing biological valves 10 and have valve prostheses of all sizes needed in surgical practice. In addition, the use of an open ring 3c as the base 3 allows you to further vary the position of the support frame in the heart valve 10.

After the description of the support frame 1 of the present invention is brought to the present paragraph, it remains to describe in detail the introduction of such a frame 1 into the biological valve of the heart 10 during the formation of the bioprosthesis of the heart valve of the invention.

As mentioned above, Fig. 4 schematically shows, by way of example, a bioprosthesis of a valve 10 for replacing an aortic valve, reinforced with an intra-wall support frame 1 according to the invention; the bioprosthesis is positioned in the aorta 20 between the aortic root 21 and the ascending aorta 22.

This valve bioprosthesis is formed from a biological valve of the heart 10, in which, in accordance with the above general description, the plane of the valve is defined by the valves 11 attached to the outer tubular wall 12 and extending from it, along with commissures 13, in the lateral direction. The valve 10 has at least one intra-wall support frame 1 located as described above. The valve may be equipped with three frames 1, located as shown in figures 1 and 2; the frame may include as a basis 3 bent rod 3A; according to the preferred method shown in FIG. 4, the valve can also be equipped with a single support frame 1, the base 3 of which has the shape of a closed ring 3b (FIG. 4) or the shape of an open ring 3c (FIG. 3).

As for the biological part of the prosthesis, in most cases it is a heart valve 10 of animal origin, in particular a porcine aortic valve, which is equipped with one or more intra-wall supporting frames 1 during the treatment prior to implantation.

After the support frame 1 is placed in the biological valve 10, the intra-wall rods 2 of such a bioprosthesis are normally located inside the outer tubular wall 12 of the biological valve 10 parallel to the lines of intersection of the tubular wall 12 with the planes of the commissures 13 of the heart valve 10.

The base 3 of the frame 1 is located inside the bioprosthesis so that it surrounds the valve at the level of the valve plane; this region is also the region of insertion of the support frame 1 or rods 2 into the tissue of the heart valve 10. The fastening links 4 are placed at the other ends of the rods 2 in the manner required in specific cases.

The lengths of the rods 2 of the frame 1 depend on the size of the aortic, mitral or tricuspid valve equipped with the frame and on the position of the rods relative to the sinusoidal border of the outer tubular wall 12; these lengths are usually in the range of 3 to 30 mm. The thickness of the frame elements is usually a few tenths of a millimeter. Therefore, the intra-wall supporting frame 1 makes it possible to provide, after implantation, sufficient stability of the shape of the biological valve of the heart 10, in particular, the stability of the shape of its outer tubular wall 12 and areas near commissures 13.

It is preferable that the base 3 and / or, if required, the fastening link 4 of the intra-wall support frame 1 be coated with biological material, such as pericardial tissue. In this case, since the artificial (non-biological origin) elements of the bioprosthesis are coated with a pericardium or some other suitable biological material, only the biological material of the bioprosthesis will be in contact with the circulatory system and tissues of the patient’s body after implantation.

Alternatively, the base 3 and / or the fastening element 4 of the intraparietal support frame can be covered only with a fabric made of a synthetic material such as Teflon, Dacron, Gortex.

Valve bioprosthesis reinforced with an intra-wall support frame according to this invention can be used to replace the aortic, mitral or tricuspid valve, and the space occupied by the device used to strengthen the stiffness of the prosthesis is reduced as much as possible, since a traditional stent, which takes up a significant amount, is not used a place. Therefore, the space reserved for blood flow is less crowded, and this is one of the important positive factors after implantation.

In particular, such a supporting frame allows to give sufficient stability and rigidity to the bioprosthesis of the heart valve, which is required to maintain the prosthesis of its shape after implantation, while avoiding damage to the organic tissue of the biological valve of the heart, in particular in areas around special points of commissures.

In addition, a valve bioprosthesis reinforced with an intra-wall support frame according to the invention allows the use of a relatively simple and quick implantation technique, especially when the base is in the form of a circular arc, since in this case the support frame rods serve simultaneously as a means of reinforcing stiffness and as a “reference frame” that helps the surgeon performing the implantation to accurately position the bioprosthesis inside a hard-to-reach natural lumen.

In addition, after implantation of an enhanced valve bioprosthesis, due to the fact that the metal components of the heart valve bioprosthesis are covered with biological material, such as pericardium, only the biological tissue of the bioprosthesis will come into contact with the circulatory system and tissues of the patient's body.

Claims (12)

1. Intra-wall supporting frame (1) for integration into the bioprosthesis of the heart valve (10), which has commissures (13) and valves (11a, b, c) that define the plane of the valve attached to and extending from the outer tubular wall (12) in the lateral direction along the commissures (13), consisting of a base (3) and a stabilizing part (2) installed on the base (3) and containing at least two intra-wall rods (2a, 2b) mounted on the base (3) with the possibility lateral displacements along an arc of a circle relative to the point of intersection of the line along which outside NJ tubular wall (12) intersects with the commissures (13), the valve plane (10). 2. The frame (1) according to claim 1, in which the intra-wall rods (2) are mounted with the possibility of displacement by the same distance along the arc of a circle in different directions from the aforementioned intersection point. 3. The frame (1) of claim 1 or 2, in which the intra-wall rods (2) are rigidly fixed at right angles to the base (3). 4. The frame (1) according to claim 1, in which the base is made in the form of a curved or straight bar (3A). 5. The frame (1) according to claim 1, in which the base is made in the form of a closed ring (3b). 6. The frame (1) according to claim 1, in which the base is made in the form of an open ring (3c). 7. The frame (1) according to claim 1, which contains at least one fastening link (4), through which the ends of the rods (2) free from fastening are connected to the base. 8. A heart valve bioprosthesis (10), including commissures (13), valves (11) defining the plane of the valve connected to the external tubular wall (12) and laterally extending from it along commissures, (13) and at least one Intra-wall support frame (1) according to claims 1-7. 9. The bioprosthesis of claim 8, which is a bioprosthesis of the aortic valve of animal origin. 10. A bioprosthesis according to claim 8, in which the intra-wall rods (2) of the intra-wall supporting frame (1) are placed inside the outer tubular wall (12) parallel to the lines of intersection of the specified wall (12) with commissures (13). 11. A bioprosthesis according to claims 8 to 10, in which the base (3) and / or the fastening link (4) of the intra-wall support frame (1) are coated with biological material. 12. A bioprosthesis according to claims 8 to 10, in which the base (3) and / or the fastening link (4) of the intra-wall support frame (1) are covered with a fabric made of synthetic material.

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