RU2737577C1 - Cardiac valve prosthesis (embodiments) - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medical equipment, namely to aortic valve prosthesis. Prosthetic aortic valve prosthesis comprises a self-expanding frame having a mesh structure formed by radially closed rows of cells, each of which is limited by ribs connected by webs. At that, the frame includes an inlet part and a releasing part, besides, the inlet part is located distally relative to the releasing part. Inlet portion comprises a distal row of carcass cells. Bridges connecting the distal ends of the ribs of the distal row of the carcass cells form an adherent edge of the frame. Each row of cells of frame contains 8–12 cells. Thickness of the ribs of the cells ranges from 320 to 450 mcm, and the width of the ribs of the cells ranges from 200 mcm to 350 mcm. Frame has a compressed configuration for delivery and an expanded configuration for use, wherein when the frame is in an expanded configuration for use, the diameter of the releasing part is greater than the diameter of the inlet part. Valve body attached to the frame includes a skirt and a folding device attached to the skirt to form a connection line of the folding apparatus and the skirt. At the same time the folding device contains flaps, wherein the adjoining flaps are interconnected to form a commissure.

EFFECT: broader functional capabilities.

18 cl, 5 dwg, 1 tbl

Description

Technology area

[001] The present invention relates to medical devices and can be used to treat a person as a permanently implantable articular valve prosthesis into a naturally diseased valve having dysfunctions such as aortic valve regurgitation or aortic stenosis. More specifically, the present invention relates to prostheses for transcatheter delivery and implantation with small invasive approaches.

State of the art

[002] The treatment of acquired heart valve disease has become a routine procedure in open cardiovascular surgery in recent years. The vast majority of valve replacements are performed by open surgery with a longitudinal median sternotomy and connection of the patient to the cardiopulmonary bypass system. Such an operation requires a long period of rehabilitation and can lead to life-threatening complications.

[003] Recently, to minimize the risks associated with traditional open surgery, minimally invasive techniques have been developed that reduce the risk of postoperative complications. One of these methods of treatment is transcatheter prosthetics of heart valve prostheses. In these methods, a prosthetic heart valve is neatly folded and placed in a catheter that serves to deliver the prosthetic valve. A catheter with a valve prosthesis inserted into it is advanced, for example, through a puncture in the femoral artery up to the ascending aorta, and specifically into the area of the aortic annulus, where the valve prosthesis is implanted. The transcatheter valve delivery system eliminates the need for open surgery, which reduces the patient's time in the intensive care unit. This ensures a more favorable and sparing treatment for patients who are contraindicated or undesirable to undergo open heart surgery. Transcatheter delivery of a heart valve prosthesis makes it possible to implant a valve prosthesis on a beating heart, which significantly reduces the patient's risk of complications associated with cardiac arrest and connecting it to a heart-lung machine. However, the transcatheter delivery system of the valve prosthesis to the implantation site involves compression of the valve prosthesis so that it can pass through the main blood vessels, as well as some kind of expansion system of the valve prosthesis at the implantation site.

[004] Balloon-expandable heart valve prostheses with a transcatheter delivery system (ie, delivered via a catheter) are known. For example, patent RU2634418 (published: 10/26/2017; IPC: A61F 2/24) describes a heart valve prosthesis for transcatheter delivery, containing a radially deformable frame made of plastic metal - stainless steel or cobalt-chromium alloy, with a braid made of tensile synthetic material, and a liner made of elastic biological or synthetic material. Before implantation, the frame is placed on a balloon catheter, in which the balloon is in a deflated state, and compressed on the balloon with a corresponding reduction in the frame diameter. When the balloon catheter is brought to the site of valve implantation, the balloon inflates, expanding the valve frame and pressing it against the walls of the aorta and the fibrous ring of the valve to be replaced. The valve leaflets expand and begin to move under the action of blood pressure in the heart, performing the function of an aortic heart valve prosthesis.

[005] Another example of a balloon-expandable heart valve prosthesis is described in patent US6454799 (published: 09.24.2002; IPC: A61F 2/24; A61F 2/06; A61F 2/82). The disclosed prosthesis comprises a tissue-based valve located within a mesh radially deformable base made of stainless steel, titanium, Elgiloy, or a biocompatible polymer such as Delrin or polyacetyl. The described prosthesis is delivered to the heart via a catheter and is placed in place by balloon expansion.

[006] Mentioned prosthetic heart valves are typical representatives of balloon-expandable models widely and successfully used all over the world. A significant disadvantage of delivering a prosthetic valve through a balloon catheter is that the valve leaflets can be damaged when compressed between the balloon and the base during deployment. In addition, because expandable balloon structures tend to experience some recoil after balloon deflation, paravalvular leaks may occur around the entire circumference of the valve prosthesis.

[007] Over the past decade, self-expanding prosthetic heart valves have been proposed for use in a balloon-less transcatheter delivery system for implanting a valve prosthesis.

[008] US Pat. No. 6,682,559 (published: 05/02/2002; IPC: A61F 2/24;) describes a valve prosthesis having a substantially tubular design. A significant disadvantage of this configuration is that a significant horizontally directed force acts along the coaptation line, which prevents the valve from closing completely. In addition, in the specified valve prosthesis, when the leaflets are closed, excessive force is created at the place of attachment of the leaflets to the body, and this fastening quickly wears out, because the design of this valve prosthesis does not imply the formation of full-fledged commissures.

[009] Prosthetic valves are known (US5855601 published: 01/05/1999; IPC: A61F 2/24, A61B 17/22, A61B 17/32, A61F 2/06, A61F 2/90; US6582462 published: 06.24.2003; IPC: A61F 2/24), in which the distribution of force along the valve leaflets is close to natural. These valve models include a circumferential frame made of stainless steel wire hinges. This design more evenly distributes horizontal forces along the lines of co-optation, rather than concentrating these forces on commissures. These valve prostheses can be easily rolled up for placement in a delivery catheter. However, the wire loops of the framework of these prostheses may not provide sufficient rigidity to withstand the compressive forces applied during physiological contractions. Deformation of the wire loops can lead to the emergence of various forces acting on the commissures and valve leaflets, which significantly reduces the durability of the valve leaflets and the entire prosthesis.

[0010] In patents RU187483 (published: 03/06/2019, IPC: A61F 2/24), RU165827 (published: 11/10/2016, IPC: A61F2 / 24), prostheses of the heart valve are described, having essentially cylindrical or weakly expressed conical shape of the framework with increased rigidity, which is achieved due to relatively short straight struts, to which the valve body commissures are attached. Such a shape and rigidity of the frame prevent the adaptation of the valve prosthesis to the individual characteristics of the patient's anatomy, which significantly reduces the number of patients who can be implanted with these prostheses.

[0011] To reduce the risk of deformation of the valve prosthesis, the rigidity of the frame is increased by adding longitudinal struts and increasing the number of cells in the mesh structure of the frame. For example, in the patent US7993394 (published: 09.08.2011, IPC: A61F2 / 24) a valve prosthesis is described, the frame of which has a fine-mesh mesh structure and contains reinforced longitudinal frame struts, to which the commissures of the leaflet apparatus are attached. The disadvantage of this prosthesis is the essentially cylindrical shape of the frame, which has limited adaptability to the individual anatomy of the patient and a low level of fixation of the valve prosthesis, which increases the likelihood of displacement of the prosthesis after implantation.

[0012] To prevent displacement of the valve prostheses after implantation, special fixation anchors are used, which are additional protrusions, loops or regions of a self-expanding frame. In patents US10321992 (published: 06/18/2019; IPC: A61F2 / 24), US10456277B2 (published: 10/29/2019; IPC: 61F 2/24; A61F 2/82; A61F 2/915; A61F 2/848), US10350065B2 ( published: 07/16/2019; IPC: 61F 2/24) describes prosthetic heart valves containing fixation areas or anchors located at the proximal and / or distal end of the framework and are required to capture the leaflets of the native valve and / or to engage the subannular tissue of the patient's native valve. However, additional protrusions, loops, or anchoring areas of the self-expanding scaffold increase the delivery profile — the diameter of the valve prosthesis in a compressed configuration in the delivery system. In addition, additional protrusions, loops or fixing areas increase the trauma hazard of the valve prosthesis for the patient's native tissues, complicate the valve positioning process, increase the likelihood of coronary artery orifice closure, which disrupts blood flow to the coronary arteries and prevents subsequent coronary artery catheterization.

[0013] To solve the problem of fixing a valve prosthesis at the site of implantation, valve prostheses are proposed having a multilevel mesh self-expanding frame. One of the best-known representatives of this class of prostheses is the Medtronic CoreValve®System prosthesis (US10478291, published: 11/19/2019, IPC: A61F 2/24), containing a self-expanding mesh frame made of nitinol and having three regions. In the expanded configuration, the frame takes on an asymmetrical hourglass shape. In this case, the narrowest area is located above the fibrous ring of the patient's native valve. The extended distal and proximal regions of the framework provide anchorage for the valve prosthesis. The main disadvantages of the described valve prosthesis, which require correction, include the relatively high probability of paravalvular leaks after implantation. Also, the described valve prosthesis can be improved by reducing the number of cells and the area of the ribs that define the cells, while maintaining the required degree of rigidity of the prosthesis and protection of critical valve components. Reducing the number of cells and the area of the ribs of the cells will reduce the likelihood of occlusion of the orifices of the coronary arteries in the case of non-standard patient anatomy.

[0014] The most common problem with endovascular valve replacement is paravalvular leaks. To prevent the appearance of paravalvular leaks, a so-called skirt is used, which is attached to the valve apparatus of the prosthesis and to the metal frame. However, the skirt does not completely solve the problem of leaks. For example, the CoreValve® prosthesis described above contains a skirt made of animal biomaterial or synthetic material, but the likelihood of paravalvular leaks even with this design of the valve prosthesis remains significant.

[0015] Another solution to the problem of paravalvular leaks is a sealing collar, which, unlike a skirt, is located on the outer surface of the chassis. In patent US9636222 (published: 05/02/2017, IPC: A61F 2/24), containing a sealing cuff, which is a patch of biomaterial or synthetic material on the outer surface of the frame. The disadvantage of this prosthesis is the increased delivery profile due to the design of the cuff, which is a ring formed from a tourniquet in a circular cross section. In addition, these prostheses have an essentially cylindrical or weakly expressed conical frame shape with increased rigidity, which is achieved due to relatively short straight struts to which the valve body commissures are attached. Such a shape and rigidity of the framework prevent adaptation of the valve prosthesis to the individual characteristics of the patient's anatomy, which significantly reduces the number of patients who can be implanted with these prostheses.

[0016] Other models of heart valve prostheses are known that include a cuff for reducing the volume of paravalvular leaks. Thus, in patents US9889004 (published: 02/13/2018, IPC: A61F 2/24), US9326856 (published: 05/03/2016, IPC: A61F 2/24, A61F 2/07, A61F 2/86) and US8986375 (published: 03.24.2015, IPC: A61F 2/24) describes valve prostheses containing a multi-level self-expanding frame with a mesh structure, to which a cuff is attached from the outside. The main problem with the use of sealing cuffs remains the increase in the delivery profile of valve prostheses due to the cuff material. Accordingly, reducing the overall delivery profile is one of the important challenges in the design of new valve prostheses.

The essence of the invention

[0017] It is an object of the present invention to provide a durable self-expanding heart valve prosthesis with a reduced risk of regurgitation, migration and damage to the patient's body, and suitable for transcatheter delivery. The problem is solved by the claimed invention by achieving such a technical result as reducing the volume of paravalvular leaks after implantation, reliable fixation of the valve prosthesis at the implantation site, reducing the risk of trauma to the patient's tissues in the area of implantation, increasing the strength of the valve prosthesis, reducing the delivery profile, reducing the risk of damage to the prosthesis valve during delivery to the implantation site, which ultimately leads to the achievement of optimal parameters of the heart valve prosthesis, improves its characteristics both during delivery to the implantation site and during further operation.

[0018] The technical result is achieved due to the fact that the claimed prosthesis of the heart valve contains a self-expanding frame, with a valve body fixed thereon, consisting of a flap apparatus and a skirt.

[0019] In this case, the self-expanding scaffold can be in a compressed configuration for transcatheter delivery to the implantation site, and then transition into an expanded configuration for implantation when released from the catheter. The self-expanding property of the frame allows avoiding the use of a balloon catheter during implantation, which excludes the possibility of causing compression damage to the valve body during balloon inflation.

[0020] In an expanded configuration, the frame has several levels with radial stiffness and cross-sectional diameter, including an inlet portion and an outlet portion. Moreover, the inlet part is located distally relative to the outlet part. In a preferred embodiment, the frame has a three-level asymmetric shape including a tapered inlet portion, a widened outlet portion, and a constriction region located between the inlet and outlet portions. Moreover, in the expanded configuration, the constriction region has a diameter smaller than that of the inlet part.

[0021] The tapered shape of the inlet portion of the scaffold and the smooth transitions between adjacent portions of the scaffold play an important role in reducing turbulence in blood flow through the valve body, compared to valve prostheses having stepped diameters of different portions of the frame.

[0022] The frame has a mesh structure formed by radially closed rows of cells. In this case, the distal row of cells of the inlet part is the distal row of cells of the frame, and the proximal row of cells of the outlet part is the proximal row of cells of the frame.

[0023] Each cell of the frame is delimited by two undulating ribs. The ribs of one cell are interconnected by bridges at the distal and proximal ends. In this case, the ribs of radially adjacent cells of one row are also connected by bridges. The proximal ends of the ribs of a cell of one row are connected by bridges with the distal ends of the ribs of the cell of the adjacent proximal row, and the distal ends of the ribs of the first cell are connected by bridges with the proximal ends of the ribs of the cell of the adjacent distal row. In this case, the bridges connecting the distal ends of the ribs of the cells of the distal row of the framework form distal crowns, which together form the inlet edge of the framework. The bridges connecting the proximal ends of the ribs of the cells of the proximal row of the scaffold form the proximal crowns that form the emitting edge of the scaffold.

[0024] The shape and size of the cells can vary along the longitudinal line of the frame. Varying the shapes and sizes of the cells allows the frame to have different radial stiffness along the longitudinal axis. At the same time, in the inlet part, the frame has a lower radial stiffness, which reduces the risk of crushing the patient's cardiac pathways located behind the fibrous ring of the patient's native valve, and in the area of narrowing, the frame has a greater radial rigidity, which reduces the risk of deformation of the leaflet apparatus with an uneven fibrous ring of the native valve the patient.

[0025] The frame contains no more than five rows of cells, while the row of cells refers to the distal row of cells of the frame, or a row of cells in which the cells are located without radial displacement relative to the cells of the distal row of cells of the frame. Each row contains no more than twelve cells. In a preferred embodiment, the frame comprises four rows of cells with twelve cells in each row.

[0026] The thickness of the mesh ribs, measured from the inner surface of the frame to the outer surface of the frame, is 320-450 µm. The width of the ribs of each cell, measured along the outer surface of the frame, is 200-350 μm.

[0027] The width of the ribs of the cells in combination with the number of cells reduces the risk of the ribs overlapping the cells of the vessels located in the area of valve implantation. For example, in the case of using the claimed valve prosthesis to replace the affected aortic valve, the risk of the ribs overlapping the cells of the orifices of the coronary arteries is reduced in the case of a non-standard anatomy of the patient's coronary arteries.

[0028] The ratio of the width and thickness of the edges of the cells in combination with the number of cells allows you to reduce the volume of metal in the cross section of the delivery profile. This creates additional space to accommodate the valve body in a collapsed configuration in the delivery system, which reduces the likelihood of damage to the valve body, especially the valve body, during folding and delivery of the valve prosthesis to the implantation site.

[0029] The ratio of the width and thickness of the ribs of the cells in combination with the number of cells reduces the radial stiffness, which reduces the risk of injury as a result of compression of the patient's tissues in the implantation area. At the same time, the radial rigidity of the inventive frame remains functional and ensures correct deployment of the valve prosthesis during implantation, reliable seamless fixation of the valve prosthesis and physical support of the valve body.

[0030] The specified number of cells increases the area of the open part of each cell. The increased area of the open part of the cells of the frame contributes to a more intimate contact of the skirt with the patient's tissues in the implantation area, which reduces the volume of paravalvular leaks and the risk of migration of the valve prosthesis.

[0031] The ejection portion of the scaffold contains loops that serve to attach the valve prosthesis to the delivery system. In a preferred embodiment, the scaffold contains two loops that are positioned on diametrically opposed proximal crowns.

[0032] The valve body includes a flap and a skirt. In this case, the flap device is attached to the skirt, and the entire valve body is attached to the frame.

[0033] The flap apparatus comprises a plurality of flaps, with adjacent flaps attached to each other in lateral regions to form commissures. The free edges of the adjacent valves form the edges of the coaptation, which meet in the center of the coaptation. The valve apparatus can be made of artificial, synthetic or polymer material. In a preferred embodiment, the valve apparatus is made of biological tissue such as, for example, the pericardium of a pig, horse or cow. The use of biological tissue is more preferable, since biological tissue demonstrates better mechanical and dynamic properties under conditions of constant movement and stress. Accordingly, the valve apparatus made of biological tissue exhibits greater cycle resistance and ensures the durability of the valve prosthesis. In addition, biological tissue is less thrombogenic than artificial material, and is also practically impermeable to blood, which reduces the volume of transvalvular leaks. In a preferred embodiment, the details of the flap apparatus are cut from biological tissue by laser cutting. In this case, laser cutting can be performed in a liquid layer, for example, in water or isotonic solution. The specified method of laser cutting allows to reduce the edge thermal damage to biological tissue, which increases the biocompatibility of the valve body and the strength of the connection of the valve body parts to each other.

[0034] The skirt is approximately frusto-conical and approximately follows the shape of the inlet portion of the frame. The skirt can be made of artificial, synthetic or polymer material. In a preferred embodiment, the skirt is made of biological tissue, such as the pericardium of a pig, horse, or cow. Biological tissue is less thrombogenic than artificial material, and at the same time does not allow blood to pass through, which makes it possible to reduce the volume of paravalvular leaks.

[0035] The skirt has a proximal end and a distal end. The proximal end of the skirt is connected to the flap apparatus to form a connection line between the flap apparatus and the skirt.

[0036] The valve body is attached to the frame mainly from the inside. At the same time, commissures and most of the connection line of the flap apparatus and the skirt are attached to the frame. This makes it possible to effectively transfer to the frame the force acting on the valve apparatus, thereby reducing stress concentration, valve body fatigue and, accordingly, prolonging the durability of the valve prosthesis.

[0037] A distal end of the skirt is also attached to the frame. Attaching the distal end of the skirt to the frame prevents the distal end of the skirt from wrapping inside the valve body, thereby avoiding disrupted blood flow through the valve body, reducing the risk of thrombus formation and the risk of migration of the valve prosthesis. In this case, the distal end of the skirt is bent over the inlet edge of the frame and attached from the outside to the edges of the cells of the distal row of the frame cells. Due to this attachment of the distal end, the skirt covers the distal crowns, which reduces the risk of injury to the patient's tissues. In this case, the part of the skirt located outside the frame is called the outer part of the skirt, and the part of the skirt located inside the frame is called the inner part of the skirt. In some embodiments, the distal end of the skirt forms an undulating fold along the upstream edge of the frame, which further seals the connection of the valve prosthesis to the patient's tissues and reduces the volume of paravalvular leaks.

[0038] Also, the skirt is further attached to all of the webs and ribs of the frame cells located distal to the ribs and webs of the frame cells to which the flap-skirt connection line is attached, but excluding the ribs of the distal row of cells of the frame to which the distal end of the skirt is attached. This additional skirt attachment enhances the retention of the valve body to the frame.

[0039] The valve body can be attached to the frame in any suitable way, for example, using biocompatible glue or staples made of biocompatible material. In a preferred embodiment, the valve body is attached to the frame by sewing. Moreover, each commissure is attached to the frame with 12-40 stitches. In this way, a secure attachment of the valve body to the frame is achieved, contributing to the durability of the valve prosthesis.

Description of drawings

[0040] FIG. 1A shows a side view of the aortic valve prosthesis as an exemplary embodiment of the present invention.

[0041] FIG. 1B shows the aortic valve prosthesis, top view.

[0042] FIG. 1B shows one of the meshes of the distal row of meshes of the scaffold.

[0043] FIG. 2A shows a valve body.

[0044] FIG. 2B shows the pattern of the valve body flap.

[0045] FIG. 2B shows a pattern for a valve body skirt panel.

[0046] FIG. 3A-B show options for attaching the distal end of the skirt to the frame.

[0047] FIG. 4A shows an embodiment of a cuffed aortic valve prosthesis 1.

[0048] FIG. 4B schematically shows a lip seal 46.

[0049] FIG. 5 shows the results of measuring the radial stiffness of various variants of the valve prosthesis framework according to the present invention in comparison with the CoreValve prosthesis framework (Medtronic).

Detailed description of the invention

[0050] In the following detailed description of an implementation of the invention, numerous implementation details are set forth in order to provide a thorough understanding of the present invention. However, it is obvious to those skilled in the art how the present invention can be used, with or without these implementation details. In other instances, well-known techniques, procedures, and components are not described in detail so as not to obscure the details of the present invention.

[0051] In addition, it is clear from the foregoing that the invention is not limited to the foregoing implementation. Numerous possible modifications, changes, variations and substitutions, while retaining the spirit and form of the present invention, will be apparent to those skilled in the art.

[0052] The present invention relates to heart valve prostheses having a self-expanding frame on which a valve body is attached. The valve prosthesis can be in a collapsed configuration for delivery through a catheter to the implantation site or in an expanded configuration for implantation. The self-expanding frame allows a prosthetic valve to be placed at the implantation site without using a balloon catheter, which eliminates the possibility of compressive damage to the valve body during balloon inflation.

[0053] FIG. 1A and 1B, an aortic valve prosthesis is shown as an exemplary embodiment of the present invention. The valve prosthesis 1 contains a frame 2 having several levels, for example, a conical inlet part 4, an expanded outlet part 6 and a region of constriction 5 located between the inlet part 4 and an outlet part 6. Moreover, the inlet part 4 of the frame 2 is located distal to the outlet part 6 of the frame ... In the installed form, the inlet part 4 of the frame 2 is located in the annular space of the left ventricle of the patient, and the outlet part 6 of the frame 2 is located in the ascending aorta of the patient.

[0054] The frame 2 has a reticular structure formed by radially closed rows of 42 cells 10 whole frame 2.

[0055] The mesh structure of the carcass 2 is preferably created by laser cutting made from a metal alloy containing, for example, stainless steel or a shape memory material such as titanium nickelide (Nitinol).

[0056] Each cell 10 of the frame 2 is delimited by two undulating ribs 9. The ribs 9 of one cell 10 are interconnected by bridges 43 at the distal 44 and at the proximal 45 ends. In this case, the ribs 9 of radially adjacent cells 10 of one row 42 are also connected by bridges. The proximal 45 ends of the ribs 9 of the cell 10 of one row 42 are connected by bridges 43 with the distal 44 ends of the ribs 9 of the cell 10 of the adjacent proximal row 42, and the distal 44 ends of the ribs 9 of the first cell 10 are connected by the bridges 43 with the proximal 45 ends of the ribs 9 of the cell 10 of the adjacent distal row 42 In this case, the bridges 43 connecting the proximal 45 ends of the ribs 9 cells 10 of the proximal row 8 cells of the frame 2 form the proximal crowns 11. The bridges 43 connecting the distal 44 ends of the ribs 9 cells 14 of the distal row 7 of the frame cells 2 form the distal crowns 12, which all together form the inlet edge 13 of the chassis 2. FIG. 1B shows a cell 14 of a distal row 7 of frame cells 2. In a preferred embodiment, the distal crowns 12 comprise approximately circular lugs 15.

[0057] In this case, the ribs 9 of the cells 10 and the bridges 43 are residual elements of the tube from which the mesh structure is made. The thickness of this tube determines the thickness of the fins 9 of the cells 10, which is 320-450 μm. The width of the ribs 9 of each cell 10, measured along the outer surface of the frame, is 200-350 μm.

[0058] The frame 2 contains no more than five rows of 42 cells 10, including the distal row 7 of the cells of the frame 2, as well as rows of 42 cells 10, in which the cells 10 are located without radial displacement relative to the cells 14 of the distal row 7 of the cells of the frame 2, including the proximal row 8 of the scaffold 2. Each row 42 contains no more than twelve cells 10. In a preferred embodiment, the scaffold 2 comprises four rows 42 of twelve cells 10 in each row 42.

[0059] For the illustrated aortic valve prosthesis, the specified number of meshes 10 of the framework 2 in combination with the specified width of the ribs 9 of the meshes 10 reduces the likelihood of the ribs 9 meshes 10 overlapping the orifices of the coronary arteries and facilitates access to the coronary arteries in medical procedures such as stenting or angioplasty that the patient may need after implantation of a prosthetic valve. This is especially true in the case of non-standard anatomy of the coronary arteries, for example, when they are located in the middle of the sinus bulb.

[0060] The number of cells 10 of the frame 2 and the ratio of the thickness and width of the ribs 9 of the cells 10 provides a radial stiffness of 5-40 N. This radial stiffness reduces the risk of compression of the patient's tissues and arrhythmias after implantation. It is important to note that this radial stiffness remains functional and ensures the correct deployment and fixation of the valve prosthesis 1 during implantation.

[0061] The number of cells 10 in each row 42 makes it possible to increase the area of the open part of each cell 10. The open part is understood as that part of the cell 10 that is not occupied by the edges 9 of the cell. Due to the increase in the area of the open part of the cells 10, the contact surface area of the inner part 16 of the skirt 20 increases with the patient's tissues at the site of implantation of the valve prosthesis 1. The inner part 16 of the skirt 20 can contact with the patient's native valve cusps, which, after implantation of the valve prosthesis 1, are constantly open ...

[0062] Also in one of the embodiments shown in FIG. 3B, the inner part 16 of the skirt 20 can contact the fibrous ring of the patient's native valve through the cells 14 of the distal row 7 of the scaffold 2. Increasing the contact area of the inner part 16 of the skirt 20 with the patient tissue at the implantation site reduces the volume of paravalvular leaks and the risk of migration of the valve prosthesis.

[0063] All parts of the frame 2 in the expanded configuration have a substantially circular cross-section, but in addition, the shape of the cells 10 of the inlet 4 and outlet 6 of the frame 2 allows these parts to adapt to the individual anatomy of the patient, thereby reducing the risk of migration of the valve prosthesis and the volume of paravalvular leaks after implantation of a valve prosthesis 1.

[0064] The cells 10 in the region of the constriction 5 are shaped so as to provide, in the expanded configuration, a uniformly circular cross-sectional area of the region of the constriction 5 and the radius of curvature R of the outer surface of the frame 2 in the region of the transition between the region of the constriction 5 and the ejection part 6 of the frame 2. The R is at least 7 mm and ensures that the framework 2 is held at a distance from the opposite sinus wall in the ascending aorta, thereby providing adequate blood flow to the coronary arteries and facilitating catheter access to the coronary arteries for subsequent medical procedures.

[0065] In the extended configuration shown in FIG. 1A, the inlet portion 4 of the carcass 2 has a nominal unfolded diameter D1, the outlet portion 6 of the carcass 2 has a nominal unfolded diameter D3, and the taper 5 has a nominal diameter D2. The shape of the mesh 10 of the carcass mesh allows the inlet portion 4 and the outlet portion 6 of the carcass to expand to a diameter within the diameter range of the expanded configuration while maintaining a substantially constant diameter of the constriction region 5. The diameter D1 of the inlet portion 4 can be from 24.5 mm to 32 mm, the diameter D3 of the outlet part 6 can be 35 to 43 mm. The diameter D2 of the region of constriction 5 is in the range from 20.5 mm to 25.5 mm.

[0066] The protruding portion 6 of the framework 2 may comprise loops 18 that serve to secure the valve prosthesis 1 to the delivery system during the implantation operation. The hinges 18 can be cut from the tube during the fabrication of the mesh structure of the frame 2, or made separately and then glued, welded, soldered or attached to the frame 2 in any other suitable way. In a preferred embodiment, the framework 2 contains two loops 18, which are located on diametrically opposite proximal crowns 11.

[0067] FIG. 2A, the valve body 3 is shown as it appears when attached to the frame 2. In order to better show the structure of the valve body 3, the frame 2 in FIG. 2A is not displayed. The valve body 3 includes a flap device 19 and a skirt 20. The flap device 19 is attached to the skirt 20 to form a connection line 21 of the flap device 19 and the skirt 20. The valve body 3 is attached to the frame 2. The valve body 3 can be glued, welded, attached staples or attached to the frame 2 in any other suitable way. In a preferred embodiment, the valve body 3 is sewn to the frame 2 with polytetrafluoroethylene (PTFE) thread.

[0068] The flap assembly 19 comprises a plurality of flaps 22, with adjacent flaps 22 partially connected to each other. In the example of aortic valve prosthesis 1 shown in FIG. 1B, the flap apparatus 19 has three separate flaps 22 which are attached to each other in lateral regions 26 to form commissures 23. FIG. 2B shows a flap 22 that has an approximately semicircular base 24, a free edge 25, and widened lateral regions 26 located at each end of the free edge 25. The free edges 25 of adjacent flaps 22 form the edges of coaptation 27, which meet at the center of coaptation 28. the edges 25 of the adjacent flaps 22 contact each other when the valve body 3 is assembled and attached to the frame 2. Moreover, the configuration of the free edges 25 of the flaps 22 provides a uniform load along the entire length of the edges of the coaptation 27. The expanded lateral regions 26 of the adjacent flaps are connected to each other to form commissure 23. Commissures 23 are formed in such a way as to reduce the concentration of stress on the leaflets 22, which occurs during the opening-closing cycles of the leaflet device 19 after implantation of the valve prosthesis 1. Such stress can lead to fatigue or rupture of the leaflet device 19. In this case, in the assembled and attached to frame 2 valve body 3 comis Suras 23 are located proximal to the edges of coaptation 27 and the center of coaptation 28, which makes it possible to reduce the delivery profile of the valve prosthesis 1.

[0069] The flap apparatus 19 can be made of an artificial, synthetic or polymeric material such as Dacron, ePTFE, or another material selected for its properties and biocompatibility. In a preferred embodiment, the valve apparatus 19 is made of biological tissue, such as the pericardium of a pig, horse, or cow. In this case, in the case of biological tissue, the flaps 22 have a thickness of 240-360 μm. The use of biological tissue is more preferable, since biological tissue demonstrates better mechanical and dynamic properties under conditions of constant movement. Accordingly, the valve apparatus 19 made of biological tissue exhibits greater cycle resistance and ensures durability of the valve prosthesis 1. In addition, biological tissue is less thrombogenic than artificial material. Another advantage of biological tissue is its almost complete impermeability to blood, which reduces the volume of transvalvular leaks. The biological tissue can be processed according to biological tissue processing techniques that are known per se in the art to form parts of a prosthetic heart valve. In a preferred embodiment, parts of the flap apparatus 19 are cut from biological tissue using an automated laser cutting system. In this case, laser cutting is performed in a liquid layer, for example, in water or isotonic solution. During laser cutting, areas of biological tissue adjacent to the incision line are heated, as a result of which a zone of thermonecrosis or carbonization is formed - the so-called edge damage. Charred biological tissue can cause inflammatory reactions, as well as rejection from the patient's body. When facing the bloodstream, the charred edge of biological tissue can cause blood clots. In addition, when fastening the parts of the flap device 19, edge damage can reduce the strength of the connection. This is especially true when sewing is used to fasten the parts of the flap device 19, since in this case, the edge damage can lead to rupture of biological tissue at the site of localization of the suture holes. Laser cutting in a liquid layer can reduce the edge damage to biological tissue and thus increase the biocompatibility and strength of the connection of the parts of the flap apparatus 19.

[0070] The skirt 20 shown in FIG. 2A roughly follows the shape of the inlet portion 4 of the frame 2. In a preferred embodiment, the skirt 20 is made of biological tissue, such as, for example, the pericardium of a pig, horse, or cow. In this case, the skirt 20 has a thickness of at least 150 microns, since at a smaller thickness, the fatigue tensile strength is significantly reduced. The preferred thickness of the skirt 20 is 150-270 microns. When the skirt 20 is made from biological tissue, the parts are also laser cut into the liquid layer, as is the case with the parts of the flap apparatus 19. In another embodiment, the skirt 20 is made of an artificial, synthetic, or polymeric material, such as described for the flap apparatus. The use of artificial material for the manufacture of skirt 20 allows a reduction in the delivery profile, since the artificial material can be thinner than biological tissue, with the same mechanical characteristics. However, artificial material can be more thrombogenic than biological tissue. In addition, the artificial material, unlike biological tissue, can leak blood, which will lead to an increase in regurgitation.

[0071] In one embodiment, the skirt 20 is formed from a single approximately trapezoidal member whose sides are connected. However, in this case, the skirt tends to wrinkle when the valve prosthesis 1 is brought into a compressed delivery configuration.

[0072] In another embodiment, the skirt 20 is formed from a single seamless tubular member. However, such an embodiment is only possible when artificial material is used to make the skirt 20.

[0073] In the preferred embodiment shown in FIG. 2A and 2B, the skirt 20 is formed from discrete panels 29 joined together along the longitudinal edges 30. In this embodiment, the skirt 20 does not form the folds described above in a collapsed delivery configuration, and the delivery profile can be substantially reduced. Each panel 29 has a concave proximal edge 31, a distal edge 32, and longitudinal edges 30. In one embodiment, the distal edge 32 of the skirt panel 29 includes end tabs 33, which are shown in FIG. 2A. In the finished valve body 3, the longitudinal edges 30 of adjacent panels 29 of the skirt 20 are connected to each other, for example, by seams or biocompatible glue, so that the skirt 20 approximately forms a frustoconical

[0074] The skirt 20 has a proximal end 34 and a distal end 35. The proximal end 34 of the skirt 20 is connected to the flap device 19 to form a connection line 21. The flap device 19 is attached to the skirt 20 along the base 24 of the flaps 22, for example, by seams, staples or a suitable biocompatible adhesive. As shown in FIG. 1A, the connection line 21 of the flap device 19 and the skirt 20 generally follows the contour of the mesh 10 of the frame 2, so that most of the connection line 21 is directly supported by the frame 2, transferring the force applied to the flap device onto the frame 2.

[0075] The following describes a preferred embodiment of assembling the valve body 3 from the flaps 22 and the skirt 20 made of biological tissue, where the elements of the valve body 3 are fastened together by means of sewing. In this case, during the entire assembly process, the elements of the valve body 3 are moistened in an isotonic solution, for example, 0.9% of the mass. sodium chloride to avoid drying and deformation of biological tissue. In a preferred embodiment, the biological tissue is the pericardium, one surface of which is formed by a smooth serous layer and the other by a fleecy fibrous layer. Accordingly, one surface of the elements of the valve body 3 is smooth and the other is fleecy.

[0076] To form the commissure 23, the two flaps 22 are aligned with a smooth surface inward and sewn along imaginary line a. Then it is folded along the seam line with a smooth surface outward, thereby hiding in the fold the seam 36 passing along the line a. This is done in order to minimize the thrombogenicity of the leaflet apparatus 19. The fact is that the edges of a part cut from biological tissue by a laser inevitably contain some amount of carbonized biological tissue, which, when facing the bloodstream, contributes to the formation of blood clots. Next, the wings 37 are bent back along an imaginary line c so that the fold with the seam 36 is clamped between the wings 37. The resulting structure is fixed with stitches that simultaneously capture the wings 37 and the fold with the seam 36. At the same time, it is controlled that the resulting commissure 23 does not bend and remained straight. The rest of the commissures are formed similarly. The specified method of forming commissures 23 allows you to strengthen their structure so that the strength of the fastening between the flaps 22 increases, and also increases the ability of the commissures 23 to transfer force from the flap device 19 to the frame 2.

[0077] Panels 29 of the skirt 20 are sewn to the assembled flap device 19. For this, the semicircular base 24 of the flap 22 and the concave proximal edge 31 of the panel 29 of the skirt 20 are sutured so that in the finished valve prosthesis 1 when the flap device 19 is open, the flaps 22 face a smooth surface to the frame 2. This reduces the risk of thrombosis due to the fact that during diastole blood from the aorta strikes the less thrombogenic smooth surface of the closed flaps 22. Flaps 22 and panels 29 of the skirt 20 are sutured along the joint line 21, overlapping a suture at a distance of approximately 1 mm along the edge of the base 24 of the sash 22 and the concave region 31 of the panel 29 of the skirt 20. The remaining panels 29 of the skirt 20 are sewn in the same way to the sash device 19.

[0078] After sewing the panels 29 of the skirt 20 to the flap assembly 19, adjacent panels 29 of the skirt 20 are sewn together along the longitudinal edges 30, overlapping a seam 38 from the proximal end 34 to the distal end 35 of the skirt 20. This completely assembles the valve body 3. Note that the valve body 3 is assembled so that in the implanted valve prosthesis 1 the amount of biological tissue carbonized by the laser facing the bloodstream or in contact with the patient's tissues is minimal. For this, all the edges of the parts to be fastened are hidden in the folds of biological tissue, which are formed along the line of fastening of the parts. As a result, in the implanted valve prosthesis 1, only the free edges 25 of the leaflets 22, forming the edges of coaptation 27, face the bloodstream.

[0079] It will be apparent to one skilled in the art of valve prosthesis design that the assembly steps described above are illustrative and a different order of assembly of the flap 19 and skirt 20 may be used to form the valve body 3.

[0080] The assembled valve body 3 is sewn to the bridges 43 and the ribs 9 of the cells 10 of the frame 2. At the same time, the commissures 23, the connection lines 21 and the skirt 20, including the distal end 35 of the skirt 20, are sewn to the bridges 43 and the ribs 9 of the cells 10 of the frame 2.

[0081] The commissure 23 is sewn to the ribs 9 of the cell 40 so that the edges of the commissure 23 cover the ribs 9 of the cell 40. In this case, 12-40 stitches are made on each edge 9 of the cell 40. Similarly, the remaining commissures 23 of the valve body 3 are sewn to the frame 2. The specified method of sewing on the commissures 23 allows you to reliably fix the commissures 23 on the frame 2, as well as evenly distribute over the commissures 23 and transfer to the frame 2 the force acting on the valve apparatus 19 at the time of diastole, when the blood pressure from the ascending part of the aorta presses on the closed leaflets 22.

[0082] To the jumpers 43 and the ribs 9 of the cells 10 of the frame 2, the connection lines 21 are sewn. Moreover, only that part of the connection lines 21 is sewn to the ribs 9 of the cells 10 of the frame 2, which repeats the contour of the ribs 9 of the cells 10 of the frame 2. Moreover, for each half of the rib 9 cells 10 impose 3-5 stitches, and on each bridge 43 impose at least one stitch.

[0083] The distal end 35 of the skirt 20 is folded over the inlet edge 13 of the frame 2 along the line e, which in FIG. 2A is approximately indicated by a dotted line. The folded distal end 35 of the skirt 20 is sewn to the frame 2 from the outside. In this case, the part of the skirt 20 located outside the frame 2 is called the outer part 17 of the skirt 20, and the part of the skirt 20 located inside the frame 2 is called the inner part 16 of the skirt 20. The distal end 35 of the skirt 20 is sewn so that the inner part 16 of the skirt 20 is adjacent to the inner surface of the frame 2 tightly, but without tension. The outer part 17 of the skirt 20 is sewn to the ribs 9 cells 14 of the distal row 7 cells of the frame 2. 3-5 stitches are applied to each half of the rib 9 cells 14, and at least one stitch is made on the bridges 43. In this case, the material of the skirt 20 covers the distal crowns 12, which reduces the risk of injury to the patient's tissues.

[0084] The attachment of the distal end 35 of the skirt 20 to the frame 2 prevents the distal end 35 of the skirt 20 from being folded inside the valve body 3 to form folds. Such folds can block the flow of blood through the valve prosthesis 1 and serve as points of thrombus formation. In addition, the hemodynamic flow against such folds can cause migration of the valve prosthesis 1 after implantation.

[0085] In one embodiment shown in FIG. 1A, the outer part 17 of the skirt 20 is sewn only to the distal 47 halves of the ribs 9 of the cells 14 of the distal row 7 of the frame cells 2. In this case, the end protrusions 33 at the distal end 35 of the skirt 20 cover the distal 47 halves of the ribs 9 cells 14 of the distal row 7 of the frame cells 2.

[0086] In another embodiment shown in FIG. 3A, the outer part 17 of the skirt 20 is sewn to the entire length of the ribs 9 cells 14 of the distal row 7 cells of the frame 2. In this case, the end protrusions 33 at the distal end 35 of the skirt 20 cover the proximal 48 halves of the ribs 9 cells 14 of the distal row 7 cells of the frame 2. Still in in one embodiment shown in FIG. 3B, the distal end 35 of the skirt 20 is also sewn only to the distal 47 halves of the ribs 9 cells 14 of the distal row 7 of the frame cells 2. However, in this embodiment, the skirt 20 does not contain end protrusions 33 at the distal end 35, and the smooth edge of the skirt 20 is sewn to the bridges 43 radially adjacent cells 14 of the distal row 7 of frame cells 2. In all of the above embodiments, the skirt 20 forms an undulating fold 41 along the inlet edge 13 of the frame 2. The undulating fold 41 along the inlet edge 13 of the frame 2 further seals the connection of the valve prosthesis 1 with tissues of the patient, which reduces the volume of paravalvular leaks.

[0087] In an alternative embodiment shown in FIG. 3B, the skirt 20 does not form a wavy fold 41 along the inlet edge 13 of the frame 2, but follows the contour of the inlet edge 13 of the frame 2. In this case, the entire outer part 17 of the skirt 20 is formed only by end protrusions 33 at the distal end 35 of the skirt 20, which enclose the distal crowns 12 and distal halves 47 of the ribs 9 cells 14 of the distal row 7 cells of the frame 2.

[0088] The skirt 20 is sewn to the distal crowns 12 with no less than three stitches. In a preferred embodiment, the skirt 20 is sewn to the distal crowns 12 with three stitches. In this case, on each distal crown 12, two stitches are directed approximately along the inlet edge 13 of the framework 2, and one stitch covering the inlet edge 13 of the framework 2 is directed approximately perpendicular to the inlet edge 13 of the framework 2. Attaching the skirt 20 to the distal crowns 12 with three stitches makes it possible to strengthen the attachment valve body 3 to frame 2.

[0089] The inner part 16 of the skirt 20 is additionally sewn with at least one stitch to the ribs 9 and webs 43 of the cells 10 of the frame 2, located distal to the ribs 9 and the webs 43 of the cells 10 of the frame 2, to which the connection line 21 of the flap device 19 is attached and a skirt 20, excluding the bridges 43 and the ribs 9 of the cells 14 of the distal row 7 of the cells of the frame 2, to which the outer part 17 of the skirt 20 is sewn.

[0090] Due to the above-described method of attaching the valve body 3 to the frame 2, the forces acting on the flaps 22, commissures 23 and joints 21 of the flap device 19 and the skirt 20 are effectively and evenly distributed over the valve body 3 and transferred to the frame 2, thereby reducing stress concentration and fatigue of valve body elements 3. This increases the life of the valve prosthesis 1.

[0091] The center of coaptation 28 is displaced longitudinally distally relative to the cells 40 to which commissures 23 are attached, thereby increasing the overall length of the edges of coaptation 27. Due to this design, flaps 22 require minimal opening pressure and exhibit fast closing times. At the same time, a decrease in turbulence is observed along the free edges 25 of the valves 22 in the open state. In addition, the specified longitudinal displacement of the center of coaptation 28 provides a more uniform distribution of force along the edges of the coaptation 27. With the specified design of the leaflet apparatus 19, the angle at which the force is transmitted to the commissures 23 increases, which significantly reduces the horizontal component of the force pulling the commissures 23 from the frame 2 All of the above advantages reduce the uneven load on the valve body 3, which significantly increases the durability of the valve prosthesis 1. Another important advantage of the longitudinal displacement of the coaptation center 28 relative to the cells 40 to which the commissures 23 are attached is the ability to reduce the delivery profile of the valve prosthesis 1.

[0092] The number of meshes 10 in combination with the thickness and width of the ribs 9 of the meshes 10 of the scaffold 2, as well as the displacement of the center of coaptation 28 relative to the meshes 40 to which the commissures 23 are attached, result in a delivery profile from about 4.7 mm to about 5.8 mm. At the same time, the relatively small width of the ribs 9 of the cells 10 of the frame 2 leaves more space for placing the flap device 19 in a compressed configuration, which reduces the likelihood of damage to the flap device 19 during folding and delivery of the valve prosthesis 1.

[0093] FIG. 4A shows an embodiment of a valve prosthesis 1 including a seal sleeve 46. The seal sleeve 46 is attached to the inlet portion 4 of the frame 2. As shown in FIG. 4A and 4B, the cuff 46 is a radially closed strip of fabric that encloses on the outside the portion of the inlet portion 4 of the frame 2 formed by one or two rows 42 of the cells 10 of the frame 2. The cuff 46 may be made of a plastics material such as Dacron, ePTFE or other material selected for its properties and biocompatibility. As noted above, the artificial material can be thinner than biological tissue, thereby reducing the delivery profile. However, in a preferred embodiment, the cuff 46 is made of biological tissue, such as, for example, the pericardium of a pig, horse or bovine, due to the lesser thrombogenicity of biological tissue. The collar 46 may be formed from a single element or formed from separate approximately trapezoidal elements connected to each other along short edges. The collar 46 can be sewn, glued, welded, stapled, or attached to the frame 2 in any other suitable manner. In a preferred embodiment, the cuff 46 is sewn to the bridges 43 and the ribs 9 of the cells 10 of the frame 2 with a surgical thread. The cuff 46 reduces the risk of paravalvular leaks arising from a loose fit of the skirt 20 of the valve prosthesis 1 to the fibrous ring of the patient's native valve, which may be a consequence of the non-circular shape of the fibrous ring of the native valve, arising from the individual characteristics of the patient's anatomy, or associated with calcium deposits on the fibrous ring.

[0094] While the preferred embodiments of the invention have been described above, it will be apparent to those skilled in the art that various changes and modifications can be made. The appended claims are intended to cover all such changes and modifications that are consistent with the true spirit and scope of the invention.

Examples of implementation of the invention

[0095] Example 1. Parameters of specific embodiments of the valve prosthesis framework according to the present invention

Valve prosthesis no. D1, mm D2, mm D3, mm 26 25.7 21.9 36.5 29 28.9 23.3 37.9 31 31.7 23,7 37.4

[0096] These scaffold options allow the valve prosthesis to adapt to a wide variety of patient anatomical features. Valve prosthesis variants containing these scaffold embodiments can be used in more than 75% of patients. This eliminates the need to create a large number of different valve prostheses, thereby significantly reducing the costs associated with manufacturing and inventorying large quantities of parts.

[0097] Example 2. Measurement of the Radial Stiffness of Specific Embodiments of the Valve Prosthetic Framework of the Present Invention

[0098] Measurement of radial stiffness was performed using a Blockwise RLU124 radial force tester (Blockwise Engineering LLC, USA). The inlet part of the frame was clamped with tester petals at a distance of about 8 mm from the inlet edge of the frame. This approximately corresponds to the contact zone of the inlet part of the framework with the fibrous ring of the patient's native valve during implantation. Next, the frame was compressed in diameter, and then unclenched, and the change in radial force was recorded. FIG. 5 shows graphs illustrating changes in radial force depending on the compression ratio of the frame. The abscissa shows the reduction of the frame diameter ΔD in mm, and the ordinate shows the radial force F in newtons (N). The radial stiffness was taken as the value of the radial force obtained for such a compression of the frame, when the nominal diameter D1 compressed by 6 mm (ΔD = 6) was expanded to the original (ΔD = 0). Compression ΔD = 6 corresponds to the maximum compression during implantation after the opening of the valve prosthesis. For the specific embodiments described in Example 1, the following radial stiffness was obtained: # 26 - 29 N, for # 29 - 25 N, # 31 - 22 N.

[0099] For comparison, a radial stiffness study was conducted for the CoreValve aortic valve prosthesis (Medtronic), which most closely resembles the claimed valve prosthesis # 29. As seen in FIG. 5, already starting from a ΔD of approximately 3 mm, CoreValve exhibits a radial stiffness of 15-35 N, greater than that of the framework of the claimed valve prosthesis No. 29.

[00100] Example 3. Measurement of the volume of paravalvular leaks

[00101] The volume of paravalvular leaks was measured on a hydrodynamic stand manufactured by MedIntell using a ring simulating the fibrous ring of the human aortic valve. The bench ring had an inner diameter 3 mm less than the diameter D1 of the inlet portion of the valve prosthesis. For example, for valve prosthesis # 29, the stand ring diameter was 26 mm. The 3mm difference between the stand ring diameter and the D1 diameter simulates the difficult operating conditions of an implanted valve prosthesis, characterized by weak compression. The valve prosthesis was placed in the ring, and the volume V1 of the backflow of physiological solution (0.9 wt% sodium chloride in purified water) was measured, thus recording the capabilities of the stand. Then, the prosthetic valve portion including the inlet portion of the frame was glued with a silicone sealant, and the physiological saline backflow volume V2 was measured again. The use of a silicone sealant simulated optimal contact of the implanted valve prosthesis with the patient's tissues. By subtracting V1 from V2, the paravalvular leak volume was obtained.

[00102] For specific variants of aortic valve prostheses containing the frameworks described in [00102] Example 1, the volume of paravalvular leaks was: for # 26 - 2 ml, for # 29 - 1 ml, for # 31 - 1.5 ml.

[00103] In the present application materials, the preferred disclosure of the implementation of the claimed technical solution is presented, which should not be used as limiting other, particular embodiments of its implementation, which do not go beyond the scope of the claimed scope of legal protection and are obvious to specialists in the relevant field of technology.

Claims (36)

1. Aortic valve prosthesis, containing: a self-expanding frame having a mesh structure formed by radially closed rows of cells, each of which is bounded by ribs connected by bridges; • wherein the frame includes an inlet part and an outlet part, and the inlet part is located distally relative to the outlet part; • in this case, the inlet part contains a distal row of frame cells; • in this case, the bridges connecting the distal ends of the ribs of the distal row of the frame cells form the inlet edge of the frame; • while each row of frame cells contains 8-12 cells; • in this case, the thickness of the edges of the cells is from 320 to 450 μm, and the width of the edges of the cells is from 200 μm to 350 μm; • wherein the frame is in a compressed delivery configuration and an expanded configuration for use, wherein when the frame is in an expanded application configuration, the diameter of the outlet portion is greater than the diameter of the inlet portion; a valve body attached to the frame, including a skirt and a flap device attached to the skirt to form a connection line between the flap device and the skirt; • in this case, the flap apparatus contains flaps, and the adjacent flaps are interconnected to form commissures. 2. The aortic valve prosthesis according to claim 1, in which the frame contains 3-5 rows of cells, wherein a row of cells means a distal row of cells of the frame or a row of cells in which the cells are located without radial displacement relative to the cells of the distal row of cells of the frame. 3. The aortic valve prosthesis according to claim 1, wherein the emitting part of the frame comprises 2-3 loops. 4. The aortic valve prosthesis according to claim 1, wherein the frame comprises a region of constriction between the inlet portion and the outlet portion, wherein in the expanded configuration, the diameter of the constricted region is less than the diameter of the inlet portion. 5. The aortic valve prosthesis according to claim 1, wherein the skirt and valve apparatus are cut from biological tissue by laser cutting in the fluid layer. 6. The aortic valve prosthesis according to claim 1, wherein the commissures, skirt and junction line of the flap apparatus and the skirt are attached to the webs and ribs of the frame cells. 7. The aortic valve prosthesis according to claim 6, wherein the skirt is attached to the webs and ribs of the frame cells located distal to the webs and ribs of the frame cells to which the flap and skirt junction line is attached. 8. The aortic valve prosthesis according to claim 6, wherein a portion of the skirt is folded past the inlet edge of the frame and is attached to the ribs of the cells of the distal row of cells of the frame. 9. The aortic valve prosthesis according to claim 6, wherein the commissures, the skirt and the junction line of the flap apparatus and the skirt are attached to the ribs and bridges of the frame cells by sewing. 10. The aortic valve prosthesis of claim 9, wherein each commissure is attached to the scaffold with 12-40 stitches. 11. Aortic valve prosthesis, containing: a self-expanding frame having a mesh structure formed by radially closed rows of cells, each of which is bounded by ribs connected by bridges; • wherein the frame includes an inlet part and an outlet part, and the inlet part is located distally relative to the outlet part; • in this case, the inlet part contains a distal row of frame cells; • in this case, the bridges connecting the distal ends of the ribs of the distal row of the frame cells form the inlet edge of the frame; • in this case, the thickness of the edges of the cells is from 320 to 450 μm, and the width of the edges of the cells is from 200 μm to 350 μm; a valve body attached to the frame, including a skirt and a flap device attached to the skirt to form a connection line between the flap device and the skirt; • in this case, the flap apparatus contains flaps, and the adjacent flaps are interconnected to form commissures; • in this case, the commissures, the skirt and the connection line of the flap apparatus and the skirt are attached to the webs and edges of the frame cells; • moreover, a part of the skirt is bent over the inlet edge of the frame and is attached to the ribs of the cells of the distal row of cells of the frame so that the skirt covers the bridges connecting the distal ends of the ribs of the distal cells of the frame cells. 12. The aortic valve prosthesis of claim 11, wherein each row of frame cells comprises 8-12 cells. 13. The aortic valve prosthesis according to claim 11, wherein the valve apparatus and the skirt are made of biological tissue. 14. The aortic valve prosthesis according to claim 13, wherein the leaflet and skirt are cut from biological tissue by laser cutting in the fluid layer. 15. The aortic valve prosthesis of claim 11, wherein the skirt forms an undulating fold along the upstream edge of the frame. 16. The aortic valve prosthesis according to claim 11, wherein the skirt is attached to the webs and ribs of the frame cells located distally relative to the webs and ribs of the frame cells to which the flap and skirt junction line is attached. 17. The aortic valve prosthesis according to claim 11, wherein the commissures, the skirt and the junction line of the flap apparatus and the skirt are attached to the webs and ribs of the frame cells by sewing. 18. The aortic valve prosthesis of claim 17, wherein the commissures are attached to the scaffold.

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