RU2380060C2 - Artificial valve - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention concerns medicine and is used in cardiosurgery in natural valve replacement surgeries. An artificial valve comprises a ring body, two turnable leaflets that form the primary throat area along the centre of a body opening, and leaflet slewing limiters representing two pairs of ledges located on an end face of the body turned to the descending blood flow. Each ledge of the second pair is opposed to a part of the side face of the appropriate leaflet. The side faces of the first pair of ledges comprise guide surfaces that interacts with the appropriate thrust faces of the side face of the leaflets while closed and opened. Each leaflet has a through groove that interacts with the appropriate ledge of second pair of slewing limiters in service of the artificial valve.

EFFECT: higher reliability of leaflet retention in transfer.

21 cl, 10 dwg

Description

The present invention relates to medicine, in particular to cardiovascular surgery, and is intended to replace the affected natural heart valves during cardiac surgery.

Widely used implantable prosthetic implants are highly reliable and provide satisfactory hemodynamics, the corresponding improvements reduce acoustic noise, patient anxiety, and increase uptime. Standard prostheses include a ring-shaped body that provides a channel for blood flow. One or more valves are mounted in the body with the possibility of repetition between the open position for passing a direct blood flow and the closed position for blocking the channel and limiting the return blood flow. In addition, the prosthetic valve of the heart contains a connecting mechanism for connecting the valve body to the surrounding tissues of the heart. Basically, this mechanism is made in the form of a cuff, which is sewn to the tissues of the heart and covers the lateral surface of the valve prosthesis body. The effectiveness of the valve prosthesis is determined by the valve cross-sectional area when the flaps are in the open position. Preferred is the design of the valve with the main passage area of the valve body located in the center. In this case, the hemodynamic distortion is minimal and the blood flow through the artificial valve is close to natural.

Known designs (see US patent 4274437, RF patent 2066984) with the provision of the main zone of the bore in the center. With this arrangement, it is obvious that the central part of the flow through the valve remains weakly perturbed, and the distortions introduced by the valves are minimal. However, these valves are not used in surgical practice due to the low reliability and high likelihood of sash loss. As it turned out, the development of such limiters of movement of the valves, which would reliably and throughout the life of the valve, kept the valves and contributed to the smooth operation of the valve, poses the main difficulties.

One solution to this problem is disclosed in published international application WO 2007/075121, publication date: 07/05/2007. The known prosthetic valve of the heart includes an annular body, the sash with the possibility of rotation and the formation of the main zone of the passage section of the valve in the center, installed in the body, and the rotation stops of the valves, the rotation limiters of the valves are two pairs of protrusions located on the end surface of the housing facing the downward flow blood, the first pair of protrusions has an inner surface, at least part of which is made flat and which has the ability to interact with the flat area the flaps to restrict the reverse flow of blood in the closed position, on the opposite lateral sides, the protrusions have guide surfaces that interact with the corresponding supporting surfaces of the side surface of the flaps when they are rotated, the guiding surface of the protrusions are inclined at an angle to their inner surface and have a shape corresponding to the turning path the supporting surfaces of the valves, determining the axis of their rotation when opening and closing the prosthesis, each protrusion of the second pair is located opposite of the part of the lateral surface of the corresponding leaflet, which is completely remote from the central surface and has the ability to interact with its inner surface with the indicated part of the leaflet of the leaflet during the opening of the heart valve prosthesis, leaflet stoppers are provided with at least two stops interacting with the leaflet surfaces facing downward blood flow in their open position, determining the angle of rotation of the valves.

Another variant of the known heart valve prosthesis has three flaps, with the possibility of rotation and the formation of the main passage area in the center of the opening of the housing installed in the housing, and the rotation limits of the valves, the rotation limits of the valves are two triples of protrusions located on the end surface of the body facing downward the blood flow, the first three protrusions has on their opposite sides the guide surfaces interacting with the respective supporting surfaces by the side surface of the cusps when opening and closing the prosthesis, each protrusion of the second triple is located opposite the most remote part of the side surface of the corresponding cusp from the central surface and has the ability to interact with its inner surface with the indicated part of the side surface of the cusp during the opening of the heart valve prosthesis; at least three stops interacting with the surfaces of the valves, facing the downward flow of blood in their open position, determining the angle of rotation of the wings.

The present invention seeks to provide yet another design for a heart valve prosthesis in which the main passage area is located in the center of the valve body opening and in which the flaps are held securely during operation and the valve has a long life without failures.

The technical result achieved using the present invention is to increase the reliability of holding the wings during movement.

The technical result is achieved due to the fact that in the prosthesis of the heart valve, including an annular body, two flaps installed in it with the possibility of rotation and the formation of the main zone of the passage section in the center of the opening of the body, and the rotation limiters of the flaps, made in the form of two pairs of protrusions located on the end surface of the body facing the downward flow of blood, each protrusion of the second pair is located opposite to the part of the side surface corresponding to the most remote from the central axis of the prosthesis the sash, on the sides of the first pair of protrusions there are guide surfaces that can interact with the corresponding abutment surfaces of the side surface of the sash when they are closed and opened, and a through groove is made on each sash, which can interact with the corresponding protrusion of the second pair of turn stops during operation prosthesis.

The technical result is enhanced due to the fact that from the side facing the downward flow of blood, the first pair of protrusions is equipped with four supporting surfaces that are arranged in pairs and interact with the corresponding surfaces of the valves in their closed position.

The guiding surfaces of the second pair of protrusions interacting with the through grooves of the sash are made arcuate.

The guiding surfaces of the second pair of protrusions are made by rotating their generatrix relative to the axis of rotation of the wings.

Cross sections of the protrusions of the second pair of travel stops interacting with through grooves of the flaps are rectangular.

The inner surface of the hole of the annular body is made in the form of a lateral surface of a circular cylinder and is limited by two flat ends facing respectively the upward and downward flows.

At the end facing the downward flow of blood, two recesses are made, the surfaces of each of which serve to interact with the part of the corresponding leaflet that is most remote from the central surface when opening and closing the prosthesis and forming a limited reverse blood flow in its closed state.

An annular groove is made on the outer surface of the housing for attaching the sewing cuff.

The outer surface of each leaf facing the downward flow of blood is at least partially convex, and the outer surface facing the upward flow of blood is at least partially concave.

The convex and concave parts of the outer surfaces of the valves are the lateral surfaces of the annular cylinder, inclined relative to the central axis of the prosthetic heart valve. The prosthesis is made of pyrocarbon.

The technical result for the second embodiment of the invention is achieved due to the fact that in the prosthesis of the heart valve, including an annular body, three flaps installed in the body with the possibility of rotation and the formation of the main zone of the passage section in the center of the opening of the body, and the rotation limiters of the valves made in the form of two three protrusions located on the end surface of the body facing the downward flow of blood, the first three protrusions have on their opposite sides the guiding surfaces in interacting with the corresponding supporting surfaces of the lateral surface of the valves when opening and closing the prosthesis, and each protrusion of the second three is located opposite the most remote part of the side surface of the corresponding valve from the central axis of the prosthesis, a through groove is made on each leaf that can interact with the corresponding protrusion of the second three of the rotation limiters during operation of the prosthetic heart valve.

The technical result for the second embodiment of the invention is enhanced due to the fact that interacting with the through grooves of the sash of the surface of the second three protrusions made arcuate.

The guiding surfaces of the first pair of protrusions are made by rotating their generatrix relative to the axis of rotation of the flaps.

The cross sections of the protrusions of the second pair of travel stops interacting with the through grooves of the flaps and the through grooves of the flaps are rectangular.

The inner surface of the hole of the annular body is made in the form of a lateral surface of a circular cylinder and is limited by two flat ends facing respectively the ascending and descending blood flows.

At the end facing the downward flow of blood, three recesses are made, the surfaces of each of which serve to interact with the part of the lateral surface of the corresponding leaflet that is most remote from the central surface when opening and closing the prosthesis and forming a limited reverse blood flow in its closed state.

An annular groove is made on the outer surface of the housing for attaching the sewing cuff.

The outer surface of each leaf facing the downward flow of blood is at least partially convex, and the outer surface facing the upward flow of blood is at least partially concave.

The convex and concave parts of the outer surfaces of the wings are the lateral surfaces of the cone. The prosthesis is made of pyrocarbon.

The invention will be better understood from the description below with reference to the position of the drawings, where Figs. 1-5 show a first embodiment of a valve having two flaps, in particular in Fig. 1 is a side sectional view with closed cusps, in Figs. .2 - shows the interaction of the flaps with the second pair of protrusions, Fig.3 is a top view with closed flaps, Fig.4 is a side view in section with open flaps, Fig.5 is a top view with open flaps.

Figures 6-10 show a second embodiment of a valve having three wings, in particular Figure 6 is a sectional side view with the wings closed, Fig. 7 shows the interaction of the valves with a second triple of projections, and Fig. 8 is a view top with closed shutters, Fig.9 is a side view in section with open shutters, Fig.10 is a top view with open shutters.

The heart valve prosthesis comprises an annular body 1 made of pyrocarbon and having two (Figs. 1-5) or three (Figs. 6-10) flaps 2, also made of pyrocarbon and, with the possibility of rotation and the formation of the main passage area in the center, are installed in the housing 1. The inner surface 16 of the opening of the housing 1 is made in the form of a lateral surface of a circular cylinder and is limited by two flat ends 4 and 18, facing the ascending 19 and descending 5 blood flows, respectively.

Limiters 3 of the rotation of the valves are made in the form of two pairs of protrusions 6 and 12 located on the end 4 of the surface of the housing 1, facing the downward flow of blood 5. Each protrusion 12 of the second pair is located opposite to the part of the side surface of the corresponding flap 2, which is most remote from the central axis 24 of the prosthesis. On the sides of the first pair of protrusions 6 there are guide surfaces 7. These surfaces (interaction surfaces with the contact surfaces of the flaps) 7 interact with the corresponding contact surfaces 8 the lateral surface of 9 wings 2 when they are closed and opened. From the side facing the downward flow of blood, the first pair of protrusions 6 is provided with four supporting surfaces 10, which are arranged in pairs. The supporting surfaces 10 interact with the corresponding surfaces (surfaces of interaction with the supporting surfaces of the protrusions) 11 of the flaps 2 in their closed position. A through groove 13 is made on each leaf 2. Through grooves 13 interact with the corresponding protrusion of the second pair 12 of rotation limiters 3 during opening and closing of the prosthesis. The surfaces 14 and 15 of the second pair of protrusions 12, interacting with the through grooves 13 of the flaps 2, are made arcuate. The cross sections of the interacting protrusions 12 of the rotation limiters and the through grooves 13 of the flaps 2 are rectangular. The guide surfaces 14 and 15 of the second pair of protrusions 12 are made by rotating their generatrices relative to the axis of rotation of the leaflets 2. At the end facing the downward flow of blood 5, two recesses 20 are made, the surfaces of each of which serve to interact with the part most distant from the central surface the corresponding sash 2 when opening and closing the prosthesis and the formation of a limited reverse flow of blood in its closed state. An annular groove 21 is made on the outer surface of the housing for attaching a sewing cuff. The outer surface 22 of each leaf 2, facing the downward flow of blood, at least partially made convex, and the outer surface 23, facing the upward flow of blood, at least partially made concave, while forming these parts of the surfaces are inclined at an angle to the central surface of the leaf 2. The convex and concave parts of the outer surfaces 22 of the flaps 2 are lateral surfaces of the annular cylinder inclined relative to the central axis 24 of the heart valve prosthesis.

The prosthesis of the heart valve works as follows. When the valve prosthesis is opened by direct blood flow, the leaflets 2 rotate around an imaginary axis, determined by the geometry of the arcuate guide surfaces 14 and 15 of the second pair of protrusions 12. This rotation occurs to the equilibrium state and until the lateral surface 9 of the leaflet 2 interacts with a recess 20 at the end 4. In this case, the blood flows in the forward direction, the central part of the opening of the valve body 1 passes freely without distortion. At the end of the stroke, when the valve is opened, the valves are almost vertical and do not create resistance to the direct flow of blood 19. The execution of the outer surfaces of the flaps 2 convex-concave provides a more complete opening of the valve. When the direct flow stops, the flaps 2 begin to rotate and interacting with the guide surfaces 14 and 15 of the second pair of protrusions 12 and the surface of the recess 20 return to their original position until the central surfaces and the end face 4 of the housing 1 touch each other. In this position, the flaps 2 provide a hole overlap case 1 with the formation of a limited reverse blood flow at the locations of the recesses 30 at the end 4.

The second version of the prosthetic valve of the heart (see Fig.6-10) includes three leaves 2 installed in the housing 1 with the possibility of rotation and the formation of the main zone of the passage section in the center of the opening of the housing 1. The rotation limiters of the valves 3 are made in the form of two triples of the protrusions 6 and 12, located on the end surface of the body 4, facing the downward flow of blood 5. The first three protrusions 6 have on their opposite lateral sides guide surfaces 7 that interact with the corresponding abutment surfaces 8 of the side surface 9 of the flaps 2 when opening and closing the prosthesis. Each protrusion 12 of the second triple is located opposite to the part of the side surface 9 of the corresponding sash 2 that is most remote from the central axis 24 of the prosthesis. A through groove 13 is made on each sash 2. The grooves 13 interact with the corresponding protrusion 12 of the second three of the rotation limiters during operation of the heart valve prosthesis. The cross sections of the interacting protrusions 12 of the second pair of rotation limiters and the through grooves 13 of the flaps 2 are rectangular. The guiding surfaces 14 and 15 of the second three protrusions 12 interacting with the through grooves of the sash 2 are arcuate and by rotation of their generatrix relative to the axis of rotation 26 of the sash 2. The inner surface 16 of the hole of the annular body 1 is made in the form of a side surface of a circular cylinder and is limited by two flat ends 4 and 18, facing respectively the ascending 19 and descending 5 blood flows. At the end 4, facing the descending blood 5, three recesses 20 are made. The surfaces of each recess 20 serve to interact with the part of the side surface of the corresponding leaf 2, which is most remote from the central surface when opening and closing the prosthesis and forming a limited reverse blood flow in its closed state. On the outer surface of the housing 1, an annular groove 21 is made for attaching a sewing cuff. The outer surface 22 of each leaf 2, facing the downward flow of blood 5, at least partially made convex. The outer surface 23 facing the upward flow of blood is at least partially concave. The generators of the indicated parts of the surfaces are inclined at an angle to the central surface (indicate on the drawing) of the sash 2. The convex and concave parts of the outer surfaces of the sashes are parts of the side surface of the cone.

The prosthesis of the heart valve works as follows. When the valve prosthesis is opened by direct blood flow, the leaflets 2 rotate around an imaginary axis, determined by the geometry of the arcuate guide surfaces 14 and 15 of the second three protrusions 12. This rotation occurs to the equilibrium state and until the lateral surface 9 of the leaflet 2 interacts with a recess 20 at the end 4. In this case, the blood flows in the forward direction, the central part of the opening of the valve body 1 passes freely without distortion. At the end of the stroke, when the valve is opened, the valves are almost vertical and do not create resistance to the direct flow of blood 19. The execution of the outer surfaces of the flaps 2 convex-concave provides a more complete opening of the valve. When the direct flow stops, the flaps 2 begin to rotate and, interacting with the guide surfaces 14 and 15 of the second three protrusions 12 and the surfaces of the recess 20, return to their original position until the side surfaces touch the end face 4 of the housing 1. In this position, the flaps 2 provide overlapping the opening of the housing 1 with the formation of a limited reverse blood flow at the locations of the recesses 30 at the end 4.

An artificial heart valve can be manufactured industrially from materials widely known and used in medicine, for example pyrocarbon, and using known equipment.

When used in cardiac surgery to replace the function of naturally affected valves, the patented prosthesis has the following advantages:

1) provides high efficiency of the valve cross section, practically without resistance to flow in the open position of the valves;

2) eliminates the formation of stagnant zones due to washing away the areas of the flow restrictors and stops with direct and reverse blood flow;

3) significantly reduces the factor of thrombosis;

4) eliminates the instability of the valve when opening due to the execution of the outer surfaces of the valves is convex-concave;

5) excludes the loss of the valves due to the implementation of the rotation limiters with stops;

6) eliminates the rotation of the valves under the action of the reverse flow of blood due to the support of the outer surface of the valve on the limiters and the interaction of the central lateral;

7) has high reliability and durability, good compatibility with natural fabrics.

Claims (21)

1. The prosthesis of the heart valve, comprising an annular body, two flaps mounted with the possibility of rotation and the formation of the main zone of the passage section in the center of the opening of the casing, and the rotation limiters of the flaps, made in the form of two pairs of protrusions located on the end surface of the casing facing the downward flow blood, the first pair of protrusions has on their opposite lateral sides guiding surfaces that interact with the corresponding supporting surfaces of the lateral surface of the cusps when they open ytii and closing and each protrusion located opposite the second pair most distant from the central axis of the prosthesis of the side surface of the corresponding flap, characterized in that on each leaf is formed a through slot having a possibility of interaction with a corresponding projection of the second pair of pivot stops during operation of the prosthesis. 2. The prosthesis according to claim 1, characterized in that from the side facing the downward blood flow, the first pair of protrusions is provided with four supporting surfaces that are arranged in pairs and interact with the corresponding surfaces of the valves in their closed position. 3. The prosthesis according to claim 1, characterized in that the guiding surfaces of the second pair of protrusions interacting with the through grooves of the sash are made arcuate. 4. The prosthesis according to claim 1, characterized in that the guide surfaces of the second pair of protrusions are made by rotating their generatrix relative to the axis of rotation of the flaps. 5. The prosthesis according to claim 1, characterized in that the cross sections of the protrusions of the second pair of rotation limiters interacting with the through grooves of the flaps are rectangular. 6. The prosthesis according to claim 1, characterized in that the inner surface of the hole of the annular body is made in the form of a lateral surface of a circular cylinder and is limited by two flat ends facing respectively the upward and downward flows. 7. The prosthesis according to claim 1, characterized in that at the end facing the downward flow of blood, two recesses are made, the surfaces of each of which serve to interact with the part of the corresponding leaflet that is most remote from the central surface when opening and closing the prosthesis and forming a limited reverse blood flow in its closed state. 8. The prosthesis according to claim 1, characterized in that the outer surface of the body is made of an annular groove for attaching the sewing cuff. 9. The prosthesis according to claim 1, characterized in that the outer surface of each leaf facing the downward flow of blood is at least partially convex, and the outer surface facing the upward flow of blood is at least partially concave. 10. The prosthesis according to claim 1, characterized in that the convex and concave parts of the outer surfaces of the valves are lateral surfaces of the annular cylinder inclined relative to the central axis of the prosthetic heart valve. 11. The prosthesis according to any one of the preceding paragraphs, characterized in that it is made of pyrocarbon. 12. The prosthesis of the heart valve, including an annular body, three flaps installed in the body with the possibility of rotation and the formation of the main zone of the passage section in the center of the opening of the case, and the rotation limiters of the valves made in the form of two triples of protrusions located on the end surface of the body facing in the downward flow of blood, the first three protrusions have on their opposite lateral sides guiding surfaces that interact with the corresponding abutment surfaces of the lateral surface of the stem rock at the opening and closing of the prosthesis, and each protrusion of the second triple is located opposite the most remote part of the lateral surface of the corresponding flap from the central axis of the prosthesis, characterized in that a through groove is made on each flap that can interact with the corresponding protrusion of the second three of the rotation limiters during operation heart valve prosthesis. 13. The prosthesis according to claim 12, characterized in that the surfaces of the second three protrusions interacting with the through grooves are made arcuate. 14. The prosthesis according to claim 12, characterized in that the guiding surfaces of the first pair of protrusions are made by rotating their generatrix relative to the axis of rotation of the flaps. 15. The prosthesis according to claim 12, characterized in that the cross sections of the protrusions of the second pair of travel stops interacting with the through grooves of the flaps and the through grooves of the flaps are rectangular. 16. The prosthesis according to claim 12, characterized in that the inner surface of the hole of the annular body is made in the form of a lateral surface of a circular cylinder and is limited by two flat ends facing respectively the ascending and descending blood flows. 17. The prosthesis according to claim 12, characterized in that at the end facing the downward blood flow, three recesses are made, the surfaces of each of which serve to interact with the part of the lateral surface of the corresponding sash that is most remote from the central surface when opening and closing the prosthesis and forming limited backflow of blood in its closed state. 18. The prosthesis according to claim 12, characterized in that an annular groove is made on the outer surface of the body for attaching the cuff. 19. The prosthesis according to claim 12, characterized in that the outer surface of each leaf facing the downward flow of blood is at least partially convex, and the outer surface facing the upward flow of blood is at least partially concave. 20. The prosthesis according to claim 12, characterized in that the convex and concave parts of the outer surfaces of the valves are the lateral surfaces of the cone. 21. The prosthesis according to any one of paragraphs.12-20, characterized in that it is made of pyrocarbon.

Images