SU1544418A1 - Aortic valve prosthesis - Google Patents

Abstract

The invention relates to medical technology, more specifically to prosthetic artificial heart valves. The purpose of the invention is to reduce the load on the myocardium and reduce thrombosis by stabilizing the locking element in the blood stream. The aortic valve prosthesis contains an annular body 1 with a hollow locking element 4 with a thickened spherical part compared to a conical, on the outer surface of which spiral-shaped protrusions or depressions 5 are made, counterclockwise in the aortic blood flow, which preserves physiological twisted clockwise) blood flow in the aorta. In addition, blood moving in spiraling guides stabilizes the position of the locking element 4 without forming turbulent jets on its surface and distal, which reduces the load on the myocardium and eliminates stagnant zones distal to the prosthesis, reducing the likelihood of thrombus formation. 2 Il.

Description

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14

6 POLOGES 414299458 / 2b

08/20/87

23.02.90. Bul , "7

Novosibirsk Institute of Chemistry of the Siberian Branch of the USSR Academy of Sciences V.N. Zakharov and A.G. Gunin 615.475 (088.8)

(56) USSR Author's Certificate No. 797683, cl. A 61 F 2/24. 1979

(54) PROTESIS OF AORTIC VALVE

(57) The invention relates to medical technology, more specifically to prosthetic artificial heart valves. The purpose of the invention is to reduce the load on the myocardium and decrease thrombosis by stabilizing the blocking element in the blood flow. The aortic valve prosthesis contains an annular body 1 with an empty locking element 4 with a thickened spherical part (as compared with the conical one). on the outer surface of which there are spiral-shaped protrusions or depressions 5 directed counterclockwise in the aortic blood flow, which preserves the physiological twisted (counterclockwise) blood flow in the aorta. Kpovu additionally, the blood moving along the spiral-shaped guides stabilizes the position of the locking element 4 without the formation of turbulent jets on its surface and distal, which reduces the load on the myocardium and eliminates stagnant zones of the prosthesis, reducing the likelihood of thrombus formation. 2 Il.

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The invention relates to medical technology, more specifically to prosthetic artificial heart valves.

The purpose of the invention is to reduce the load on the myocardium and reduce thrombogenesis by stabilizing the locking element in the blood stream.

FIG. 1 shows the aortic valve prosthesis, general view; in fig. 2 - the same section.

The aortic valve prosthesis consists of a case I, made in the form of a ring with an outer tube 2 for accommodating the cuff 3. On the surface of the locking element 4 there are helical recesses (projections) 5 counterclockwise from the valve inlet. The locking element 4 is made drop-shaped and hollow, and its wall in the spherical part has a thickness of 6. The wall of the conical part 7 is thinner than the spherical part. In the region of the spherical part, the stops 8 are fixed, in which the free ends 9 are bent at a right angle. To ensure durability, the locking element 4 is made of a non-corrosive material (e.g. titanium).

The principle of operation of the aortic valve prosthesis is as follows.

As the forward pressure increases in the direction of the aorta, the locking element 4 extends, allowing blood to pass through the opening bounded by the inner surface of the valve body.

Further, the blood flows around the locking element 4 and, moving along the recesses (protrusions) 5, creates a spiral swirling blood flow, which approximates the movement of blood.

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See the aorta to the physiological. Creating an orderly swirling blood flow eliminates the formation of stasis along the blood flow. Due to the fact that the discharge occurs near the conical part of the locking element 4, the jets of flow along the central axis of its movement are constricted, and this ensures that the aortic intima is not traumatized.

The pressure reversal causes the return movement of the locking element 4, which spherical part 6 closes the working opening of the housing I. The inertia of the spherical part is larger, therefore the locking element 4 is stabilized, i.e. it is located downstream and returns exactly to its original position. The same circumstance contributes to the preservation of steady, laminar physiological blood flow in the aorta.

Claims (1)

Invention Formula A prosthetic aortic valve containing an annular body with a locking element made with travel stops, the spherical part of the locking element facing the valve inlet and located opposite the apex of the conical part, characterized in that in order to decrease myocardium and reduce clot formation by stabilizing in the flow the blood of the locking element, the locking element is hollow, with a hundred walls in the spherical part thicker than in the conical part, and spiral-shaped and Is the counterstrokes directed counterclockwise from the valve inlet?