Gentle artificial heart valve with improved wear characteristics
Abstract
Disclosed herein is an artificial heart valve, comprising a valve housing comprising a distal plate and a proximal valve ring operably connected by a plurality of struts; one or more helical springs having a proximal end and a distal end; and a bellows spring having a proximal end, enclosed area, and a distal end, the distal end of the bellows spring operably attached to a first surface of a moving spring plate positioned axially in between the one or more helical springs and the bellows spring, the proximal end of the helical spring operably attached to a second surface of the moving spring plate; and a movable valve plate operably attached to the proximal end of the bellows spring, wherein the movable valve plate is configured to reversibly contact the proximal valve ring to create a seal and close the valve.
Claims
exact text as granted — not AI-modifiedWhat is claimed is:
1 . An artificial heart valve, comprising: a moveable valve ring that moves to a flat gate plate to form a seal valve.
2 . The artificial heart valve of claim 1 , further comprising a flat contact area between the moveable valve ring and the valve plate, to minimize the force per unit area of contact between the moveable valve ring and the valve plate.
3 . The artificial heart valve of claim 2 , further comprising a bellows spring operably attached to the moveable valve ring.
4 . The artificial heart valve of claim 3 , wherein the bellows spring is operably hung to a helical spring assembly.
5 . The artificial heart valve of claim 4 , wherein an end of the helical spring assembly is operably attached to a cage housing, to provide a force reference point.
6 . The artificial heart valve of claim 5 , wherein the bellows spring has a first spring constant and the helical spring assembly has a second spring constant, the first spring constant and the second spring constant configured to assist in opening and closing of the valve, minimizing pressure and keeping movement gentle.
7 . The artificial heart valve of claim 6 , wherein the bellows spring and the helical spring assembly are configured to isolate pressure on the valve, and substantially prevent high pressure forces from acting on the valve.
8 . The artificial heart valve of claim 7 , wherein the bellows spring is suspended on the helical spring assembly, reducing the pressure on the valve, and wherein the valve is configured such that the valve gate force is effected substantially only by an area of the moveable valve ring that contacts the flat gate plate to seal the valve, minimizing the effect of blood pressure on valve pressure.
9 . The artificial heart valve of claim 8 , wherein the moveable valve ring is configured to not move radially or slide to lengthen the lifespan of the valve.
10 . The artificial heart valve of claim 9 , wherein the valve is configured such that the impact force upon closure of the valve is minimized, and movement of the bellows spring and the helical spring assembly are programmed to control the valve.
11 . The artificial heart valve of claim 10 , wherein the valve comprises a metal or plastic material.
12 . An artificial heart valve, comprising:
a movable valve plate configured to reversibly contact a proximal valve ring to create a seal and close the valve; wherein at least some stress forces on the valve are alleviated via at least one helical spring operably attached to a bellows spring, the bellows spring operably attached to the movable valve plate.
13 . The artificial heart valve of claim 12 , wherein the bellows spring has a pre-selected spring constant sufficient that the movable valve plate contacts the proximal valve ring substantially entirely by virtue of the spring force of the bellows spring, reducing the impact force on the valve.
14 . The artificial heart valve of claim 12 , wherein the bellows spring has a pre-selected spring constant sufficient to prevent a sudden stop force on the movable valve plate or the proximal valve ring.
15 . The artificial heart valve of claim 12 , wherein the proximal valve ring has a first surface having a surface area and the movable valve plate has a second surface having a surface area, wherein less than the entire surface area of the first surface and the second surface reversibly contact each other to create the seal to close the valve in order to reduce the pressure force on the valve.
16 . The artificial heart valve of claim 12 , configured to reduce hemolysis of red blood cells flowing through the valve by virtue of at least the large contact area and low impact force on the valve.
17 . The artificial heart valve of claim 12 , configured such that no valve component is configured to move in a direction other than coaxial with respect to the longitudinal axis of the valve.
18 . The artificial heart valve of claim 12 , configured to have a long life expectancy within a patient of at least 25 years.
19 . An artificial heart valve, comprising:
a valve housing comprising a distal plate and a proximal valve ring operably connected by a plurality of struts; one or more helical springs having a proximal end and a distal end; and a bellows spring having a proximal end, enclosed area, and a distal end, the distal end of the bellows spring operably attached to a first surface of a moving spring plate positioned axially in between the one or more helical springs and the bellows spring, the proximal end of the helical spring operably attached to a second surface of the moving spring plate; and a movable valve plate operably attached to the proximal end of the bellows spring, wherein the movable valve plate is configured to reversibly contact the proximal valve ring to create a seal and close the valve.
20 . The artificial heart valve of claim 19 , comprising a plurality of intertwined helical springs.Cited by (0)
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