Bioprosthetic heart valve with strain matched leaflets
Abstract
Heart valve leaflet selection methods and apparatuses which subject individual leaflets to loads and measure the resulting deflection to more reliably group leaflets of similar physical characteristics for later assembly in prosthetic heart valves. The deflection testing may be accomplished using a variety of test set ups which are designed to impart a load on the leaflet which simulates the actual loading within a heart valve. The results from a number of deflection tests are used to categorize individual leaflets, which data can be combined with other data regarding the characteristics of the leaflet to better select leaflets for assembly into a multi-leaflet heart valve. In one embodiment, the deflection test is combined with an intrinsic load test, and leaflets having similar deflection and intrinsic load values used in the same heart valve. One apparatus for testing the leaflets includes a frame for securing the arcuate cusp of the leaflet while the straight coapting edge remains free, to simulate the actual leaflet mounting configuration within the heart valve prosthesis. The frame may include a lower portion having a recess for the leaflet and plurality of receptor holes around the peripheral edge of the recess, and an upper portion having a plurality of needles which extend downward through the leaflet and into the receptor holes and secure the edges of the leaflet.
Claims
exact text as granted — not AI-modifiedWhat is claimed:
1 . An implantable heart valve manufactured by a process comprising the steps of:
providing a collection of similarly sized leaflets; applying a load to each leaflet; observing the strain response in each leaflet caused by applying the load; sorting the leaflets into subgroups based on their respective strain responses such that the leaflets in each subgroup each have a strain response within a predetermined range; and, attaching only leaflets from a single subgroup to the heart valve such that when fluid pressure is applied to the implantable heart valve the leaflets thereon will exhibit similar strain response.
2 . The implantable heart valve of claim 1 , wherein the step of providing a collection includes providing a collection of natural tissue leaflets.
3 . The implantable heart valve of claim 2 , further including the step of chemically fixing the leaflets prior to testing.
4 . The implantable heart valve of claim 2 , wherein the step of providing a collection of natural tissue leaflets includes providing a collection of bovine pericardium leaflets.
5 . The implantable heart valve of claim 1 , wherein the step of providing a collection of leaflets includes providing a collection of leaflets having a matrix and natural tissue ingrowth.
6 . The implantable heart valve of claim 1 , wherein the step of providing a collection of leaflets includes providing a collection of leaflets having a substrate on which is formed a cell growth covering.
7 . The implantable heart valve of claim 1 , wherein the step of providing a collection of leaflets includes providing a collection of extruded collagen leaflets.
8 . The implantable heart valve of claim 1 , wherein the step of applying a load comprises applying a load sufficient to create an average stress in at least some of the leaflets within a generally linear, high modulus region of a stress/strain curve of the leaflet material.
9 . The implantable heart valve of claim 1 , further including the step of applying a load for a predetermined number of times prior to observing the strain response.
10 . The implantable heart valve of claim 9 , wherein the predetermined number is at least three.
11 . The implantable heart valve of claim 1 , further including the steps of:
performing an intrinsic load test on the leaflets; and sorting the leaflets based on the intrinsic load test results.
12 . The implantable heart valve of claim 1 , wherein the step of forming subgroups of leaflets having a strain response within a predetermined range comprises a measuring a deflection of each leaflet resulting from applying a load thereto, and forming a subgroup of leaflets each having a deflection within about 0.030 inches of the others.
13 . An implantable heart valve having multiple leaflets, wherein each leaflet has been tested by a process comprising the steps of:
mounting the leaflet in a framing assembly so that portions which are to be sutured in the valve are held stationary, wherein the leaflet defines a cusp edge and a coapted edge generally opposite the cusp edge, and the framing assembly includes an upper member and a lower member, the lower member having a recess for receiving at least the cusp edge of the leaflet, the upper member being shaped to mate over the recess, and the framing assembly defining a cavity circumscribed by the recess, the step of mounting including positioning the leaflet in the recess and piercing the leaflet cusp edge with needles extending between and supported from movement by the upper and lower members, to hold at least the cusp edge of the leaflet stationary; applying a load to the leaflet in a location adapted to simulate a point at which an average load is applied in the valve; sensing the resulting strain in the leaflet; sorting the leaflets into subgroups based on their respective strain responses such that the leaflets in each subgroup have a strain response within a predetermined range; and, attaching only leaflets from a single subgroup to the heart valve.
14 . The implantable heart valve of claim 13 , wherein the step of applying a load comprises applying a mechanical deflector to an upper surface of the leaflet over the cavity.
15 . The implantable heart valve of claim 13 , further including the step of recording the sensed strain.
16 . The implantable heart valve of claim 15 , further including applying a load at least twice before recording the sensed strain.
17 . The implantable heart valve of claim 16 , further including the step of performing a droop test on the leaflet by extending the leaflet over the end of a structure, and observing the resulting droop of the extended end of the leaflet.
18 . The implantable heart valve of claim 17 , further including testing a second leaflet and correlating the results of the droop tests and applied load tests for the two leaflets.
19 . The implantable heart valve of claim 13 , wherein the leaflet is made of a leaflet material, and the step of applying a load comprises applying a load sufficient to stress the leaflet within a generally linear high modulus region of a stress/strain curve of the leaflet material.
20 . The implantable heart valve of claim 13 , wherein the step of applying a load comprises applying a load sufficient to stress the leaflet between 300 and 600 kPa.Join the waitlist — get patent alerts
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