Magnetic retrieval of prosthetic heart valves for redo-TAVI
Magnetic retrieval of prosthetic heart valves for redo-TAVI
Bioprosthetic aortic heart valves are known to degenerate within 7–15 years of implantation. Currently, the options for treating a failing valve are (a) redo surgical aortic valve replacement or, increasingly, (b) valve-in-valve transcatheter aortic valve implantation (ViV-TAVI). The ViV-TAVI procedure is referred to as redo-TAVI when the failing valve is a TAVI device. Repeated procedures, such as two or three valve-in-valves, significantly reduce the effective valve flow area, putting a limit on recurrent treatments. With increasing life expectancy and the use of TAVI in younger, lower-risk patients, the demand for multiple replacement procedures will inevitably increase. Against this background, we describe a novel valve system named exchangeable-TAVI (e-TAVI) in which an electromagnetic catheter is used to remove and retrieve a failed exchangeable valve, followed by the immediate deployment of a new valve. The e-TAVI system comprises (i) an exchangeable valve, (ii) a permanent holding member that anchors the exchangeable valve and (iii) a dedicated catheter with electromagnets for removal of the exchangeable valve. Simulations have been performed to determine the forces, frame design and electromagnetic parameters required to crimp and retrieve a 26 mm diameter valve. An optimum configuration was found to comprise a 12 cell self-expanding frame with circular ferromagnetic regions of 1 mm radius and 0.5 mm thickness, along with eight electromagnets of 1 mm radius and 2 mm thickness. A force of 2.87 N and a current of 2.52 A per electromagnet were required to partially crimp the frame to an envelope radius of 11 mm. While this amount of force allowed the frame to be crimped solely through magnetic attraction, re-sheathing of the frame was not possible due to the weaker shear holding force of the magnets. Also, the current was close to the fusing current of the copper wire needed to fit sufficient windings into the available volume. These issues led to the conclusion that, in addition to the magnetic coupling, a mechanical mating between the removal catheter and the exchangeable valve is needed. This would decrease both the force that the electromagnets had to exert during crimping and the current required to generate this force.
Eren, Oguz Can
5f8919c2-78c4-44af-a52f-33df27c052ad
Curzen, Nick
70f3ea49-51b1-418f-8e56-8210aef1abf4
Bressloff, Neil W.
a5a07a74-3adb-42bf-8df7-a54aae4975a8
26 January 2022
Eren, Oguz Can
5f8919c2-78c4-44af-a52f-33df27c052ad
Curzen, Nick
70f3ea49-51b1-418f-8e56-8210aef1abf4
Bressloff, Neil W.
a5a07a74-3adb-42bf-8df7-a54aae4975a8
Eren, Oguz Can, Curzen, Nick and Bressloff, Neil W.
(2022)
Magnetic retrieval of prosthetic heart valves for redo-TAVI.
Medical Engineering & Physics, 101, [103761].
(doi:10.1016/j.medengphy.2022.103761).
Abstract
Bioprosthetic aortic heart valves are known to degenerate within 7–15 years of implantation. Currently, the options for treating a failing valve are (a) redo surgical aortic valve replacement or, increasingly, (b) valve-in-valve transcatheter aortic valve implantation (ViV-TAVI). The ViV-TAVI procedure is referred to as redo-TAVI when the failing valve is a TAVI device. Repeated procedures, such as two or three valve-in-valves, significantly reduce the effective valve flow area, putting a limit on recurrent treatments. With increasing life expectancy and the use of TAVI in younger, lower-risk patients, the demand for multiple replacement procedures will inevitably increase. Against this background, we describe a novel valve system named exchangeable-TAVI (e-TAVI) in which an electromagnetic catheter is used to remove and retrieve a failed exchangeable valve, followed by the immediate deployment of a new valve. The e-TAVI system comprises (i) an exchangeable valve, (ii) a permanent holding member that anchors the exchangeable valve and (iii) a dedicated catheter with electromagnets for removal of the exchangeable valve. Simulations have been performed to determine the forces, frame design and electromagnetic parameters required to crimp and retrieve a 26 mm diameter valve. An optimum configuration was found to comprise a 12 cell self-expanding frame with circular ferromagnetic regions of 1 mm radius and 0.5 mm thickness, along with eight electromagnets of 1 mm radius and 2 mm thickness. A force of 2.87 N and a current of 2.52 A per electromagnet were required to partially crimp the frame to an envelope radius of 11 mm. While this amount of force allowed the frame to be crimped solely through magnetic attraction, re-sheathing of the frame was not possible due to the weaker shear holding force of the magnets. Also, the current was close to the fusing current of the copper wire needed to fit sufficient windings into the available volume. These issues led to the conclusion that, in addition to the magnetic coupling, a mechanical mating between the removal catheter and the exchangeable valve is needed. This would decrease both the force that the electromagnets had to exert during crimping and the current required to generate this force.
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Accepted/In Press date: 18 January 2022
e-pub ahead of print date: 21 January 2022
Published date: 26 January 2022
Identifiers
Local EPrints ID: 492651
URI: http://eprints.soton.ac.uk/id/eprint/492651
ISSN: 1350-4533
PURE UUID: 36ce77aa-ec04-4907-8c42-7d9bacaf7c62
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Date deposited: 09 Aug 2024 16:32
Last modified: 10 Aug 2024 01:40
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Author:
Oguz Can Eren
Author:
Neil W. Bressloff
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