A Virtual Heart Valve Implant System : Navigating the idea space and developing a proof of concept for virtual transcatheter aortic valve replacement

Abstract: Aortic stenosis is a disease that causes a narrowing of the aortic valve opening. It is a disease that can be found in more than 2% of the elderly population. In the past, the only effective treatment has been open heart valve replacement, but in the last decade it has become possible to also treat aortic stenosis through a percutaneous procedure known as transcatheter aortic valve replacement. An implant-carrying catheter is led up to the patient’s heart where the implant is deployed. Sizing, positioning, and orientation of the implant are important considerations in transcatheter aortic valve replacement. Purpose: The purpose was to investigate the feasibility and potential features of a virtual heart valve implant system and how the available assets at the Medical Devices Center and its collaborators could create a useful tool for virtual transcatheter aortic valve implant selection, sizing, positioning, and orientation. Implementation: Challenges with transcatheter aortic valve replacement among clinicians and engineers were identified. A virtual heart valve implant system was proposed as a solution. The idea space for a virtual heart valve implant system was explored and structured systematically with a new approach called the idea connection tree method. A proof of concept prototype with a 3D model of an aorta and an implant in three different sizes was created as a way to gauge if there is user value in a virtual heart valve implant system. Result & Conclusion: For the proposed solution of a virtual heart valve implant system, 43 unique ideas were generated. Three main branches of ideas were identified: Design, simulation, and a database branch. It was estimated that the simulation branch would provide the most user value for comparatively low work effort. The proof of concept prototype showed that it was possible to visually evaluate the interference produced by different sized implants inside a 3D model of an aorta on a virtual reality system.