Authors: Aldo Chipana, Sarah G Sanderson, Joseph Moore, Jeffery R Hill, Christopher R Dillon
Mentors: Chris Dillon
Insitution: Brigham Young University
Nitinol shape memory alloys have shown immense promise in biomedical engineering, with their exceptional biocompatibility and corrosion resistance. Interestingly, most biomedical applications rely on Nitinol’s super elasticity rather than its hysteretic properties. Previous research in this lab has highlighted the challenges and potential of using focused ultrasound to effectively heat Nitinol wire without causing damage to adjacent tissue.
Building upon these findings, our current study presents an extension of the initial experiments, incorporating more realistic in-body conditions. This includes simulating blood flow, which influences the heat transfer taking place in our control volume. Furthermore, we utilize artery mimicking materials to recreate the conditions of human arterial walls.
Through comprehensive experimentation and accurate temperature measurements using embedded thermocouples, we aim to enhance our understanding of the interactions between Nitinol wires, surrounding tissues, and focused ultrasound heating. An integral part of our investigation is to discern whether the focused ultrasound directly heats the Nitinol wire or if actuation is achieved indirectly by heating the surrounding tissue. These results will offer insights into the applications of shape memory alloys in diverse biomedical settings, potentially paving the way for more effective and safer medical use.