Fluid-structure interactions of peripheral arteries using a coupled in silico and in vitro approach

Fluid-structure interactions of peripheral arteries using a coupled in silico and in vitro approach

Schoenborn, S. (University of Queensland; Queensland University of Technology)
Lorenz, T. (RWTH Aachen University)
Kuo, K. (RWTH Aachen University)
Fletcher, D. F. (University of Sydney)
Woodruff, M. A. (Queensland University of Technology)
Dr Pirola, S.P. (TU Delft Medical Instruments & Bio-Inspired Technology; Imperial College London)
Allenby, M. C. (University of Queensland; Queensland University of Technology)

2023

Vascular compliance is considered both a cause and a consequence of cardiovascular disease and a significant factor in the mid- and long-term patency of vascular grafts. However, the biomechanical effects of localised changes in compliance cannot be satisfactorily studied with the available medical imaging technologies or surgical simulation materials. To address this unmet need, we developed a coupled silico-vitro platform which allows for the validation of numerical fluid-structure interaction results as a numerical model and physical prototype. This numerical one-way and two-way fluid-structure interaction study is based on a three-dimensional computer model of an idealised femoral artery which is validated against patient measurements derived from the literature. The numerical results are then compared with experimental values collected from compliant arterial phantoms via direct pressurisation and ring tensile testing. Phantoms within a compliance range of 1.4–68.0%/100 mmHg were fabricated via additive manufacturing and silicone casting, then mechanically characterised via ring tensile testing and optical analysis under direct pressurisation with moderately statistically significant differences in measured compliance ranging between 10 and 20% for the two methods. One-way fluid-structure interaction coupling underestimated arterial wall compliance by up to 14.7% compared with two-way coupled models. Overall, Solaris™ (Smooth-On) matched the compliance range of the numerical and in vivo patient models most closely out of the tested silicone materials. Our approach is promising for vascular applications where mechanical compliance is especially important, such as the study of diseases which commonly affect arterial wall stiffness, such as atherosclerosis, and the model-based design, surgical training, and optimisation of vascular prostheses.

Blood flow
Cardiovascular biomechanics
Computational fluid dynamics
Fluid-structure interaction
Peripheral artery disease

http://resolver.tudelft.nl/uuid:3916c81d-8323-4d9d-bc13-b152784ad8f2

https://doi.org/10.1016/j.compbiomed.2023.107474

0010-4825

Computers in Biology and Medicine, 165

Institutional Repository

journal article

© 2023 S. Schoenborn, T. Lorenz, K. Kuo, D. F. Fletcher, M. A. Woodruff, S.P. Dr Pirola, M. C. Allenby