论文信息 - Multiphysics modeling in support of ultrasonic image development: Integration of fluid-structure interaction simulations and Field II applied to the carotid artery

Multiphysics modeling in support of ultrasonic image development: Integration of fluid-structure interaction simulations and Field II applied to the carotid artery

Previously, we proposed a multiphysics model coupling computational fluid dynamics (CFD) and Field II, allowing assessment of the performance of current and new blood flow estimators (e.g. color flow imaging=CFI, PW Doppler, speckle tracking, vector Doppler) in the carotid artery against ground truth information retrieved from CFD. Important limitations however were the rigid walls and the absence of the arterial wall and surrounding tissue in the simulations. The aim of this study was to improve and expand the model to a more realistic setup of a distensible carotid artery embedded in surrounding tissue. For this purpose, we integrated fluid-structure interaction (FSI) simulations with an ultrasound simulator (Field II), which allows comparison of the ultrasound (US) images with the input data from FSI. Field II represents tissue as random points on which ultrasound waves reflect and whose position can be updated based on the flow field and vessel wall deformation from FSI.We simulated the RF-signal of a patient-specific carotid bifurcation, including the blood pool as well as the vessel wall and surrounding tissue. Realism of the multiphysics model was demonstrated with duplex images.

[1] J. Jensen,et al. Calculation of pressure fields from arbitrarily shaped, apodized, and excited ultrasound transducers , 1992, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[2] K. Bathe,et al. Performance of a new partitioned procedure versus a monolithic procedure in fluid-structure interaction , 2009 .

[3] K. Boone,et al. Effect of skin impedance on image quality and variability in electrical impedance tomography: a model study , 1996, Medical and Biological Engineering and Computing.

[4] H. Torp,et al. Ultrasound simulation of complex flow velocity fields based on computational fluid dynamics , 2009, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[5] Jan Vierendeels,et al. A simulation environment for validating ultrasonic blood flow and vessel wall imaging based on fluid-structure interaction simulations: ultrasonic assessment of arterial distension and wall shear rate. , 2010, Medical physics.

[6] Patrick Segers,et al. Assessment of Numerical Simulation Strategies for Ultrasonic Color Blood Flow Imaging, Based on a Computer and Experimental Model of the Carotid Artery , 2009, Annals of Biomedical Engineering.

[7] J. Arendt. Paper presented at the 10th Nordic-Baltic Conference on Biomedical Imaging: Field: A Program for Simulating Ultrasound Systems , 1996 .