Multi-fidelity uncertainty-aware coronary hemodynamics personalized by CT myocardial perfusion imaging
POSTER
Abstract
This work presents a novel framework for personalized and uncertainty-aware coronary artery bypass graft (CABG) surgical planning that is informed by CT myocardial perfusion imaging. Current computational models of coronary hemodynamics distribute flow amongst coronary arteries based on purely empirical scaling between flow and the size of each artery. However, this does not account for anatomical inaccuracy, patient variability, disease, etc. Patient-specific models also do not incorporate uncertainty stemming from the clinical data they are based on. We demonstrate a framework for improved model personalization by estimating patient-specific and vessel-specific coronary flows from non-invasive myocardial perfusion imaging. We show significantly improved CABG predictions using these personalized models. We also develop an uncertainty-aware personalization framework that accounts for noisy clinical data. We use probabilistic Bayesian estimation of model parameters based on clinical data. We propagate clinical uncertainty into predicted quantities of interest using a novel multi-fidelity uncertainty quantification technique relying on non-linear dimensionality reduction. We demonstrate clinical data-informed confidence intervals with vastly improved precision in the estimated quantities of interest.
*This work was supported by NIH grant 5R01HL141712 and NSF grants #104831 and #2105345. Computing resources were provided by Stanford Research Computing Center.
Publication:K. Menon, M.O. Khan, Z.A. Sexton, J. Richter, P.K. Nguyen, S.B. Malik, J. Boyd, K. Nieman, A.L. Marsden. "Personalized coronary and myocardial blood flow models incorporating CT perfusion imaging and synthetic vascular trees." npj Imaging. 2024;2(1):9.
M. O. Khan, A. A. Seresti, K. Menon, A. L. Marsden and K. Nieman, "Quantification and Visualization of CT Myocardial Perfusion Imaging to Detect Ischemia-Causing Coronary Arteries." IEEE Transactions on Medical Imaging, doi: 10.1109/TMI.2024.3401552.
A. Zanoni, G. Geraci, M. Salvador, K. Menon, A.L. Marsden, D.E. Schiavazzi. "Improved multifidelity Monte Carlo estimators based on normalizing flows and dimensionality reduction techniques." Computer Methods in Applied Mechanics and Engineering, Volume 429, 2024, 117119.
Presenters
Alison L Marsden
Stanford Cardiovascular Institute; Department of Pediatrics (Cardiology), Stanford University
Stanford University
Authors
Karthik Menon
Stanford University
Andrea Zanoni
Stanford University
Owais Khan
Toronto Metropolitan University
Gianluca Geraci
Sandia National Laboratories
Koen Nieman
Stanford University
Daniele E Schiavazzi
University of Notre Dame
Alison L Marsden
Stanford Cardiovascular Institute; Department of Pediatrics (Cardiology), Stanford University
