Modelling coronary flows: impact of differently measured inflow boundary conditions on vessel-specific computational hemodynamic profiles

Maurizio Lodi Rizzini; Alessandro Candreva; Claudio Chiastra; Emanuele Gallinoro; Karol Calò; Fabrizio D'Ascenzo; Bernard De Bruyne; Takuya Mizukami; Carlos Collet; Diego Gallo; Umberto Morbiducci

doi:10.1016/j.cmpb.2022.106882

Modelling coronary flows: impact of differently measured inflow boundary conditions on vessel-specific computational hemodynamic profiles

Comput Methods Programs Biomed. 2022 Jun:221:106882. doi: 10.1016/j.cmpb.2022.106882. Epub 2022 May 13.

Affiliations

¹ Polito(BIO)Med Lab, Department of Mechanical and Aerospace Engineering, Politecnico di Torino, Torino, Italy.
² Polito(BIO)Med Lab, Department of Mechanical and Aerospace Engineering, Politecnico di Torino, Torino, Italy; Department of Cardiology, Zurich University Hospital, Zurich, Switzerland.
³ Cardiovascular Center Aalst, OLV-Clinic, Aalst, Belgium.
⁴ Hemodynamic Laboratory, Department of Medical Sciences, University of Turin, Turin, Italy.
⁵ Polito(BIO)Med Lab, Department of Mechanical and Aerospace Engineering, Politecnico di Torino, Torino, Italy. Electronic address: diego.gallo@polito.it.

PMID: 35597205
DOI: 10.1016/j.cmpb.2022.106882

Abstract

Background and objectives: The translation of hemodynamic quantities based on wall shear stress (WSS) or intravascular helical flow into clinical biomarkers of coronary atherosclerotic disease is still hampered by the assumptions/idealizations required by the computational fluid dynamics (CFD) simulations of the coronary hemodynamics. In the resulting budget of uncertainty, inflow boundary conditions (BCs) play a primary role. Accordingly, in this study we investigated the impact of the approach adopted for in vivo coronary artery blood flow rate assessment on personalized CFD simulations where blood flow rate is used as inflow BC.

Methods: CFD simulations were carried out on coronary angiograms by applying personalized inflow BCs derived from four different techniques assessing in vivo surrogates of flow rate: continuous thermodilution, intravascular Doppler, frame count-based 3D contrast velocity, and diameter-based scaling law. The impact of inflow BCs on coronary hemodynamics was evaluated in terms of WSS- and helicity-based quantities.

Results: As main findings, we report that: (i) coronary flow rate values may differ based on the applied flow derivation technique, as continuous thermodilution provided higher flow rate values than intravascular Doppler and diameter-based scaling law (p = 0.0014 and p = 0.0023, respectively); (ii) such intrasubject differences in flow rate values lead to different surface-averaged values of WSS magnitude and helical blood flow intensity (p<0.0020); (iii) luminal surface areas exposed to low WSS and helical flow topological features showed robustness to the flow rate values.

Conclusions: Although the absence of a clinically applicable gold standard approach prevents a general recommendation for one coronary blood flow rate derivation technique, our findings indicate that the inflow BC may impact computational hemodynamic results, suggesting that a standardization would be desirable to provide comparable results among personalized CFD simulations of the coronary hemodynamics.

Keywords: Computational hemodynamics; Coronary artery; Flow rate measurement techniques; Helical flow; Inflow boundary conditions; Intravascular Doppler; Thermodilution; Uncertainty of cardiovascular models; Wall shear stress.

MeSH terms

Blood Flow Velocity
Coronary Artery Disease*
Hemodynamics / physiology
Humans
Hydrodynamics
Models, Cardiovascular*
Stress, Mechanical