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The influence of inlet velocity profile on predicted flow in type B aortic dissection

Chlӧe H. Armour, Baolei Guo, Selene Pirola, Simone Saitta, Yifan Liu, Zhihui Dong, Xiao Yun Xu

2020Biomechanics and Modeling in Mechanobiology86 citationsDOIOpen Access PDF

Abstract

In order for computational fluid dynamics to provide quantitative parameters to aid in the clinical assessment of type B aortic dissection, the results must accurately mimic the hemodynamic environment within the aorta. The choice of inlet velocity profile (IVP) therefore is crucial; however, idealised profiles are often adopted, and the effect of IVP on hemodynamics in a dissected aorta is unclear. This study examined two scenarios with respect to the influence of IVP-using (a) patient-specific data in the form of a three-directional (3D), through-plane (TP) or flat IVP; and (b) non-patient-specific flow waveform. The results obtained from nine simulations using patient-specific data showed that all forms of IVP were able to reproduce global flow patterns as observed with 4D flow magnetic resonance imaging. Differences in maximum velocity and time-averaged wall shear stress near the primary entry tear were up to 3% and 6%, respectively, while pressure differences across the true and false lumen differed by up to 6%. More notable variations were found in regions of low wall shear stress when the primary entry tear was close to the left subclavian artery. The results obtained with non-patient-specific waveforms were markedly different. Throughout the aorta, a 25% reduction in stroke volume resulted in up to 28% and 35% reduction in velocity and wall shear stress, respectively, while the shape of flow waveform had a profound influence on the predicted pressure. The results of this study suggest that 3D, TP and flat IVPs all yield reasonably similar velocity and time-averaged wall shear stress results, but TP IVPs should be used where possible for better prediction of pressure. In the absence of patient-specific velocity data, effort should be made to acquire patient's stroke volume and adjust the applied IVP accordingly.

Topics & Concepts

Shear stressAortaWaveformMechanicsHemodynamicsFlow velocityLumen (anatomy)Pressure dropMaterials scienceFlow (mathematics)GeologyCardiologyPhysicsMedicineInternal medicineQuantum mechanicsVoltageAortic Disease and Treatment ApproachesAortic aneurysm repair treatmentsCardiac Valve Diseases and Treatments