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Abstract
In the cardiovascular diseased (CVD) conditions, it is essential to choose a suitable rheological model for capturing the correct physics behind the hemodynamic in the multiply afflicted diseased arterial network. This study investigates the effect of blood rheology on hemodynamics in a blood vessel with abdominal aortic aneurysm (AAA) and right internal iliac stenosis (RIIAS). A model with AAA and RIIAS is reconstructed from a human subject’s computed tomography (CT) data. Localized mesh generation and pulsatile inflow condition are considered. Non-Newtonian models such as the Power-law, Carreau, Cross, and Herschel Berkley models are used in simulations. The outcome from a validated computational model is compared with the Newtonian model to identify the suitable model for dealing with pathological complications under consideration. The capabilities and significance of various rheological models are also examined via Wall Pressure (WP), Wall Shear Stress (WSS), velocity, Global non-Newtonian importance factor (IG), Vorticity Streamlines, and Swirling Strength. It is noted that during the entire cardiac cycle, the IG factor of the cross model is found to be relatively more significant. Power Law depicts larger IG factor during peak systole and early diastole. Also, the cross model depicts larger WSS, WPS, swirling strength distribution and vorticity during the peak systolic and diastolic phases It is noted that IG ∼0.02 is an appropriate non-Newtonian blood activity cut-off value in the descending abdominal artery having AAA and RIIAS. The critical important WSS values are in the range of 0–9 Pa which is stated in WSS contour plot.
Acknowledgements
The authors would like to thank the Department of Radiology, Institute of Medical Science, BHU, and Varanasi, India, for providing ethical clearance and data support, as well as the School of Biomedical Engineering, Indian Institute of Technology BHU, Varanasi, for providing ANSYS V.21R and heavy workstation facilities support.
Disclosure statement
The authors show no conflict of interest with anyone.
Data availability statement
We are pleased to submit our manuscript, ‘Effect of rheological models on pulsatile hemodynamics in a multiply afflicted descending human aortic network’ for review by the editorial team of Computer Methods in Biomechanics and Biomedical Engineering. This manuscript has not been available and is not being considered for publication elsewhere.