A framework for incorporating 3D hyperelastic vascular wall models in 1D blood flow simulations

We present a novel framework for investigating the role of vascular structure on arterial haemodynamics in large vessels, with a special focus on the human common carotid artery (CCA). The analysis is carried out by adopting a three-dimensional (3D) derived, fibre-reinforced, hyperelastic structural...

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Veröffentlicht in:	Biomechanics and modeling in mechanobiology 2021-08, Vol.20 (4), p.1231-1249
Hauptverfasser:	Coccarelli, Alberto, Carson, Jason M., Aggarwal, Ankush, Pant, Sanjay
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Attenuation Biological and Medical Physics Biomechanical Phenomena Biomedical Engineering and Bioengineering Biophysics Blood flow Blood Flow Velocity - physiology Blood pressure Blood Pressure - physiology Blood vessels Carotid artery Carotid Artery, Common - physiology Computational fluid dynamics Computer applications Distension Elasticity Engineering Fiber reinforced materials Flow simulation Fluid dynamics Hemodynamics Humans Hydrodynamics Imaging, Three-Dimensional - methods Legislation Models, Cardiovascular Original Paper Parameter identification Pressure Prognosis Pulse Wave Analysis Reduced order models Residual stress Sensitivity analysis Structural analysis Structural models Theoretical and Applied Mechanics Wave velocity Waveforms
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creator	Coccarelli, Alberto Carson, Jason M. Aggarwal, Ankush Pant, Sanjay
description	We present a novel framework for investigating the role of vascular structure on arterial haemodynamics in large vessels, with a special focus on the human common carotid artery (CCA). The analysis is carried out by adopting a three-dimensional (3D) derived, fibre-reinforced, hyperelastic structural model, which is coupled with an axisymmetric, reduced order model describing blood flow. The vessel transmural pressure and lumen area are related via a Holzapfel–Ogden type of law, and the residual stresses along the thickness and length of the vessel are also accounted for. After a structural characterization of the adopted hyperelastic model, we investigate the link underlying the vascular wall response and blood-flow dynamics by comparing the proposed framework results against a popular tube law. The comparison shows that the behaviour of the model can be captured by the simpler linear surrogate only if a representative value of compliance is applied. Sobol’s multi-variable sensitivity analysis is then carried out in order to identify the extent to which the structural parameters have an impact on the CCA haemodynamics. In this case, the local pulse wave velocity (PWV) is used as index for representing the arterial transmission capacity of blood pressure waveforms. The sensitivity analysis suggests that some geometrical factors, such as the stress-free inner radius and opening angle, play a major role on the system’s haemodynamics. Subsequently, we quantified the differences in haemodynamic variables obtained from different virtual CCAs, tube laws and flow conditions. Although each artery presents a distinct vascular response, the differences obtained across different flow regimes are not significant. As expected, the linear tube law is unable to accurately capture all the haemodynamic features characterizing the current model. The findings from the sensitivity analysis are further confirmed by investigating the axial stretching effect on the CCA fluid dynamics. This factor does not seem to alter the pressure and flow waveforms. On the contrary, it is shown that, for an axially stretched vessel, the vascular wall exhibits an attenuation in absolute distension and an increase in circumferential stress, corroborating the findings of previous studies. This analysis shows that the new model offers a good balance between computational complexity and physics captured, making it an ideal framework for studies aiming to investigate the profound link between vascula
doi_str_mv	10.1007/s10237-021-01437-5
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The analysis is carried out by adopting a three-dimensional (3D) derived, fibre-reinforced, hyperelastic structural model, which is coupled with an axisymmetric, reduced order model describing blood flow. The vessel transmural pressure and lumen area are related via a Holzapfel–Ogden type of law, and the residual stresses along the thickness and length of the vessel are also accounted for. After a structural characterization of the adopted hyperelastic model, we investigate the link underlying the vascular wall response and blood-flow dynamics by comparing the proposed framework results against a popular tube law. The comparison shows that the behaviour of the model can be captured by the simpler linear surrogate only if a representative value of compliance is applied. Sobol’s multi-variable sensitivity analysis is then carried out in order to identify the extent to which the structural parameters have an impact on the CCA haemodynamics. In this case, the local pulse wave velocity (PWV) is used as index for representing the arterial transmission capacity of blood pressure waveforms. The sensitivity analysis suggests that some geometrical factors, such as the stress-free inner radius and opening angle, play a major role on the system’s haemodynamics. Subsequently, we quantified the differences in haemodynamic variables obtained from different virtual CCAs, tube laws and flow conditions. Although each artery presents a distinct vascular response, the differences obtained across different flow regimes are not significant. As expected, the linear tube law is unable to accurately capture all the haemodynamic features characterizing the current model. The findings from the sensitivity analysis are further confirmed by investigating the axial stretching effect on the CCA fluid dynamics. This factor does not seem to alter the pressure and flow waveforms. 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The analysis is carried out by adopting a three-dimensional (3D) derived, fibre-reinforced, hyperelastic structural model, which is coupled with an axisymmetric, reduced order model describing blood flow. The vessel transmural pressure and lumen area are related via a Holzapfel–Ogden type of law, and the residual stresses along the thickness and length of the vessel are also accounted for. After a structural characterization of the adopted hyperelastic model, we investigate the link underlying the vascular wall response and blood-flow dynamics by comparing the proposed framework results against a popular tube law. The comparison shows that the behaviour of the model can be captured by the simpler linear surrogate only if a representative value of compliance is applied. Sobol’s multi-variable sensitivity analysis is then carried out in order to identify the extent to which the structural parameters have an impact on the CCA haemodynamics. In this case, the local pulse wave velocity (PWV) is used as index for representing the arterial transmission capacity of blood pressure waveforms. The sensitivity analysis suggests that some geometrical factors, such as the stress-free inner radius and opening angle, play a major role on the system’s haemodynamics. Subsequently, we quantified the differences in haemodynamic variables obtained from different virtual CCAs, tube laws and flow conditions. Although each artery presents a distinct vascular response, the differences obtained across different flow regimes are not significant. As expected, the linear tube law is unable to accurately capture all the haemodynamic features characterizing the current model. The findings from the sensitivity analysis are further confirmed by investigating the axial stretching effect on the CCA fluid dynamics. This factor does not seem to alter the pressure and flow waveforms. On the contrary, it is shown that, for an axially stretched vessel, the vascular wall exhibits an attenuation in absolute distension and an increase in circumferential stress, corroborating the findings of previous studies. This analysis shows that the new model offers a good balance between computational complexity and physics captured, making it an ideal framework for studies aiming to investigate the profound link between vascular mechanobiology and blood flow.</description><subject>Algorithms</subject><subject>Attenuation</subject><subject>Biological and Medical Physics</subject><subject>Biomechanical Phenomena</subject><subject>Biomedical Engineering and Bioengineering</subject><subject>Biophysics</subject><subject>Blood flow</subject><subject>Blood Flow Velocity - physiology</subject><subject>Blood pressure</subject><subject>Blood Pressure - physiology</subject><subject>Blood vessels</subject><subject>Carotid artery</subject><subject>Carotid Artery, Common - physiology</subject><subject>Computational fluid dynamics</subject><subject>Computer applications</subject><subject>Distension</subject><subject>Elasticity</subject><subject>Engineering</subject><subject>Fiber reinforced materials</subject><subject>Flow simulation</subject><subject>Fluid dynamics</subject><subject>Hemodynamics</subject><subject>Humans</subject><subject>Hydrodynamics</subject><subject>Imaging, Three-Dimensional - 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The analysis is carried out by adopting a three-dimensional (3D) derived, fibre-reinforced, hyperelastic structural model, which is coupled with an axisymmetric, reduced order model describing blood flow. The vessel transmural pressure and lumen area are related via a Holzapfel–Ogden type of law, and the residual stresses along the thickness and length of the vessel are also accounted for. After a structural characterization of the adopted hyperelastic model, we investigate the link underlying the vascular wall response and blood-flow dynamics by comparing the proposed framework results against a popular tube law. The comparison shows that the behaviour of the model can be captured by the simpler linear surrogate only if a representative value of compliance is applied. Sobol’s multi-variable sensitivity analysis is then carried out in order to identify the extent to which the structural parameters have an impact on the CCA haemodynamics. In this case, the local pulse wave velocity (PWV) is used as index for representing the arterial transmission capacity of blood pressure waveforms. The sensitivity analysis suggests that some geometrical factors, such as the stress-free inner radius and opening angle, play a major role on the system’s haemodynamics. Subsequently, we quantified the differences in haemodynamic variables obtained from different virtual CCAs, tube laws and flow conditions. Although each artery presents a distinct vascular response, the differences obtained across different flow regimes are not significant. As expected, the linear tube law is unable to accurately capture all the haemodynamic features characterizing the current model. The findings from the sensitivity analysis are further confirmed by investigating the axial stretching effect on the CCA fluid dynamics. This factor does not seem to alter the pressure and flow waveforms. On the contrary, it is shown that, for an axially stretched vessel, the vascular wall exhibits an attenuation in absolute distension and an increase in circumferential stress, corroborating the findings of previous studies. This analysis shows that the new model offers a good balance between computational complexity and physics captured, making it an ideal framework for studies aiming to investigate the profound link between vascular mechanobiology and blood flow.</abstract><cop>Berlin/Heidelberg</cop><pub>Springer Berlin Heidelberg</pub><pmid>33683514</pmid><doi>10.1007/s10237-021-01437-5</doi><tpages>19</tpages><orcidid>https://orcid.org/0000-0003-1511-9015</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Algorithms Attenuation Biological and Medical Physics Biomechanical Phenomena Biomedical Engineering and Bioengineering Biophysics Blood flow Blood Flow Velocity - physiology Blood pressure Blood Pressure - physiology Blood vessels Carotid artery Carotid Artery, Common - physiology Computational fluid dynamics Computer applications Distension Elasticity Engineering Fiber reinforced materials Flow simulation Fluid dynamics Hemodynamics Humans Hydrodynamics Imaging, Three-Dimensional - methods Legislation Models, Cardiovascular Original Paper Parameter identification Pressure Prognosis Pulse Wave Analysis Reduced order models Residual stress Sensitivity analysis Structural analysis Structural models Theoretical and Applied Mechanics Wave velocity Waveforms
title	A framework for incorporating 3D hyperelastic vascular wall models in 1D blood flow simulations
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