Incorporating vessel taper and compliance properties in Navier-Stokes based blood flow models

Ye, Guo-Fan; Moore, Thomas W.; Jaron, Dov

doi:10.1007/bf02367605

Ann Biomed Eng

1993

DOI: 10.1007/bf02367605

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Incorporating vessel taper and compliance properties in Navier-Stokes based blood flow models

Guo-Fan Ye

Thomas W. Moore

Dov Jaron

Abstract: A popular and useful technique used to model blood flow in cardiovascular simulations is to divide each blood vessel into a series of segments, each with its own lumped resistance, inertance, and compliance parameters. The values of these parameters are usually obtained through a simplification of the Navier-Stokes equations for fluid flow. However, the simplification often ignores the nonlinear and convective terms of the equations, resulting in errors in the parameter values, especially in the value found fo… Show more

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Cited by 7 publications

(1 citation statement)

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“…However, the computational cost of the WK model is significantly lower. Ye reported that the simplification of the WK model often ignores the nonlinear and convective term of the Navier-Stokes equations, resulting in errors in the parameter values19. Therefore, the authors considered the effects of the vessel taper and compliance when calculating the vessel resistance.…”

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Patient-specific structural effects on hemodynamics in the ischemic lower limb artery

Liu

Song³

et al. 2016

Sci Rep

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Lower limb peripheral artery disease is a prevalent chronic non-communicable disease without obvious symptoms. However, the effect of ischemic lower limb peripheral arteries on hemodynamics remains unclear. In this study, we investigated the variation of the hemodynamics caused by patient-specific structural artery characteristics. Computational fluid dynamic simulations were performed on seven lower limb (including superficial femoral, deep femoral and popliteal) artery models that were reconstructed from magnetic resonance imaging. We found that increased wall shear stress (WSS) was mainly caused by the increasing severity of stenosis, bending, and branching. Our results showed that the increase in the WSS value at a stenosis at the bifurcation was 2.7 Pa. In contrast, the isolated stenosis and branch caused a WSS increase of 0.7 Pa and 0.5 Pa, respectively. The WSS in the narrow popliteal artery was more sensitive to a reduction in radius. Our results also demonstrate that the distribution of the velocity and pressure gradient are highly structurally related. At last, Ultrasound Doppler velocimeter measured result was presented as a validation. In conclusion, the distribution of hemodynamics may serve as a supplement for clinical decision-making to prevent the occurrence of a morbid or mortal ischemic event.

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mentioning

confidence: 99%

Patient-specific structural effects on hemodynamics in the ischemic lower limb artery

Liu

Song³

et al. 2016

Sci Rep

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In Vitro and finite-element model investigation of the conductance technique for measurement of aortic segmental volume

et al. 1996

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This investigation examined the feasibility of applying the conductance catheter technique for measurement of absolute aortic segmental volume. Aortic segment volume was estimated simultaneously in vitro by using the conductance catheter technique and sonomicrometer crystals. Experiments were performed in five isolated canine aortas. Vessel diameter and pressure were altered, as were the conductive properties of the surrounding medium. In addition, a three-dimensional finite-element model of the vessel and apparatus was developed to examine the electric field and parallel conductance volume under different experimental conditions. The results indicated that in the absence of parallel conductance volume, the conductance catheter technique predicted absolute changes in segmental volumes and segmental pressure-volume relationships that agreed closely with those determined by sonomicrometry. The introduction of parallel conductance volume added a significant offset error to measurements of volume made with the conductance catheter that were nonlinearly related to the conductive properties of the surrounding medium. The finite-element model was able to predict measured resistance and parallel conductance volume, which correlated strongly with those measured in vitro. The results imply that absolute segmental volume and distensibility may be determined only if the parallel conductance volume is known. If the offset volume is not known precisely, the conductance catheter technique may still be applied to measure absolute changes in aortic segmental volume and compliance.

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Accuracy of the inverse womersley method for the calculation of hemodynamic variables

Cezeaux

Grondelle

1997

Ann Biomed Eng

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We have studied the accuracy of the inverse Womersley method, a linear theory for the calculation of hemodynamic variables from measured volumetric flow rate or centerline velocity, for two canine arteries with different degrees of arterial wall motion and taper. The results from the linear theory are compared with the estimates from the nonlinear theory of Ling and Atabek for a canine thoracic aorta and femoral artery. For the thoracic aorta, the linear theory underestimates the mean wall shear stress by as much as 77%, when compared with the nonlinear theory. For the femoral artery, on the other hand, the mean wall shear stress value is underestimated by as much as 23%. Estimates of other hemodynamic variables show similar discrepancies between the nonlinear and linear theories. Thus, the inverse Womersley method does not give accurate estimates of hemodynamic quantities. This failure results from the neglect of convective accelerations due to arterial wall motion and taper, with the neglect of arterial taper leading to the largest errors.

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Incorporating vessel taper and compliance properties in Navier-Stokes based blood flow models

Cited by 7 publications

References 20 publications

Patient-specific structural effects on hemodynamics in the ischemic lower limb artery

Patient-specific structural effects on hemodynamics in the ischemic lower limb artery

In Vitro and finite-element model investigation of the conductance technique for measurement of aortic segmental volume

Accuracy of the inverse womersley method for the calculation of hemodynamic variables

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