A Computer Reconstruction of the Entire Coronary Arterial Tree Based on Detailed Morphometric Data

Mittal, Nishant; Zhou, Yi; Ung, Sonky; Linares, Carlos; Molloi, Sabee; Kassab, Ghassan S.

doi:10.1007/s10439-005-5758-z

Cited by 63 publications

(53 citation statements)

References 23 publications

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“…The impedance boundary conditions are computed through a Womersley-type model at every flow outlet. Both models are based on the measured morphometric data of Kassab et al (15,20). This is the first investigation to implement the time-domain model coupled with the frequencydomain model in the entire coronary arterial tree on the basis of experimentally measured morphometric data of the entire coronary arterial tree.…”

Section: Discussionmentioning

confidence: 99%

A hybrid one-dimensional/Womersley model of pulsatile blood flow in the entire coronary arterial tree

Huo

Kassab²

2007

American Journal of Physiology-Heart and Circulatory Physiology

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Huo Y, Kassab GS. A hybrid one-dimensional/Womersley model of pulsatile blood flow in the entire coronary arterial tree. Am J Physiol Heart Circ Physiol 292: H2623-H2633, 2007. First published January 5, 2007; doi:10.1152/ajpheart.00987.2006.-Using a frequency-domain Womersley-type model, we previously simulated pulsatile blood flow throughout the coronary arterial tree. Although this model represents a good approximation for the smaller vessels, it does not take into account the nonlinear convective energy losses in larger vessels. Here, using Womersley's theory, we present a hybrid model that considers the nonlinear effects for the larger epicardial arteries while simulating the distal vessels (down to the 1st capillary segments) with the use of Womersley's Theory. The main trunk and primary branches were discretized and modeled with one-dimensional Navier-Stokes equations, while the smaller-diameter vessels were treated as Womersley-type vessels. Energy losses associated with vessel bifurcations were incorporated in the present analysis. The formulation enables prediction of impedance and pressure and pulsatile flow distribution throughout the entire coronary arterial tree down to the first capillary segments in the arrested, vasodilated state. We found that the nonlinear convective term is negligible and the loss of energy at a bifurcation is small in the larger epicardial vessels of an arrested heart. Furthermore, we found that the flow waves along the trunk or at the primary branches tend to scale (normalized with respect to their mean values) to a single curve, except for a small phase angle difference. Finally, the model predictions for the inlet pressure and flow waves are in excellent agreement with previously published experimental results. This hybrid one-dimensional/Womersley model is an efficient approach that captures the essence of the hemodynamics of a complex large-scale vascular network. The present model has numerous applications to understanding the dynamics of coronary circulation. coronary flow; pulse wave; admittance; impedance THE FLUID DYNAMIC APPROACH uses the geometry and mechanical properties of the vasculature and the principles of conservation of mass and momentum to obtain the blood flow-pressure relation. The solution of such equations yields information on instantaneous velocity and pressure distributions. The fluid dynamic approach was first formulated in 1755 by Euler. Womersley (32,33) and McDonald [as reported by Nichols and O'Rourke (22)] linearized Euler's equation and presented the theory and solution in great detail. Because of the complexity of the vascular architecture, however, this approach recognizes that it is necessary to idealize the geometry of the vasculature.The frequency-domain Womersley-type approach was recently applied to the entire coronary arterial tree down to the first segment of (arterial) capillaries in a vasodilated, potassiumarrested heart (7). Inasmuch as this approach represents a linearization of the fluid dynamic (time-domain) approach, it ign...

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Section: Discussionmentioning

confidence: 99%

A hybrid one-dimensional/Womersley model of pulsatile blood flow in the entire coronary arterial tree

Huo

Kassab²

2007

American Journal of Physiology-Heart and Circulatory Physiology

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“…The morphometric and mechanical parameters used for the computation of the pulsatile flow through the arterial tree were adopted from our previous publications (13,19,22). The length and diameter of every vessel segment were assigned to the entire coronary arterial tree (22), on the basis of detailed morphometric data. The blood flow density () in the coronary arterial tree was assumed to be 1.23 g/cm 3 (8).…”

Section: Methods Of Solutionmentioning

confidence: 99%

“…Figure 14 shows a comparison of the measured pressure-crosssectional area (pressure-CSA) relationship between these two models. Figure 7 shows a comparison of the flow waves when these two models are implemented in the entire coronary arterial trees (22). Although there is a phase angle and amplitude difference between the results, it is found the mean flow rates are similar.…”

Section: Z͑00͒ ϭ Limmentioning

confidence: 99%

“…Kassab et al (17,18,20) have previously measured the morphometric data of the coronary vasculature. Recently, a computer model of the entire coronary arterial tree has been developed by Mittal et al (22) based on measured morphometric data of Kassab et al (20). This model will serve as the platform for the present systematic pulse pressure and flow wave transmission analysis.…”

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confidence: 99%

“…Here, we shall use the platform of the entire coronary arterial tree (22) to carry out a Womersley-type numerical analysis of pulse wave transmission. The constitutive equation that relates pressure to cross-sectional area for the several largest orders is based on experimental data (19).…”

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Pulsatile blood flow in the entire coronary arterial tree: theory and experiment

Huo¹,

Kassab²

2006

American Journal of Physiology-Heart and Circulatory Physiology

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Huo, Yunlong, and Ghassan S. Kassab. Pulsatile blood flow in the entire coronary arterial tree: theory and experiment. Am J Physiol Heart Circ Physiol 291: H1074 -H1087, 2006. First published April 14, 2006 doi:10.1152/ajpheart.00200.2006.-The pulsatility of coronary circulation can be accurately simulated on the basis of the measured branching pattern, vascular geometry, and material properties of the coronary vasculature. A Womersley-type mathematical model is developed to analyze pulsatile blood flow in diastole in the absence of vessel tone in the entire coronary arterial tree on the basis of previously measured morphometric data. The model incorporates a constitutive equation of pressure and cross-section area relation based on our previous experimental data. The formulation enables the prediction of the impedance, the pressure distribution, and the pulsatile flow distribution throughout the entire coronary arterial tree. The model is validated by experimental measurements in six diastolic arrested, vasodilated porcine hearts. The agreement between theory and experiment is excellent. Furthermore, the present pulse wave results at low frequency agree very well with previously published steady-state model. Finally, the phase angle of flow is seen to decrease along the trunk of the major coronary artery and primary branches toward the capillary vessels. This study represents the first, most extensive validated analysis of Womersley-type pulse wave transmission in the entire coronary arterial tree down to the first segment of capillaries. The present model will serve to quantitatively test various hypotheses in the coronary circulation under pulsatile flow conditions. pulse wave transmission; Womersley's method; impedance; admittance; Fourier transform THE BLOOD FLOW in the coronary arteries is very pulsatile with zero or even reversing (negative) flow in systole. The two major determinants of coronary flow pulsatility are 1) the pulsatile aortic pressure, and 2) the myocardial/vascular interaction in systole. To understand coronary blood flow, we must understand each of these two effects. Because the former is simpler, it is the logical starting point. Hence, the objective of the present study is to develop a validated mathematical model of pulsatile blood flow in the entire coronary arterial tree in diastole in the absence of vessel tone. Kassab et al. (17,18,20) have previously measured the morphometric data of the coronary vasculature. Recently, a computer model of the entire coronary arterial tree has been developed by Mittal et al. (22) based on measured morphometric data of Kassab et al. (20). This model will serve as the platform for the present systematic pulse pressure and flow wave transmission analysis.

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Branching Pattern of the Cerebral Arterial Tree

Helthuis

Doormaal

Hillen

et al. 2018

The Anatomical Record

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Quantitative data on branching patterns of the human cerebral arterial tree are lacking in the 1.0–0.1 mm radius range. We aimed to collect quantitative data in this range, and to study if the cerebral artery tree complies with the principle of minimal work (Law of Murray). To enable easy quantification of branching patterns a semi‐automatic method was employed to measure 1,294 bifurcations and 2,031 segments on 7 T‐MRI scans of two corrosion casts embedded in a gel. Additionally, to measure segments with a radius smaller than 0.1 mm, 9.4 T‐MRI was used on a small cast section to characterize 1,147 bifurcations and 1,150 segments. Besides MRI, traditional methods were employed. Seven hundred thirty‐three bifurcations were manually measured on a corrosion cast and 1,808 bifurcations and 1,799 segment lengths were manually measured on a fresh dissected cerebral arterial tree. Data showed a large variation in branching pattern parameters (asymmetry‐ratio, area‐ratio, length‐radius‐ratio, tapering). Part of the variation may be explained by the variation in measurement techniques, number of measurements and location of measurement in the vascular tree. This study confirms that the cerebral arterial tree complies with the principle of minimum work. These data are essential in the future development of more accurate mathematical blood flow models. Anat Rec, 302:1434–1446, 2019. © 2018 The Authors. The Anatomical Record published by Wiley Periodicals, Inc. on behalf of American Association of Anatomists.

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A Computer Reconstruction of the Entire Coronary Arterial Tree Based on Detailed Morphometric Data

Cited by 63 publications

References 23 publications

A hybrid one-dimensional/Womersley model of pulsatile blood flow in the entire coronary arterial tree

A hybrid one-dimensional/Womersley model of pulsatile blood flow in the entire coronary arterial tree

Pulsatile blood flow in the entire coronary arterial tree: theory and experiment

Branching Pattern of the Cerebral Arterial Tree

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