Patient-Specific Multiscale Modeling of Blood Flow for Coronary Artery Bypass Graft Surgery

Sankaran, Sethuraman; Esmaily, Mahdi; Kahn, Andrew; Tseng, Elaine; Guccione, Julius M.; Marsden, Alison L.

doi:10.1007/s10439-012-0579-3

Cited by 190 publications

(173 citation statements)

References 52 publications

(67 reference statements)

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“…7,8 Many prior studies report WSS as an important parameter for comparison of different anatomies and clinical scenarios. [9][10][11][12] This measure partly accounts for the time-history of red blood cell exposure to altered shear conditions. In this context, RT calculation is a measure of the degree of fluid entrapment in a specific region, providing a time scale for the thrombus formation process to occur.…”

Section: Introductionmentioning

confidence: 99%

A non-discrete method for computation of residence time in fluid mechanics simulations

2013

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Cardiovascular simulations provide a promising means to predict risk of thrombosis in grafts, devices, and surgical anatomies in adult and pediatric patients. Although the pathways for platelet activation and clot formation are not yet fully understood, recent findings suggest that thrombosis risk is increased in regions of flow recirculation and high residence time (RT). Current approaches for calculating RT are typically based on releasing a finite number of Lagrangian particles into the flow field and calculating RT by tracking their positions. However, special care must be taken to achieve temporal and spatial convergence, often requiring repeated simulations. In this work, we introduce a non-discrete method in which RT is calculated in an Eulerian framework using the advection-diffusion equation. We first present the formulation for calculating residence time in a given region of interest using two alternate definitions. The physical significance and sensitivity of the two measures of RT are discussed and their mathematical relation is established. An extension to a point-wise value is also presented. The methods presented here are then applied in a 2D cavity and two representative clinical scenarios, involving shunt placement for single ventricle heart defects and Kawasaki disease. In the second case study, we explored the relationship between RT and wall shear stress, a parameter of particular importance in cardiovascular disease. C 2013 AIP Publishing LLC. [http://dx

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Section: Introductionmentioning

confidence: 99%

A non-discrete method for computation of residence time in fluid mechanics simulations

2013

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“…(3) [24]. The initial outlet coronary artery flow rate under hyperemic conditions was estimated as 5.2 ml/s from a 4-fold greater flow rate under basal conditions at 1.3 ml/s [24,29]. The physiological data, e.g., SBP, DBP, heart rate(HR) are listed in Table 1.…”

Section: Numerical Boundary Conditions and Assumptionsmentioning

confidence: 99%

“…This was split in to the coronary arterial resistance, coronary capillary resistance, and coronary venal resistance, in dicated by   ,   and   , respectively. Values of   = 0.32·  ,   = 0.52·   , and Rcv = 0.16·  were imposed [19,29]. Total coronary capacitance,   , was split in to coronary arterial capacitance   and intramyocardial capacitance   , respectively.…”

Section: Numerical Boundary Conditions and Assumptionsmentioning

confidence: 99%

The Influences of Swirl Flow on Fractional Flow Reserve in Mild/Moderate/Severe Stenotic Coronary Arterial Models

Lee¹,

Kim²,

Ryu³

et al. 2017

Journal of computational fluids engineering

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“…CABG surgery is performed to revascularize diseased coronary arteries, using (in order of preference) arterial, venous, or synthetic grafts. Vein grafts, used in 70% of CABG procedures, have failure rates as high as 10-40% within 1 yr and more than 50% within 10 yr [1,2]. An increasing number of patients undergoing these procedures thus require repeat procedures, which carry higher morbidity and mortality rates [3,4].…”

Section: Introductionmentioning

confidence: 99%

Computational Simulation of the Adaptive Capacity of Vein Grafts in Response to Increased Pressure

Ramachandra

Sankaran

Humphrey

et al. 2015

Journal of Biomechanical Engineering

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Vein maladaptation, leading to poor long-term patency, is a serious clinical problem in patients receiving coronary artery bypass grafts (CABGs) or undergoing related clinical procedures that subject veins to elevated blood flow and pressure. We propose a computational model of venous adaptation to altered pressure based on a constrained mixture theory of growth and remodeling (G&R). We identify constitutive parameters that optimally match biaxial data from a mouse vena cava, then numerically subject the vein to altered pressure conditions and quantify the extent of adaptation for a biologically reasonable set of bounds for G&R parameters. We identify conditions under which a vein graft can adapt optimally and explore physiological constraints that lead to maladaptation. Finally, we test the hypothesis that a gradual, rather than a step, change in pressure will reduce maladaptation. Optimization is used to accelerate parameter identification and numerically evaluate hypotheses of vein remodeling.

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Patient-Specific Multiscale Modeling of Blood Flow for Coronary Artery Bypass Graft Surgery

Cited by 190 publications

References 52 publications

A non-discrete method for computation of residence time in fluid mechanics simulations

A non-discrete method for computation of residence time in fluid mechanics simulations

The Influences of Swirl Flow on Fractional Flow Reserve in Mild/Moderate/Severe Stenotic Coronary Arterial Models

Computational Simulation of the Adaptive Capacity of Vein Grafts in Response to Increased Pressure

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