Your search keyword '"Lee LC"' showing total 2 results

1. Heterogeneous growth-induced prestrain in the heart

Author

Genet, M, Rausch, MK, Lee, LC, Choy, S, Zhao, X, Kassab, GS, Kozerke, S, Guccione, JM, and Kuhl, E

Subjects

Heart Disease, Cardiovascular, Animals, Arteries, Biomechanical Phenomena, Female, Finite Element Analysis, Heart Ventricles, Humans, Male, Models, Animal, Models, Cardiovascular, Stress, Mechanical, Swine, Ventricular Function, Residual stress, Prestrain, Opening angle, Patient-specific modeling, Finite element method, Finite strain, Biomedical Engineering, Mechanical Engineering, Human Movement and Sports Sciences

Abstract

Even when entirely unloaded, biological structures are not stress-free, as shown by Y.C. Fung׳s seminal opening angle experiment on arteries and the left ventricle. As a result of this prestrain, subject-specific geometries extracted from medical imaging do not represent an unloaded reference configuration necessary for mechanical analysis, even if the structure is externally unloaded. Here we propose a new computational method to create physiological residual stress fields in subject-specific left ventricular geometries using the continuum theory of fictitious configurations combined with a fixed-point iteration. We also reproduced the opening angle experiment on four swine models, to characterize the range of normal opening angle values. The proposed method generates residual stress fields which can reliably reproduce the range of opening angles between 8.7±1.8 and 16.6±13.7 as measured experimentally. We demonstrate that including the effects of prestrain reduces the left ventricular stiffness by up to 40%, thus facilitating the ventricular filling, which has a significant impact on cardiac function. This method can improve the fidelity of subject-specific models to improve our understanding of cardiac diseases and to optimize treatment options.

Published

2015

2. A computational model that predicts reverse growth in response to mechanical unloading

Author

Lee, LC, Genet, M, Acevedo-Bolton, G, Ordovas, K, Guccione, JM, and Kuhl, E

Subjects

Engineering, Biomedical Engineering, Cardiovascular, Bioengineering, Biomechanical Phenomena, Elasticity, Heart Ventricles, Humans, Models, Cardiovascular, Pressure, Stress, Mechanical, Weight-Bearing, Remodeling, Reverse remodeling, Growth, End-diastolic pressure-volume relationship, Finite element method, Magnetic resonance imaging, Mechanical Engineering, Biomedical engineering

Abstract

Ventricular growth is widely considered to be an important feature in the adverse progression of heart diseases, whereas reverse ventricular growth (or reverse remodeling) is often considered to be a favorable response to clinical intervention. In recent years, a number of theoretical models have been proposed to model the process of ventricular growth while little has been done to model its reverse. Based on the framework of volumetric strain-driven finite growth with a homeostatic equilibrium range for the elastic myofiber stretch, we propose here a reversible growth model capable of describing both ventricular growth and its reversal. We used this model to construct a semi-analytical solution based on an idealized cylindrical tube model, as well as numerical solutions based on a truncated ellipsoidal model and a human left ventricular model that was reconstructed from magnetic resonance images. We show that our model is able to predict key features in the end-diastolic pressure-volume relationship that were observed experimentally and clinically during ventricular growth and reverse growth. We also show that the residual stress fields generated as a result of differential growth in the cylindrical tube model are similar to those in other nonidentical models utilizing the same geometry.

Published

2015