4-D Computational Modeling of Cardiac Outflow Tract Hemodynamics over Looping Developmental Stages in Chicken Embryos

4-D Computational Modeling of Cardiac Outflow Tract Hemodynamics over Looping Developmental Stages in Chicken Embryos

Cardiogenesis is interdependent with blood flow within the embryonic system. Recently, a number of studies have begun to elucidate the effects of hemodynamic forces acting upon and within cells as the cardiovascular system begins to develop. Changes in flow are picked up by mechanosensors in endocar...

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Main Authors: Katherine Courchaine, MacKenzie J. Gray, Kaitlin Beel, Kent Thornburg, Sandra Rugonyi
Format: Article
Language:English
Published: MDPI AG 2019-02-01
Series:Journal of Cardiovascular Development and Disease
Subjects:
cardiovascular development
computational fluid dynamics
congenital heart defects
hemodynamics
outflow tract
Online Access:https://www.mdpi.com/2308-3425/6/1/11
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spelling doaj-d25dcbd35b964e3ba42fe69265c56da72020-11-24T23:56:45ZengMDPI AGJournal of Cardiovascular Development and Disease2308-34252019-02-01611110.3390/jcdd6010011jcdd60100114-D Computational Modeling of Cardiac Outflow Tract Hemodynamics over Looping Developmental Stages in Chicken EmbryosKatherine Courchaine0MacKenzie J. Gray1Kaitlin Beel2Kent Thornburg3Sandra Rugonyi4Department of Biomedical Engineering, Oregon Health and Science University, Portland, OR 97239, USASchool of Public Health, Portland State University, Portland, OR 97035, USACamas High School, Camas, WA 98607, USAKnight Cardiovascular Institute, Oregon Health and Science University, Portland, OR 97239, USADepartment of Biomedical Engineering, Oregon Health and Science University, Portland, OR 97239, USACardiogenesis is interdependent with blood flow within the embryonic system. Recently, a number of studies have begun to elucidate the effects of hemodynamic forces acting upon and within cells as the cardiovascular system begins to develop. Changes in flow are picked up by mechanosensors in endocardial cells exposed to wall shear stress (the tangential force exerted by blood flow) and by myocardial and mesenchymal cells exposed to cyclic strain (deformation). Mechanosensors stimulate a variety of mechanotransduction pathways which elicit functional cellular responses in order to coordinate the structural development of the heart and cardiovascular system. The looping stages of heart development are critical to normal cardiac morphogenesis and have previously been shown to be extremely sensitive to experimental perturbations in flow, with transient exposure to altered flow dynamics causing severe late stage cardiac defects in animal models. This paper seeks to expand on past research and to begin establishing a detailed baseline for normal hemodynamic conditions in the chick outflow tract during these critical looping stages. Specifically, we will use 4-D (3-D over time) optical coherence tomography to create in vivo geometries for computational fluid dynamics simulations of the cardiac cycle, enabling us to study in great detail 4-D velocity patterns and heterogeneous wall shear stress distributions on the outflow tract endocardium. This information will be useful in determining the normal variation of hemodynamic patterns as well as in mapping hemodynamics to developmental processes such as morphological changes and signaling events during and after the looping stages examined here.https://www.mdpi.com/2308-3425/6/1/11cardiovascular developmentcomputational fluid dynamicscongenital heart defectshemodynamicsoutflow tract
collection DOAJ
language English
format Article
sources DOAJ
author Katherine Courchaine
MacKenzie J. Gray
Kaitlin Beel
Kent Thornburg
Sandra Rugonyi
spellingShingle Katherine Courchaine
MacKenzie J. Gray
Kaitlin Beel
Kent Thornburg
Sandra Rugonyi
4-D Computational Modeling of Cardiac Outflow Tract Hemodynamics over Looping Developmental Stages in Chicken Embryos
Journal of Cardiovascular Development and Disease
cardiovascular development
computational fluid dynamics
congenital heart defects
hemodynamics
outflow tract
author_facet Katherine Courchaine
MacKenzie J. Gray
Kaitlin Beel
Kent Thornburg
Sandra Rugonyi
author_sort Katherine Courchaine
title 4-D Computational Modeling of Cardiac Outflow Tract Hemodynamics over Looping Developmental Stages in Chicken Embryos
title_short 4-D Computational Modeling of Cardiac Outflow Tract Hemodynamics over Looping Developmental Stages in Chicken Embryos
title_full 4-D Computational Modeling of Cardiac Outflow Tract Hemodynamics over Looping Developmental Stages in Chicken Embryos
title_fullStr 4-D Computational Modeling of Cardiac Outflow Tract Hemodynamics over Looping Developmental Stages in Chicken Embryos
title_full_unstemmed 4-D Computational Modeling of Cardiac Outflow Tract Hemodynamics over Looping Developmental Stages in Chicken Embryos
title_sort 4-d computational modeling of cardiac outflow tract hemodynamics over looping developmental stages in chicken embryos
publisher MDPI AG
series Journal of Cardiovascular Development and Disease
issn 2308-3425
publishDate 2019-02-01
description Cardiogenesis is interdependent with blood flow within the embryonic system. Recently, a number of studies have begun to elucidate the effects of hemodynamic forces acting upon and within cells as the cardiovascular system begins to develop. Changes in flow are picked up by mechanosensors in endocardial cells exposed to wall shear stress (the tangential force exerted by blood flow) and by myocardial and mesenchymal cells exposed to cyclic strain (deformation). Mechanosensors stimulate a variety of mechanotransduction pathways which elicit functional cellular responses in order to coordinate the structural development of the heart and cardiovascular system. The looping stages of heart development are critical to normal cardiac morphogenesis and have previously been shown to be extremely sensitive to experimental perturbations in flow, with transient exposure to altered flow dynamics causing severe late stage cardiac defects in animal models. This paper seeks to expand on past research and to begin establishing a detailed baseline for normal hemodynamic conditions in the chick outflow tract during these critical looping stages. Specifically, we will use 4-D (3-D over time) optical coherence tomography to create in vivo geometries for computational fluid dynamics simulations of the cardiac cycle, enabling us to study in great detail 4-D velocity patterns and heterogeneous wall shear stress distributions on the outflow tract endocardium. This information will be useful in determining the normal variation of hemodynamic patterns as well as in mapping hemodynamics to developmental processes such as morphological changes and signaling events during and after the looping stages examined here.
topic cardiovascular development
computational fluid dynamics
congenital heart defects
hemodynamics
outflow tract
url https://www.mdpi.com/2308-3425/6/1/11
work_keys_str_mv AT katherinecourchaine 4dcomputationalmodelingofcardiacoutflowtracthemodynamicsoverloopingdevelopmentalstagesinchickenembryos
AT mackenziejgray 4dcomputationalmodelingofcardiacoutflowtracthemodynamicsoverloopingdevelopmentalstagesinchickenembryos
AT kaitlinbeel 4dcomputationalmodelingofcardiacoutflowtracthemodynamicsoverloopingdevelopmentalstagesinchickenembryos
AT kentthornburg 4dcomputationalmodelingofcardiacoutflowtracthemodynamicsoverloopingdevelopmentalstagesinchickenembryos
AT sandrarugonyi 4dcomputationalmodelingofcardiacoutflowtracthemodynamicsoverloopingdevelopmentalstagesinchickenembryos
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