We applied a statistical mechanics based microstructural model of pulmonary artery mechanics, developed from our previous studies of rats with pulmonary arterial hypertension (PAH), to patient-specific clinical studies of children with PAH. Our previous animal studies provoked the hypothesis that increased cross-linking density of the molecular chains may be one biological remodeling mechanism by which the PA stiffens in PAH. This study appears to further confirm this hypothesis since varying molecular cross-linking density in the model allows us to simulate the changes in the loops between normotensive and hypertensive conditions reasonably well. The model was combined with patient-specific three-dimensional vascular anatomy to obtain detailed information on the topography of stresses and strains within the proximal branches of the pulmonary vasculature. The effect of orthotropy on stress∕strain within the main and branch PAs obtained from a patient was explored. This initial study also puts forward important questions that need to be considered before combining the microstructural model with complex patient-specific vascular geometries.
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e-mail: robin.shandas@colorado.edu
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April 2007
Technical Papers
Application of A Microstructural Constitutive Model of the Pulmonary Artery to Patient-Specific Studies: Validation and Effect of Orthotropy
Yanhang Zhang,
Yanhang Zhang
Department of Aerospace and Mechanical Engineering,
Boston University
, Boston, MA 02215
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Martin L. Dunn,
Martin L. Dunn
Department of Mechanical Engineering,
University of Colorado at Boulder
, Boulder, CO 80309
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Kendall S. Hunter,
Kendall S. Hunter
Division of Cardiology,
The Children’s Hospital of Denver
, Denver, CO 80218
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Craig Lanning,
Craig Lanning
Division of Cardiology,
The Children’s Hospital of Denver
, Denver, CO 80218
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D. Dunbar Ivy,
D. Dunbar Ivy
Division of Cardiology,
The Children’s Hospital of Denver
, Denver, CO 80218
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Lori Claussen,
Lori Claussen
Division of Cardiology,
The Children’s Hospital of Denver
, Denver, CO 80218
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S. James Chen,
S. James Chen
Department of Medicine, Division of Cardiology,
University of Colorado at Denver
and Health Sciences Center
, Denver, CO 80262
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Robin Shandas
Robin Shandas
Department of Mechanical Engineering, 427 UCB,
e-mail: robin.shandas@colorado.edu
University of Colorado
, Boulder, CO 80309 and Division of Cardiology, The Children’s Hospital of Denver
, Denver, CO 80218
Search for other works by this author on:
Yanhang Zhang
Department of Aerospace and Mechanical Engineering,
Boston University
, Boston, MA 02215
Martin L. Dunn
Department of Mechanical Engineering,
University of Colorado at Boulder
, Boulder, CO 80309
Kendall S. Hunter
Division of Cardiology,
The Children’s Hospital of Denver
, Denver, CO 80218
Craig Lanning
Division of Cardiology,
The Children’s Hospital of Denver
, Denver, CO 80218
D. Dunbar Ivy
Division of Cardiology,
The Children’s Hospital of Denver
, Denver, CO 80218
Lori Claussen
Division of Cardiology,
The Children’s Hospital of Denver
, Denver, CO 80218
S. James Chen
Department of Medicine, Division of Cardiology,
University of Colorado at Denver
and Health Sciences Center
, Denver, CO 80262
Robin Shandas
Department of Mechanical Engineering, 427 UCB,
University of Colorado
, Boulder, CO 80309 and Division of Cardiology, The Children’s Hospital of Denver
, Denver, CO 80218e-mail: robin.shandas@colorado.edu
J Biomech Eng. Apr 2007, 129(2): 193-201 (9 pages)
Published Online: August 22, 2006
Article history
Received:
October 7, 2005
Revised:
August 22, 2006
Citation
Zhang, Y., Dunn, M. L., Hunter, K. S., Lanning, C., Ivy, D. D., Claussen, L., Chen, S. J., and Shandas, R. (August 22, 2006). "Application of A Microstructural Constitutive Model of the Pulmonary Artery to Patient-Specific Studies: Validation and Effect of Orthotropy." ASME. J Biomech Eng. April 2007; 129(2): 193–201. https://doi.org/10.1115/1.2485780
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