As the next step in our investigations into the structural adaptations of the main pulmonary artery (PA) during postnatal growth, we utilized the extensive experimental measurements of the growing ovine PA from our previous study (Fata et al., 2013, “Estimated in vivo Postnatal Surface Growth Patterns of the Ovine Main Pulmonary Artery and Ascending Aorta,” J. Biomech. Eng., 135(7), pp. 71010–71012). to develop a structural constitutive model for the PA wall tissue. Novel to the present approach was the treatment of the elastin network as a distributed fiber network rather than a continuum phase. We then utilized this model to delineate structure-function differences in the PA wall at the juvenile and adult stages. Overall, the predicted elastin moduli exhibited minor differences remained largely unchanged with age and region (in the range of 150 to 200 kPa). Similarly, the predicted collagen moduli ranged from ∼1,600 to 2700 kPa in the four regions studied in the juvenile state. Interestingly, we found for the medial region that the elastin and collagen fiber splay underwent opposite changes (collagen standard deviation juvenile = 17 deg to adult = 28 deg, elastin standard deviation juvenile = 35 deg to adult = 27 deg), along with a trend towards more rapid collagen fiber strain recruitment with age, along with a drop in collagen fiber moduli, which went from 2700 kPa for the juvenile stage to 746 kPa in the adult. These changes were likely due to the previously observed impingement of the relatively stiff ascending aorta on the growing PA medial region. Intuitively, the effects of the local impingement would be to lower the local wall stress, consistent with the observed parallel decrease in collagen modulus. These results suggest that during the postnatal somatic growth period local stresses can substantially modulate regional tissue microstructure and mechanical behaviors in the PA. We further underscore that our previous studies indicated an increase in effective PA wall stress with postnatal maturation. When taken together with the fact that the observed changes in mechanical behavior and structure in the growing PA wall were modest in the other three regions studied, our collective results suggest that the majority of the growing PA wall is subjected to increasing stress levels with age without undergoing major structural adaptations. This observation is contrary to the accepted theory of maintenance of homeostatic stress levels in the regulation of vascular function, and suggests alternative mechanisms might regulate postnatal somatic growth. Understanding the underlying mechanisms will help to improve our understanding of congenital defects of the PA and lay the basis for functional duplication in their repair and replacement.
Skip Nav Destination
Article navigation
February 2014
Research-Article
Insights Into Regional Adaptations in the Growing Pulmonary Artery Using a Meso-Scale Structural Model: Effects of Ascending Aorta Impingement
Bahar Fata,
Bahar Fata
Department of Bioengineering,
University of Pittsburgh
,Pittsburgh, PA
19104;Center for Cardiovascular Simulation,
Institute for Computational
Engineering and Science,
Department of Biomedical Engineering,
Institute for Computational
Engineering and Science,
Department of Biomedical Engineering,
University of Texas
,Austin, TX 78712
Search for other works by this author on:
Will Zhang,
Will Zhang
Center for Cardiovascular Simulation,
Institute for Computational
Engineering and Science,
Department of Biomedical Engineering,
Institute for Computational
Engineering and Science,
Department of Biomedical Engineering,
University of Texas
,Austin, TX 78712
Search for other works by this author on:
Rouzbeh Amini,
Rouzbeh Amini
Department of Biomedical Engineering,
Auburn Science and Engineering Center 275,
West Tower,
Auburn Science and Engineering Center 275,
West Tower,
The University of Akron
,Akron, OH 44325
Search for other works by this author on:
Michael S. Sacks
Michael S. Sacks
1
2
Professor
W. A. “Tex” Moncrief, Jr. Simulation-Based
Engineering Science Chair I,
Center for Cardiovascular Simulation,
Institute for Computational
Engineering and Science,
Department of Biomedical Engineering,
e-mail: msacks@ices.utexas.edu
W. A. “Tex” Moncrief, Jr. Simulation-Based
Engineering Science Chair I,
Center for Cardiovascular Simulation,
Institute for Computational
Engineering and Science,
Department of Biomedical Engineering,
University of Texas
,Austin, TX
78712e-mail: msacks@ices.utexas.edu
1Present address: Institute for Computational Engineering and Sciences (ICES), The University of Texas at Austin, 201 East 24th Street, ACES 5.438, 1 University Station, C0200, Austin TX 78712-0027.
Search for other works by this author on:
Bahar Fata
Department of Bioengineering,
University of Pittsburgh
,Pittsburgh, PA
19104;Center for Cardiovascular Simulation,
Institute for Computational
Engineering and Science,
Department of Biomedical Engineering,
Institute for Computational
Engineering and Science,
Department of Biomedical Engineering,
University of Texas
,Austin, TX 78712
Will Zhang
Center for Cardiovascular Simulation,
Institute for Computational
Engineering and Science,
Department of Biomedical Engineering,
Institute for Computational
Engineering and Science,
Department of Biomedical Engineering,
University of Texas
,Austin, TX 78712
Rouzbeh Amini
Department of Biomedical Engineering,
Auburn Science and Engineering Center 275,
West Tower,
Auburn Science and Engineering Center 275,
West Tower,
The University of Akron
,Akron, OH 44325
Michael S. Sacks
Professor
W. A. “Tex” Moncrief, Jr. Simulation-Based
Engineering Science Chair I,
Center for Cardiovascular Simulation,
Institute for Computational
Engineering and Science,
Department of Biomedical Engineering,
e-mail: msacks@ices.utexas.edu
W. A. “Tex” Moncrief, Jr. Simulation-Based
Engineering Science Chair I,
Center for Cardiovascular Simulation,
Institute for Computational
Engineering and Science,
Department of Biomedical Engineering,
University of Texas
,Austin, TX
78712e-mail: msacks@ices.utexas.edu
1Present address: Institute for Computational Engineering and Sciences (ICES), The University of Texas at Austin, 201 East 24th Street, ACES 5.438, 1 University Station, C0200, Austin TX 78712-0027.
2Corresponding author.
Contributed by the Bioengineering Division of ASME for publication in the Journal of Biomechanical Engineering. Manuscript received October 21, 2013; final manuscript received January 7, 2014; accepted manuscript posted January 10, 2014; published online February 5, 2014. Editor: Beth Winkelstein.
J Biomech Eng. Feb 2014, 136(2): 021009 (13 pages)
Published Online: February 5, 2014
Article history
Received:
October 21, 2013
Revision Received:
January 7, 2014
Accepted:
January 10, 2014
Citation
Fata, B., Zhang, W., Amini, R., and Sacks, M. S. (February 5, 2014). "Insights Into Regional Adaptations in the Growing Pulmonary Artery Using a Meso-Scale Structural Model: Effects of Ascending Aorta Impingement." ASME. J Biomech Eng. February 2014; 136(2): 021009. https://doi.org/10.1115/1.4026457
Download citation file:
Get Email Alerts
Improvement in Active Cell Proliferation Area at Higher Permeability With Novel TPMS Lattice Structure
J Biomech Eng (November 2024)
Modeling Fatigue Failure of Cartilage and Fibrous Biological Tissues Using Constrained Reactive Mixture Theory
J Biomech Eng (December 2024)
A Numerical Study of Crack Penetration and Deflection at the Interface Between Peritubular and Intertubular Dentin
J Biomech Eng (December 2024)
Related Articles
Constitutive Modeling of Mouse Arteries Suggests Changes in Directional Coupling and Extracellular Matrix Remodeling That Depend on Artery Type, Age, Sex, and Elastin Amounts
J Biomech Eng (June,2024)
Decreased Elastic Energy Storage, Not Increased Material Stiffness, Characterizes Central Artery Dysfunction in Fibulin-5 Deficiency Independent of Sex
J Biomech Eng (March,2015)
Related Proceedings Papers
Related Chapters
Analysis of Components: Strain- and Deformation-Controlled Limits
Design & Analysis of ASME Boiler and Pressure Vessel Components in the Creep Range
Introduction to Stress and Deformation
Introduction to Plastics Engineering
Strain Rate History Effects in Body-Centered-Cubic Metals
Mechanical Testing for Deformation Model Development