Abstract

Using autologous cells and biodegradable polymers, tissue engineered pulmonary valves (TEPV) have been fabricated and have functioned in the pulmonary circulation of growing lambs for up to 20 weeks, with tissue evolving into a differentiated layered structure resembling that of native valve. More recent studies have demonstrated that use of bone marrow mesenchymal stem cells (BMSC) and PGA/PLLA scaffolds produce functioning implants for up to 8 months in growing lambs which also demonstrated in-vivo structural evolution. These studies have demonstrated the feasibility of engineering pulmonary valve (PV) leaflets and segments of main pulmonary artery (PA) in-vitro. Both structures have functioned well without thrombosis. Moreover, both the gross and microscopic characteristics of the TEPV structures began to approximate those of normal tissues, strongly suggesting that cell phenotypes evolved in a directed fashion to remodel the valvular and vascular tissue. However, while these intriguing studies have yielded insight into TEPV development, our efforts thus far have been largely empirical. There remain significant bioengineering challenges in determining parameters that lead to optimal ECM development and strength. For example, despite the in-vivo evolution of TEPV valve tissue into a tri-layered structure that resembles native valve tissue, we have only very limited information on the extent to which TEPV truly duplicates native PV biomechanical function, nor the mechanisms that regulate the in-vivo remodeling process. The goal of the current research program is to thus quantify and simulate tissue remodeling events that occur post- implantation, and to understand the factors that influence the remodeling rate and the quality and architecture of the ultimate tissue. Specifically, we hypothesize that TEPV implant remodeling is primarily mediated by the level of in-vivo mechanical stimuli to the interstitial cells and developing ECM. Mechanical stimuli will affect the rate of scaffold degradation and the degree of post-implant cellular ingrowth. Relevance to public health includes the develop of valved pulmonary conduits for the pediatric population that can grow with the patient, minimizing the need for continued re-operations to bring the patient to adulthood. ? ? ?

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL089750-02
Application #
7460939
Study Section
Bioengineering, Technology and Surgical Sciences Study Section (BTSS)
Program Officer
Lundberg, Martha
Project Start
2007-07-05
Project End
2011-06-30
Budget Start
2008-07-01
Budget End
2009-06-30
Support Year
2
Fiscal Year
2008
Total Cost
$764,250
Indirect Cost

  Institution

Name
University of Pittsburgh
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
004514360
City
Pittsburgh
State
PA
Country
United States
Zip Code
15213

  Publications

Soares, João S; Zhang, Will; Sacks, Michael S (2017) A mathematical model for the determination of forming tissue moduli in needled-nonwoven scaffolds. Acta Biomater 51:220-236
Goth, Will; Lesicko, John; Sacks, Michael S et al. (2016) Optical-Based Analysis of Soft Tissue Structures. Annu Rev Biomed Eng 18:357-85
Soares, Joao S; Feaver, Kristen R; Zhang, Will et al. (2016) Biomechanical Behavior of Bioprosthetic Heart Valve Heterograft Tissues: Characterization, Simulation, and Performance. Cardiovasc Eng Technol 7:309-351
Soares, Joao S; Sacks, Michael S (2016) A triphasic constrained mixture model of engineered tissue formation under in vitro dynamic mechanical conditioning. Biomech Model Mechanobiol 15:293-316
Sakamoto, Yusuke; Buchanan, Rachel M; Sacks, Michael S (2016) On intrinsic stress fiber contractile forces in semilunar heart valve interstitial cells using a continuum mixture model. J Mech Behav Biomed Mater 54:244-58
D'Amore, Antonio; Soares, Joao S; Stella, John A et al. (2016) Large strain stimulation promotes extracellular matrix production and stiffness in an elastomeric scaffold model. J Mech Behav Biomed Mater 62:619-635
Carleton, James B; D'Amore, Antonio; Feaver, Kristen R et al. (2015) Geometric characterization and simulation of planar layered elastomeric fibrous biomaterials. Acta Biomater 12:93-101
D'Amore, Antonio; Amoroso, Nicholas; Gottardi, Riccardo et al. (2014) From single fiber to macro-level mechanics: A structural finite-element model for elastomeric fibrous biomaterials. J Mech Behav Biomed Mater 39:146-61
Ramaswamy, Sharan; Boronyak, Steven M; Le, Trung et al. (2014) A novel bioreactor for mechanobiological studies of engineered heart valve tissue formation under pulmonary arterial physiological flow conditions. J Biomech Eng 136:121009
Fata, Bahar; Zhang, Will; Amini, Rouzbeh et al. (2014) Insights into regional adaptations in the growing pulmonary artery using a meso-scale structural model: effects of ascending aorta impingement. J Biomech Eng 136:021009

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