Vascular disease, caused by the blockage of blood vessels, is the largest cause of mortality in the developed world. Autologous or synthetic vascular grafts are used in treating this disease. However, some patients either lack suitable autologous tissue or cannot receive synthetic grafts due to the small size of target vessels. Tissue-engineered blood vessels (TEBVs) grown using vascular smooth muscle cells (SMCs) isolated from primary tissue hold great potential as tools for surgical replacement of the affected vessels in these patients. However, the development of autologous TEBVs for clinical application using SMCs has been hampered by limited accessibility to patient vascular SMCs, rapid loss of SMC differentiation in cell culture and limited ability of primary SMCs to expand. Thus, it is of great interest to establish a human cell-based model that provides an abundant and renewable source of functional SMCs for the establishment of TEBVs. A renewable source of human cells can be generated by human induced pluripotent stem cells (hiPSCs), which resemble human embryonic stem cells (hESCs) and can be derived from a person's own somatic cells by forced gene expression. Both hiPSCs and hESCs can self-renew and differentiate into virtually every cell type in the human body including functional vascular SMCs, providing ideal cell sources for generating TEBVs to treat vascular diseases. We recently established hiPSC lines and derived unlimited amounts of highly homogeneous functional vascular SMCs from hiPSCs (hiPSC-SMCs) and hESCs (hESC-SMCs). As the potential reactivation of reprogramming transgenes in these iPSCs could ultimately affect their safety as therapy and utility in disease modeling, we will generate and validate transgene-free hiPSC lines by using Cre recombinase and then derive and characterize hiPSC-SMCs from these transgene-free hiPSC lines. TEBVs typically lack elastin (ELN), which is essential to mechanical properties of blood vessels, providing recoil and resistance to aneurysm and dilation. Since we have shown that inhibition of microRNA-29a (miR-29a) markedly increases the expression of ELN, crosslinking of ELN fiber and distensibility of TEBVs derived from primary SMCs, we will generate TEBVs using hiPSC-SMCs and hESC-SMCs in the presence of a miR-29a inhibitor and then determine the suture retention strength, burst pressure, collagen content, ELN content, and mechanical properties of TEBVs. To investigate the function of SMC-derived TEBVs in vivo we will implant TEBVs as aortic interpositional grafts in nude rats. We choose the rat model since other preferred large animals (dog or pig) might reject the human tissue even with immunosuppression due to a significant xenogenic response. Although a non-human primate model is not appropriate for a first in vivo study of such new hiPSC technology, it could be used in the future with immunosuppression as a follow-up model if the rodent model succeeds. We will test the hypothesis that TEBVs derived from hiPSC-SMCs and hESC-SMCs possess suitable properties for implantation in vitro and then remain mechanically stable in a rat aortic model in vivo.

Public Health Relevance

This research will lead to the production of autologous, well-characterized vascular smooth muscle cells as an abundant renewable cell source for cell-based therapies and for disease mechanism study. Development of tissue-engineered blood vessels with markedly improved elasticity/compliance using smooth muscle cells derived from human induced pluripotent stem cells will enable us to take the next step toward developing autologous tissue engineered grafts for clinical intervention in vascular diseases.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
1R01HL116705-01A1
Application #
8529043
Study Section
Bioengineering, Technology and Surgical Sciences Study Section (BTSS)
Program Officer
Lee, Albert
Project Start
2013-09-01
Project End
2018-06-30
Budget Start
2013-09-01
Budget End
2014-06-30
Support Year
1
Fiscal Year
2013
Total Cost
$396,270
Indirect Cost
$158,270
Name
Yale University
Department
Internal Medicine/Medicine
Type
Schools of Medicine
DUNS #
043207562
City
New Haven
State
CT
Country
United States
Zip Code
06520
Jiao, Yang; Li, Guangxin; Li, Qingle et al. (2017) mTOR (Mechanistic Target of Rapamycin) Inhibition Decreases Mechanosignaling, Collagen Accumulation, and Stiffening of the Thoracic Aorta in Elastin-Deficient Mice. Arterioscler Thromb Vasc Biol 37:1657-1666
Sivarapatna, Amogh; Ghaedi, Mahboobe; Xiao, Yang et al. (2017) Engineered Microvasculature in PDMS Networks Using Endothelial Cells Derived from Human Induced Pluripotent Stem Cells. Cell Transplant 26:1365-1379
Luo, Jiesi; Qin, Lingfeng; Kural, Mehmet H et al. (2017) Vascular smooth muscle cells derived from inbred swine induced pluripotent stem cells for vascular tissue engineering. Biomaterials 147:116-132
Anderson, Christopher W; Boardman, Nicole; Luo, Jiesi et al. (2017) Stem Cells in Cardiovascular Medicine: the Road to Regenerative Therapies. Curr Cardiol Rep 19:34
Misra, Ashish; Sheikh, Abdul Q; Kumar, Abhishek et al. (2016) Integrin ?3 inhibition is a therapeutic strategy for supravalvular aortic stenosis. J Exp Med 213:451-63
Schwan, Jonas; Kwaczala, Andrea T; Ryan, Thomas J et al. (2016) Anisotropic engineered heart tissue made from laser-cut decellularized myocardium. Sci Rep 6:32068
Dash, Biraja C; Levi, Karen; Schwan, Jonas et al. (2016) Tissue-Engineered Vascular Rings from Human iPSC-Derived Smooth Muscle Cells. Stem Cell Reports 7:19-28
Gui, Liqiong; Dash, Biraja C; Luo, Jiesi et al. (2016) Implantable tissue-engineered blood vessels from human induced pluripotent stem cells. Biomaterials 102:120-9
Abrahimi, Parwiz; Chang, William G; Kluger, Martin S et al. (2015) Efficient gene disruption in cultured primary human endothelial cells by CRISPR/Cas9. Circ Res 117:121-8
Sivarapatna, Amogh; Ghaedi, Mahboobe; Le, Andrew V et al. (2015) Arterial specification of endothelial cells derived from human induced pluripotent stem cells in a biomimetic flow bioreactor. Biomaterials 53:621-33

Showing the most recent 10 out of 13 publications