Ischemic heart disease (IHD) is the number one cause of morbidity and mortality in the US. With an estimated 1.6 million new or recurrent myocardial infarctions, the total economic burden of IHD on our health care system is tremendous. Although conventional pharmacotherapy and surgical interventions often improve cardiac function and quality of life, many patients continue to develop refractory symptoms. Thus, the development of new therapeutic strategies is urgently needed. """"""""Tissue engineering"""""""" can be broadly defined as the application of novel engineering methods toward understanding structure-function relationships in normal or pathological conditions and the development of biological substitutes to restore, maintain, or improve function. It is different from """"""""cell therapy"""""""" which intends to improve the function of an injured tissue by simply injecting suspensions of isolated cells. To date, two of the main limitations have been the lack of available methodology for scaling up the number of cells for potential clinical application and the inability to track the functionality of either cells or tissues after transplantation. Thus, the application of nanotechnology for development of novel techniques that address both deficits will provide a new catalyst for the entire field of investigation.
The aims of our R21 proposal are to (1) significantly enhance the in vitro and in vivo performance of differentiated cardiomyocytes by electromechanical conditioning in an integrated stretchable microelectrode array-bioreactor system and (2) to engineer safe, durable, and biodegradable nanostructured scaffold sheets that can improve survival of conditioned cardiomyocytes. Once validated, we will transition into the R33 phase in years 3-5. The goals are (1) to scale-up nanostructured sheets from a single cell layer to a large area, multi-cell layer tissue graft, (2) to perform small animal in vivo assessment using molecular imaging techniques comparing the durability of injected cells alone versus our nanostructured tissue graft, and (3) to demonstrate safety and efficacy of our nanostructured tissue graft in a pre-clinical large animal model. We are confident that these developments will contribute substantially and help merge the fields of nanotechnology, tissue engineering, and molecular imaging. Progress in the field of cell therapy has been hindered by the lack of long-term engraftment and inability to monitor cell fate reliably post transplantation. Tissue engineering, by delivering cells with electrical and mechanical conditioning coupled to a supporting nanostructured scaffold may be a more promising and logical alternative. Our proposal uses multi-layers of conditioned cardiomyocytes patterned on a nanostructured scaffold to form a tissue graft that will be more durable, biodegradable, and safe. Concurrently, the application of molecular imaging modalities in small and large animal models will help us validate their functionality in vivo. With a multi-disciplinary team approach, we are confident that these combined efforts will accelerate the translation of nanotechnology-based tissue engineering to the clinical arena in the future. ? ? ?

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21HL089027-01
Application #
7286800
Study Section
Special Emphasis Panel (ZRG1-CB-B (52))
Program Officer
Lundberg, Martha
Project Start
2007-09-01
Project End
2012-07-31
Budget Start
2007-09-01
Budget End
2008-07-31
Support Year
1
Fiscal Year
2007
Total Cost
$389,549
Indirect Cost
Name
Stanford University
Department
Radiation-Diagnostic/Oncology
Type
Schools of Medicine
DUNS #
009214214
City
Stanford
State
CA
Country
United States
Zip Code
94305
Myers, Frank B; Silver, Jason S; Zhuge, Yan et al. (2013) Robust pluripotent stem cell expansion and cardiomyocyte differentiation via geometric patterning. Integr Biol (Camb) 5:1495-506
Myers, Frank B; Zarins, Christopher K; Abilez, Oscar J et al. (2013) Label-free electrophysiological cytometry for stem cell-derived cardiomyocyte clusters. Lab Chip 13:220-8
Simmons, Chelsey S; Ribeiro, Alexandre J S; Pruitt, Beth L (2013) Formation of composite polyacrylamide and silicone substrates for independent control of stiffness and strain. Lab Chip 13:646-9
Rhee, June-Wha; Wu, Joseph C (2013) Advances in nanotechnology for the management of coronary artery disease. Trends Cardiovasc Med 23:39-45
Plews, Jordan R; Gu, Mingxia; Longaker, Michael T et al. (2012) Large animal induced pluripotent stem cells as pre-clinical models for studying human disease. J Cell Mol Med 16:1196-202
Abilez, Oscar J (2012) Cardiac optogenetics. Conf Proc IEEE Eng Med Biol Soc 2012:1386-9
Panula, Sarita; Medrano, Jose V; Kee, Kehkooi et al. (2011) Human germ cell differentiation from fetal- and adult-derived induced pluripotent stem cells. Hum Mol Genet 20:752-62
Lee, Andrew S; Wu, Joseph C (2011) Imaging of embryonic stem cell migration in vivo. Methods Mol Biol 750:101-14
Hiona, Asimina; Lee, Andrew Stephen; Nagendran, Jayan et al. (2011) Pretreatment with angiotensin-converting enzyme inhibitor improves doxorubicin-induced cardiomyopathy via preservation ofýýmitochondrial function. J Thorac Cardiovasc Surg 142:396-403.e3
Xie, Xiaoyan; Hiona, Asimina; Lee, Andrew Stephen et al. (2011) Effects of long-term culture on human embryonic stem cell aging. Stem Cells Dev 20:127-38

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