Coronary heart disease is a major cause of mortality in the US and in our Veterans. Biological approaches to treat the diseased heart using cell delivery have shown only modest therapeutic benefit, in part due to poor cell survival and ineffective electromechanical coupling to the host myocardium. Our previous research demonstrates that delivery of therapeutic cells cultured in an extracellular matrix (ECM) can improve the survival and functionality of the transplanted cells, owing to the structural support of the ECM as a scaffold and the signaling cues they impart to the cells. In particular, we have previously demonstrated the potency of anisotropic nanofibrillar scaffolds in guiding cellular alignment along the direction of the nanofibrils, enhancing cell survival in ischemic tissues, and imparting signaling cues that confer cell function consistent with a non- diseased state. Anisotropic scaffolds may be well-suited for engineering cardiac tissue which also has highly organized cellular structure. In addition, induced pluripotent stem cells (iPSCs) may be a candidate cell source for the generation of autologous therapeutic cardiovascular cells. The long-term objectives of this research are to engineer a three-dimensional vascularized cardiac patch with pre-formed physiological cellular organization to repair ischemic heart disease; and to investigate the basic biological mechanisms underlying ECM-mediated cell-cell interactions that enhance cardioprotection under conditions of ischemia. We hypothesize that a three- dimensionally aligned iPSC-derived cardiac patch with endothelial interactions will provide more functional and viable engineered tissues for repair of myocardial infarction, due to more effective electrical coupling and organized tissue morphology, as well as the activation of cardioprotective nitric oxide signaling imparted by ECM nanopatterning. Accordingly, our specific aims are: 1) To engineer a vascularized aligned iPSC-derived cardiomyocyte (CM) patch and elucidating the molecular mechanisms of ECM-mediated nitric oxide signaling in enhancing iPSC-CM survival and phenotype. The iPSC-derived CMs (iPSC- CMs) and iPSC-derived endothelial cells (iPSC-ECs) will be co-cultured on three-dimensional oriented nanofibrillar collagen scaffolds with culture conditions optimized to promote iPSC-CM cell survival and function within the patch, when compared to patches that lack oriented nanopatterning or vascular interactions. The role of ECM-mediated nitric oxide signaling in enhancing iPSC-CM survival and phenotype will be investigated in the context of gain- and loss-of-function assays. 2) To determine the therapeutic effect of a vascularized aligned iPSC-CM patch for treatment of myocardial infarction. The vascularized oriented cardiac patch will be transplanted onto the epicardium of rats after myocardial infarction. The animals will be monitored over time for functional improvement in cardiac function, wall thickness, and electromechanical coupling. The role of nitric oxide in mediating the functional effects of the aligned vascularized cardiac patch will be quantified by measuring production of nitric oxide and related signaling molecules. The knowledge gained from these studies will provide a stronger foundation of basic knowledge and improved methods for clinical development of engineered cardiac patches, ultimately with the goal of restoring myocardial function to the diseased hearts of our Veterans.

Public Health Relevance

Cardiovascular disease is the leading cause of death in Americans and in the Veteran population. In particular, coronary heart disease (CHD) is characterized by narrowing of the blood vessels that supply blood flow to the heart, leading to heart attack and ultimately heart failure. Understanding how to engineer biological replacement cardiac tissue is important for developing effective treatments for CHD in our Veterans. We believe that using scaffolds that guide the organization of cardiac cells will help to scale-up the size of engineered tissues, due to the ability of the scaffolds to maintain cell survival and promote cardiac health. Importantly, we will examine the biochemical processes that help improve cardiac cell survival and function within the cardiac patches. Together, these studies offer great hope to the development of therapies that for treating Veterans with CHD.

Agency
National Institute of Health (NIH)
Institute
Veterans Affairs (VA)
Type
Non-HHS Research Projects (I01)
Project #
5I01BX002310-04
Application #
9487850
Study Section
Surgery (SURG)
Project Start
2014-10-01
Project End
2018-09-30
Budget Start
2017-10-01
Budget End
2018-09-30
Support Year
4
Fiscal Year
2018
Total Cost
Indirect Cost
Name
Veterans Admin Palo Alto Health Care Sys
Department
Type
DUNS #
046017455
City
Palo Alto
State
CA
Country
United States
Zip Code
94304
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Hou, Luqia; Coller, John; Natu, Vanita et al. (2016) Combinatorial extracellular matrix microenvironments promote survival and phenotype of human induced pluripotent stem cell-derived endothelial cells in hypoxia. Acta Biomater 44:188-99
Hou, Luqia; Kim, Joseph J; Woo, Y Joseph et al. (2016) Stem cell-based therapies to promote angiogenesis in ischemic cardiovascular disease. Am J Physiol Heart Circ Physiol 310:H455-65

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