There are 1.2 million new or recurrent coronary attacks each year in the U.S, resulting in myocardial infarction or tissue death. The generation of functional cardiac tissue to replace damaged tissue could significantly change the way we currently treat heart disease. Consequently, a robust method of fabricating blood vessels could facilitate growth of larger scale cardiac tissue for treating this increasing burden of disease in America.
Our aim i n this proposal is to add a vascular network which can supply the cardiac graft with nutrient transport in vitro and be connected to blood supply in vivo. Micro fabrication technologies allow for the spatially precise creation of a cell-instructive environment and will be used to pattern 100 um to 1 mm channels within a graft material. Mimicking physiologic vasculature, the hierarchically organized vascular network of blood vessels will be induced to branch from relatively large (millimeters) to very small (10 um) conduits. Cardiac tissue will be grown around the vessel structure, using a hydrogel encapsulation method. Bioreactors will provide biophysical signaling using a time varying fluid flow regime to mature the blood vessels along with angiogenic cytokines to induce individual capillary sprouting providing transport at the cellular scale. This hierarchical design is particularly important because it creates a specific inlet and outlet for in vitro connectivity and clear ends for surgical anastomosis in vivo, while maintaining a micro vascular network for efficient nutrient delivery. This design bridges the gap between larger scale singular vascular tubes which often lack effective transport to individual cells, and co culture studies with endothelial cells which lack fluid perfusion. The vascular functionality of the cardiac graft will be assessed in vivo an interposition graft in an end to end anastomosis in the rat abdominal aorta.
The specific aims of the proposal will be to (1) Use micro fabrication technologies to create a hierarchically designed template for vascular formation, (2) Apply biophysical regulation to induce capillary sprouting, (3) Functionally test the survival and functional perfusion of the cardiac graft in an in vivo rat abdominal aorta model. This project will build upon our laboratory's previous experience and expertise in cardiac tissue engineering with advanced biological micro fabrication techniques, to create a large, perfused cardiac graft that can be used in vivo. We hope that these studies can aid to the overall effort to reduce the national burden of cardiovascular disease, by creating a cardiac patch that can be used for patients suffering from myocardial infarctions and coronary artery disease.

Public Health Relevance

Coronary artery disease, the most common form of heart disease, causes heart vessel narrowing leading to myocardial infarction, associated with massive death of cardiac cells. This proposal intends to use advanced microfabrication techniques, in combination with molecular induction and physical conditioning, to build cardiac tissues with functional blood vessel networks arranged in a hierarchical branching design. This functional vasculature will be tested in a small animal model, towards cardiac grafts useful for reversing the loss of cardiac function.

National Institute of Health (NIH)
National Heart, Lung, and Blood Institute (NHLBI)
Individual Predoctoral NRSA for M.D./Ph.D. Fellowships (ADAMHA) (F30)
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Special Emphasis Panel (ZRG1)
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Meadows, Tawanna
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Columbia University (N.Y.)
Schools of Medicine
New York
United States
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Eng, George; Lee, Benjamin W; Protas, Lev et al. (2016) Autonomous beating rate adaptation in human stem cell-derived cardiomyocytes. Nat Commun 7:10312
Lee, Benjamin W; Liu, Bohao; Pluchinsky, Adam et al. (2016) Modular Assembly Approach to Engineer Geometrically Precise Cardiovascular Tissue. Adv Healthc Mater 5:900-6
Eng, George; Lee, Benjamin W; Parsa, Hesam et al. (2013) Assembly of complex cell microenvironments using geometrically docked hydrogel shapes. Proc Natl Acad Sci U S A 110:4551-6