Heart disease frequently leads to cardiac fibrosis. In almost all cases of chronic heart disease, the myocardium exhibits fibrosis developed by activated cardiac fibroblasts. These fibroblasts are quiescent in the healthy heart. Interstitial fibrosis due to extracellular matrix deposition by fibroblasts increases the stiffness of the tissue and impairs cardiac relaxation. Discovering pharmaceutical treatments that can reverse fibrosis is a critical unmet need;no such drugs currently exist. This project will develop a novel high-throughput screening platform for drug discovery that measures the physiological properties of live, engineered tissue samples, and their controls, cultured in 96-well plates(the PalpatorTM system). This platform will measure drug-induced changes in the physiological properties of engineered tissues. The Phase I project focuses on completing the development of the PalpatorTM screening system and obtaining feedback from academic and industrial collaborators. In addition, the algorithm used for the data analysis software will be modified to reduce failure rates. The modified software will be beta tested for its ability to obtain meaningful values for the physiological parameters used to indicate that treatment with the panel of chemical compounds has altered the properties of the engineered tissues. The final packaging of the project-related software will be outsourced for its launch. The Phase II project focuses on scaling up the engineered tissue-based screening system to make it amenable to high-throughput applications in industry. The tissue culture consumables for growing engineered tissues in 96-well plates will be produced in collaboration with Engineering Industries, Inc. (Verona, WI). The scaled-up engineered tissue production will significantly improve screening efficiency. This highly efficient Palpator screening system will be used to profile the effects of 50 commonly prescribed cardiovascular drugs on engineered heart tissues. Although the engineered heart tissues are constructed to mimic the physiological properties of native heart muscles, profiling known cardiovascular drugs will validate the utility of employing engineered heart tissues in drug discovery and toxic compound testing. To further validate the engineered tissue model, a library of compounds with known cardiovascular effects will be screened using the Palpator system. A novel phenotypic screening protocol that employs both engineered tissues cultured with highly contractile fibroblasts to mimic the fibrotic heart and 'normal'engineered heart tissues will be used to identify chemical compounds that reduce the contractility of the fibrotic engineered tissues but yet maintain the healthy contractile activities of normal engineered heart tissues. The combination of the engineered tissue models and the Palpator screening device will accelerate drug discovery and reduce the need (and associated costs) of extensive animal studies.

Public Health Relevance

In the United States today, about 5 million people suffer from heart disease, one of the most prevalent chronic conditions and the number one complication of heart attacks. This proposal describes an entirely new method for testing potential drugs to learn if they can help repair the heart or if they are toxic to the body, by measuring whether a drug changes how a heart tissue model behaves. This research may provide a breakthrough in accelerating drug discovery and reducing costs, because it is rapid, high-throughput, and may reduce the need for animal testing.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Small Business Innovation Research Grants (SBIR) - Phase II (R44)
Project #
4R44GM087784-02
Application #
8010461
Study Section
Special Emphasis Panel (ZRG1-CVS-K (10))
Program Officer
Okita, Richard T
Project Start
2009-06-17
Project End
2011-11-30
Budget Start
2010-01-22
Budget End
2010-11-30
Support Year
2
Fiscal Year
2010
Total Cost
$887,123
Indirect Cost
Name
Invivo Sciences, LLC.
Department
Type
DUNS #
610347713
City
Madison
State
WI
Country
United States
Zip Code
53719
Conway, Michael K; Gerger, Michael J; Balay, Erin E et al. (2015) Scalable 96-well Plate Based iPSC Culture and Production Using a Robotic Liquid Handling System. J Vis Exp :e52755
Daily, Neil J; Yin, Yue; Kemanli, Pinar et al. (2015) Improving Cardiac Action Potential Measurements: 2D and 3D Cell Culture. J Bioeng Biomed Sci 5:
Sonin, Dmitry L; Wakatsuki, Tetsuro; Routhu, Kasi V et al. (2013) Protease-activated receptor 1 inhibition by SCH79797 attenuates left ventricular remodeling and profibrotic activities of cardiac fibroblasts. J Cardiovasc Pharmacol Ther 18:460-75
Hazeltine, Laurie B; Simmons, Chelsey S; Salick, Max R et al. (2012) Effects of substrate mechanics on contractility of cardiomyocytes generated from human pluripotent stem cells. Int J Cell Biol 2012:508294
Lam, Vy; Bigley, Tarin; Terhune, Scott S et al. (2012) A method for quantifying mechanical properties of tissue following viral infection. PLoS One 7:e42197
Lam, Vy; Wakatsuki, Tetsuro (2011) Hydrogel tissue construct-based high-content compound screening. J Biomol Screen 16:120-8