Functional Integration of Electrically Active Cardiac Derivatives From Genetically Engineered Human Embryonic Stem Cells With Quiescent Recipient Ventricular Cardiomyocytes: Insights Into the Development of Cell-Based Pacemakers

doi:10.1161/01.CIR.0000151313.18547.A2

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Circulation. 2005;111:11-20
Published online before print December 20, 2004, doi: 10.1161/01.CIR.0000151313.18547.A2

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(Circulation. 2005;111:11-20.)
© 2005 American Heart Association, Inc.

Arrhythmia/Electrophysiology

Functional Integration of Electrically Active Cardiac Derivatives From Genetically Engineered Human Embryonic Stem Cells With Quiescent Recipient Ventricular Cardiomyocytes

Insights Into the Development of Cell-Based Pacemakers

Tian Xue, PhD^*; Hee Cheol Cho, PhD^*; Fadi G. Akar, PhD^*; Suk-Ying Tsang, PhD; Steven P. Jones, PhD; Eduardo Marbán, MD, PhD; Gordon F. Tomaselli, MD; Ronald A. Li, PhD

From the Department of Medicine, Johns Hopkins University, Baltimore, Md.

Correspondence to Ronald Li, PhD, Assistant Professor of Medicine, Johns Hopkins University, Ross 1165, 720 Rutland Ave, Baltimore MD 21205. E-mail ronaldli{at}jhmi.edu

Received August 19, 2004; revision received September 23, 2004; accepted September 30, 2004.

Background— Human embryonic stem cells (hESCs) derivedfrom blastocysts can propagate indefinitely in culture whilemaintaining pluripotency, including the ability to differentiateinto cardiomyocytes (CMs); therefore, hESCs may provide an unlimitedsource of human CMs for cell-based therapies. Although CMs canbe derived from hESCs ex vivo, it remains uncertain whethera functional syncytium can be formed between donor and recipientcells after engraftment.

Methods and Results— Using a combination of electrophysiologicaland imaging techniques, here we demonstrate that electricallyactive, donor CMs derived from hESCs that had been stably geneticallyengineered by a recombinant lentivirus can functionally integratewith otherwise-quiescent, recipient, ventricular CMs to inducerhythmic electrical and contractile activities in vitro. Theintegrated syncytium was responsive to the ß-adrenergicagonist isoproterenol as well as to other pharmacological agentssuch as lidocaine and ZD7288. Similarly, a functional hESC-derivedpacemaker could be implanted in the left ventricle in vivo.Detailed optical mapping of the epicardial surface of guineapig hearts transplanted with hESC-derived CMs confirmed thesuccessful spread of membrane depolarization from the site ofinjection to the surrounding myocardium.

Conclusions— We conclude that electrically active, hESC-derivedCMs are capable of actively pacing quiescent, recipient, ventricularCMs in vitro and ventricular myocardium in vivo. Our resultsmay lead to an alternative or a supplemental method for correctingdefects in cardiac impulse generation, such as cell-based pacemakers.

Key Words: stem cells • cardiac development • viruses • gene therapy • pacemakers

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				Y.-H. Choi, C. Stamm, P. E. Hammer, K. F. Kwaku, J. J. Marler, I. Friehs, M. Jones, C. M. Rader, N. Roy, M.-T. Eddy, et al. Cardiac Conduction through Engineered Tissue Am. J. Pathol., July 1, 2006; 169(1): 72 - 85. [Abstract] [Full Text] [PDF]

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