Prevascularized Microtemplated Fibrin Scaffolds for Cardiac Tissue Engineering Applications

Myocardial infarction (MI) causes significant cell loss and damage to myocardium. Cell-based therapies for treatment of MI aim to remuscularize the resultant scar tissue, but the majority of transplanted cells do not survive or integrate with the host tissue. Scaffolds can improve cell retention fol...

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Veröffentlicht in:Tissue engineering. Part A 2013-04, Vol.19 (7-8), p.967-977
Hauptverfasser: Thomson, Kassandra S., Korte, F. Steven, Giachelli, Cecilia M., Ratner, Buddy D., Regnier, Michael, Scatena, Marta
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Sprache:eng
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Zusammenfassung:Myocardial infarction (MI) causes significant cell loss and damage to myocardium. Cell-based therapies for treatment of MI aim to remuscularize the resultant scar tissue, but the majority of transplanted cells do not survive or integrate with the host tissue. Scaffolds can improve cell retention following construct implantation, but often do little to enhance host-graft integration and/or show limited biodegradation. Fibrin is an ideal biomaterial for cardiac tissue engineering as it is a natural, biodegradable polymer that can induce neovascularization, promote cell attachment, and has tunable mechanical properties. Here we describe a novel, high-density microtemplated fibrin scaffold seeded with a tri-cell mixture of cardiomyocytes, endothelial cells (ECs), and fibroblasts to mimic native cardiac tissue in structure and cellular composition to improve cell retention and promote integration with the host tissue. Scaffolds were designed with uniform architecture of parallel 60 μm microchannels surrounded by an interconnected microporous network of 27-μm-diameter pores and mechanical stiffness comparable to native cardiac tissues (70–90kPa). Scaffold degradation was controlled with the addition of Factor XIII (FXIII) and/or protease inhibitor (aprotinin). Unmodified scaffolds had a fast degradation profile both in vitro (19.9%±3.9% stiffness retention after 10 days) and in vivo . Scaffolds treated with FXIII showed an intermediate degradation profile in vitro (45.8%±5.9%), while scaffolds treated with aprotinin or both FXIII and aprotinin showed significantly slowed degradation in vitro (60.9%±5.2% and 76.4%±7.6%, respectively, p
ISSN:1937-3341
1937-335X
DOI:10.1089/ten.tea.2012.0286