TY - JOUR
T1 - A tissue engineering approach to progenitor cell delivery results in significant cell engraftment and improved myocardial remodeling
AU - Simpson, David
AU - Liu, Hong
AU - Fan, Tai Hwang Michael
AU - Nerem, Robert
AU - Dudley, Samuel C.
PY - 2007/9
Y1 - 2007/9
N2 - Cell replacement therapy has become an attractive solution for myocardial repair. Typical cell delivery techniques, however, suffer from poor cell engraftment and inhomogeneous cell distributions. Therefore, we assessed the hypothesis that an epicardially applied, tissue-engineered cardiac patch containing progenitor cells would result in enhanced exogenous cell engraftment. Human mesenchymal stem cells (hMSCs) were embedded into a rat tail type I collagen matrix to form the cardiac patch. Myocardial infarction was induced by left anterior descending coronary artery ligation in immunocompetent male cesarean-derived fischer rats, and patches with or without cells were secured to hearts with fibrin sealant. After patch formation, hMSCs retained a viability of >90% over 5 days in culture. In addition, >75% of hMSCs maintained a high degree of potency prior to patch implantation. After 4 days in culture, patches were applied to the epicardial surface of the infarct area and resulted in 23% ± 4% engraftment of hMSCs at 1 week (n = 6). Patch application resulted in a reduction in left ventricle interior diameter at systole, increased anterior wall thickness, and a 30% increase in fractional shortening. Despite this improvement in myocardial remodeling, hMSCs were not detectable at 4 weeks after patch application, implying that improvement did not require long-term cell engraftment. Patches devoid of progenitor cells showed no improvement in remodeling. In conclusion, pluripotent hMSCs can be efficiently delivered to a site of myocardial injury using an epicardial cardiac patch, and such delivery results in improved myocardial remodeling after infarction.
AB - Cell replacement therapy has become an attractive solution for myocardial repair. Typical cell delivery techniques, however, suffer from poor cell engraftment and inhomogeneous cell distributions. Therefore, we assessed the hypothesis that an epicardially applied, tissue-engineered cardiac patch containing progenitor cells would result in enhanced exogenous cell engraftment. Human mesenchymal stem cells (hMSCs) were embedded into a rat tail type I collagen matrix to form the cardiac patch. Myocardial infarction was induced by left anterior descending coronary artery ligation in immunocompetent male cesarean-derived fischer rats, and patches with or without cells were secured to hearts with fibrin sealant. After patch formation, hMSCs retained a viability of >90% over 5 days in culture. In addition, >75% of hMSCs maintained a high degree of potency prior to patch implantation. After 4 days in culture, patches were applied to the epicardial surface of the infarct area and resulted in 23% ± 4% engraftment of hMSCs at 1 week (n = 6). Patch application resulted in a reduction in left ventricle interior diameter at systole, increased anterior wall thickness, and a 30% increase in fractional shortening. Despite this improvement in myocardial remodeling, hMSCs were not detectable at 4 weeks after patch application, implying that improvement did not require long-term cell engraftment. Patches devoid of progenitor cells showed no improvement in remodeling. In conclusion, pluripotent hMSCs can be efficiently delivered to a site of myocardial injury using an epicardial cardiac patch, and such delivery results in improved myocardial remodeling after infarction.
KW - Mesenchymal stem cell transplantation
KW - Myocardial infarction
KW - Tissue engineering
KW - Ventricular remodeling
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U2 - 10.1634/stemcells.2007-0132
DO - 10.1634/stemcells.2007-0132
M3 - Article
C2 - 17525236
AN - SCOPUS:34748874691
SN - 1066-5099
VL - 25
SP - 2350
EP - 2357
JO - STEM CELLS
JF - STEM CELLS
IS - 9
ER -