TY - JOUR
T1 - Characterization and functionality of cardiac progenitor cells in congenital heart patients
AU - Mishra, Rachana
AU - Vijayan, Kalpana
AU - Colletti, Evan J.
AU - Harrington, Daniel A.
AU - Matthiesen, Thomas S.
AU - Simpson, David
AU - Kia Goh, Saik
AU - Walker, Brandon L.
AU - Almeida-Porada, Graça
AU - Wang, Deli
AU - Backer, Carl L.
AU - Dudley, Samuel C.
AU - Wold, Loren E.
AU - Kaushal, Sunjay
PY - 2011/2/1
Y1 - 2011/2/1
N2 - Background- Human cardiac progenitor cells (hCPCs) may promote myocardial regeneration in adult ischemic myocardium. The regenerative capacity of hCPCs in young patients with nonischemic congenital heart defects for potential use in congenital heart defect repair warrants exploration. Methods and Results- Human right atrial specimens were obtained during routine congenital cardiac surgery across 3 groups: neonates (age, <30 days), infants (age, 1 month to 2 years), and children (age, >2 to ≤13 years). C-kit hCPCs were 3-fold higher in neonates than in children >2 years of age. hCPC proliferation was greatest during the neonatal period as evidenced by c-kit Ki67 expression but decreased with age. hCPC differentiation capacity was also greatest in neonatal right atrium as evidenced by c-kit, NKX2-5, NOTCH1, and NUMB expression. Despite the age-dependent decline in resident hCPCs, we isolated and expanded right atrium-derived CPCs from all patients (n=103) across all ages and diagnoses using the cardiosphere method. Intact cardiospheres contained a mix of heart-derived cell subpopulations that included cardiac progenitor cells expressing c-kit, Islet-1, and supporting cells. The number of c-kit-expressing cells was highest in human cardiosphere-derived cells (hCDCs) grown from neonatal and infant right atrium. Furthermore, hCDCs could differentiate into diverse cardiovascular lineages by in vitro differentiation assays. Transplanted hCDCs promoted greater myocardial regeneration and functional improvement in infarcted myocardium than transplanted cardiac fibroblasts. Conclusions- Resident hCPCs are most abundant in the neonatal period and rapidly decrease over time. hCDCs can be reproducibly isolated and expanded from young human myocardial samples regardless of age or diagnosis. hCPCs are functional and have potential in congenital cardiac repair.
AB - Background- Human cardiac progenitor cells (hCPCs) may promote myocardial regeneration in adult ischemic myocardium. The regenerative capacity of hCPCs in young patients with nonischemic congenital heart defects for potential use in congenital heart defect repair warrants exploration. Methods and Results- Human right atrial specimens were obtained during routine congenital cardiac surgery across 3 groups: neonates (age, <30 days), infants (age, 1 month to 2 years), and children (age, >2 to ≤13 years). C-kit hCPCs were 3-fold higher in neonates than in children >2 years of age. hCPC proliferation was greatest during the neonatal period as evidenced by c-kit Ki67 expression but decreased with age. hCPC differentiation capacity was also greatest in neonatal right atrium as evidenced by c-kit, NKX2-5, NOTCH1, and NUMB expression. Despite the age-dependent decline in resident hCPCs, we isolated and expanded right atrium-derived CPCs from all patients (n=103) across all ages and diagnoses using the cardiosphere method. Intact cardiospheres contained a mix of heart-derived cell subpopulations that included cardiac progenitor cells expressing c-kit, Islet-1, and supporting cells. The number of c-kit-expressing cells was highest in human cardiosphere-derived cells (hCDCs) grown from neonatal and infant right atrium. Furthermore, hCDCs could differentiate into diverse cardiovascular lineages by in vitro differentiation assays. Transplanted hCDCs promoted greater myocardial regeneration and functional improvement in infarcted myocardium than transplanted cardiac fibroblasts. Conclusions- Resident hCPCs are most abundant in the neonatal period and rapidly decrease over time. hCDCs can be reproducibly isolated and expanded from young human myocardial samples regardless of age or diagnosis. hCPCs are functional and have potential in congenital cardiac repair.
KW - cardiomyopathy
KW - heart defects congenital
KW - heart failure
KW - pediatrics
KW - remodeling
KW - stem cells
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U2 - 10.1161/CIRCULATIONAHA.110.971622
DO - 10.1161/CIRCULATIONAHA.110.971622
M3 - Article
C2 - 21242485
AN - SCOPUS:79751529119
SN - 0009-7322
VL - 123
SP - 364
EP - 373
JO - Circulation
JF - Circulation
IS - 4
ER -