Growth characteristics of different heart cells on novel nanopatch substrate during electrical stimulation

Bio-Medical Materials and Engineering

Volumn 24, Issue 6, 2014, Pages 2101-2107

  Stout, David A ^a,b   Raimondo, Emilia ^c   Marostica, Giuliano ^a   Webster, Thomas J ^d  

^a Brown University   (United States)

^b CALIFORNIA STATE UNIVERSITY   (United States)

^c BROWN UNIVERSITY   (United States)

^d Northeastern University   (United States)

Author keywords

Carbon nanofiber; Cardiomyocyte; Cardiovascular patch; Fibroblast; Nanomaterials

Indexed keywords

CARBON NANOFIBERS; CELL CULTURE; COPOLYMERS; EXPERIMENTS; FIBROBLASTS; GROWTH KINETICS; NANOSTRUCTURED MATERIALS; NANOTECHNOLOGY; OXYGEN SUPPLY; TISSUE;

CARDIO-VASCULAR DISEASE; CARDIOMYOCYTES; CARDIOVASCULAR APPLICATIONS; CARDIOVASCULAR PATCHES; CYTOCOMPATIBILITY; ELECTRICAL STIMULATIONS; GROWTH CHARACTERISTIC; POLY LACTIC-CO-GLYCOLIC ACID;

CELL GROWTH;

CARBON NANOFIBER; GLYCOLIC ACID; TROPONIN I; CARBON NANOTUBE; LACTIC ACID; NANOPARTICLE; POLYGLYCOLIC ACID; POLYLACTIC ACID-POLYGLYCOLIC ACID COPOLYMER;

ANIMAL CELL; AORTA; BIOCOMPATIBILITY; CELL FUNCTION; CELL GROWTH; CELL PROLIFERATION; CELL STIMULATION; CELL TYPE; CONFERENCE PAPER; CONTROLLED STUDY; DENSITY; ENDOTHELIUM CELL; EXCRETION; FIBROBLAST; HEART MUSCLE CELL; HEART STIMULATION; IN VITRO STUDY; INTRACARDIAC PATCH; NONHUMAN; PROTEIN SECRETION; RAT; TISSUE SCAFFOLD; VASCULAR ENDOTHELIUM; ANIMAL; CELL CULTURE; CELL SURVIVAL; CHEMISTRY; CLASSIFICATION; COMPARATIVE STUDY; CYTOLOGY; ELECTROSTIMULATION; MATERIALS TESTING; PHYSIOLOGY; PROCEDURES;

ANIMALS; CELL PROLIFERATION; CELL SURVIVAL; CELLS, CULTURED; ELECTRIC STIMULATION; ENDOTHELIAL CELLS; FIBROBLASTS; LACTIC ACID; MATERIALS TESTING; MYOCYTES, CARDIAC; NANOPARTICLES; NANOTUBES, CARBON; POLYGLYCOLIC ACID; RATS; TISSUE SCAFFOLDS;

EID: 84907271540     PISSN: 09592989     EISSN: 18783619     Source Type: Journal    
DOI: 10.3233/BME-141020     Document Type: Conference Paper

References (12)

1. R. Khan and R. Sheppard, Fibrosis in heart disease: understanding the role of transforming growth factor-β1 in cardiomyopathy, valvular disease and arrhythmia, Immunology 118 (2002), 10-24.
2. B.J. Gersh, K. Sliwa, B.M. Mayosi and S. Yusuf, The epidemic of cardiovascular disease in the developing world: global implications, European Heart Journal 31 (2010), 642-648.
3. R. Valiev, Materials science: Nanomaterial advantage, Nature 419 (2002), 887-889.
4. T. Dvir, B.P. Timko, M.D. Brigham, S.R. Naik and S.S. Karajanagi, Nanowired three-dimensional cardiac patches, Nature Nano 720 (2011), 720-725.
5. D.A. Stout, B. Basu and T.J. Webster, Poly(lactic-co-glycolic acid): Carbon nanofiber composites for myocardial tissue engineering applications, Acta Biomaterialia 7 (2011), 3101-3112.
6. A. Verma and F. Stellacci, Effect of Surface Properties on Nanoparticle-Cell Interactions, Small 6 (2010), 12-21.
7. Y. Xia, L.M. Buja and J.B. McMillin, Change in Expression of Heart Carnitine Palmitoyltransferase I Isoforms with Electrical Stimulation of Cultured Rat Neonatal Cardiac Myocytes, Journal of Biological Chemistry 271 (1996), 12082-12087.
8. D.A. Stout, J. Yoo, A.N. Santiago-Miranda and T.J.Webster, Mechanisms of greater cardiomyocyte functions on conductive nanoengineered composites for cardiovascular application, International Journal of Nanomedicine 7 (2012), 5653-5669.
9. A.T. Soufan, G. van den Berg, J.M. Ruijter, P.A.J. de Boer and M. J. B. van den Hoff, Regionalized Sequence of Myocardial Cell Growth and Proliferation Characterizes Early Chamber Formation, Circulation Research 99 (2006), 545-552.
10. P. Lee, M. Klos, C. Bollensdorff, L. Hou, P. Ewart, T.J. Kamp, J. Zhang, A. Bizy, G. Guerrero-Serna, P. Kohl, J. Jalife and T.J. Herron, Simultaneous Voltage and Calcium Mapping of Genetically Purified Human Induced Pluripotent Stem Cell-Derived Cardiac Myocyte Monolayers, Circulation Research 110 (2012), 1556-1563.
11. T.J.Webster, C. Ergun, R.H. Doremus, R.W. Siegel and R. Bizios, Specific proteins mediate enhanced osteoblast adhesion on nanophase ceramics, Journal of Biomedical Materials Research 51 (2000), 475-479.
12. L. Yang, B.W. Sheldon and T.J. Webster, The impact of diamond nanocrystallinity on osteoblast functions, Biomaterials 30 (2009), 3458-3462.