Biomedical Engineering Reference
In-Depth Information
PUNSHON, G., SALES, K.M., VARA, D.S., HAMILTON, G., and SEIFALIAN, A.M. (2008). Assess-
ment of the potential of progenitor stem cells extracted from human peripheral
blood for seeding a novel vascular graft material.
Cell Proliferation
41
, 321-335.
RABKIN, E., and SCHOEN, F. J. (2002). Cardiovascular tissue engineering.
Cardiovasc
Pathol
11
, 305-317.
RAFI I, S., and LYDEN, D. (2003). Therapeutic stem and progenitor cell transplantation
for organ vascularization and regeneration.
Nat Med
9
, 702-712.
RAVI, S., QU, Z., and CHAIKOF, E.L. (2009). Polymeric materials for tissue engineering
of arterial substitutes.
Vascular
17
Suppl 1, S45-54.
REDONDO, S., SANTOS-GALLEGO, C.G., and TEJERINA, T. (2007). TGF-beta1: a novel
target for cardiovascular pharmacology.
Cytokine Growth Factor Rev
18
,
279-286.
REUBINOFF, B.E., PERA, M.F., FONG, C.Y., TROUNSON, A., and BONGSO, A. (2000). Embry-
onic stem cell lines from human blastocysts: somatic differentiation
in vitro
.
Nat
Biotechnol
18
, 399-404.
REUSCH, P. , WAGDY, H., REUSCH, R., WILSON, E., and IVES, H.E. (1996). Mechanical strain
increases smooth muscle and decreases nonmuscle myosin expression in rat vas-
cular smooth muscle cells.
Circulation Res
79
, 1046-1053.
RISAU, W., SARIOLA, H., ZERWES, H.G., SASSE, J., EKBLOM, P. , KEMLER, R., and DOETSCHMAN,
T. (1988). Vasculogenesis and angiogenesis in embryonic-stem-cell-derived
embryoid bodies.
Development (Cambridge, England)
102
, 471-478.
RITTER, E.F., FATA, M.M., RUDNER, A.M., and KLITZMAN, B. (1998). Heparin bonding
increases patency of long microvascular prostheses.
Plastic Reconstructive Surg
101
, 142-146.
RODGERS, U.R., and WEISS, A.S. (2005). Cellular interactions with elastin.
Pathologie-
biologie
53
, 390-398.
ROH, J.D., NELSON, G.N., BRENNAN, M.P., MIRENSKY, T.L., YI, T., HAZLETT, T.F., TELLIDES,
G., SINUSAS, A.J., POBER, J.S., SALTZMAN, W.M.,
et al.
(2008). Small-diameter biode-
gradable scaffolds for functional vascular tissue engineering in the mouse model.
Biomaterials
29
, 1454-1463.
ROSENMAN, J.E., KEMPCZINSKI, R.F., PEARCE, W.H., and SILBERSTEIN, E.B. (1985). Kinetics
of endothelial cell seeding.
J Vasc Surg
2
, 778-784.
ROSS, J.J., HONG, Z., WILLENBRING, B., ZENG, L., ISENBERG, B., LEE, E.H., REYES, M.,
KEIRSTEAD, S.A., WEIR, E.K., TRANQUILLO, R.T.,
et al.
(2006). Cytokine-induced dif-
ferentiation of multipotent adult progenitor cells into functional smooth muscle
cells.
J Clin Investi
116
, 3139-3149.
ROWE, S.L., LEE, S., and STEGEMANN, J.P. (2007). Infl uence of thrombin concentration
on the mechanical and morphological properties of cell-seeded fi brin hydrogels.
Acta Biomaterialia
3
, 59-67.
RUFAIHAH, A.J., HAIDER, H.K., HENG, B.C., YE, L., TOH, W.S., TIAN, X.F., LU, K., SIM, E.K.,
and CAO, T. (2007). Directing endothelial differentiation of human embryonic
stem cells via transduction with an adenoviral vector expressing the VEGF(165)
gene.
J Gene Med
9
, 452-461.
SACHLOS, E., and CZERNUSZKA, J.T. (2003). Making tissue engineering scaffolds work.
Review: the application of solid freeform fabrication technology to the produc-
tion of tissue engineering scaffolds.
Europ Cells Mater
5
, 29-39; discussion 39-40.
SAHOO, S., ANG, L.T., GOH, J.C., and TOH, S.L. (2010). Growth factor delivery through
electrospun nanofi bers in scaffolds for tissue engineering applications.
J Biomed
Mater Res A
93
, 1539-1550.
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