Differential effects of cyclic stretch on bFGF- and VEGF-induced sprouting angiogenesis.

How mechanical factors affect angiogenesis and how they and chemical angiogenic factors work in concert remain not yet well-understood. This study investigated the interactive effects of cyclic uniaxial stretch and two potent proangiogenic molecules [basic fibroblast growth factor (bFGF) and vascular endothelial growth factor (VEGF)] on angiogenesis using a stretchable three-dimensional (3-D) cell culture model. Endothelial cells seeded atop a 3-D collagen gel underwent sprouting angiogenesis while being subjected to either 10 or 20% cyclic uniaxial stretch at a frequency of either 1/12 or 1 Hz, in conjunction with an elevated concentration of bFGF or VEGF. Without the presence of additional growth factors, 10 and 20% stretch at 1 Hz induced angiogenesis and the perpendicular alignment of new sprouts, and both inductive effects were abolished by cytochalasin D (an actin polymerization inhibitor). While "10% stretch at 1 Hz," "20% stretch at 1 Hz," bFGF, and VEGF were strong angiogenesis stimulants individually, only the combination of "20% stretch at 1 Hz" and bFGF had an additive effect on inducing new sprouts. Interestingly, the combination of "20% stretch at a lower frequency (1/12 Hz)" and bFGF decreased sprouting angiogenesis, even though the level of perpendicular alignment of new sprouts was the same for both stretch frequencies. Taken together, these results demonstrate that both stretch frequency and magnitude, along with interactions with various growth factors, are essential in mediating formation of endothelial sprouts and vascular patterning. Furthermore, work in this area is warranted to elucidate synergistic or competitive signaling mechanisms.

Investigating surface topology and cyclic-RGD peptide functionalization on vascular endothelialization.

The advantages of endothelialization of a stent surface in comparison with the bare metal and drug-eluting stents used today include reduced late-stent restenosis and in-stent thrombosis. In this article, we study the effect of surface topology and functionalization of tantalum (Ta) with cyclic-(arginine-glycine-aspartic acid-d-phenylalanine-lysine) (cRGDfK) on the attachment, spreading, and growth of vascular endothelial cells. Self-assembled nanodimpling on Ta surfaces was performed using a one-step electropolishing technique. Next, cRGDfK was covalently bonded onto the surface using silane chemistry. Our results suggest that nanotexturing alone was sufficient to enhance cell spreading, but the combination of a nanodimpled surfaces along with the cRGDfK peptide may produce a better endothelialization coating on the surface in terms of higher cell density, better cell spreading, and more cell-cell interactions, when compared to using cRGDfK peptide functionalization alone or nanotexturing alone. We believe that future research should look into how to implement both modifications (topographic and chemical modifications) to optimize the stent surface for endothelialization.