Biologically Inspired, Cell-Selective Release of Aptamer-Trapped Growth Factors by Traction Forces
Stejskalova, Anna; Oliva, Nuria; England, Frances J.; Almquist, Benjamin D.
ADVANCED MATERIALS
2019
VL / 31 - BP / - EP /
abstract
Biomaterial scaffolds that are designed to incorporate dynamic, spatiotemporal information have the potential to interface with cells and tissues to direct behavior. Here, a bioinspired, programmable nanotechnology-based platform is described that harnesses cellular traction forces to activate growth factors, eliminating the need for exogenous triggers (e.g., light), spatially diffuse triggers (e.g., enzymes, pH changes), or passive activation (e.g., hydrolysis). Flexible aptamer technology is used to create modular, synthetic mimics of the Large Latent Complex that restrains transforming growth factor-beta 1 (TGF-beta 1). This flexible nanotechnology-based approach is shown here to work with both platelet-derived growth factor-BB (PDGF-BB) and vascular endothelial growth factor (VEGF-165), integrate with glass coverslips, polyacrylamide gels, and collagen scaffolds, enable activation by various cells (e.g., primary human dermal fibroblasts, HMEC-1 endothelial cells), and unlock fundamentally new capabilities such as selective activation of growth factors by differing cell types (e.g., activation by smooth muscle cells but not fibroblasts) within clinically relevant collagen sponges.
-
362 InfluRatio
AccesS level
Hybrid, Green accepted
MENTIONS DATA
Materials Science
-
2 Twitter
-
44 Wikipedia
-
0 News
-
55 Policy
Chemistry
-
2 Twitter
-
44 Wikipedia
-
0 News
-
55 Policy
Physics
-
2 Twitter
-
44 Wikipedia
-
0 News
-
55 Policy
Engineering
-
2 Twitter
-
44 Wikipedia
-
0 News
-
55 Policy
Among papers in Materials Science
Among papers in Chemistry
Among papers in Physics
Among papers in Engineering
Más información
Influscience
Rankings
- BETA VERSION