Enhancement of In Vitro Capillary Tube Formation by Substrate Nanotopography.

Abstract

Vascular engineering remains a key thrust in advancing the field of tissue engineering of highly vascularized, complex, metabolic organs. A wide variety of strategies have been employed to control the formation of organized vascular structures in vitro and in vivo. Some of these methods include, but are not limited to, controlled growth factor delivery,[1] filamentous scaffold geometry,[2] protein micropatterning,[3] and enhanced scaffold biomaterials.[4] Many of these approaches are motivated by biomimicry of the in vivo microenvironment. Extracellular matrix (ECM) proteins, both in vitro and in vivo, provide mammalian cells with biophysical cues including specific surface chemistry and rich three-dimensional surface topography[5] with features on the nanometer length scale.[6] ECM substrates provide chemical and physical external cues that dictate a variety of cell responses. Therefore, it is not only the milieu of soluble, diffusible factors, but also the adhesive, mechanical interactions with scaffolding materials, both natural and synthetic, that control select cell functions including cell attachment, migration, proliferation, differentiation, and regulation of genes.[7–9] We hypothesized that physical features on nanofabricated substrates could promote the organization of endothelial cell lineages into well-defined vascular structures in vitro by inducing the contact guidance phenomenon, which is known to affect the morphology of endothelial cells.[10–12]We found that endothelial progenitor cells (EPCs) responded to ridge-groove grating of 1200 nm in period and 600 nm in depth through alignment, elongation, reduced proliferation, and enhanced migration. Although endothelial- specific markers were not significantly altered, EPCs cultured on substrate nanotopography formed supercellular band structures after 6 d. Furthermore, an in vitro Matrigel assay led to enhanced capillary tube formation and organization.