Three-dimensional 10% cyclic strain reduces bovine aortic endothelial cell angiogenic sprout length and augments tubulogenesis in tubular fibrin hydrogels.

The development of a functional microvasculature is critical to the long-term survival of implanted tissue-engineered constructs. Dynamic culture conditions have been shown to significantly modulate phenotypic characteristics and stimulate proliferation of cells within hydrogel-based tissue engineered blood vessels. Although prior work has described the effects uniaxial or equibiaxial mechanical stimulation has on endothelial cells, no work has outlined effects of three-dimensional mechanical stimulation on endothelial cells within tubular vessel analogues.

The temporal and spatial dynamics of microscale collagen scaffold remodeling by smooth muscle cells.

Smooth muscle cells (SMCs) and collagen scaffolds are widely used in vascular tissue engineering but their interactions in remodeling at the microscale level remained unclear. We characterized microscale morphologic alterations of collagen remodeled by SMCs in six dimensions: three spatial, time, multichannel and multi-position dimensions. In live imaging assays, computer-assisted cell tracking showed locomotion characteristics of SMCs; reflection and fluorescent confocal microscopy and spatial reconstruction images of each time point showed detailed morphologic changes of collagen fibers and spatial collagen-SMC interactions.