Engineering the microstructure and spatial bioactivity of MAP scaffolds instructs vasculogenesis in vitro and modifies vessel formation in vivo.

In tissues where the vasculature is either lacking or abnormal, biomaterials can be designed to promote vessel formation and enhance tissue repair. In this work, we independently tune the microstructure and bioactivity of microporous annealed particle (MAP) scaffolds to guide cell growth in 3D and promote de novo assembly of endothelial progenitor-like cells into vessels. We implement both in silico characterization and in vitro experimentation to elucidate an optimal scaffold formulation for vasculogenesis. We determine that MAP scaffolds with pore volumes on the same order of magnitude as cells facilitate cell growth and vacuole formation. We achieve spatial control over cell spreading by incorporating adhesive microgels in well-mixed, heterogeneous MAP scaffolds. While we demonstrate that integrin engagement is the primary driver of network formation in these materials, introducing adhesive microgels loaded with heparin nanoparticles leads to the formation of vascular tubes after 3 days in culture. We then show in vivo that this unique scaffold formulation enhances vessel maturation in a wound healing model and instructs differential vascular development in the tumor microenvironment. Taken together, this work determines the optimal microstructure and ligand presentation within MAP scaffolds that leads to vascular constructs in vitro and facilitates vessel formation in vivo.

Duke Scholars

Author Sharon Gerecht Biomedical Engineering

Author Tatiana Segura Biomedical Engineering