Abstract
The in vitro vascularization of 3D tissue constructs, such as hydrogels, remains a paramount challenge in tissue engineering. Extracellular matrix degradation and remodeling are key parts of the vascularization process; however, it is difficult to isolate the effects of degradability in both natural and synthetic matrix models. Naturally-derived matrices typically couple degradability to other material properties, whereas synthetic matrices rely on short peptide sequences to impart degradability, which typically exhibit substrate overlap to many proteases. Here, we present a method to independently and broadly tune 3D hydrogel degradation using crosslinkers with non-natural peptoid (N-substituted glycine) substitutions. Increased peptoid substitutions reduced hydrogel degradability to collagenases without altering hydrogel modulus, swelling ratio, or crosslinker length. Using this approach, human umbilical vein endothelial cells (HUVECs) encapsulated in more degradable hydrogels proliferated more, formed more vessels, exhibited higher metabolic activity, and secreted more extracellular matrix than HUVECs encapsulated in less degradable or non-degradable hydrogels. Interestingly, HUVECs encapsulated in the least degradable hydrogels secreted significantly higher matrix metalloproteinase-2 (MMP-2) and matrix metalloproteinase-9 (MMP-9) than HUVECs encapsulated in the most degradable hydrogels, suggesting higher MMP secretion to compensate for the reduced matrix degradability. Overall, this work highlights the importance of protease-mediated remodeling on vascularization and suggests that peptoid substitutions are effective for tuning hydrogel degradability for a variety of 3D cell applications.