Prolonging The Viability Of Induced Pluripotent Stem Cellderived Endothelial Cells For Treatment Of Peripheral Arterial Disease Using Engineered Biomaterials

Dysfunctional endothelial cells (EC) can restrict flow in the extremities, leading to limb ischemia. We aim to improving revascularization of ischemic limbs using cell therapy, augmented with spatially patterned scaffolds that promote survival. The purpose was to evaluate the effect spatially patterned scaffolds on endothelial cell survival. The biophysical parameters of collagen scaffolds (alignment, crosslinking, and fibril diameter) were characterized with atomic force microscopy and degradation assays. Cytoskeletal arrangement of primary human coronary artery ECs and human induced pluripotent stem cell (iPSC)-derived ECs on collagen scaffolds was evaluated by F-actin staining. To evaluate the effect of mechanical properties on cell viability in vitro, Live/Dead and MTS assays were used. Cell seeded scaffolds were implanted into a mouse hindlimb ischemia model, and cell survival was tracked by bioluminescent imaging. Both primary EC and iPSC-ECs reorganized their F-actin cytoskeleton corresponding to the alignment of the fibrils, irrespective of crosslinking degree, stiffness or fibril diameter. When cells were grown in hypoxic mimicking ischemia however, viability was improved using aligned scaffolds with 200 nm fibril diameter. Degradation assays showed that scaffolds with higher crosslinking had significantly more durability. When cell-seeded scaffolds were implanted to the ischemic limb, the aligned scaffolds with 200nm fibril diameter had the highest survival, confirming in vitro studies. Aligned collagen scaffolds with 200nm fibril diameter and high cross-linking degree led to improved viability of primary and iPSC-ECs in a mouse model of PAD.