A key feature of peripheral arterial disease (PAD) is damage to endothelial cells (ECs), resulting in lower limb pain and restricted blood flow. Recent preclinical studies demonstrate that the transplantation of ECs via direct injection into the affected limb can result in significantly improved blood circulation. Unfortunately, the clinical application of this therapy has been limited by low cell viability and poor cell function. To address these limitations we have developed an injectable, recombinant hydrogel, termed SHIELD (Shear-thinning Hydrogel for Injectable Encapsulation and Long-term Delivery) for cell transplantation. SHIELD provides mechanical protection from cell membrane damage during syringe flow. Additionally, secondary in situ crosslinking provides a reinforcing network to improve cell retention, thereby augmenting the therapeutic benefit of cell therapy. In this study, we demonstrate the improved acute viability of human induced pluripotent stem cell-derived endothelial cells (iPSC-ECs) following syringe injection delivery in SHIELD, compared to saline. Using a murine hind limb ischemia model of PAD, we demonstrate enhanced iPSC-EC retention in vivo and improved neovascularization of the ischemic limb based on arteriogenesis following transplantation of iPSC-ECs delivered in SHIELD.
A key feature of peripheral arterial disease (PAD) is damage to endothelial cells (ECs), resulting in lower pan class="Disease">limb pain and restricted blood flow. Recent preclinical studies demonstrate that the transplantation of ECs via direct injection into the affected limb can result in significantly improved blood circulation. Unfortunately, the clinical application of this therapy has been limited by low cell viability and poor cell function. To address these limitations we have developed an injectable, recombinant hydrogel, termed SHIELD (Shear-thinning Hydrogel for Injectable Encapsulation and Long-term Delivery) for cell transplantation. SHIELD provides mechanical protection from cell membrane damage during syringe flow. Additionally, secondary in situ crosslinking provides a reinforcing network to improve cell retention, thereby augmenting the therapeutic benefit of cell therapy. In this study, we demonstrate the improved acute viability of human induced pluripotent stem cell-derived endothelial cells (iPSC-ECs) following syringe injection delivery in SHIELD, compared to saline. Using a murine hind limb ischemia model of PAD, we demonstrate enhanced iPSC-EC retention in vivo and improved neovascularization of the ischemic limb based on arteriogenesis following transplantation of iPSC-ECs delivered in SHIELD.
Authors: Yu-An Cao; Michael H Bachmann; Andreas Beilhack; Yang Yang; Masashi Tanaka; Rutger-Jan Swijnenburg; Robert Reeves; Cariel Taylor-Edwards; Stephan Schulz; Timothy C Doyle; C Garrison Fathman; Robert C Robbins; Leonore A Herzenberg; Robert S Negrin; Christopher H Contag Journal: Transplantation Date: 2005-07-15 Impact factor: 4.939
Authors: Martina Montagnana; Cristiano Fava; Enrico Arosio; Maurizio Degan; Rosa Maria Tommasoli; Sergio De Marchi; Pietro Delva; Roberta Spadaro; Gian Cesare Guidi; Alessandro Lechi; Clara Lechi Santonastaso; Pietro Minuz Journal: Int J Angiol Date: 2007
Authors: N Fiotti; C Giansante; E Ponte; C Delbello; S Calabrese; T Zacchi; A Dobrina; G Guarnieri Journal: Atherosclerosis Date: 1999-07 Impact factor: 5.162
Authors: Christopher B Rodell; John W MacArthur; Shauna M Dorsey; Ryan J Wade; Leo L Wang; Y Joseph Woo; Jason A Burdick Journal: Adv Funct Mater Date: 2014-12-12 Impact factor: 18.808
Authors: Santiago Correa; Abigail K Grosskopf; Hector Lopez Hernandez; Doreen Chan; Anthony C Yu; Lyndsay M Stapleton; Eric A Appel Journal: Chem Rev Date: 2021-05-03 Impact factor: 60.622
Authors: Joscha Mulorz; Mahdis Shayan; Caroline Hu; Cynthia Alcazar; Alex H P Chan; Mason Briggs; Yan Wen; Ankita P Walvekar; Anand K Ramasubramanian; Joshua M Spin; Bertha Chen; Philip S Tsao; Ngan F Huang Journal: Biomater Sci Date: 2021-10-12 Impact factor: 7.590