Beta-cell replacement therapy via islet transplantation remains a promising technology for the reversal of type 1 diabetes. A significant barrier to the clinical utilization of beta cell transplants has been the lack of a host-derived blood supply to maintain the viability and thus the function of transplanted cells. We have developed a new cell-based therapy for the generation of pre-vascularized tissue engineered constructs. We have also developed a new generation of biomaterials that support extensive neovascularization. The combined cell and material construct to be evaluated is termed a Prevascularized Immuno-Isolation Device or PVID. We propose to use these materials in the development of a new beta-cell immuno-isolation device to prolong beta cell viability and function. These constructs represent a pre-formed microcirculation that can be constructed from a patient's own fat-derived microvascular endothelial cells, avoiding the use of immuno- suppressive drugs.
Specific aim 1 will evaluate the maturation of the microcirculation within a prevascularized construct following implantation in an animal model.
Specific aim 2 will evaluate novel porous biomaterials and material surface modification to support the neovascularization of the porous material to assure perfusion of encapsulated islets. The biomaterial developed is a two component hybrid system that also provides immunoisolation for the encapsulated islets.
Specific aim 3 will evaluate the viability and function of islets encapsulated in the prevascularized immunoisolation devices in an animal model of diabetes.
Krishnan, Laxminarayanan; Touroo, Jeremy; Reed, Robert et al. (2014) Vascularization and cellular isolation potential of a novel electrospun cell delivery vehicle. J Biomed Mater Res A 102:2208-19 |
Krishnan, Laxminarayanan; Chang, Carlos C; Nunes, Sara S et al. (2013) Manipulating the microvasculature and its microenvironment. Crit Rev Biomed Eng 41:91-123 |
Nunes, S S; Maijub, J G; Krishnan, L et al. (2013) Generation of a functional liver tissue mimic using adipose stromal vascular fraction cell-derived vasculatures. Sci Rep 3:2141 |
Chang, Carlos C; Krishnan, Laxminarayanan; Nunes, Sara S et al. (2012) Determinants of microvascular network topologies in implanted neovasculatures. Arterioscler Thromb Vasc Biol 32:5-14 |
Krishnan, L; Clayton, L R; Boland, E D et al. (2011) Cellular immunoisolation for islet transplantation by a novel dual porosity electrospun membrane. Transplant Proc 43:3256-61 |
Chang, Carlos C; Boland, Eugene D; Williams, Stuart K et al. (2011) Direct-write bioprinting three-dimensional biohybrid systems for future regenerative therapies. J Biomed Mater Res B Appl Biomater 98:160-70 |
Williams, Stuart K; Kleinert, Leigh B; Patula-Steinbrenner, Vangie (2011) Accelerated neovascularization and endothelialization of vascular grafts promoted by covalently bound laminin type 1. J Biomed Mater Res A 99:67-73 |
Nunes, Sara S; Greer, Kevin A; Stiening, Chad M et al. (2010) Implanted microvessels progress through distinct neovascularization phenotypes. Microvasc Res 79:10-20 |
Gruionu, Gabriel; Stone, Alice L; Schwartz, Mark A et al. (2010) Encapsulation of ePTFE in prevascularized collagen leads to peri-implant vascularization with reduced inflammation. J Biomed Mater Res A 95:811-8 |