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Coating Collagen Modules with Fibronectin Increases in vivo HUVEC Survival and Vessel Formation through the Suppression of ApoptosisCooper, Thomas 13 January 2010 (has links)
Modular tissue engineering is a novel approach to creating scalable, self-assembling three-dimensional tissue constructs with inherent vascularisation. Under initial methods, the subcutaneous implantation of human umbilical vein endothelial cell (HUVEC)-covered collagen modules in immunocompromised mice resulted in significant host inflammation and limited HUVEC survival. Subsequently, a minimally-invasive injection technique was developed to minimize surgery-related inflammation, and cell death was attributed to extensive apoptosis within 72 hours of implantation. In confirmation of in vitro results, coating collagen modules with fibronectin (Fn) was shown in vivo to reduce short-term HUVEC apoptosis by nearly 40%, while increasing long-term HUVEC survival by 30% to 45%. Consequently, a 100% increase in the number of HUVEC-lined vessels was observed with Fn-coated modules, as compared to collagen-only modules, at 7 and 14 days post-implantation. Furthermore, vessels appeared to be perfused with host erythrocytes by day 7, and vessel maturation and stabilization was evident by day 14.
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Coating Collagen Modules with Fibronectin Increases in vivo HUVEC Survival and Vessel Formation through the Suppression of ApoptosisCooper, Thomas 13 January 2010 (has links)
Modular tissue engineering is a novel approach to creating scalable, self-assembling three-dimensional tissue constructs with inherent vascularisation. Under initial methods, the subcutaneous implantation of human umbilical vein endothelial cell (HUVEC)-covered collagen modules in immunocompromised mice resulted in significant host inflammation and limited HUVEC survival. Subsequently, a minimally-invasive injection technique was developed to minimize surgery-related inflammation, and cell death was attributed to extensive apoptosis within 72 hours of implantation. In confirmation of in vitro results, coating collagen modules with fibronectin (Fn) was shown in vivo to reduce short-term HUVEC apoptosis by nearly 40%, while increasing long-term HUVEC survival by 30% to 45%. Consequently, a 100% increase in the number of HUVEC-lined vessels was observed with Fn-coated modules, as compared to collagen-only modules, at 7 and 14 days post-implantation. Furthermore, vessels appeared to be perfused with host erythrocytes by day 7, and vessel maturation and stabilization was evident by day 14.
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Translating Early Outgrowth Cell Therapy into a Clinically Relevant Approach for Long Term RenoprotectionKepecs, David 29 November 2013 (has links)
Current therapy for chronic kidney disease (CKD) is limited; however, recent studies have shown that a subpopulation of cells derived from the bone marrow, known as early outgrowth cells (EOCs), are able to attenuate kidney injury. Here we examined the efficacy of a modular tissue engineering system whereby the EOCs might be easily removed in the event of malignant change. While modular therapy mimicked the effects seen with standard EOC therapy, the modules degraded allowing the encapsulated EOCs to enter systemic circulation.
Given the presumed egress of EOCs, we explored an alternative strategy for kidney protection. Here we investigated the long-term effectiveness of administering the conditioned medium (EOC-CM) that contains the factors the EOCs secrete, rather than the cells themselves. In these studies, repeated administration of EOC-CM attenuated the structural and functional manifestations of kidney injury suggesting that this approach may provide an effective and feasible, cell-free approach for CKD.
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Translating Early Outgrowth Cell Therapy into a Clinically Relevant Approach for Long Term RenoprotectionKepecs, David 29 November 2013 (has links)
Current therapy for chronic kidney disease (CKD) is limited; however, recent studies have shown that a subpopulation of cells derived from the bone marrow, known as early outgrowth cells (EOCs), are able to attenuate kidney injury. Here we examined the efficacy of a modular tissue engineering system whereby the EOCs might be easily removed in the event of malignant change. While modular therapy mimicked the effects seen with standard EOC therapy, the modules degraded allowing the encapsulated EOCs to enter systemic circulation.
Given the presumed egress of EOCs, we explored an alternative strategy for kidney protection. Here we investigated the long-term effectiveness of administering the conditioned medium (EOC-CM) that contains the factors the EOCs secrete, rather than the cells themselves. In these studies, repeated administration of EOC-CM attenuated the structural and functional manifestations of kidney injury suggesting that this approach may provide an effective and feasible, cell-free approach for CKD.
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