Vascularization and engraftment of a human skin substitute using circulating progenitor cell‐derived endothelial cells

Shepherd, Benjamin R.; Enis, David R.; Wang, Feiya; Suárez, Yajaira; Pober, Jordan S.; Schechner, Jeffrey S.

doi:10.1096/fj.05-5682fje

Cited by 130 publications

(89 citation statements)

References 40 publications

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“…Transplanted HUVEC transfected with an antiapoptotic gene, Bcl-2, 21,25 or HUVEC mixed with mesenchymal precursor cells 20 were shown to form stable blood vessels in SCID mice. Also, HUVEC-derived vessels in SCID mice were shown to increase overall tissue perfusion in an ischemic hindlimb model 20 and to effectively vascularize tissues, including skin substitutes 26 and three-dimensional skeletal muscle constructs. 27 This work has been extended recently to the problem of prevascularizing a cardiac patch with HUVEC in a nude rat with cyclosporine, 28 or SpragueDawley rats with immune suppression.…”

Section: Discussionmentioning

confidence: 99%

“…and vessel formation was only realized after the HUVEC were transfected with antiapoptotic genes (Bcl-2) or cotransplanted with supporting cells (mesenchymal stem cells, embryonic fibroblasts, or perivascular cell precursors) as HUVEC alone did not achieve stable vascularization in vivo. 20,21,25,26 Here, transplanted EC survival was obtained without genetic modification of the EC or without cotransplantation of supporting cells. Presumably, in this model the transplanted EC drive the remodeling process that results in both host EC and supporting cell recruitment required to create a stable vasculature.…”

Section: Discussionmentioning

confidence: 99%

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Chimeric Vessel Tissue Engineering Driven by Endothelialized Modules in Immunosuppressed Sprague-Dawley Rats

Chamberlain

Gupta

Sefton

2011

Tissue Engineering Part A

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Modular tissue engineering is a means of building functional, vascularized tissues using small (*1 mm long 0.5 mm diameter) components. While this approach is being explored for its utility in adipose and cardiac tissue engineering and in islet transplantation, the initial question in this study was to assess the fate of the endothelial cells (EC) after transplantation delivered on the surface of modules, without an embedded cell. Rat aortic ECcovered collagen gel modules were transplanted into the omental pouch of allogeneic (outbred) Sprague-Dawley rats with and without immunosuppressive drug treatment (atorvastatin and tacrolimus) for 3-60 days. There was a significant increase in vessel density at all time points in the drug treated rats as compared to untreated rats. Green fluorescent protein (GFP)-positive donor rat aortic EC migrated from the surface of the modules and formed primitive vessels by day 7. In the untreated rats, the GFP-positive cells were not seen after day 7. In drugtreated rats, GFP-positive vessels matured over time, accumulated erythrocytes, were supported by host smooth muscle cells, and formed chimeric vessels that survived until day 60. This resulted in the formation of a densely vascularized, perfusable network by day 60. To our knowledge, this is the first study that demonstrates that primary unmodified EC, without the addition of supporting cells, form a chimeric and stable vascular bed in allogeneic, although drug-treated, animals.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Chimeric Vessel Tissue Engineering Driven by Endothelialized Modules in Immunosuppressed Sprague-Dawley Rats

Chamberlain

Gupta

Sefton

2011

Tissue Engineering Part A

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“…Schechner and colleagues [30,31] pioneered the use of marrow-derived circulating EPCs to promote vascularization prior to skin graft transplantation. After ex vivo culture of EPCs on the collagen-based skin graft, EPCs revascularized and promoted the survival of the skin grafts with minimal immune response [32]. More recently, putative EPCs have been redefined as ECFCs to underscore their stem cell properties, including their robust proliferative potential, their ability to form secondary and tertiary colonies, and their capacity, in vivo, to form blood vessels de novo [33,34].…”

Section: Introductionmentioning

confidence: 99%

Integration and Regression of Implanted Engineered Human Vascular Networks During Deep Wound Healing

Hanjaya‐Putra

Shen

Wilson

et al. 2013

Stem Cells Translational Medicine

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The ability of vascularized constructs to integrate with tissues may depend on the kinetics and stability of vascular structure development. This study assessed the functionality and durability of engineered human vasculatures from endothelial progenitors when implanted in a mouse deep burn-wound model. Human vascular networks, derived from endothelial colony-forming cells in hyaluronic acid hydrogels, were transplanted into third-degree burns. On day 3 following transplantation, macrophages rapidly degraded the hydrogel during a period of inflammation; through the transitions from inflammation to proliferation (days 5-7), the host's vasculatures infiltrated the construct, connecting with the human vessels within the wound area. The growth of mouse vessels near the wound area supported further integration with the implanted human vasculatures. During this period, the majority of the vessels (ϳ60%) in the treated wound area were human. Although no increase in the density of human vessels was detected during the proliferative phase, they temporarily increased in size. This growth peaked at day 7, the middle of the proliferation stage, and then decreased by the end of the proliferation stage. As the wound reached the remodeling period during the second week after transplantation, the vasculatures including the transplanted human vessels generally regressed, and few microvessels, wrapped by mouse smooth muscle cells and with a vessel area less than 200 m 2 (including the human ones), remained in the healed wound. Overall, this study offers useful insights for the development of vascularization strategies for wound healing and ischemic conditions, for tissue-engineered constructs, and for tissue regeneration. STEM CELLS TRANSLATIONAL MEDICINE 2013;2:297-306

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“…Besides the direct incorporation into vessels, BOEC indirectly stimulate host angiogenesis. 52 Unlike previously assumed, 53 we and others have shown that BOEC secrete several GFs that modulate angiogenesis and wound healing 9,52 (Table 1). Interestingly, early outgrowth EPC (or the factors they secrete) have a stimulatory effect on tube formation by BOEC, 53 which makes a combination therapy of both cell types attractive.…”

mentioning

confidence: 81%

“…Cord blood: Many studies highlight the excellent outgrowth of BOEC from CB (CB-BOEC) and suggest them, due to their high expansion and vasculogenic potential, to be ideal candidates for (S)TE purposes. 43,52,56,57 Au et al examined the in vivo vessel formation capacity of CB-BOEC in combination with pericyte-like cells and noted firmly increased survival, vessel formation and stability in comparison with ABderived BOEC (AB-BOEC). 56 CB-BOEC formed stable vessels in a dermal PGA-PLLA matrix when cotransplanted with SMC.…”

mentioning

confidence: 99%

Cell-Based Vascularization Strategies for Skin Tissue Engineering

Hendrickx

Vranckx

Luttun

2011

Tissue Engineering Part B: Reviews

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Vascularization and engraftment of a human skin substitute using circulating progenitor cell‐derived endothelial cells

Cited by 130 publications

References 40 publications

Chimeric Vessel Tissue Engineering Driven by Endothelialized Modules in Immunosuppressed Sprague-Dawley Rats

Chimeric Vessel Tissue Engineering Driven by Endothelialized Modules in Immunosuppressed Sprague-Dawley Rats

Integration and Regression of Implanted Engineered Human Vascular Networks During Deep Wound Healing

Cell-Based Vascularization Strategies for Skin Tissue Engineering

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