Biomimetic hydrogels with pro-angiogenic properties

Moon, James J.; Saik, Jennifer E.; Poché, Ross A.; Leslie-Barbick, Julia E.; Lee, Soo Hong; Smith, April Ann; Dickinson, Mary E.; West, Jennifer L.

doi:10.1016/j.biomaterials.2010.01.104

Cited by 325 publications

(345 citation statements)

References 31 publications

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“…However, the inherent chemical and physical properties of these natural materials have limited their clinical usage [14,15]. Recent studies have explored synthetic materials as a xeno-free and more clinically relevant alternative for both therapeutic angiogenesis [16,17] and vascularization of tissue-engineered constructs [18,19]. We recently reported that hyaluronic acid (HA) hydrogels can be engineered to precisely control the generation of functional human vascular networks by ECFCs [20].…”

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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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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“…165 Hydrogels were fabricated with integrin binding sites and protease-sensitive substrates to mimic the natural provisional ECM, and ECs cultured in these hydrogels organized into stable, intricate networks of capillary-like structures. The resulting structures were further stabilized by recruitment of mesenchymal progenitor cells that differentiated to a SMC lineage and deposited collagen IV and laminin.…”

Section: 폴리머 제38권 제2호 2014년mentioning

confidence: 99%

Recent Applications of Polymeric Biomaterials and Stem Cells in Tissue Engineering and Regenerative Medicine

Lee

Yoo

Atala³

2014

Polymer Korea

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Tissue engineering and regenerative medicine strategies could offer new hope for patients with serious tissue injuries or end-stage organ failure. Scientists are now applying the principles of cell transplantation, material science, and engineering to create biological substitutes that can restore and maintain normal function in diseased or injured tissues/ organs. Specifically, creation of engineered tissue construct requires a polymeric biomaterial scaffold that serves as a cell carrier, which would provide structural support until native tissue forms in vivo. Even though the requirements for scaffolds may be different depending on the target applications, a general function of scaffolds that need to be fulfilled is biodegradability, biological and mechanical properties, and temporal structural integrity. The scaffold's internal architecture should also enhance the permeability of nutrients and neovascularization. In addition, the stem cell field is advancing, and new discoveries in tissue engineering and regenerative medicine will lead to new therapeutic strategies. Although use of stem cells is still in the research phase, some therapies arising from tissue engineering endeavors that make use of autologous adult cells have already entered the clinic. This review discusses these tissue engineering and regenerative medicine strategies for various tissues and organs.

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“…In addition, hydrolytic degradation is not representative of the cellularly mediated and dynamic process of proteolysis that takes place within the native ECM. Therefore, numerous studies have covalently incorporated peptide sequences susceptible to cleavage by cell-secreted proteases (i.e., plasmin-sensitive or MMPsensitive sequences) into PEG hydrogels thus manipulating gel degradation dynamically in response to cellularly mediated events (Gobin & West, 2002;Lee et al, 2007;Lutolf et al, 2003;Moon et al, 2007;Moon et al, 2010;Patterson & Hubbell 2010;Phelps et al, 2009;Seliktar et al, 2004;West & Hubbell, 1999;Zisch et al, 2003).…”

Section: Engineering Ecm Cues Into Peg Hydrogel Scaffoldsmentioning

confidence: 99%

“…Studies using UV-based freeradical photopolymerization for the formation of MMP-sensitive, VEGF-bearing PEGDA hydrogels as potential matrices for the induction of vascularization indicated that endothelial cell tubule formation and maintenance was directly affected by gel mechanical properties. Hydrogels formed with an intermediate polymer weight percentage of 10% resulted in the formation of tubules, while less crosslinked PEGDA matrices (7.5% PEG content) caused complete tubule regression, and matrices (15% PEG content) reduced tubule formation in vitro (Moon et al, 2010). PEG hydrogels of this intermediate stiffness were implanted into mouse cornea using a micropocket angiogenesis assay and resulted in neovascularization in the presence of vascular endothelial growth factor (VEGF) (Rogers et al, 2007).…”

Section: Wwwintechopencommentioning

confidence: 99%

Synthetic PEG Hydrogels as Extracellular Matrix Mimics for Tissue Engineering Applications

Papavasiliou¹,

Sokic²,

Turturro³

2012

Biotechnology - Molecular Studies and Novel Applications for Improved Quality of Human Life

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Biomimetic hydrogels with pro-angiogenic properties

Cited by 325 publications

References 31 publications

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

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

Recent Applications of Polymeric Biomaterials and Stem Cells in Tissue Engineering and Regenerative Medicine

Synthetic PEG Hydrogels as Extracellular Matrix Mimics for Tissue Engineering Applications

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