Browsing by Subject "Vasculogenesis"
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Item Open Access A Tissue-Engineered Microvascular System to Evaluate Vascular Progenitor Cells for Angiogenic Therapies(2015) Brown Peters, Erica ChoThe ability of tissue engineered constructs to replace diseased or damaged organs is limited without the incorporation of a functional vascular system. To design microvasculature that recapitulates the vascular niche functions for each tissue in the body, we investigated the following hypotheses: (1) cocultures of human umbilical cord blood-derived endothelial progenitor cells (hCB-EPCs) with mural cells can produce the microenvironmental cues necessary to support physiological microvessel formation in vitro; (2) poly(ethylene glycol) (PEG) hydrogel systems can support 3D microvessel formation by hCB-EPCs in coculture with mural cells; (3) mesenchymal cells, derived from either umbilical cord blood (MPCs) or bone marrow (MSCs), can serve as mural cells upon coculture with hCB-EPCs. Coculture ratios between 0.2 (16,000 cells/cm2) and 0.6 (48,000 cells/cm2) of hCB-EPCs plated upon 3.3 µg/ml of fibronectin-coated tissue culture plastic with (80,000 cells/cm2) of human aortic smooth muscle cells (SMCs), results in robust microvessel structures observable for several weeks in vitro. Endothelial basal media (EBM-2, Lonza) with 9% v/v fetal bovine serum (FBS) could support viability of both hCB-EPCs and SMCs. Coculture spatial arrangement of hCB-EPCs and SMCs significantly affected network formation with mixed systems showing greater connectivity and increased solution levels of angiogenic cytokines than lamellar systems. We extended this model into a 3D system by encapsulation of a 1 to 1 ratio of hCB-EPC and SMCs (30,000 cells/µl) within hydrogels of PEG-conjugated RGDS adhesive peptide (3.5 mM) and PEG-conjugated protease sensitive peptide (6 mM). Robust hCB-EPC microvessels formed within the gel with invasion up to 150 µm depths and parameters of total tubule length (12 mm/mm2), branch points (127/mm2), and average tubule thickness (27 µm). 3D hCB-EPC microvessels showed quiescence of hCB-EPCs (<1% proliferating cells), lumen formation, expression of EC proteins connexin 32 and VE-cadherin, eNOS, basement membrane formation by collagen IV and laminin, and perivascular investment of PDGFR-β+/α-SMA+ cells. MPCs present in <15% of isolations displayed >98% expression for mural markers PDGFR-β, α-SMA, NG2 and supported hCB-EPC by day 14 of coculture with total tubule lengths near 12 mm/mm2. hCB-EPCs cocultured with MSCs underwent cell loss by day 10 with a 4-fold reduction in CD31/PECAM+ cells, in comparison to controls of hCB-EPCs in SMC coculture. Changing the coculture media to endothelial growth media (EBM-2 + 2% v/v FBS + EGM-2 supplement containing VEGF, FGF-2, EGF, hydrocortisone, IGF-1, ascorbic acid, and heparin), promoted stable hCB-EPC network formation in MSC cocultures over 2 weeks in vitro, with total segment length per image area of 9 mm/mm2. Taken together, these findings demonstrate a tissue engineered system that can be utilized to evaluate vascular progenitor cells for angiogenic therapies.
Item Embargo Engineering the microstructure and spatial bioactivity of granular biomaterials to guide vascular patterning(2023) Anderson, Alexa R.In tissues where the vasculature is either lacking or abnormal, biomaterial interventions can be designed to induce vessel formation and promote tissue repair. The porous architecture of biomaterials plays a key role in influencing cell infiltration and inducing vascularization by enabling the diffusion of nutrients and providing structural avenues for vessel ingrowth. Microporous annealed particle (MAP) scaffolds are a class of biomaterial that inherently possess a tunable, porous architecture. These materials are composed of small hydrogel particles, or microgels, that pack together to produce an interconnected, porous network. We first demonstrated that the particle fraction in MAP scaffolds serves as a bioactive cue for cell growth. To control this bioactive cue, we developed methods to form MAP scaffolds with user-defined particle fractions to reproducibly assess mechanical properties, macromolecular diffusion, as and cell responses. We then modulated the microstructure of the MAP scaffolds by changing microgel size as well as the spatial bioactivity using heterogeneous microgel populations to promote de novo assembly of endothelial progenitor-like cells into vessel-like structures. Through a combination of in silico and in vitro experimentation, we found that the microstructure (dimension of the void), integrin binding, and growth factor sequestration were all shown to guide vascular morphogenesis. We then demonstrated that the findings produced in a reductionist model of vasculogenesis translated to an in vivo effect on vessel formation in both dermal wounds and glioblastoma tumors.