Abstract: Modified polysaccharides and crosslinked modified polysaccharide compositions are described. Methods of using the crosslinked modified polysaccharide compositions to deliver proteins, oligonucleotides, or pharmaceutical agents are also disclosed.

Abstract: The present invention is in the area of pluripotent stem cells and more particularly deals with a method to differentiate a vascular network from stem cells.

Abstract: Low oxygen tension is a critical regulator of the developing or regenerating vasculature. The present invention is based on the determination that low oxygen tension during early stages of early vascular cell (EVC) derivation induces endothelial commitment and maturation of pluripotent stem cells. Inhibition of reactive oxygen species generation during the early stages of differentiation abrogates the endothelial inductive effects of the low oxygen environments. Methods of generating various types of cells from pluripotent stem cells (PSCs) are described, as well as compositions and methods of use thereof. In particular, generation of EVCs, bicellular vascular populations, early endothelial cells (ECs) and pericytes via culture in a low oxygen environment is described.

Abstract: A bicellular vascular population derived from human pluripotent stem cells (hPSCs) undergoes morphogenesis and assembly in a synthetic hydrogel. It is shown that hPSCs can be induced to co-differentiate into early vascular cells (EVCs) in a clinically-relevant strategy dependent upon Notch activation. These EVCs mature into ECs and pericytes, and self-organize to form vascular networks in an engineered matrix. Upon in vivo implantation, multicellular human vascular networks are functionally perfused. Thus, a derived bicellular population is exploited for its intrinsic self-assembly capability to create functional microvasculature in a deliverable matrix.

Abstract: A medium for growing vascular lineage cells is described. The vascular lineage cell growth medium includes an oligosaccharide-based hydrogel and a growth factor that promotes vascularization by vascular lineage cells.

Abstract: This invention relates, e.g., to a method for differentiating mammalian (e.g.

Abstract: Novel hydrogels that can serve as 3D hypoxic microenvironments are disclosed. Oxygen controllable, hypoxia-inducible hydrogels (HI hydrogels) are composed of a phenolic agent and polymer backbone, which can form hydrogel networks via oxygen consumption in an enzyme-mediated crosslinking reaction. The HI hydrogels are degradable, cytocompatible, and have tunable mechanical properties. Oxygen levels and gradients within the HI hydrogels are controlled and precisely predicted. As a result, the HI hydrogels induce prolonged hypoxic conditions. The HI hydrogels guide vascular morphogenesis in vitro by activating hypoxia-inducible factors and promote neovascularization from tissue, as well as stimulate tissue in dynamic in vivo environments. The HI hydrogels are a new class of biomaterials that are useful in many applications, ranging from the engineering of de novo tissues and disease models to the treatment of vascular disorders.

Abstract: Methods for promoting skin regeneration, promoting hair follicle regeneration, and reducing scarring by topically administering polysaccharide-based hydrogel compositions to injured skin are presented.

Abstract: A medium for growing vascular lineage cells is described. The vascular lineage cell growth medium includes an oligosaccharide-based hydrogel and a growth factor that promotes vascularization by vascular lineage cells.

Abstract: An in vitro model system that guides the development of microvasculature, recapitulating the detailed organization of both its cellular and a-cellular components is established. Use of electrostretched fibrin microfibers enables both endothelial layer organization and co-culture of supporting perivascular (mural) cells such as vascular smooth muscle cells and pericytes. The fiber curvature affects the circumferential deposition of endothelial-produced ECM independently of cellular organization and induces deposition of higher quantities of vascular ECM proteins. Further, a luminal multicellular microvascular structure is disclosed.

Abstract: This invention relates, e.g., to a method for differentiating mammalian (e.g., human) pluripotent stem cells (PSCs) into endothelial cells (ECs) in vitro, by plating a single-cell suspension of PSCs onto a suitable surface such as type IV collagen and culturing the cells with VEGF after which ECs can be harvested. A preferred embodiment of the method first cultures the cells without VEGF and then sequentially cultures the cells with VEGF. Differentiation can be enhanced by adding an inhibitor of transforming growth factor ? to the culturing with VEGF.

Abstract: A medium for growing vascular lineage cells is described. The vascular lineage cell growth medium includes an oligosaccharide-based hydrogel and a growth factor that promotes vascularization by vascular lineage cells.

Abstract: A bicellular vascular population derived from human pluripotent stem cells (hPSCs) undergoes morphogenesis and assembly in a synthetic hydrogel. It is shown that hPSCs can be induced to co-differentiate into early vascular cells (EVCs) in a clinically-relevant strategy dependent upon Notch activation. These EVCs mature into ECs and pericytes, and self-organize to form vascular networks in an engineered matrix. Upon in vivo implantation, multicellular human vascular networks are functionally perfused. Thus, a derived bicellular population is exploited for its intrinsic self-assembly capability to create functional microvasculature in a deliverable matrix.

Abstract: Embryonic vascular smooth muscle cells (vSMCs) have a synthetic phenotype (Syn-vSMC), but in adults, they commit to the mature contractile phenotype (Con-vSMC). Con-vSMCs differ from Syn-vSMC derivatives in condensed morphology, prominent filamentous cytoskeleton proteins, elastin production and assembly elastin, low proliferation, numerous active caveolae, enlarged endoplasmic reticulum, ample stress fibers and bundles, as well as high contractility. The human pluripotent stem cell-derivatives can differentiate into a desired phenotype. Differentiation can be controlled by appropriate concentrations of relevant factors. Growth in high serum with platelet-derived growth factor-BB (PDGF-BB) and transforming growth factor-?1 induces the Syn-SMC phenotype with increased extracellular matrix protein expression and reduced expression of contractile proteins. Serum starvation and PDGF-BB deprivation causes maturation towards the Con-vSMC phenotype.

Abstract: Slow vascularization of functional blood limits the transplantation of tissue constructs and the recovery of ischemic and wounded tissues. Blood vessel ingrowth into polysaccharide-based hydrogel scaffolds remains a challenge. A synergistic effect of multiple angiogenic GFs was established; the co-encapsulation of VEGF plus other growth factors induced more and larger blood vessels than any individual GF, while the combination of all GFs dramatically increased the size and number of newly formed functional vessels. Rapid, efficient, and functional neovascularization may be achieved.

Abstract: This invention relates, e.g., to a method for differentiating mammalian (e.g.

Abstract: A medium for growing vascular lineage cells is described. The vascular lineage cell growth medium includes an oligosaccharide-based hydrogel and a growth factor that promotes vascularization by vascular lineage cells.

Abstract: Modified polysaccharides and crosslinked modified polysaccharide compositions are described. Methods of using the crosslinked modified polysaccharide compositions to deliver proteins, oligonucleotides, or pharmaceutical agents are also disclosed.

Abstract: The present invention is of a method of dynamically generating human embryoid bodies which can be used for generating lineage specific cells and cell lines. Specifically, the present invention can be used to generate ESC-differentiated cells for cell-replacement therapy.

Abstract: The present invention is of a method of dynamically generating human embryoid bodies which can be used for generating lineage specific cells and cell lines. Specifically, the present invention can be used to generate ESC-differentiated cells for cell-replacement therapy.