The invention relates to a method for improving angiogenic potential of a mesenchymal stem cell (MSC), the method comprising culturing the MSC on a substrate having stiffness of about 1 kPa to 100 kPa and coated with a matrix protein, wherein the MSC has improved angiogenic potential when compared with a MSC cultured under identical conditions except not cultured on a substrate having stiffness of about 1 kPa to 100 kPa and not coated with a matrix protein. The invention also relates to a MSC having angiogenic potential when improved by the method, and to therapeutic use of the improved MSC for treating coronary artery disease (CAD) or peripheral artery disease (PAD) in a subject having CAD or PAD.

The invention relates to a method for improving angiogenic potential of a mesenchymal stem cell (MSC), the method comprising culturing the MSC on a substrate having stiffness of about 1 kPa to 100 kPa and coated with a matrix protein, wherein the MSC has improved angiogenic potential when compared with a MSC cultured under identical conditions except not cultured on a substrate having stiffness of about 1 kPa to 100 kPa and not coated with a matrix protein. The invention also relates to a MSC having angiogenic potential when improved by the method, and to therapeutic use of the improved MSC for treating coronary artery disease (CAD) or peripheral artery disease (PAD) in a subject having CAD or PAD.

Disclosed herein are methods and compositions for stimulating angiogenesis, using cells descended from marrow adherent stromal cells that have been transfected with sequences encoding a Notch intracellular domain. Applications of these methods and compositions include treatment of ischemic disorders such as stroke.

Disclosed herein are methods and compositions for stimulating angiogenesis, using cells descended from marrow adherent stromal cells that have been transfected with sequences encoding a Notch intracellular domain. Applications of these methods and compositions include treatment of ischemic disorders such as stroke.

The present application relates to biomimetic three-dimensional (3D) scaffolds, constructs and methods of making the same. The three-dimensional scaffold can include a sacrificial internal cast and a durable external scaffold material, wherein the durable external scaffold material comprises a biocompatible material which completely surrounds the sacrificial internal cast and wherein the sacrificial internal cast be removed to yield a branching 3D network of hollow, vessel-like tubes that substantially mimics a native tissue or organ.

The present application relates to biomimetic three-dimensional (3D) scaffolds, constructs and methods of making the same. The three-dimensional scaffold can include a sacrificial internal cast and a durable external scaffold material, wherein the durable external scaffold material comprises a biocompatible material which completely surrounds the sacrificial internal cast and wherein the sacrificial internal cast be removed to yield a branching 3D network of hollow, vessel-like tubes that substantially mimics a native tissue or organ.

Disclosed herein are methods of producing a population of venous angioblast cells from stem cells using a venous angioblast inducing media and optionally isolating a CD34+ population from the cell population comprising the venous angioblast cells, for example using a CD34 affinity reagent, CD31 affinity reagent and/or CD144 affinity reagent, optionally with or without a CD73 affinity reagent as well as methods of further differentiating the venous angioblasts in vitro to produce SEC-LCs and/or in vivo to produce SECs. Uses of the cells and compositions comprising the cells are also described.

Embodiments of the disclosure pertain to the treatment of diabetes through replacement of insulin producing cells. In specific embodiments, the disclosure encompasses the use of cellular adjuvants to enhance survival, engraftment and tolerogenesis of insulin-producing cells. In certain cases the disclosure concerns the manipulation of a hepatic microenvironment to promote immunological tolerance at an enhanced level to allow for integration of allogeneic insulin-producing cells. Particular embodiments utilize fibroblasts to enhance immunological tolerance for insulin-producing cells upon engraftment.

Embodiments of the disclosure pertain to the treatment of diabetes through replacement of insulin producing cells. In specific embodiments, the disclosure encompasses the use of cellular adjuvants to enhance survival, engraftment and tolerogenesis of insulin-producing cells. In certain cases the disclosure concerns the manipulation of a hepatic microenvironment to promote immunological tolerance at an enhanced level to allow for integration of allogeneic insulin-producing cells. Particular embodiments utilize fibroblasts to enhance immunological tolerance for insulin-producing cells upon engraftment.

Embodiments of the disclosure pertain to the treatment of diabetes through replacement of insulin producing cells. In specific embodiments, the disclosure encompasses the use of cellular adjuvants to enhance survival, engraftment and tolerogenesis of insulin-producing cells. In certain cases the disclosure concerns the manipulation of a hepatic microenvironment to promote immunological tolerance at an enhanced level to allow for integration of allogeneic insulin-producing cells. Particular embodiments utilize fibroblasts to enhance immunological tolerance for insulin-producing cells upon engraftment.