Abstract: Compositions and methods for the promotion of wound healing and tissue regeneration are described. The compositions and methods make use of water-soluble soy protein isolates (WSsoy), Fraction 5, Fraction 9, and/or bioactive peptide components of soy protein isolates. The invention also relates to the unexpected discovery that purified WSsoy forms gel-like matrices when suspended within certain concentration ranges in an aqueous environment. The compositions of the invention comprising WSsoy promote natural healing and have a low risk profile.

Abstract: Compositions and methods for the promotion of wound healing and tissue regeneration are described. The compositions and methods make use of water-soluble soy protein isolates (WSsoy), Fraction 5, Fraction 9, and/or bioactive peptide components of soy protein isolates. The invention also relates to the unexpected discovery that purified WSsoy forms gel-like matrices when suspended within certain concentration ranges in an aqueous environment. The compositions of the invention comprising WSsoy promote natural healing and have a low risk profile.

Abstract: Methylene-cycloalkylacetate compounds and derivatives thereof and their use in methods for treatment of neurotropic conditions.

Abstract: Compositions and methods for the promotion of wound healing and tissue regeneration are described. The compositions and methods make use of water-soluble soy protein isolates (WSsoy), Fraction 5, Fraction 9, and/or bioactive peptide components of soy protein isolates. The invention also relates to the unexpected discovery that purified WSsoy forms gel-like matrices when suspended within certain concentration ranges in an aqueous environment. The compositions of the invention comprising WSsoy promote natural healing and have a low risk profile.

Abstract: Methods of making a biologically active three-dimensional scaffold capable of supporting growth and differentiation of a cell are described. Biologically active three-dimensional scaffold made by the methods of the invention and an engineered tissue made from the scaffolds are described. Fibers of desired porosity can be obtained from non-structural ECM by lyophilization and/or electrospinning which can be useful for numerous tissue engineering applications requiring complex scaffolds, such as wound healing, artificial skin (burns), soft tissue replacement/repair and spinal cord injury.

Abstract: Methods of making a biologically active three-dimensional scaffold capable of supporting growth and differentiation of a cell are described. Biologically active three-dimensional scaffold made by the methods of the invention and an engineered tissue made from the scaffolds are described. Fibers of desired porosity can be obtained from non-structural ECM by lyophilization and/or electrospinning which can be useful for numerous tissue engineering applications requiring complex scaffolds, such as wound healing, artificial skin (burns), soft tissue replacement/repair and spinal cord injury.

Abstract: Methods of making a biologically active three-dimensional scaffold capable of supporting growth and differentiation of a cell are described. Biologically active three-dimensional scaffold made by the methods of the invention and an engineered tissue made from the scaffolds are described. Fibers of desired porosity can be obtained from non-structural ECM by lyophilization and/or electrospinning which can be useful for numerous tissue engineering applications requiring complex scaffolds, such as wound healing, artificial skin (burns), soft tissue replacement/repair and spinal cord injury.

Abstract: The present invention provides particles comprising either a water-soluble polymer or a phospholipid, wherein at least one near infrared (NIR) fluorescent probe and optionally at least one active agent such as a targeting moiety, capable of selectively recognizing a particular cellular marker, are non-covalently bound to the outer surface of the particles.

Abstract: Methods of making a biologically active three-dimensional scaffold capable of supporting growth and differentiation of a cell are described. Biologically active three-dimensional scaffold made by the methods of the invention and an engineered tissue made from the scaffolds are described. Fibers of desired porosity can be obtained from non-structural ECM by lyophilization and/or electrospinning which can be useful for numerous tissue engineering applications requiring complex scaffolds, such as wound healing, artificial skin (burns), soft tissue replacement/repair and spinal cord injury.