The present invention involves implants suitable for surgical implantation into subjects. In some embodiments the implants comprise a biocompatible scaffold material and blood vessels containing engineered endothelial cells—such as E4ORF1+ engineered endothelial cells or engineered endothelial cells that express certain marker molecules. The present invention provides implants, methods for preparing such implants, and methods of treatment utilizing such implants.

The present application provides methods of functionalizing an organ or tissue of a mammal by administering a nutrient (e.g., peracetylated N-azido galactosamine Ac4GalNAz) to the mammal or by culturing an organ or tissue in a bioreactor containing such nutrient. The present application also provides methods of selectively functionalizing extracellular matrix (ECM) of an organ or tissue of a mammal by administering a nutrient (e.g., peracetylated N-azido galactosamine Ac4GalNAz) to the mammal. In some aspects, the present application provides a decellularized scaffold of a mammalian organ or tissue comprising an extracellular matrix, wherein the extracellular matrix of the decellularized scaffold is functionalized with a chemical group that is reactive in a bioorthogonal chemical reaction, such as an azide chemical group. The present application also provides biological prosthetic mesh and mammalian organs and tissues for transplantation prepared according to the methods of the application.

The present application provides methods of functionalizing an organ or tissue of a mammal by administering a nutrient (e.g., peracetylated N-azido galactosamine Ac4GalNAz) to the mammal or by culturing an organ or tissue in a bioreactor containing such nutrient. The present application also provides methods of selectively functionalizing extracellular matrix (ECM) of an organ or tissue of a mammal by administering a nutrient (e.g., peracetylated N-azido galactosamine Ac4GalNAz) to the mammal. In some aspects, the present application provides a decellularized scaffold of a mammalian organ or tissue comprising an extracellular matrix, wherein the extracellular matrix of the decellularized scaffold is functionalized with a chemical group that is reactive in a bioorthogonal chemical reaction, such as an azide chemical group. The present application also provides biological prosthetic mesh and mammalian organs and tissues for transplantation prepared according to the methods of the application.

The present invention provides an anti-IGF-I receptor antibody that binds specifically to an IGF-I receptor of a vertebrate and has the proliferation-inducing activity of a vertebrate-derived cell, or a fragment thereof, or derivatives of these.

The technology relates to a method for inducing cardiomyogenesis comprising administering a therapeutically effective amount of either or both of KLF1 and KLF2b to increase the level of KLF1 and/or KLF2b in the cardiomyocytes thereby inducing cardiomyogenesis.

The technology relates to a method for inducing cardiomyogenesis comprising administering a therapeutically effective amount of either or both of KLF1 and KLF2b to increase the level of KLF1 and/or KLF2b in the cardiomyocytes thereby inducing cardiomyogenesis.

This document provides materials and methods for permanent arterial embolization and/or enhanced vascular healing. For example, materials and methods for using bioactive tissue derived nanocomposite hydrogels to enhance vascular healing are provided.

A method for microencapsulation includes isolating myofibroblasts from Wharton's jelly of a human umbilical cord. The myofibroblasts are microencapsulated using ultra-purified sodium alginate, wherein the myofibroblasts encapsulated in the sodium alginate form a three-dimensional spherical structure.

A method for microencapsulation includes isolating myofibroblasts from Wharton's jelly of a human umbilical cord. The myofibroblasts are microencapsulated using ultra-purified sodium alginate, wherein the myofibroblasts encapsulated in the sodium alginate form a three-dimensional spherical structure.

The present application provides materials and methods for treating a patient with Duchenne Muscular Dystrophy (DMD) both ex vivo and in vivo. In addition, the present application provides materials and methods for editing a dystrophin gene in a cell by genome editing.