Abstract: A cardiac patch for treatment of a mammalian heart including perfusable vessels embedded integratedly between two layers of anisotropically oriented myocardial fibers. The cardiac patch is made using a dual 3D bioprinting technique using stereolithography to form an anisotropic construct and extrusion printing to form perfusion vessels. A nutrient and oxygen containing media can be provided within the perfusion vessels for growth of cells in the cardiac patch. The technique permits larger patches to be made for the treatment of cardiac damage in both small and large mammalian hearts.

Abstract: Systems and methods for producing artificial blood vessels. In certain embodiments, the method for producing blood vessels includes printing an elastic outer layer and removing polyvinyl alcohol component from the elastic outer layer. The process then involves forming a first inner layer of smooth muscle cells, wherein the smooth muscle cells are mixed with 5 fibrinogen solution and extruded with thrombin to form a smooth muscle cell gel, and forming a second inner layer of endothelial cells, wherein the endothelial cells are mixed with fibrinogen solution and extruded with thrombin to form an endothelial cell gel.

Abstract: A coaxial needle having two or more passageways for forming a biomimetic bioprinted blood vessel tubular construct. The coaxial needle has an external needle passageway and an internal needle passageway separated by an internal barrier, and having a nozzle at an end thereof. A bioink is provided flowable through the external needle passageway and a crosslinking solution is provided flowable through the internal needle passageway. The crosslinking solution contacts the bioink as the crosslinking solution and bioink exit the nozzle thereby forming a tubular blood vessel construct.

Abstract: A cardiac patch for treatment of a mammalian heart including perfusable vessels embedded integratedly between two layers of anisotropically oriented myocardial fibers. The cardiac patch is made using a dual 3D bioprinting technique using stereolithography to form an anisotropic construct and extrusion printing to form perfusion vessels. A nutrient and oxygen containing media can be provided within the perfusion vessels for growth of cells in the cardiac patch. The technique permits larger patches to be made for the treatment of cardiac damage in both small and large mammalian hearts.

Abstract: Embodiments of the present invention relate to structures and systems having a three-dimensional biomimetic structure with a porous biomimetic three-dimensional scaffold and a coating deposited onto a surface of the porous biomimetic three-dimensional scaffold as well as methods of using and fabricating the like.

Abstract: The invention describes methods for producing a biphasic nanocomposite scaffold comprising custom polymer-based core-shelled nanospheres by the physical and chemical attachment of two disparate polymeric materials whose composition can be readily modified with tissue-specific nanomaterials and products created using such methods. The custom nanospheres are constructed via co-axial wet electrospraying and can be employed to deliver compounds to the polymeric materials.

Abstract: A coaxial needle having two or more passageways for forming a biomimetic bioprinted blood vessel tubular construct. The coaxial needle has an external needle passageway and an internal needle passageway separated by an internal barrier, and having a nozzle at an end thereof. A bioink is provided flowable through the external needle passageway and a crosslinking solution is provided flowable through the internal needle passageway. The crosslinking solution contacts the bioink as the crosslinking solution and bioink exit the nozzle thereby forming a tubular blood vessel construct.

Abstract: Enhancing chondrogenesis at a desired site by the application of ultrasound in the presence of microbbubles. A biomimetic scaffold may be seeded with stem cells capable of undergoing chondrogenesis and provided to the site and then subjected to ultrasound excitation in the presence of microbubbles.

Abstract: Embodiments of the present invention relate to structures and systems having a three-dimensional biomimetic structure with a porous biomimetic three-dimensional scaffold and a coating deposited onto a surface of the porous biomimetic three-dimensional scaffold as well as methods of using and fabricating the like.

Abstract: The invention describes methods for producing a biphasic nanocomposite scaffold comprising custom polymer-based core-shelled nanospheres by the physical and chemical attachment of two disparate polymeric materials whose composition can be readily modified with tissue-specific nanomaterials and products created using such methods. The custom nanospheres are constructed via co-axial wet electrospraying and can be employed to deliver compounds to the polymeric materials.

Abstract: This invention describes methods for the creation of 3D biologically inspired tissue engineered scaffolds with both excellent interfacial mechanical properties, and biocompatibility and products created using such methods. In some cases, a combination of nanomaterials, nano/microfabrication methods and 3D printing can be employed to create structures that promote tissue reconstruction and/or production. In other embodiments, electrospinning techniques can be used to create structures made of polymers and nanotubes.