Abstract: A method of fabricating a microchannel device is provided. The method includes determining, based on a plurality of design criteria, a microchannel vascular network design. The microchannel vascular network design includes a first channel network, a second microchannel network based on the first channel network, and a structure for providing fluidic communication through between the first channel network and the second channel network. The method includes receiving, in electronic form, the microchannel vascular network design at a fabrication system. The fabrication system comprises a pre-polymer solution. The method includes forming, based on the microchannel vascular network design, a microchannel vascular network device of a polymer material at the fabrication system using the pre-polymer solution, thereby fabricating the microchannel vascular network device.

Abstract: The present invention provides for compositions and constructs for craniofacial reconstruction implants, and methods for making and using same. Specific embodiments provide for a biocompatible scaffold having an auricular shape and a permanent bendable framework within the scaffold, wherein the permanent bendable framework allows deformation and return to pre-deformation shape, and thus maintains the auricular shape of the scaffold.

Abstract: The present invention provides for compositions and constructs for craniofacial reconstruction implants, and methods for making and using same. Specific embodiments provide for a biocompatible scaffold having an auricular shape and a permanent bendable framework within the scaffold, wherein the permanent bendable framework allows deformation and return to pre-deformation shape, and thus maintains the auricular shape of the scaffold.

Abstract: The present invention relates to a three-dimensional system, and compositions obtained therefrom, wherein individual layers of the system comprise channels divided longitudinally into two compartments by a centrally positioned membrane, and wherein each compartment can comprise a different cell type.

Abstract: A method and materials to create complex vascularized living tissue in three dimensions from a two-dimension microfabricated mold has been developed. The method involved creating a two dimensional surface having a branching structure etched into the surface. The pattern begins with one or more large channels which serially branch into a large array of channels as small as individual capillaries, then converge to one or more large channels. The etched surface serves a template within a mold formed with the etched surface for the circulation of an individual tissue or organ. Living vascular cells are then seeded onto the mold, where they form living vascular channels based on the pattern etched in the mold. Once formed and sustained by their own matrix, the top of the mold is removed. The organ or tissue specific cells are then added to the etched surface, where they attach and proliferate to form a thin, vascularized sheet of tissue.

Abstract: Connective tissue, including neo-tendons and ligaments, has been constructed using biodegradable synthetic scaffolds seeded with tenocytes. The scaffolds are preferably formed from biodegradable fibers formed of a polymer such as polyglycolic acid-polylactic acid copolymers, and seeded with cells isolated from autologous tendon or ligament by means of enzymatic digestion or direct seeding into tissue culture dishes from explants. The cell polymer constructs are then surgically transplanted to replace missing segments of functioning tendon or ligament.

Abstract: Polymeric materials are used to make a pliable, non-toxic, injectable porous template for vascular ingrowth. The pore size, usually between approximately 100 and 300 microns, allows vascular and connective tissue ingrowth throughout approximately 10 to 90% of the matrix following implantation, and the injection of cells uniformly throughout the implanted matrix without damage to the cells or patient. The introduced cells attach to the connective tissue within the matrix and are fed by the blood vessels. The preferred material for forming the matrix or support structure is a biocompatible synthetic polymer which degrades in a controlled manner by hydrolysis into harmless metabolites, for example, polyglycolic acid, polylactic acid, polyorthoester, polyanhydride, or copolymers thereof. The rate of tissue ingrowth increases as the porosity and/or the pore size of the implanted devices increases.

Abstract: The present invention relates to methods for the design and fabrication of biological constructs, such as organ simulants or organ replacements, which contain complex microfluidic architecture. Designs of the present invention provide increased space in the lateral dimension, enabling a large number of small channels for small vessels.

Abstract: Methods and materials for treating intracranial aneurysms with a tissue-engineered biopolymer are disclosed. A novel technique has been developed which utilizes a tissue-engineering biopolymer (TEBP) with living endothelial cells such that the endothelial cells will produce a neoendothelium across the aneurysm ostium. Alternatively, biocompatible materials can be coated onto aneurysm maintenance devices, and the cells can be seeded onto the biocompatible material.

Abstract: This invention relates generally to methods and compositions for bioengineering tooth tissue, as well as methods of producing new tooth tissue in a subject.

Abstract: The present invention generally relates to a combination of the fields of tissue engineering, drug discovery and drug development. It more specifically provides new methods and materials for testing the efficacy and safety of experimental drugs, defining the metabolic pathways of experimental drugs and characterizing the properties (e.g., side effects, new uses) of existing drugs. Preferably, evaluation is carried out in three-dimensional tissue-engineered systems, wherein drug toxicity, metabolism, interaction and/or efficacy can be determined.

Abstract: Methods and materials for making an apparatus which duplicates the functionality of a physiological system id provided.

Abstract: Connective tissue, including neo-tendons and ligaments, has been constructed using biodegradable synthetic scaffolds seeded with tenocytes. The scaffolds are preferably formed from biodegradable fibers formed of a polymer such as polyglycolic acid-polylactic acid copolymers, and seeded with cells isolated from autologous tendon or ligament by means of enzymatic digestion or direct seeding into tissue culture dishes from explants. The cell polymer constructs are then surgically transplanted to replace missing segments of functioning tendon or ligament.