Abstract: The invention is directed to methods of inducing cell recruitment and tissue regeneration at a target site in a subject. It is also based, in part, on the discovery that a subject's own biologic resources and environmental conditions can be used for in situ tissue regeneration and thereby reduce or eliminate the need for donor cell procurement and ex vivo manipulation of such donor cells. Methods are disclosed for recruitment of a subject's own stem cells to a target region by inducing a sustained positive pressure at a target site, such as the kidney, thereby increasing the number of pluripotent cells capable of differentiating to regenerate the target tissue.

Abstract: A method for ameliorating erectile dysfunction (ED) in a subject, by injecting a population of cells capable of increasing nitric oxide production in corporal tissue, and maintaining the cells in vivo to increase local tissue concentrations of nitric oxide, whereby intracavernous pressure can be improved upon stimulation.

Abstract: The invention is directed to compositions and methods for preparing electrospun matrices comprising at least one natural biological material component and at least one synthetic polymer material. The natural component makes the matrices highly biocompatible while the molecular weight polymer component can impart additional strength mechanical strength to the scaffold and/or improve ease of manufacture by increasing viscosity and spinning characteristics of the solution during electrospining.

Abstract: A method of producing organized skeletal muscle tissue from precursor muscle cells in vitro comprises: (a) providing precursor muscle cells on a support in a tissue media; then (b) cyclically stretching and relaxing the support at least twice along a first axis during a first time period; and then (c) optionally but preferably maintaining the support in a substantially static position during a second time period; and then (d) repeating steps (b) and (c) for a number of times sufficient to enhance the functionality of the tissue formed on the support and/or produce organized skeletal muscle tissue on the solid support from the precursor muscle cells.

Abstract: A method of forming an array of viable cells is carried out by ink-jet printing a cellular composition containing said cells on a substrate. At least two different types of viable mammalian cells are printed on the substrate, the at least two different types of viable mammalian cells selected to together form a tissue. In some embodiments at least three or four different viable mammalian cells are printed on the substrate, the cells selected to together form a tissue. In some embodiments one of the viable mammalian cell types is a stem cell. In some embodiments the method further comprises printing at least one support compound on the substrate, the support compound selected to form a tissue together with said cells. In some embodiments the method further comprises printing at least one growth factor on the substrate, the growth factor selected to cause the cells to form a tissue.

Abstract: The present invention provides methods and devices for isolating cells from a subject by circulating the subject's body fluid over an affinity moeity coupled matrix to isolate isolate cells from a subject either ex vivo or in vivo. One aspect of the invention is directed to connecting a subject to a system capable of circulating the subject's body fluid through an affinity moiety coupled matrix, such that the affinity moiety coupled matrix is capable of binding to and extracting target cells from the body fluid, and then eluting the target cells from the affinity moiety. Another aspect of the invention is directed to the apparatus for isolating cells from a subject, comprising a blood circulation system with an arterial side blood circuit for extracting blood and flowing the blood over an affinity moiety coupled matrix that binds to and extracts target cells and a venous side blood circuit for returning the blood to the patient.

Abstract: The invention is directed to methods and compositions for preparing matrices for controlled delivery of at least one therapeutic or biological agent to a target site in a subject. This is accomplished using nanoparticles coupled to the therapeutic or biological agent that are incorporated within the matrix or reacted on the surface of the matrix.

Abstract: The invention pertains to methods of producing artificial composite tissue constructs that permit coordinated motion. Biocompatable structural matrices having sufficient rigidity to provide structural support for cartilage-forming cells and bone-forming cells are used. Biocompatable flexible matrices seeded with muscle cells are joined to the structural matrices to produce artificial composite tissue constructs that are capable of coordinated motion.

Abstract: The invention is directed to methods for preparing artificial heart valves by preconditioning a matrix seeded with endothelial cells and smooth muscle cells differentiated from isolated progenitor cells. These cell seeded matrices are exposed to fluid conditions that mimic blood flow through the heart to produce tissue engineered heart valves that are analogous to native heart valves.

Abstract: The invention is directed to methods for preparing artificial blood vessels by preconditioning a matrix seeded with endothelial cells to fluid flow conditions that mimic blood flow.

Abstract: A method of producing organized skeletal muscle tissue from precursor muscle cells in vitro comprises: (a) providing precursor muscle cells on a support in a tissue media; then (b) cyclically stretching and relaxing the support at least twice along a first axis during a first time period; and then (c) optionally but preferably maintaining the support in a substantially static position during a second time period; and then (d) repeating steps (b) and (c) for a number of times sufficient to enhance the functionality of the tissue formed on the support and/or produce organized skeletal muscle tissue on the solid support from the precursor muscle cells.

Abstract: The invention is directed to compositions and methods for preparing electrospun matrices comprising at least one natural biological material component and at least one synthetic polymer material. The natural component makes the matrices highly biocompatible while the molecular weight polymer component can impart additional strength mechanical strength to the scaffold and/or improve ease of manufacture by increasing viscosity and spinning characteristics of the solution during electrospining.

Abstract: The invention is directed to methods and compositions for preparing matrices for controlled delivery of at least one therapeutic or biological agent to a target site in a subject. This is accomplished using nanoparticles coupled to the therapeutic or biological agent that are incorporated within the matrix or reacted on the surface of the matrix.

Abstract: The invention is directed to methods and compositions for monitoring remodeling of an artificial tissue construct using image or contrast enhancing agents. The invention allows the growth, development, and remodeling of the artificial tissue to be monitored.

Abstract: The invention is directed to compositions and methods for preparing an artificial oral tissue. The artificial oral tissue is prepared using a biocompatible substrate seeded with salivary gland cells that develop to produce a salivary gland tissue layer with a prototypal salivary system and a prototypal secretory system. The salivary gland cells proliferate, mature and differentiate into a salivary gland structure that are analogous to its in vivo counterpart.

Abstract: The invention is directed to compositions and methods for reconstructing artificial female reproductive organs. The constructs and methods of the invention can be used for ameliorating congenital malformations and disorders of female reproductive tract using tissue engineered female reproductive organs, such as the uterus, vagina, cervix, and fallopian tubes. These tissue engineered female reproductive organs can be generated by perfusing cultured cell populations derived from cells of the female reproductive tissues, such as uterine, vaginal, cervical, fallopian tube epithelial cells as well as smooth muscle cells.

Abstract: A cartilaginous structural member (CSM) for use in penile reconstruction, for the correction of developmental defects, postoperative reconstruction, and for reconstructive preprosthetic surgery. The cartilaginous structural member (CSM) comprise of live cells seeded onto pre-formed shaped structure which may be biodegradable. The live cells may comprise chondrocyte and the cartilaginous structural member (CSM) for use in reconstructive surgery may be constructed of polyglycolic acid. The implant structure is applicable to use for the regeneration and reconstruction or augmentation of semirigid members of the body such as the penis, nose, ear and locations which naturally has cartilage. Further, the cartilaginous structural member (CSM) may be used in plastic surgery such as, for example, breast augmentation or pectoral augmentation.