Abstract: Highly undifferentiated spore-like cells can be isolated from many different tissues and bodily fluids and used to treat a wide variety of disorders.

Abstract: Compositions and methods for growing new skin, which can be used to repair or replace skin that has been damaged or removed by a variety of insults.

Abstract: The invention features a method for generating new tissue by obtaining a liquid hydrogel-cell composition including a hydrogel and tissue precursor cells; delivering the liquid hydrogel-cell composition into a permeable, biocompatible support structure; and allowing the liquid hydrogel-cell composition to solidify within the support structure and the tissue precursor cells to grow and generate new tissue. The invention also features a tissue forming structure including a permeable, biocompatible support structure having a predetermined shape that corresponds to the shape of desired tissue; and a hydrogel-cell composition at least partially filling the support structure, wherein the hydrogel-cell composition includes a hydrogel and tissue precursor cells. The new tissue forming structure can be used in new methods to generate various tissues (e.g., to treat defective tissue) including new bone, cartilage, and nervous tissue such as spinal cord tissue. The invention also new isolated nervous system stem cells.

Abstract: The invention provides methods of generating a natural, living biological matrix that can serve as, or form a part of, a natural biological scaffold. The matrix is generated by incubating together biological cells and cellular debris. Any naturally occurring cell can be a biological cell included in the matrix. The invention also provides methods of treating a patient by implanting the matrix or scaffolding into a tissue of the patient, thereby augmenting the existing 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: Highly undifferentiated spore-like cells can be isolated from many different tissues and bodily fluids after those tissues and fluids have been exposed to extreme conditions. The spore-like cells can be used to treat a wide variety of disorders.

Abstract: The invention features methods of making living tissue constructs having a predetermined shape by obtaining a negative mold having a defined shape; suspending isolated tissue precursor cells in a hydrogel to form a liquid hydrogel-precursor cell composition; filling the liquid hydrogel-precursor cell composition into the mold; implanting the filled mold into a living host for incubation; removing the mold after a suitable incubation period; and removing the living tissue construct from the mold. The final living tissue construct can then be surgically implanted into a patient.

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: 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: The present invention comprises an implantable device that provides artificial tissues for repair, augmentation and reconstructive surgery which have mechanical properties comparable to the natural tissues that they supplement or replace. Such devices can be produced by a tissue engineering method comprising seeding a polymer matrix with a first cell type and a second cell type and culturing the seeded matrix under conditions suitable for cell growth or maintenance, whereby a tissue comprising a mixed cell population containing both the first and second cell types is produced. The tissue produced by this method contains a mixed population in which the two cell types are intimately associated without apparent stratification and has mechanical properties which are intermediate between similarly produced tissues containing either one of the two cell types. This invention is particularly useful in forming implantable structural members.

Abstract: Highly undifferentiated spore-like cells can be isolated from many different tissues and bodily fluids after those tissues and fluids have been exposed to extreme conditions. The spore-like cells can be used to treat a wide variety of disorders.

Abstract: Slowly polymerizing polysaccharide hydrogels have been demonstrated to be useful as a means of delivering large numbers of isolated cells via injection. The gels promote engraftment and provide three dimensional templates for new cell growth. The resulting tissue is similar in composition and histology to naturally occurring tissue. This method can be used for a variety of reconstructive procedures, including custom molding of cell implants to reconstruct three dimensional tissue defects, as well as implantation of tissues generally.

Abstract: The invention provides methods of generating a natural, living biological matrix that can serve as, or form a part of, a natural biological scaffold. The matrix is generated by incubating together biological cells and cellular debris. Any naturally occurring cell can be a biological cell included in the matrix. The invention also provides methods of treating a patient by implanting the matrix or scaffolding into a tissue of the patient, thereby augmenting the existing tissue.

Abstract: The invention features a method for generating new tissue by obtaining a liquid hydrogel-cell composition including a hydrogel and tissue precursor cells; delivering the liquid hydrogel-cell composition into a permeable, biocompatible support structure; and allowing the liquid hydrogel-cell composition to solidify within the support structure and the tissue precursor cells to grow and generate new tissue. The invention also features a tissue forming structure including a permeable, biocompatible support structure having a predetermined shape that corresponds to the shape of desired tissue; and a hydrogel-cell composition at least partially filling the support structure, wherein the hydrogel-cell composition includes a hydrogel and tissue precursor cells. The new tissue forming structure can be used in new methods to generate various tissues (e.g., to treat defective tissue) including new bone, cartilage, and nervous tissue such as spinal cord tissue. The invention also new isolated nervous system stem cells.

Abstract: Slowly polymerizing polysaccharide hydrogels have been demonstrated to be useful as a means of delivering large numbers of isolated cells via injection. The gels promote engraftment and provide three dimensional templates for new cell growth. The resulting tissue is similar in composition and histology to naturally occurring tissue. This method can be used for a variety of reconstructive procedures, including custom molding of cell implants to reconstruct three dimensional tissue defects, as well as implantation of tissues generally.

Abstract: Highly undifferentiated spore-like cells can be isolated from many different tissues and bodily fluids and used to treat a wide variety of disorders.

Abstract: Compositions and methods for growing new skin, which can be used to repair or replace skin that has been damaged or removed by a variety of insults.

Abstract: Highly undifferentiated spore-like cells can be isolated from many different tissues and bodily fluids after those tissues and fluids have been exposed to extreme conditions. The spore-like cells can be used to treat a wide variety of disorders.

Abstract: Slowly polymerizing polysaccharide hydrogels have been demonstrated to be useful as a means of delivering large numbers of isolated cells via injection. The gels promote engraftment and provide three dimensional templates for new cell growth. The resulting tissue is similar in composition and histology to naturally occurring tissue. This method can be used for a variety of reconstructive procedures, including custom molding of cell implants to reconstruct three dimensional tissue defects, as well as implantation of tissues generally.

Abstract: Slowly polymerizing polysaccharide hydrogels have been demonstrated to be useful as a means of delivering large numbers of isolated cells via injection. The gels promote engraftment and provide three dimensional templates for new cell growth. The resulting tissue is similar in composition and histology to naturally occurring tissue. This method can be used for a variety of reconstructive procedures, including custom molding of cell implants to reconstruct three dimensional tissue defects, as well as implantation of tissues generally.