Abstract: A tissue engineering construct made from a nonwoven fabric. The fabric is made from first and second staple fibers. The first staple fibers are made from a first biocompatible, bioabsorbable material, and the second staple fibers are made from a second biocompatible, bioabsorbable material. The first material has a melting temperature lower than the second material. The fabric is formed into a three-dimensional construct suitable for the repair of urinary tract structures.

Abstract: We have disclosed an induced pluripotent stem cell and the method of preparing the induced pluripotent stem cell from a human kidney-derived cell. More particularly, we have disclosed a human kidney-derived iPS cell which may be differentiated into cells of ectoderm, mesoderm, and endoderm lineages.

Abstract: This invention relates to methods of treating amyotrophic lateral sclerosis. In particular, the invention provides for methods of treating amyotrophic lateral sclerosis by administering umbilical cord tissue-derived cells, an effective amount of a substantially homogenous population of umbilical cord tissue-derived cells or a pharmaceutical composition comprising umbilical cord tissue-derived cells to a patient.

Abstract: We have disclosed an induced pluripotent stem cell and the method of preparing the induced pluripotent stem cell from a human kidney-derived cell. More particularly, we have disclosed a human kidney-derived iPS cell which may be differentiated into cells of ectoderm, mesoderm, and endoderm lineages.

Abstract: We have disclosed an induced pluripotent stem cell and the method of preparing the induced pluripotent stem cell from a human umbilical cord tissue-derived cell. More particularly, we have disclosed a human umbilical cord tissue-derived iPS cell which may be differentiated into cells of ectoderm, mesoderm, and endoderm lineages.

Abstract: A bioprosthetic device is provided for soft tissue attachment, reinforcement, and or reconstruction. The device comprises a naturally occurring extracellular matrix portion and a three-dimensional synthetic portion. In illustrated embodiments, the naturally occurring extracellular matrix portion comprises layers of small intestine submucosa, and the three-dimensional synthetic portion comprises a foam or a three-dimensional mesh, textile, or felt.

Abstract: Compositions and methods of using cells derived from umbilical cord tissue, to stimulate and support angiogenesis, to improve blood flow, to regenerate, repair, and improve skeletal muscle damaged by a peripheral ischemic event, and to protect skeletal muscle from ischemic damage in peripheral vascular disease patients are disclosed. In particular, methods of treating a patient having a peripheral vascular disease with umbilical derived cells and fibrin glue are disclosed.

Abstract: A biocompatible meniscal repair device is disclosed. The tissue repair device includes a scaffold adapted to be placed in contact with a defect in a meniscus, the scaffold comprising a high-density, dry laid nonwoven polymeric material and a biocompatible foam. The scaffold provides increased suture pull-out strength.

Abstract: A biocompatible meniscal repair device is disclosed. The tissue repair device includes a scaffold adapted to be placed in contact with a defect in a meniscus, the scaffold comprising a high-density, dry laid nonwoven polymeric material and a biocompatible foam. The scaffold provides increased suture pull-out strength.

Abstract: A biocompatible meniscal repair device is disclosed. The tissue repair device includes a scaffold adapted to be placed in contact with a defect in a meniscus, the scaffold comprising a high-density, dry laid nonwoven polymeric material and a biocompatible foam. The scaffold provides increased suture pull-out strength.

Abstract: The invention relates to a fibrin-based scaffold suitable for supporting a population of cells comprising mesenchymal stem cells (MSC) and/or umbilical tissue derived cells (UTC) at the site of administration for a prolonged period of time. The scaffold is capable of supporting at least 1×106 cells/ml scaffold. The invention also relates to the preparation of the scaffold and to its use. Preparation of the scaffold is carried out with a fibrinogen component comprising fibrinogen having a final concentration of higher than 17.5 mg/ml scaffold. The scaffold and the embedded MSC and/or UTC can be used for increasing vascularization and/or wound healing at the site of administration.

Abstract: A biocompatible meniscal repair device is disclosed. The tissue repair device includes a scaffold adapted to be placed in contact with a defect in a meniscus, the scaffold comprising a high-density, dry laid nonwoven polymeric material and a biocompatible foam. The scaffold provides increased suture pull-out strength.

Abstract: A biocompatible meniscal repair device is disclosed. The tissue repair device includes a scaffold adapted to be placed in contact with a defect in a meniscus, the scaffold comprising a high-density, dry laid nonwoven polymeric material and a biocompatible foam. The scaffold provides increased suture pull-out strength.

Abstract: The invention is a method for the treatment of mammalian articular cartilage disorders, inflammatory joint disease, trauma-related cartilage injuries, and degenerative disc disease. The method involves treating the affected area with a composition containing a therapeutically effective dose of Centella extract. The composition is delivered locally by parenteral administration to the affected site.

Abstract: This invention relates to methods of treating amyotrophic lateral sclerosis. In particular, the invention provides for methods of treating amyotrophic lateral sclerosis by administering umbilical cord tissue-derived cells, an effective amount of a substantially homogenous population of umbilical cord tissue-derived cells or a pharmaceutical composition comprising umbilical cord tissue-derived cells to a patient.

Abstract: A biocompatible tissue repair implant or scaffold device is provided for use in repairing a variety of tissue injuries, particularly injuries to cartilage, ligaments, tendons, and nerves. The repair procedures may be conducted with implants that contain a biological component that assists in healing or tissue repair. The biocompatible tissue repair implants include a biocompatible scaffold and particles of living tissue, such that the tissue and the scaffold become associated. The particles of living tissue contain one or more viable cells that can migrate from the tissue and populate the scaffold.

Abstract: A tissue engineering construct made from a nonwoven fabric. The fabric is made from first and second staple fibers. The first staple fibers are made from a first biocompatible, bioabsorbable material, and the second staple fibers are made from a second biocompatible, bioabsorbable material. The first material has a melting temperature lower than the second material. The fabric is formed into a three-dimensional construct suitable for the repair of urinary tract structures.

Abstract: The present invention is directed to a method of using a multilayered fabric comprising a first absorbable nonwoven fabric and a second absorbable woven or knitted fabric in tissue repair and regeneration.

Abstract: Compositions and methods of using tissue engineered blood vessels to repair and regenerate blood vessels of patients with vascular disease are disclosed.

Abstract: Tissue engineering devices and methods are provided for the reconstruction, repair, augmentation, or replacement of a luminal organ or tissue structure involving the use of a biodegradable polymer matrix conforming to a portion of a laminarly arranged luminal organ, the processing of autologous, allogeneic or xenogeneic tissue comprising multiple cell populations to obtain a minced tissue composition, the seeding of the matrix with the composition, and the implanting of the seeded polymer matrix into a patient.