Abstract: A composition, comprising: a plurality of mechanically-activated microcapsules; a mechanically-activated microcapsule defining a shell and an exterior surface; and the mechanically-activated microcapsule comprising one or more adhesion groups disposed Non the exterior surface of the mechanically-activated microcapsule, the one or more adhesion groups being configured to effect a covalent interaction, a non-covalent interaction, or both between the one or more adhesion groups and a matrix material, the covalent interaction, the non-covalent interaction, or both adhering the mechanically-activated microcapsule to the matrix material. Also provided are related methods and related articles.

Abstract: Embodiments of the present invention relate to mechanically-activated microcapsules (MAMCs) for controlled drug-delivery, wherein the MAMCs release one or more active ingredients in response to mechanical stimuli in a subject's body. The MAMCs provide a platform for stimulating biological regeneration, biological repair, modifying disease, and/or controlling disease in mechanically-loaded musculoskeletal tissues.

Abstract: The invention relates to the field of storage of tissues, such as transplantable material, or allograft storage, and more specifically to the field of both short- and long-term tissues storage and preservation. Preferably the tissues are transplantable material comprises chondogenic cells, such as chondrocytes, cartilage, engineered cartilage or to osteochondral/cartilage explants or fragment thereof.

Abstract: Embodiments of the present invention relate to mechanically-activated microcapsules (MAMCs) for controlled drug-delivery, wherein the MAMCs release one or more active ingredients in response to mechanical stimuli in a subject's body. The MAMCs provide a platform for stimulating biological regeneration, biological repair, modifying disease, and/or controlling disease in mechanically-loaded musculoskeletal tissues.

Abstract: A cartilage-like biomaterial is bioengineered by using a self-aggregating suspension cell culture with hydrostatic mechanical force without the use of a scaffold or foreign matrix for cell attachment during culture. The cells in suspension culture may be preconditioned prior to application of the hydrostatic mechanical force, such as hydrostatic pressure, for a period of time in the range of about 1 week to about 10 weeks. The cartilage-like biomaterial shares critical structural, phenotype, and functional characteristics with native, intact cartilage tissue.

Abstract: A method and device the may be employed for inhibiting bone growth, including inducing epiphysiodesis or hemiepiphysiodesis, by applying electrical current to a desired region. The device includes a power source and one or a series of electrodes for applying a current sufficient to reduce or stop the growth of a bone to selected regions of the bone. The method and device may be used to correct growth discrepancies in extremities such as the arms or legs, as well as correct the curvature of the spine in scoliosis patients.

Abstract: A cartilage-like biomaterial is bioengineered by using a self-aggregating suspension cell culture with hydrostatic mechanical force without the use of a scaffold or foreign matrix for cell attachment during culture. The cells in suspension culture may be preconditioned prior to application of the hydrostatic mechanical force, such as hydrostatic pressure, for a period of time in the range of about 1 week to about 10 weeks. The cartilage-like biomaterial shares critical structural, phenotype, and functional characteristics with native, intact cartilage tissue.

Abstract: A method and device is disclosed for inhibiting bone growth, including inducing epiphysiodesis or hemiepiphysiodesis, using electrical current. The device includes a power source and one or a series of electrodes for applying a current sufficient to reduce or stop the growth of a bone to selected regions of the bone. The method and device may be used to correct growth discrepancies in extremities such as the arms or legs, as well as correct the curvature of the spine in scoliosis patients.

Abstract: A method and device is disclosed for inhibiting bone growth, including inducing epiphysiodesis or hemiepiphysiodesis, using electrical current. The device includes a power source and one or a series of electrodes for applying a current sufficient to reduce or stop the growth of a bone to selected regions of the bone. The method and device may be used to correct growth discrepancies in extremities such as the arms or legs, as well as correct the curvature of the spine in scoliosis patients.