Abstract: Methods for making an osteoimplant are provided. In one embodiment the method includes applying a mechanical force to an aqueous slurry of insoluble collagen fibers to entangle the insoluble collagen fibers so as to form a semi-solid mass of entangled insoluble collagen fibers; and lyophilizing the semi-solid mass of entangled collagen fibers to form the osteoimplant. An osteoimplant containing entangled insoluble collagen fibers is also provided.

Abstract: Methods for making an osteoimplant are provided. In one embodiment the method includes applying a mechanical force to an aqueous slurry of insoluble collagen fibers to entangle the insoluble collagen fibers so as to form a semi-solid mass of entangled insoluble collagen fibers; and lyophilizing the semi-solid mass of entangled collagen fibers to form the osteoimplant. An osteoimplant containing entangled insoluble collagen fibers is also provided.

Abstract: Methods for making an osteoimplant are provided. In one embodiment the method includes applying a mechanical force to an aqueous slurry of insoluble collagen fibers to entangle the insoluble collagen fibers so as to form a semi-solid mass of entangled insoluble collagen fibers; and lyophilizing the semi-solid mass of entangled collagen fibers to form the osteoimplant. An osteoimplant containing entangled insoluble collagen fibers is also provided.

Abstract: Described are implantable, malleable medical materials comprising mineral particles, insoluble collagen fibers, and a gel-forming polysaccharide component and/or another added gel-former. The malleable medical materials can be used treat bone or other tissue defects in patients, including in conjunction with biologically active factors such as osteogenic proteins. Also described are methods and materials that can be used to prepare the malleable medical materials.

Abstract: Described are implantable, malleable medical materials comprising mineral particles, insoluble collagen fibers, and a gel-forming polysaccharide component and/or another added gel-former. The malleable medical materials can be used treat bone or other tissue defects in patients, including in conjunction with biologically active factors such as osteogenic proteins. Also described are methods and materials that can be used to prepare the malleable medical materials.

Abstract: Described are implantable, malleable medical materials comprising mineral particles, insoluble collagen fibers, and a gel-forming polysaccharide component and/or another added gel-former. The malleable medical materials can be used treat bone or other tissue defects in patients, including in conjunction with biologically active factors such as osteogenic proteins. Also described are methods and materials that can be used to prepare the malleable medical materials.

Abstract: A lead including one or more electrodes having circuitry associated therewith. Each such electrode includes a circuit extending along and conforming to at least a portion of an inner surface of the electrode. The circuit includes an isolation substrate contacting at least a portion of the inner surface of the cylindrical electrode portion, a first contact electrically isolated from the electrode portion by the isolation substrate and an integrated circuit electrically coupled to the first contact and the electrode.

Abstract: A lead including one or more electrodes (e.g., electrodes, such as those having circuitry associated therewith).

Abstract: Methods and compositions are provided for inducing neovascularization in injured tissues with endothelial progenitor cells (EPCs). Mixtures of purified CD34+ endothelial progenitors and purified CD14+ monocytes, or products of an in vitro co-culture of purified CD34+ endothelial progenitor cells and purified CD14+ monocytes provide neovascularization after administration to a subject having a tissue injury, such as an ischemic injury.

Abstract: An endoluminal stent graft includes segments of a healing promoter to promote the “healing in” of the distal and/or proximal neck(s) of the endoluminal stent graft in a vessel, thus reducing the risk of migration and the occurrence of endoleaks that can formed at the side of the neck(s) and the consequent feeding of the aneurysm sac. In some applications, the segments of the healing promoter are located within a proximal anchor region located near the proximal neck opening of the endoluminal stent graft and, optionally, within one or more distal anchor regions located near one or more distal neck openings of the endoluminal stent graft. In other applications, the segments of the healing promoter are located within the proximal anchor region, but not the distal anchor region.

Abstract: An endoluminal stent graft includes a healing-promoting material to enhance the “healing” of the proximal and/or distal neck(s) of the endoluminal stent graft and the vessel wall; the risk of migration and the occurrence of Type 1 endoleaks is reduced. The healing-promoting material is located within a proximal anchor region located near the proximal neck opening of the endoluminal stent graft and optionally within one or more distal anchor regions located near one or more distal neck openings of the endoluminal stent graft.

Abstract: The present invention is directed to methods, compositions, systems, and medical devices for fusing bone.