Abstract: Embodiments described include devices and methods for forming a porous polymer material. Devices disclosed and formed using the methods described a spacer for spinal fusion, craniomaxillofacial (CMF) structures, and other structures for tissue implants.

Abstract: Embodiments described include devices and methods for forming a porous polymer material. Devices disclosed and formed using the methods described a spacer for spinal fusion, craniomaxillofacial (CMF) structures, and other structures for tissue implants.

Abstract: Embodiments described include devices and methods for forming a porous polymer material. Devices disclosed and formed using the methods described a spacer for spinal fusion, craniomaxillofacial (CMF) structures, and other structures for tissue implants.

Abstract: Embodiments described include devices and methods for forming a porous polymer material. Devices disclosed and formed using the methods described a spacer for spinal fusion, craniornaxillofacial (CMF) structures, and other structures for tissue implants.

Abstract: Embodiments described include devices and methods for forming a porous polymer material. Devices disclosed and formed using the methods described a spacer for spinal fusion, craniomaxillofacial (CMF) structures, and other structures for tissue implants.

Abstract: Embodiments described include devices and methods for forming a porous polymer material. Devices disclosed and formed using the methods described a spacer for spinal fusion, craniomaxillofacial (CMF) structures, and other structures for tissue implants.

Abstract: Embodiments described include devices and methods for forming a porous polymer material. Devices disclosed and formed using the methods described include a spacer for spinal fusion, craniomaxillofacial (CMF) structures, and other structures for tissue implants.

Abstract: Embodiments described include devices and methods for forming a porous polymer material. Devices disclosed and formed using the methods described include a spacer for spinal fusion, craniomaxillofacial (CMF) structures, and other structures for tissue implants.

Abstract: The present invention is directed to an improved nail and an associated method for implanting the nail into a patient's bone. The nail preferably includes a proximal end, a distal end, a plurality of spiral blades (e.g., vanes) and a cannulated bore extending from the proximal end to the distal end so that in use an injectable material such as, for example PCL material, can be injected into the patient's bone through the cannulated bore formed in the nail. The nail also preferably includes a cutout portion at the distal end thereof in order to direct the outflow of injectable material through the cannulated bore. The cutout portion preferably is configured to facilitate the injectable material outflowing past the distal end of the nail and superiorly of the nail when the nail is properly implanted and positioned in situ.

Abstract: A method for augmenting a tissue including introducing into the tissue a first thermoplastic material at a first condition; treating the first thermoplastic material to achieve a second condition that includes an at least partially crystalline skin; and introducing a second material into the tissue whereby the first thermoplastic material and the second material are contained by the at least partially crystalline skin. Also a method of fracture reduction in a tissue including exposing to gamma radiation a mass of polycaprolactone characterized by a first shape; heating the mass of irradiated polycaprolactone above its melting temperature; introducing the heated mass of polycaprolactone into the tissue annulus to deform it from the first shape; allowing the material to return to the first shape.

Abstract: A spinal cage insert for a spinal cage is provided. The spinal cage insert has a shape suitable to be inserted into and fit closely in an interior of the spinal cage. The insert may comprise a member of the calcium phosphate family. The spinal cage insert may be made to a desired shape of porous ceramic, and it may include channels and/or surface features. Various shapes of filler pieces are also provided, wherein the filler pieces may be suitable to augment external regions of vertebrae which have been fused to each other so as to promote build-up of bone. The spinal cage insert and/or the filler pieces may be osteoconductive and may also contain osteoinductive substances or material. The articles may also contain cavities suitable for containing particles of demineralized bone matrix (DBM). Methods of use and methods of manufacturing the spinal cage insert and filler pieces are also provided.

Abstract: The invention is directed to shaped bone void filler pieces having defined porosity. In embodiments of the invention, the shaped bone void filler pieces are presented substantially as wedges, wafers, and axisymmetric bone void filler pieces. The bone void filler pieces further comprise surface and internal features such as recesses, channels, and/or voids. The bone void filler pieces optionally comprise demineralized bone matrix. The invention further is directed to methods of making and methods of using the bone void filler pieces. In another embodiment of the invention, the bone void filler pieces are produced using three dimensional printing methods. In yet another embodiment of the invention, the bone void filler pieces are manufactured with selected porogens integrated therein, which optionally are decomposed following production through a heat-mediated decomposition process, resulting in voids in the bone void filler spaces previously occupied by the porogen(s).