Abstract: This invention relates to biomineral-based cements incorporating biopolymer carriers for the site specific introduction of natural or synthetic compounds that influence bone repair and/or patient recovery. The invention further relates to methods for producing such biphasic calcium phosphate cements for drug delivery.

Abstract: A vertebral replacement device for supporting adjacent vertebrae includes a vertebral body member having at least one of an upper or lower disc replacement member engaged thereto at one end thereof. The disc replacement device can be positioned in a spinal disc space when disengaged from the vertebral body member.

Abstract: Described are medical devices for supporting or inducing bone growth including an implant body defining one or more separation-assist lines that facilitate separation of the body into two or more substantially pre-defined pieces. The implant body can be used and implanted as a whole or may be separated into multiple pieces, some or all of which can be used at one or multiple implant sites in a patient. Separation-assist lines in implant bodies can serve a dual role in imparting increased and controlled flexibility to the overall body when used as a whole at an implant site. Also described are methods of making and using, and kits including, such medical devices.

Abstract: A bone cutting template is disclosed and can include a body. A plurality of grooves can be formed along the body and each groove can correspond to an incremental length of the body. The bone cutting template can include a plurality of length stamps along the body. Each of the plurality of length stamps can be adjacent to a corresponding groove.

Abstract: A carrier matrix may be delivered to a target position within a patient in a minimally invasive manner by first cutting a collagen sponge sheet into a plurality of relatively small pieces. These pieces are sized so that, when wet, they are capable of flowing through a cannula and/or reduced-diameter syringe tip. The pieces are placed into a syringe and wetted, say with a morphogenic solution, and optionally mixed with a bulking material, which is similarly sized to fit through the cannula. The thoroughly mixed and wetted product forms a viscous aggregate which may then be injected into the patient at the target site.

Abstract: A carrier matrix may be delivered to a target position within a patient in a minimally invasive manner by first cutting a collagen sponge sheet into a plurality of relatively small pieces. These pieces are sized so that, when wet, they are capable of flowing through a cannula and/or reduced-diameter syringe tip. The pieces are placed into a syringe and wetted, say with a morphogenic solution, and optionally mixed with a bulking material, which is similarly sized to fit through the cannula. The thoroughly mixed and wetted product forms a viscous aggregate which may then be injected into the patient at the target site.

Abstract: A carrier matrix may be delivered to a target position within a patient in a minimally invasive manner by first cutting a collagen sponge sheet into a plurality of relatively small pieces. These pieces are sized so that, when wet, they are capable of flowing through a cannula and/or reduced-diameter syringe tip. The pieces are placed into a syringe and wetted, say with a morphogenic solution, and optionally mixed with a bulking material, which is similarly sized to fit through the cannula. The thoroughly mixed and wetted product forms a viscous aggregate which may then be injected into the patient at the target site.

Abstract: A carrier matrix may be delivered to a target position within a patient in a minimally invasive manner by first cutting a collagen sponge sheet into a plurality of relatively small pieces. These pieces are sized so that, when wet, they are capable of flowing through a cannula and/or reduced-diameter syringe tip. The pieces are placed into a syringe and wetted, say with a morphogenic solution, and optionally mixed with a bulking material, which is similarly sized to fit through the cannula. The thoroughly mixed and wetted product forms a viscous aggregate which may then be injected into the patient at the target site.

Abstract: A carrier matrix may be delivered to a target position within a patient in a minimally invasive manner by first cutting a collagen sponge sheet into a plurality of relatively small pieces. These pieces are sized so that, when wet, they are capable of flowing through a cannula and/or reduced-diameter syringe tip. The pieces are placed into a syringe and wetted, say with a morphogenic solution, and optionally mixed with a bulking material, which is similarly sized to fit through the cannula. The thoroughly mixed and wetted product forms a viscous aggregate which may then be injected into the patient at the target site.

Abstract: A carrier matrix may be delivered to a target position within a patient in a minimally invasive manner by first cutting a collagen sponge sheet into a plurality of relatively small pieces. These pieces are sized so that, when wet, they are capable of flowing through a cannula and/or reduced-diameter syringe tip. The pieces are placed into a syringe and wetted, say with a morphogenic solution, and optionally mixed with a bulking material, which is similarly sized to fit through the cannula. The thoroughly mixed and wetted product forms a viscous aggregate which may then be injected into the patient at the target site.

Abstract: Described is an implantable medical material comprising a malleable, cohesive, shape-retaining putty including mineral particles, insoluble collagen fibers and soluble collagen. The medical material can be used in conjunction with biologically active factors such as osteogenic proteins to treat bone or other tissue defects in patients.

Abstract: An implantable screw for maintaining space during bone grafting procedures is provided, where the screw has a highly-polished contoured head having a region adapted to support soft tissue, a threaded shaft and a tip adapted to penetrate bone tissue. Also provided, a device combining multiple implantable screws in series in order to increase the available space to grow new bone and a method for implanting the implantable screw. The implantable screws provided may be used in conjunction with bone graft materials and are removable once a desired amount of new bone is generated.

Abstract: An implantable screw for maintaining space during bone grafting procedures is provided, where the screw has a highly-polished contoured head having a region adapted to support soft tissue, a threaded shaft and a tip adapted to penetrate bone tissue. Also provided, a device combining multiple implantable screws in series in order to increase the available space to grow new bone and a method for implanting the implantable screw. The implantable screws provided may be used in conjunction with bone graft materials and are removable once a desired amount of new bone is generated.

Abstract: Described is an implantable medical material comprising a malleable, cohesive, shape-retaining putty including mineral particles, insoluble collagen fibers and soluble collagen. The medical material can be used in conjunction with biologically active factors such as osteogenic proteins to treat bone or other tissue defects in patients.

Abstract: Described is an implantable medical material comprising a malleable, cohesive, shape-retaining putty including mineral particles, insoluble collagen fibers and soluble collagen. The medical material can be used in conjunction with biologically active factors such as osteogenic proteins to treat bone or other tissue defects in patients.

Abstract: A carrier matrix may be delivered to a target position within a patient in a minimally invasive manner by first cutting a collagen sponge sheet into a plurality of relatively small pieces. These pieces are sized so that, when wet, they are capable of flowing through a cannula and/or reduced-diameter syringe tip. The pieces are placed into a syringe and wetted, say with a morphogenic solution, and optionally mixed with a bulking material, which is similarly sized to fit through the cannula. The thoroughly mixed and wetted product forms a viscous aggregate which may then be injected into the patient at the target site.

Abstract: Compositions for nucleus pulposus regeneration is provided. Such composition may comprise a scaffolding material and a pore creating agent dispersed within the scaffolding material. The pore creating agent is removed from the scaffolding material in vivo, after the composition is administered to a patient. The pore creating agent may include an active agent, such as a growth factor, which may be released as the pore creating agent is being gradually removed from the scaffolding material. In addition, removal of the pore creating agent results in a porous scaffold for cells capable of regeneration of nucleus pulposus, either existing in situ or delivered separately, to attach to for further proliferation and regeneration.

Abstract: A carrier matrix may be delivered to a target position within a patient in a minimally invasive manner by first cutting a collagen sponge sheet into a plurality of relatively small pieces. These pieces are sized so that, when wet, they are capable of flowing through a cannula and/or reduced-diameter syringe tip. The pieces are placed into a syringe and wetted, say with a morphogenic solution, and optionally mixed with a bulking material, which is similarly sized to fit through the cannula. The thoroughly mixed and wetted product forms a viscous aggregate which may then be injected into the patient at the target site.

Abstract: The present invention provides a composition that may be used as an implant or a bone graft substitute or extender for filling voids and/or promoting fusion of osseous tissues. The implant may comprise ceramic granules such as calcium phosphate granules and one or more polysaccharide excipients, and may be in the form of a putty or flowable paste. Optionally, the implant may also comprise a growth factor such as a bone morphogenetic protein.