Abstract: Methods for making surgical implants (or grafts) for the repair of bone defects, and more particularly, surgical implants that include demineralized bone fibers, are disclosed. Also disclosed are methods for increasing the wettability and ensuring uniform density of such implants. The surgical implants have a wettability time of less than 5 minutes and a residual moisture content of less than 6% by weight, and they remain cohesive and retain their shape upon complete rehydration.

Abstract: Methods for making surgical implants (or grafts) for the repair of bone defects, and more particularly, surgical implants that include demineralized bone fibers, are disclosed. Also disclosed are methods for increasing the wettability and ensuring uniform density of such implants. The surgical implants have a wettability time of less than 5 minutes and a residual moisture content of less than 6% by weight, and they remain cohesive and retain their shape upon complete rehydration.

Abstract: The disclosure provides implants containing a plurality of particles containing at least one population of viable cells adherent to and resident in soft tissue matrix or at least one viable population of cells caused to be in contact with the soft tissue matrix; methods of fabricating the implants; and use of the implants in tissue repair.

Abstract: The disclosure provides implants containing a plurality of particles containing at least one population of viable cells adherent to and resident in soft tissue matrix or at least one viable population of cells caused to be in contact with the soft tissue matrix; methods of fabricating the implants; and use of the implants in tissue repair.

Abstract: Methods for making surgical implants (or grafts) for the repair of bone defects, and more particularly, surgical implants that include demineralized bone fibers, are disclosed. Also disclosed are methods for increasing the wettability and ensuring uniform density of such implants. The surgical implants have a wettability time of less than 5 minutes and a residual moisture content of less than 6% by weight, and they remain cohesive and retain their shape upon complete rehydration.

Abstract: Surgical implants (or grafts) for the repair of bone defects, more particularly, surgical implants that include demineralized bone fibers, are disclosed. The surgical implants have a wettability time of less than 5 minutes and a residual moisture content of less than 6% by weight, and they remain cohesive and retain their shape upon complete rehydration. Methods for making such implants and for increasing their wettability and ensuring uniform density are also disclosed.

Abstract: The disclosure provides implants containing a plurality of particles containing at least one population of viable cells adherent to and resident in soft tissue matrix or at least one viable population of cells caused to be in contact with the soft tissue matrix; methods of fabricating the implants; and use of the implants in tissue repair.

Abstract: The disclosure provides implants containing a plurality of particles containing at least one population of viable osteogenic cells adherent to and resident in an osteoconductive matrix or at least one viable population of osteogenic cells caused to be in contact with the osteoconductive matrix; methods of fabricating the implants; and use of the implants in bone repair. The implant further contains an osteoinductive component. An example of an osteoinductive component is a demineralized bone matrix in the form of particles or fibers.

Abstract: Surgical grafts for the repair of bone defects, more particularly, surgical grafts that include demineralized bone fibers, are disclosed. Methods for making such grafts and for increasing their wettability and ensuring uniform density are also disclosed.

Abstract: The disclosure provides implants containing a plurality of particles containing at least one population of viable osteogenic cells adherent to and resident in an osteoconductive matrix or at least one viable population of osteogenic cells caused to be in contact with the osteoconductive matrix; methods of fabricating the implants; and use of the implants in bone repair. The implant further contains an osteoinductive component. An example of an osteoinductive component is a demineralized bone matrix in the form of particles or fibers.

Abstract: The invention is directed toward an instrumentation kit used to replace a damaged human knee joint meniscus with an allograft meniscus implant. The kit includes a workstation having a base and upright end sections with a clamping assembly is mounted on the end sections and a movable cutting guide mounted to a side wall of each end section. The tibia is then drilled with a drill to a desired depth and length and a groove is formed in the tibia with an osteotome so that the width is the same as the width of the bone base of the meniscus implant which has been trimmed in the workstation.

Abstract: The invention is directed toward an instrumentation kit used to replace a damaged human knee joint meniscus with an allograft meniscus implant. The kit includes a workstation having a base and upright end sections with a clamping assembly is mounted on the end sections and a movable cutting guide mounted to a side wall of each end section. The tibia is then drilled with a drill to a desired depth and length and a groove is formed in the tibia with an osteotome so that the width is the same as the width of the bone base of the meniscus implant which has been trimmed in the workstation.