Abstract: A knitted fabric, including: a front face and a rear face, wherein the front face includes a first plurality of fibres of at least one of a first colour, a first colour combination, a first material and a first material combination, and the rear face includes a second plurality of fibres of at least one of a second colour, a second colour combination, a second material and a second material combination, the fabric having a knit pattern wherein the first plurality of fibres are at least partially separated from the second plurality of fibres, such that the front face is visually different when compared to the rear face.

Abstract: There is disclosed a system and methods for safely and securely gripping osseous-based tissue during allograft processing. One embodiment includes a first forceps half pivotally coupled to a second forceps half, where the first and the second forceps halves combine to form a handle portion and a head portion. The handle portion may define a first longitudinal axis, and the head portion may define a second longitudinal axis that intersects the first longitudinal axis at a varying head angle. The first and the second halves move between an open position in which the first and second forceps halves at the head portion are separated and a closed position in which the first and second forceps halves at the head portion are together. The forceps may also include an open-biasing spring element attached between the first and second forceps halves and a selective locking mechanism. Other embodiments are also disclosed.

Abstract: A medical device, comprising a shaft, wherein the shaft has a corrugated body, and wherein the corrugated body includes a plurality of hoops extending around a circumference of the shaft, a plurality of indentations, wherein the plurality of indentations extend around a portion of the circumference of the shaft and define a reduced-diameter portion of the shaft relative to a diameter of the plurality of hoops, and wherein each of the plurality of hoops is spaced apart from an adjacent hoop of the plurality of hoops by at least one of the plurality of indentations, and a plurality of nodes, wherein each node extends between and connects adjacent hoops of the plurality of hoops, and wherein each of the plurality of nodes is radially offset relative to adjacent nodes along a longitudinal axis of the shaft.

Abstract: There is disclosed a system and methods for debriding soft tissue from bone using a high-pressure water debridement system. One embodiment includes a cylindrical sleeve bounded by endcaps and having a drainage port positioned for effluent drainage. A central shaft is configured to receive a bone segment and is disposed along a longitudinal center of the sleeve and rotatively coupled between the endcaps. At least one high-pressure water nozzle is disposed on each side of the sleeve, each of which is positioned to impact the bone segment with a high-pressure water stream. A rotational actuator is configured to rotate the central shaft and the bone segment relative to the sleeve and the water nozzles such that when the high-pressure water nozzles are operational, the high-pressure water streams debride the bone segment. Other embodiments are also disclosed.

Abstract: There is disclosed a system and methods for debriding soft tissue from bone using a high-pressure water debridement system. One embodiment includes a cylindrical sleeve bounded by endcaps and having a drainage port positioned for effluent drainage. A central shaft is configured to receive a bone segment and is disposed along a longitudinal center of the sleeve and rotatively coupled between the endcaps. At least one high-pressure water nozzle is disposed on each side of the sleeve, each of which is positioned to impact the bone segment with a high-pressure water stream. A rotational actuator is configured to rotate the central shaft and the bone segment relative to the sleeve and the water nozzles such that when the high-pressure water nozzles are operational, the high-pressure water streams debride the bone segment. Other embodiments are also disclosed.

Abstract: A knitted fabric (10) including a plurality of parallel chains of knitted loops (12), with each chain of knitted loops (12) formed from a respective yarn, and with the parallel chains of knitted loops (12) extending in the warp or vertical direction. The fabric (10) also includes a plurality of weft yarns (14), with each weft yarn (14) connected to and extending across at least two adjacent chains of knitted loops (12). Each chain of knitted loops (12) is also associated with at least one respective yarn 16, (18) that is connected to, and intertwines along the chain of knitted loops (12).

Abstract: A knitted fabric, including: a front face and a rear face, wherein the front face includes a first plurality of fibres of at least one of a first colour, a first colour combination, a first material and a first material combination, and the rear face includes a second plurality of fibres of at least one of a second colour, a second colour combination, a second material and a second material combination, the fabric having a knit pattern wherein the first plurality of fibres are at least partially separated from the second plurality of fibres, such that the front face is visually different when compared to the rear face.

Abstract: There is disclosed a system and methods for safely, precisely, and efficiently cutting cadaveric bone segments into a number of dimensionally standardized pieces. One embodiment provides a jig system for use with a band saw. The jig system may include a v-shaped trough riding upon a plate and at least one rail designed to glide within a corresponding groove formed in the band saw table and stretching parallel to the blade. The trough may include a channel having a series of incremental stops extending between its proximal and distal ends. A bone-advancement wedge may be advanced proximally along the channel between the incremental stops to advance at least one bone segment within the trough toward the proximal end of the trough such that, by sliding the rail(s) within the table groove(s), a desired incremental portion of the bone segment is introduced to the blade. Other embodiments are also disclosed.

Abstract: A knitted fabric (10) including a plurality of parallel chains of knitted loops (12), with each chain of knitted loops (12) formed from a respective yarn, and with the parallel chains of knitted loops (12) extending in the warp or vertical direction. The fabric (10) also includes a plurality of weft yarns (14), with each weft yarn (14) connected to and extending across at least two adjacent chains of knitted loops (12). Each chain of knitted loops (12) is also associated with at least one respective yarn 16, (18) that is connected to, and intertwines along the chain of knitted loops (12).

Abstract: There are disclosed systems and methods for safely and effectively removing the articular cartilage and cortical bone layers from an articular surface of a human cadaveric femoral head. One embodiment includes an osseous-sanding accessory system installed upon a conventional band saw having a motor and a cabinet that houses a pulley coupled with a primary drive shaft rotated by the motor. The accessory system may include a threaded drive shaft coupled with the primary drive shaft, a grinding disk having an abrasive surface and affixed about a distal end of the threaded drive shaft, and a removable accessory table mounted to the band saw below the grinding disk. When the motor rotates the primary drive shaft, and thus the threaded drive shaft, the grinding disk rotates relative to the accessory table and abrades osseous tissues introduced to the abrasive surface of the grinding disk. Other embodiments are also disclosed.

Abstract: There is disclosed a system and methods for debriding soft tissue from bone using a high-pressure water debridement system. One embodiment includes a cylindrical sleeve bounded by endcaps and having a drainage port positioned for effluent drainage. A central shaft is configured to receive a bone segment and is disposed along a longitudinal center of the sleeve and rotatively coupled between the endcaps. At least one high-pressure water nozzle is disposed on each side of the sleeve, each of which is positioned to impact the bone segment with a high-pressure water stream. A rotational actuator is configured to rotate the central shaft and the bone segment relative to the sleeve and the water nozzles such that when the high-pressure water nozzles are operational, the high-pressure water streams debride the bone segment. Other embodiments are also disclosed.

Abstract: There is disclosed a system and methods for debriding soft tissue from bone using a high-pressure water debridement system. One embodiment includes a cylindrical sleeve bounded by endcaps and having a drainage port positioned for effluent drainage. A central shaft is configured to receive a bone segment and is disposed along a longitudinal center of the sleeve and rotatively coupled between the endcaps. At least one high-pressure water nozzle is disposed on each side of the sleeve, each of which is positioned to impact the bone segment with a high-pressure water stream. A rotational actuator is configured to rotate the central shaft and the bone segment relative to the sleeve and the water nozzles such that when the high-pressure water nozzles are operational, the high-pressure water streams debride the bone segment. Other embodiments are also disclosed.

Abstract: There are disclosed systems and methods for safely and effectively removing the articular cartilage and cortical bone layers from an articular surface of a human cadaveric femoral head. One embodiment includes an osseous-sanding accessory system installed upon a conventional band saw having a motor and a cabinet that houses a pulley coupled with a primary drive shaft rotated by the motor. The accessory system may include a threaded drive shaft coupled with the primary drive shaft, a grinding disk having an abrasive surface and affixed about a distal end of the threaded drive shaft, and a removable accessory table mounted to the band saw below the grinding disk. When the motor rotates the primary drive shaft, and thus the threaded drive shaft, the grinding disk rotates relative to the accessory table and abrades osseous tissues introduced to the abrasive surface of the grinding disk. Other embodiments are also disclosed.

Abstract: There is disclosed a system and methods for safely, precisely, and efficiently cutting cadaveric bone segments into a number of dimensionally standardized pieces. One embodiment provides a jig system for use with a band saw. The jig system may include a v-shaped trough riding upon a plate and at least one rail designed to glide within a corresponding groove formed in the band saw table and stretching parallel to the blade. The trough may include a channel having a series of incremental stops extending between its proximal and distal ends. A bone-advancement wedge may be advanced proximally along the channel between the incremental stops to advance at least one bone segment within the trough toward the proximal end of the trough such that, by sliding the rail(s) within the table groove(s), a desired incremental portion of the bone segment is introduced to the blade. Other embodiments are also disclosed.

Abstract: There is disclosed a system and methods for debriding soft tissue from bone using a high-pressure water debridement system. One embodiment includes a cylindrical sleeve bounded by endcaps and having a drainage port positioned for effluent drainage. A central shaft is configured to receive a bone segment and is disposed along a longitudinal center of the sleeve and rotatively coupled between the endcaps. At least one high-pressure water nozzle is disposed on each side of the sleeve, each of which is positioned to impact the bone segment with a high-pressure water stream. A rotational actuator is configured to rotate the central shaft and the bone segment relative to the sleeve and the water nozzles such that when the high-pressure water nozzles are operational, the high-pressure water streams debride the bone segment. Other embodiments are also disclosed.

Abstract: There is disclosed a system and methods for safely and securely gripping osseous-based tissue during allograft processing. One embodiment includes a first forceps half pivotally coupled to a second forceps half, where the first and the second forceps halves combine to form a handle portion and a head portion. The handle portion may define a first longitudinal axis, and the head portion may define a second longitudinal axis that intersects the first longitudinal axis at a varying head angle. The first and the second halves move between an open position in which the first and second forceps halves at the head portion are separated and a closed position in which the first and second forceps halves at the head portion are together. The forceps may also include an open-biasing spring element attached between the first and second forceps halves and a selective locking mechanism. Other embodiments are also disclosed.