A bone material dispensing device is provided. The bone material dispensing device comprises a housing having a proximal end, a distal end, and a longitudinal axis. The proximal end having a first opening and the distal end having a second opening. The first opening and the second opening configured to slidably receive at least a portion of a plunger. A locking member is provided that is pivotably connected to an upper surface of the housing and extends adjacent to the upper surface of the housing. The locking member comprises a locking surface extending adjacent to the distal end of the housing configured to engage a portion of a tubular member, a funnel, or a combination thereof. The locking member is movable in a locking position to lock the portion of the tubular member, the funnel, or the combination thereof with the housing. A bone material dispensing system and a method of implanting bone material with the bone material dispensing system are also provided.

A threadless friction fit surgical implant suited for implantation or use in mammalian spinal or other boney tissues.

The invention relates to a glenoid (shoulder socket) implant prosthesis, a humeral implant prosthesis, devices for implanting glenoid and humeral implant prostheses, and less invasive methods of their use for the treatment of an injured or damaged shoulder.

The invention relates to a glenoid (shoulder socket) implant prosthesis, a humeral implant prosthesis, devices for implanting glenoid and humeral implant prostheses, and less invasive methods of their use for the treatment of an injured or damaged shoulder.

A device is disclosed that includes a bone stent positioned within a bony access channel formed within a vertebra. The bony access channel may extends from an outer end of the vertebra through an endplate. The device includes an end cap attached to a proximal end portion of the bone stent and is configured to, post-operatively, open to allow a reintroduction of a material to a spinal intradiscal space or intervertebral disc and to seal access to the spinal intradiscal space or the intervertebral disc after the reintroduction of the material.

One aspect relates to a seal for sealing a bone canal opening during the application of bone cement into the cancellous bone of a bone canal. The aspect also relates to a device for applying bone cement into the cancellous bone of a bone canal including the seal according to one embodiment, and a method for applying bone cement by using the device according to the embodiment.

A surgical system is provided that includes a body extending along a longitudinal axis. A first member is rotatably positioned within the body and includes a first threaded surface. A second member is positioned within the body and includes a second threaded surface that engages the first threaded surface. The second member is non-rotatable relative to the body. A third member is positioned within the first member. An inflatable bone tamp includes an outer shaft coupled to the body, a balloon coupled to the outer shaft and an inner shaft coupled to the third member and the balloon. The first member is rotatable relative to the body to translate the third member along the longitudinal axis to move the balloon from a first length to a second length. Kits and methods are disclosed.

A device for delivering a material to an orthopedic target site is disclosed. The device can be used to deliver bone cement to an intra-vertebral site. The device can have a pusher rod within a tube. The tube can be loaded with the bone cement distal to the pusher rod. The pusher rod can have varying rigidity along the length of the pusher rod. The tube and pusher rod can navigate tortuous pathways from a percutaneous or transcutaneous insertion en route to the target site or to improve extracorporeal ergonomics. Methods for using the same are also disclosed.

A bone cement pressuriser (50) comprising a pressuriser head. The pressuriser head has a first side (51) coupled to or configured to couple to an end of a pressuriser handle and a second side (52) configured to transfer pressure to bone cement in a bone cavity. The second side of the pressuriser head is defined by a first, convex curved surface (53) and a second surface (54) forming a ring surrounding the first surface and extending radially beyond the first surface. A method of pressurising bone cement using the bone cement pressuriser is also disclosed. The first surface is configured to pressurise bone cement within a bone cavity and the second surface is configured to both pressurise bone cement within the bone cavity and to seal about the periphery of the bone cavity.

Methods and systems are provided for robotic assisted surgery. A robotic system includes a localizer, at least one controller, and a surgical robotic manipulator which separately and detachably receives an energy applicator and an implant insertion tool that detachably receives an implant specifically for knee, hip or shoulder replacement surgery. The at least one controller determines a location within a portion of a patient's anatomy in which to form a cavity for the implant. The surgical robotic manipulator is controlled to form the cavity with the energy applicator. The surgical robotic manipulator is then controlled to insert the implant into the cavity with the implant insertion tool.