The present disclosure includes joint replacement implants. The joint replacement implant allows for full articulation of the joint, while absorbing impact of the components during normal use that will reduce wear on the implant components and prolong life. The joint replacement implant may include a bone implantable component and a bearing component having an articulation surface that is sized and shaped to substantially mate with at least a portion of the bone implantable component and a damping mechanism that includes a contact member disposed at least primarily inside a cavity; a biasing member biasing the contact member toward an upper aperture of the cavity and means for capturing the contact member within the cavity.

An expandable housing for an interbody fusion system has movable tapered external helical threaded members that travel along tracking to operably engage against the top and bottom shell members, urging them apart to cause expansion in the height of the housing. In an embodiment, the tapered members are disposed in a dual arrangement such that independent engagement of the tapered members along lateral portions of the top and bottom shells cause an angular tilt to the exterior surface of the housing when the tapered members are moved to different degrees. This function permits adjustment in the angular relationship between adjacent vertebrae and assists the lordotic adjustment of the patient's spine. When the functions of the device are used in combination by the surgeon, the device provides an effective tool for in situ adjustment when performing lateral lumbar interbody fusion.

The subject matter includes a system and method for providing graphical feedback visualizing forces within a joint through a range of motion of the joint. The method can comprise receiving position data, receiving force data, and generating a graphical representation based on the position data and the force data. The receiving position data can include data for at least one bone of a joint while the at least one bone is moved through a range of motion (ROM). The receiving force data can occur concurrently to receiving the position data and using one or more processors, the force data can be collected from at least one force sensor embedded within a trial prosthesis in the joint. The graphical representation can illustrate changes in the force data versus locations of the bone as it moved through the ROM.

A plating system is described that uses various configurations of bone fixation implants that are configured to attach to one or more portions of a bone. An exemplary bone fixation implant includes a two-dimensional structure comprising a bone-engaging surface and a tissue-engaging surface. A plurality of openings is defined in the two-dimensional structure, and arranged across a length and a width of the bone fixation implant. At least some of openings are configured to receive an attachment member for securing the bone fixation implant to an underlying bone structure. The tissue-engaging surface is configured to engage an overlying tissue structure for encouraging incorporation of the tissue structure into the bone fixation implant to promote stabilization of the underlying bone structure during healing. In certain embodiments, at least 50% of the area defined by and/or between the length and the width of the two-dimensional structure is an opening.

A bone graft or spinal interbody device includes a frame member having two end segments for forming a chamber in the frame member, and two arms each include an outer end portion hinged to the outer end portion of the end segments of the frame member, and the inner end portions of the arms are hinged together for allowing the arms to be pivoted toward the frame member at an innermost folding position or away from the frame member to an outermost working position, and the arms are sprung away from the frame member to the outermost working position when the arms are pushed away from the frame member for a selected distance to an inner dead center (D).

An artificial ligament is provided having an elongate body and two ends, with a loop being provided at least one of the ends and a loop liner being provided within the loop. A kit of artificial ligaments is also provided with each ligament in the kit having a different fixed length. Also provided are methods for determining a length of artificial ligament to be used within a prosthetic knee joint, selecting a ligament from a range or kit of ligaments, and implanting a prosthetic knee joint assembly comprising an artificial ligament.

An expandable housing for an interbody fusion system has movable tapered external helical threaded members that travel along tracking to operably engage against the top and bottom shell members, urging them apart to cause expansion in the height of the housing. In an embodiment, the tapered members are disposed in a dual arrangement such that independent engagement of the tapered members along lateral portions of the top and bottom shells cause an angular tilt to the exterior surface of the housing when the tapered members are moved to different degrees. This function permits adjustment in the angular relationship between adjacent vertebrae and assists the lordotic adjustment of the patient's spine. When the functions of the device are used in combination by the surgeon, the device provides an effective tool for in situ adjustment when performing lateral lumbar interbody fusion.

Systems, methods, and apparatuses for relieving upper airway obstructive breathing in a patient are disclosed. In some implementations, the apparatus comprises first and second pivot devices anchored to a mastoid bone and a mandible bone, respectively; an implant positioned between the first and second pivot device, the implant comprising a first end coupled to the first pivot device and a second end coupled to the second pivot device; an inactive position, the inactive position enabling a posterior displacement of the second end relative to the first end; an active position, the active position preventing posterior displacement of the second end relative to the first end, and anteriorly positioning the second end relative to the first end; and an activation mechanism enabling transition between the inactive position and the active position, and vice versa.

An expandable spinal implant configured for positioning within the intervertebral space between adjacent vertebral bodies is disclosed. The spinal implant includes a first body, a second body, a ratchet, and a locking mechanism. The first and second bodies are pivotably affixed to each other on respective first ends thereof and are capable of movement relative to each other in a medial-lateral direction with respect to the adjacent vertebral bodies. The ratchet is pivotably supported within a slot defined in the first body and is capable of engaging the second body thereby permitting movement of the first and second body relative to each other in a first direction, but not in a second direction that is different than the first direction. A method of performing spinal surgery is also disclosed.

A plating system is described that uses various configurations of bone fixation implants that are configured to attach to one or more portions of a bone. An exemplary bone fixation implant includes a two-dimensional structure comprising a bone-engaging surface and a tissue-engaging surface. A plurality of openings is defined in the two-dimensional structure, and arranged across a length and a width of the bone fixation implant. At least some of openings are configured to receive an attachment member for securing the bone fixation implant to an underlying bone structure. The tissue-engaging surface is configured to engage an overlying tissue structure for encouraging incorporation of the tissue structure into the bone fixation implant to promote stabilization of the underlying bone structure during healing. In certain embodiments, at least 50% of the area defined by and/or between the length and the width of the two-dimensional structure is an opening.