A method of performing joint arthroplasty includes accessing a surface on a bone and supporting a stop with the accessed surface. The method includes positioning an instrument at least partially within the stop, the instrument having a body and a punch, the punch including a portion thereof having a shape similar to a shape of a stem of an implant, and rotating the stop with respect to the accessed surface based upon an indicia on one of the body and the stop so as to position the punch rotationally with respect to the accessed surface at a first orientation. The method further includes moving the body axially with respect to the stop to form a cavity in the bone with the punch at the first rotational orientation, the formed cavity having a shape similar to the stem of the implant, and implanting the stem of the implant into the cavity.

An implant for interbody fusion of vertebrae comprising a unibody cage structure having an enveloping cage volume and a minimized material volume. The cage structure comprises a first and a second generally planar ring member, each ring member formed from an opposing pair of lengthwise joists and an opposing pair of cross joists, the joists together forming a large opening through the ring member. The ring members are fixedly sandwiched on a plurality of support members, the support members holding the ring members in a spaced apart relationship to thereby provide a large void volume relative to the enveloping cage volume, to thereby allow for receipt of a large volume of bone graft within the cage structure.

An implantable medical device for implantation in a hip joint is provided. The medical device comprises: at least one artificial hip joint surface adapted to replace at least the surface of at least one of the caput femur and acetabulum. At least one artificial hip joint surface comprises: a positioning hole with at least one opening in said at least one artificial hip joint surface. The hole is adapted to be placed and dimensioned such that the medical device is adapted to be fitted using a positioning shaft and at least partly surround the shaft, for positioning the at least one artificial hip joint surface in a desired position in the hip joint. The hole is adapted to be fitted using the positioning shaft, when the shaft is stabilized and placed in at least one of the femoral bone and the pelvic bone for positioning said medical device inside the hip joint.

The current invention appropriately places stable implants into both sides of the shoulder joint to relieve pain and restore function in an arthritic shoulder, and does so in a manner that is arthroscopic, that does not violate the muscles about the shoulder or other vital structures, and that allows for immediate active or voluntary movement by the patient after surgery.

Systems and methods for treating musculoskeletal disorders of the spinopelvic anatomy including treating spinal deformities by spinopelvic fixation including fusion of the sacroiliac joint at the base of long spinal fusion construct cases. The system may include implants designed to be used as an adjunct to long spinal fusions to further the immobilization and stabilization of the sacroiliac joint. The implants may be designed to augment an S2AI screw and an S1 screw in order to improve durability of the foundation of the spinal construct. The implants may have a triangular cross section.

A method of implanting an intervertebral spacer may include positioning the intervertebral spacer within an intervertebral space defined by adjacent vertebral bodies. The intervertebral spacer may include a plurality of bores, and each of the plurality of bores may be configured to receive either a linear fastening element or a curvilinear fastening element. The method also may include selecting a first fastening element from a group including linear fastening elements and curvilinear fastening elements, and inserting the first fastening element into a first bore of the plurality of bores such that the first fastening element is inserted into one of the adjacent vertebral bodies to secure the intervertebral spacer within the intervertebral space.

An implantable ankle-prosthesis component (1), comprising a main body (2) with a bone contact face (3) intended to come into contact with an area of a bone body of an ankle and extending along a median contact plane (Pc), and comprising a anchoring means (4) protruding from the bone contact face (3), the anchoring means (4) comprising two pairs (20A, 20B) of anchoring wings, each extending in a plane (P1, P2), respectively, orthogonal to said median contact plane (Pc) between a first end (23A, 23B) connected to said bone contact face (3) and an opposite second end (24A, 24B), the planes of extension (P1, P2) of the pairs (20A, 20B) of anchoring wings intersecting each other, said second ends (24A, 24B) of the pairs (20A, 20B) of anchoring wings being inscribed in a leading plane (Pa) inclined with respect to said median contact plane (Pc).

A system for performing a minimally invasive interventional fusion procedure on a sacroiliac joint of a patient. The system may include a disposable sterile packed implant and kit including access, bone cutting, accessory and extraction instruments.

A vertebral body shaver assembly may include a shaver inserter and a shaver instrument. The shaver inserter may be used to insert the shaver instrument into an intradiscal space between vertebral body endplates in a non-expanded condition with a footprint area A1. The shaver instrument may then be adjusted into a to an expanded condition with a footprint area A2 that is greater than footprint area A1. As the shaver instrument is adjusted into the expanded condition, at least one blade may shave osteochondral material off at least one of the first vertebral body endplates.

A sacroiliac joint implant is formed from a web structure having a space truss with two or more planar truss units having a plurality of struts joined at nodes. The web structure is configured for fusion of a sacroiliac joint.