The three-dimensional lattice structures disclosed herein have applications including use in medical implants, Some examples of the lattice structure are structural in that they can be used to provide structural support or mechanical spacing In some examples, the lattice can be configured as a scaffold to support bone or tissue growth Some examples can use a repeating modified rhombic dodecahedron or radial dodeca-rhombus unit cell. The lattice structures are also capable of providing a lattice structure with anisotropic properties to better suit the lattice for its intended purpose.

One aspect of the present disclosure relates to a tissue integration device. The tissue integration device can be produced by forming a polymer mixture into a shape. The polymer mixture can include a polymer resin and a growth-promoting medium. Next, at least one polymer forming the polymer resin can be oriented in at least one direction. The shaped polymeric material can then be formed into the tissue integration device.

A method for constructing a three-dimensional multi-scale surface to obtain controlled and improved physical and chemical configurations to promote the integration of orthopedic and/or dental implants, to human and/or animal tissues, in different shapes and geometries in a versatile manner, and can be applied to all types of metals, metal alloys and/or ceramic compounds. This method includes the modification at the macroscopic level of the roughness, with an objective of promoting the mechanical interlocking of the implant, followed by the modification of the surface for the formation of microtopography, then the microtopography is changed to obtain a nanotopography with characteristics that optimize cellular metabolic responses related to attraction, adhesion, spreading, proliferation and cell growth, in addition to phenotypic and genotypic inductions in undifferentiated cells and in osteoblast lineage, responsible for mineralization and bone neoformation. As a result, the interface between implant and bone is improved.

The present invention provides an expandable fusion device capable of being inserted between adjacent vertebrae to facilitate the fusion process. The expandable fusion device may include first and second endplates, a translation member configured to expand an anterior side and/or posterior side of the device, a plurality of joists configured to connect the first and second endplates to the translation member, and first and second actuation members disposed internally to the device such that openings on a back side of the device can be used to expand or compress the anterior side, the posterior side, or both and such openings may also be used to introduce graft material into the device.

Stemless components and fracture stems for joint arthroplasty, such as shoulder arthroplasty, are disclosed. Also, methods and devices are disclosed for the optimization of shoulder arthroplasty component design through the use of medical imaging data, such as computed tomography scan data.

An intervertebral implant for implantation in an intervertebral space between vertebrae. The implant includes a body extending from an upper surface to a lower surface. The body has a front end, a rear end and a pair of spaced apart first and second side walls extending between the front and rear walls such that an interior chamber is defined within the front and rear ends and the first and second walls. The body defines an outer perimeter and an inner perimeter extending about the internal chamber. At least one of the side walls is defined by a solid support structure and an integral porous structure, the porous structure extending from the outer perimeter to the inner perimeter. The porous structure embeds or encapsulates at least a portion of the solid support structure.

The present invention relates to an implant (10) comprising an implant body having a first surface area (A1, A2, A3, A4) configured for contact with soft connective tissue and a second surface area configured for contact with bone tissue, wherein the first surface area is covered with a coating comprising tantalum and the second surface area is formed by a material, which is different than the one forming the coating.

An orthopaedic surgical system for use in implanting a total knee prosthesis includes an adjustable tibial trial component that is movable in the anterior/posterior direction and rotatable when installed on the resected surface of a patient's tibia. A method of using such a system is also disclosed.

A spinal implant includes a body having opposite first and second end walls and opposite first and second side walls. The side walls each extend from the first end wall to the second end wall. A first cap is coupled to top ends of the walls. A second cap is coupled to bottom ends of the walls. The implant includes an opening extending through the caps such that the first cap defines a first ledge extending from the walls to the opening and the second cap defines a second ledge extending from the walls to the opening. Systems and methods of use are disclosed.

An orthopedic prosthesis for stimulating bone growth may include a substrate having at least one bone-facing surface and at least one internal surface, at least one piezoelectric nanostructure coupled to the at least one bone-facing surface of the substrate, at least one charge storing material placed within the orthopedic prosthesis proximate the at least one internal surface, and an interconnect in electrical communication with the at least one piezoelectric nanostructure and the charge storing material. The at least one piezoelectric nanostructure may be configured to generate an electric charge in response to at least one mechanical force applied to the at least one piezoelectric nanostructure and the interconnect may be configured to transfer the electric charge to the at least one charge storing material to promote bone in-growth within the orthopedic prosthesis and/or on the at least one bone-facing surface.