The present invention discloses a connected structure of a porous surface structure and a substrate, a method for preparing the same, and a prosthesis of the same. The connected structure consists of a pre-connected or integrally formed composite body of a porous surface structure and an intermediate; and a substrate, which is connected to said intermediate to achieve the connection of said composite body to the said substrate; the composite body comprising a first composite region corresponding to a first stiffness; a remaining composite region in the composite body other than the first composite region, which at least contains a second composite region corresponding to a second stiffness; and the first stiffness is less than the second stiffness. The present invention achieves a fastened connection between the composite and the substrate and largely maintains the mechanical properties of the substrate; and it provides a prosthesis with excellent bone ingrowth properties and that the strength of the substrate is not substantially affected.

A prosthetic disc for insertion between adjacent vertebrae includes upper and lower plates, a core disposed between the plates, and at least one projection extending from at least one of the upper and lower curved surfaces of the core into at least one recess of one of the inner surfaces of the plates. The recess is oversize with respect to the projection to allow sliding movement of the plate over the core while retaining the core between the plates during such sliding movement. The projection(s) may include a rod extending through an axial hole in the core, multiple surface features of the core, or the like.

A total hip replacement prosthesis that comprises an acetabular component and a femoral component. The acetabular component has a full or partial hemispherical shape, and comprises a shell and one or more magnets. The femoral component comprises a stem portion comprising a proximal end and a distal end, a neck portion comprising a tapered end and a base end that is joined to the proximal end of the stem portion, and a spherical head that is affixed to the tapered end of the neck portion and comprises one or more magnets. The acetabular component is configured to receive all or a portion of the spherical head of the femoral component. Further, the one or more magnets of the acetabular component and the one or more magnets of the spherical head of the femoral component are oriented to generate an attractive force therebetween.

A multi-layer substrate apparatus includes a first layer configured to provide at least one electrical-based property. A second layer proximate to the first layer is configured to provide at least one mechanical-based property. A third proximate to the second layer includes at least one chemical component such that the third layer is enabled to regulate the multi-layer substrate apparatus based on a system that the multi-layer substrate apparatus is being used with. A fourth layer proximate to the third layer is configured to provide at least one magnetic-based property. A fifth layer proximate to the fourth layer is configured to provide support based on the system that the multi-layer substrate apparatus is being used with. The fifth layer includes a geometric portion that is configured to facilitate at least one process therein.

An adjustable bone implant having a body configured to be secured to a first bone surface; an anchoring member configured to be secured to a second bone surface held at a raised position offset from the first bone surface, and a spacing member connecting the anchoring member to the body in an adjustable manner, to selectively space the anchoring member from the body, where the spacing member is located subcutaneously, where the spacing member is configured to receive an input via a transcutaneoustransmission from an external tool, and where the spacing member is configured to lower the first bone surface from a raised position upon receipt of the input and secure the first bone surface at the lowered position.

A spinal implant adapted to be positioned within a disc space between adjacent vertebrae includes a first intradiscal element, a second intradiscal element, and a coupling mechanism. The first and second intradiscal elements include respective first and second outer surfaces adapted to be positioned adjacent an endplate of respective first and second adjacent vertebrae. The first and second intradiscal elements further include respective first and second medial surfaces that are opposite the respective first and second outer surfaces, where the second medial surface is adapted to generally face the first medial surface upon assembly of the first intradiscal element with the second intradiscal element. The coupling mechanism is associated with the first and second medial surfaces and is adapted to provide relative rotational movement between the first and second intradiscal elements in a plane generally parallel with the first and second medial surfaces.

A multi-layer substrate apparatus includes a first layer configured to provide at least one electrical-based property. A second layer proximate to the first layer is configured to provide at least one mechanical-based property. A third proximate to the second layer includes at least one chemical component such that the third layer is enabled to regulate the multi-layer substrate apparatus based on a system that the multi-layer substrate apparatus is being used with. A fourth layer proximate to the third layer is configured to provide at least one magnetic-based property. A fifth layer proximate to the fourth layer is configured to provide support based on the system that the multi-layer substrate apparatus is being used with. The fifth layer includes a geometric portion that is configured to facilitate at least one process therein.

An implantable device includes at least one solid structure having an external surface and a volume beneath the surface. One or more of a first conductor or set of conductors is disposed externally and/or internally on or within the structure and an array of elongate electrically conductive elements are disposed radially outwardly within the volume. A breach is detected when a conductive fluid intrudes into the volume through the surface.

A prosthetic disc for insertion between adjacent vertebrae includes upper and lower plates, a core disposed between the plates, and at least one projection extending from at least one of the upper and lower curved surfaces of the core into at least one recess of one of the inner surfaces of the plates. The recess is oversize with respect to the projection to allow sliding movement of the plate over the core while retaining the core between the plates during such sliding movement. The projection(s) may include a rod extending through an axial hole in the core, multiple surface features of the core, or the like.

A dynamic reversible electromagnetic locking element for locking the shoulder joint of a patient, in particular, in the form of a shoulder orthosis or a shoulder prosthesis, and methods for implementing the same. The dynamic reversible electromagnetic locking element has a ball and socket configuration to assist in operation of a glenohumeral joint (GHJ) in the patient.