The present invention relates to a method for producing whitlockite, and whitlockite produced thereby. A method for producing whitlockite according to one embodiment of the present invention comprises: a step of preparing a precursor solution by mixing a first solution containing a calcium (Ca) ion source material, a second solution containing a magnesium (Mg) ion source material, and a third solution containing a phosphate (PO4) source material; a heat-treatment step of heat-treating the precursor solution; and a step of separating and purifying the precipitate formed in the solution, after the heat-treatment step.

An apparatus for use in a chemical vapor infiltration process is disclosed. The apparatus can optionally include any one or combination of a first reaction chamber, a mixing chamber and a second reaction chamber. The mixing chamber can have at least a first inlet, a second inlet and an outlet. The first inlet can be in fluid communication with the first reaction chamber and receive a second precursor gas. The second inlet can be in fluid communication to receive a third precursor gas. The second precursor gas and the third precursor gas can mix within the mixing chamber before passing to the outlet and into the second reaction chamber. The second reaction chamber can contain a substrate that can receive a film deposition from reaction of the second precursor gas and the third precursor gas within the second reaction chamber.

Placement apparatus and methods of use for impanation of spacers within an inter-vertebral disc space. In one embodiment, the load-bearing superstructure of the implant is subdivided and the bone forming material is positioned within an internal space of the placement instrument but external to the load bearing elements themselves. At least a portion of the bone graft material is freely contained within the disc space. A method of using the device is also described. In one embodiment, the placement device is used to place the implantable spacers at opposing ends of the disc space using a directly lateral surgical approach.

A selectively expanding spine cage has a minimized cross section in its unexpanded state that is smaller than the diameter of the neuroforamen through which it passes in the distracted spine. The cage conformably engages between the endplates of the adjacent vertebrae to effectively distract the anterior disc space, stabilize the motion segments and eliminate pathologic spine motion. Expanding selectively (anteriorly, along the vertical axis of the spine) rather than uniformly, the cage height increases and holds the vertebrae with fixation forces greater than adjacent bone and soft tissue failure forces in natural lordosis. Stability is thus achieved immediately, enabling patient function by eliminating painful motion. The cage shape intends to rest proximate to the anterior column cortices securing the desired spread and fixation, allowing for bone graft in, around, and through the implant for arthrodesis whereas for arthroplasty it fixes to endpoints but cushions the spine naturally.

Disclosed is an intervertebral cage for arthrodesis, where at least part of an upper and/or lower contact zone is made of a porous titanium material with a thickness of at least 1 mm and with a porosity of between 50% and 90%, where the diameter of the pores (DP) is between 200 μm and 1 mm, and where the pores have an aperiodic distribution.

Embodiments herein are generally directed to expandable spinal implants, systems, apparatuses, and components thereof that can be used in spinal fusion and/or stabilization procedures, as well as methods of installation. The expandable spinal implants may be configured for lateral insertion.

A device for hydrating particulate bone material is provided. The device comprises a tubular member having an interior surface and an exterior surface. The interior surface is configured to receive the particulate bone material and a hydration fluid. The exterior surface has a plurality of pores configured to allow the hydration fluid to flow into the interior surface of the tubular member and hydrate the particulate bone material. The plurality of pores are smaller in size than the particulate bone material. Methods of dispensing particulate the bone material are also provided.

An expandable intervertebral implant is provided for insertion into an intervertebral space defined by adjacent vertebrae. The expandable intervertebral implant includes a pair of outer sleeve portions and an inner core disposed between the outer sleeve portions. Movement of the inner core relative to the outer sleeve portions causes the outers sleeve portions to deflect away from each other, thereby engaging the expandable intervertebral implant with the vertebrae and adjusting the height of the intervertebral space.

A flexible hip joint stem includes a shoulder body connecting piece, a flexible stem body, a stem tail, and a center regulating rod. The flexible stem body includes an inner-layer cylinder and an outer-layer cylinder. The inner-layer cylinder and the outer-layer cylinder are both composed of spiral springs, where the spring wire width of the spiral springs is basically equal to the screw pitch. The regulating rod passes through the shoulder body connecting piece and the flexible stem body, and is fixed with the stem tail by screwing the threads, which allows the inner-layer cylinder and the outer-layer cylinder to produce a certain degree of elastic deformation, limits the range of the elastic deformation, and enables the flexible hip joint stem to have sufficient supporting strength as a whole.

A medical device comprising a substantially flexible porous structure. The porous structure comprises a plurality of interlocking units. Each of the plurality of interlocking units comprises a body and at least one arm. The plurality of interlocking units is configured to have space between adjacent interlocking units when the porous structure is in a neutral configuration. The plurality of interlocking units is configured to contact the respective body and arm of adjacent interlocking units when a compressive force is applied to the porous structure, thereby restricting compression of the porous structure. The plurality of interlocking units is configured to contact the respective arms of adjacent interlocking units when an extension force is applied to the porous structure, thereby restricting extension of the porous structure.