Systems and methods are provided for generating microscale structures and/or nanoscale structures, surface profiles, and surface chemistries on medical devices. Embodiments disclosed herein utilize exposure of pulsed laser radiation on to a surface of a material by a pulsed laser. The pulsed laser according to embodiments disclosed herein is configured to emit at least one laser pulse toward the surface and thereby modify the profile of the surface in order to selectively promote or inhibit bioactivity and medical functionality of the material. By selectively promoting or inhibiting bioactivity of the material, enhanced biointegration at a cellular level may be achieved. For example, modifying the surface profile and/or surface chemistry of a first substrate material can improve adhesive and/or chemical bonding of the first material to a bioactive second coating material.

The disclosure includes an implant configured to contact a portion of a bone, the implant including a stem having a proximal section and a distal section and a porous portion extending a distance along the stem in a longitudinal direction of the stem.

Disclosed is a medical device having a first implant portion having a proximal end, a second implant portion connected to the first implant portion, the second implant portion having a distal end, and a driver assembly removably connected to the distal end, the driver assembly comprising a drill connected to the distal end at a connection.

An endoprosthetic component which is set up in the implanted state to penetrate in a controlled manner into adjoining bone material.

Orthopedic implants produced by additive manufacture, followed by refinement of exterior and interior surfaces trough mechanical erosion, chemical erosion, or a combination of mechanical and chemical erosion. Surface refinement removes debris, and also produces bone-growth enhancing micro-scale and nano-scale structures.

The present invention provides a process by which both non-tissue engineered and tissue engineered cartilaginous-like structures can be fabricated. The process of the present invention provides a method to produce electrospun nanofiber-anchored NP gels. The present invention provides a functional design for novel engineered IVD. The present invention provides a method for fabrication of both non-tissue and tissue engineered IVDs. These cartilaginous-like structures can be used to produce replacements for degenerated natural IVD. The method of the present invention uses electrospun PCL nanofiber mesh to anchor the NP. The method of the present invention can create angle-ply AF structure around the circumference of NP to mimic the architecture of native IVD. The method of the present invention anchors the top and bottom sides of NP by using non-woven aligned or random nanofiber mesh to create scaffold for the generation of endplate (EP) tissue.

An interbody fusion device includes a base member, a top member, and an expansion mechanism for moving the top member relative to the base member. The expansion mechanism may include a connector drive rod assembly, a gear, a threaded rod, and a support means. The gear ring is coupled to the threaded rod and is rotatable. The expansion mechanism may also include at least one load head coupled to the threaded rod. An alternative interbody fusion device is also disclosed and includes a bottom member, a superior member, and an expansion mechanism for moving the superior member relative to the bottom member. The expansion mechanism includes a first expansion assembly for moving a first end of the superior member relative to the bottom member, a second expansion assembly for moving a second end of the superior member relative to the bottom member, and a connector drive rod assembly.

Implants are formed from a multiple staged process that combines both additive and subtractive techniques. Additive techniques melt powders and fragments of a desired material, then successively layer the molten material into the desired implant shape, without compressing or remelting for homogenization of the layers, thereby producing an implant that is substantially free of pores and inclusions. Subtractive techniques refine implant surfaces to produce a bioactive roughened surface comprised of macro, micro, and nano structural features that facilitate bone growth and fusion.

One embodiment of the present invention is directed to compositions and methods for enhancing attachment of soft tissues to a metal prosthetic device. In one embodiment a construct is provided comprising a metal implant having a porous metal region, wherein said porous region exhibits a nano-textured surface.

Interbody fusion devices, insertion tools, methods for assembling an interbody fusion device, and methods for inserting a medical device between two vertebral bodies are disclosed. The interbody fusion device includes a base member, a top member, and at least one movement mechanism. The base member includes at least one of a pivotal cylinder and a hinge channel. The top member includes at least one of a pivot cylinder and a hinge channel. The at least one pivot cylinder of the base member engages the at least one hinge channel of the top member and the at least one pivot cylinder of the top member engages the at least one hinge channel of the base member. The at least one movement mechanism engages the top member and the base member. Also disclosed are a vertebral spacer device and an interbody spacer system including an insertion tool and an interbody fusion device.