Bone-contacting surfaces and free surfaces of orthopedic implants. The implants are additively manufactured, followed by mechanical, chemical, or mechanical and chemical erosion. At least some of the surfaces of the implants include an osteoinducting roughness that has micro-scale structures and nano-scale structures that facilitate and enhance osteoinduction and osteogenesis, as well as enhanced alkaline phosphatase, osterix, and osteocalcin expression levels along the pathway of mesenchymal stem cell differentiation to osteoblasts.

A system or method for bioprinting bone graft provides obtaining an image of the patient's oral facial area, and viewed with the image viewing software. A restoratively driven dental implant treatment plan is created to restore the patient's missing dentition. The restoratively driven treatment plan is created. A physical exam, review of a patient's desires and expectations, review of imaging, acquisition and review of patient photographs and intraoral digital impressions. The imaging and digital impressions are aligned, via software to create a virtual representation. The anticipated final implant retained dentures, unitary implant crowns, or implant bridges, are planned to provide optimal esthetic and functional results. Dental implants are then planned for prosthetic anchors. Bone deficiencies are evaluated and if areas of boney deficiency are present, a patient specific bone graft is designed to restore said deficient areas. Once designed, it may be printed via additive manufacturing.

A graft cage includes cross-sectional portions and longitudinal members. Each portion includes base transverse members forming a cage base; a first arm including first arm transverse members; a second arm including second arm transverse members; base connecting struts, each base connecting strut extending between first one and second one of the base members; first arm connecting struts, each first arm connecting strut extending between a first one of the first members and a second one of the first members; and second arm connecting struts, each second arm connecting strut extending between first one and second one of the second members. The longitudinal members connect the portions to one another. Intersections of the portions with the longitudinal members forming pores in the first and second arms. The pores receive an arm tip of a further graft cage therein to interlock the cage with the further cage.

A composite comprising: a barrier, said barrier being configured to selectively pass water, and said barrier being degradable in the presence of water; a matrix material for disposition within said barrier, wherein said matrix material has a flowable state and a set state, and wherein said matrix material is degradable in the presence of water; and at least one reinforcing element for disposition within said barrier and integration with said matrix material, wherein said at least one reinforcing element is degradable in the presence of water, and further wherein, upon the degradation of said at least one reinforcing element in the presence of water, provides an agent for modulating the degradation rate of said matrix material in the presence of water.

A bone implant holding and shaping tray is provided. The tray includes a first segment having a distal end and a first surface sized to hold and shape at least a portion of the bone implant with bone material. The tray includes a second segment having a second surface sized to hold and shape at least a portion of the bone implant with bone material, the second segment having a proximal end configured to be coupled to the distal end of the first segment so as to extend the first surface to hold and shape the bone implant. Methods of making and using the bone implant holding and shaping tray are also provided.

Disclosed herein are an implant with an attachment feature and a method for attaching to the same. The implant may include a cavity with a porous layer disposed within a non-porous layer wherein the non-porous layer defines a chamber. The chamber may receive and confine liquefiable material and direct liquefiable material to permeate through the porous layer. A method of attaching a device to the implant may include liquefying a liquefiable portion of the device and allowing the liquefied material to interdigitate with the second layer and then solidify to prevent pullout.

A medical implant comprising a plurality of layers, each layer comprising a polymer and a plurality of uni-directionally aligned continuous reinforcement fibers.

A surgical fastener comprising a generally flat, circular body and a generally cylindrical post fixedly coupled to a center of the body extending perpendicular to the body. Both of the body and the post include through holes configured for passage of a suture. A length of the post is selected to extend through both of a bone graft and at least a portion of bone for providing shear and/or anti-rotational support to the surgical fastener across a fracture line in the bone.

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.

The invention relates to an implant (1) for the treatment of bone, in particular for covering defects or drill holes or for the reconstruction of bone defects or malformations. This comprises at least one frame structure (2) and at least one adaptation area (3). The edge of the implant (4) is thereby partially, but not continuously, formed by the frame structures (2), which are located outside the adaptation area (3).