Interbody cages for spinal stabilization having a frame that surrounds a central compartment suitable for retaining biological material, such as bone graft material. The central, compartment acts as a spill-free bone and biologic compartment that allows a surgeon to introduce the interbody cage into the body in an effective manner without spilling the biological material. Methods for introducing the interbody cages are disclosed.

The present invention implements a set of grooves/ridges created on Ti at the circumferential direction to increase surface area of implant in contact with bone. These grooves/ridges protect nanofiber matrix (NFM) made with Polycaprolactone (PCL) electrospun nanofiber (ENF) and collagen at the groove from physiological loading. Controlled fabrication of a ridge made with titanium nitride (TiN) around the circumference of Ti is provided using a plasma nitride deposition technique. PCL ENF may be deposited along the sub-micrometer grooves using the electrospin setup disclosed. The method provides for fabrication of microgroove on Ti using machining or TiN deposition and filling the microgrooves with the NFM. This method has proven through experimentation to be successful in increasing in vivo mechanical stability and promoting osseointegration on Ti implants. The immobilization of MgO NP and FN with the PCL-CG NFM on microgrooved Ti as provided in the invention optimizes biological performances of Ti.

Embodiments of the disclosure relate to devices (e.g., patches, plugs, beams, plates, screws, rods, granules, spacers, cages, discs, tape devices, or other shape determined by the geometry or anatomy of the site of application) and methods of use thereof.

A bufferable femoral implant includes a metallic main body, and an elastomer member integrally formed or connected to a lower portion of the metallic main body, whereby when an external force acts upon the femoral implant as implanted in a patient's femur, the elastomer member as packed within the medullary cavity in the femur will bufferably dampen such an external force for safely protecting the patient's femur, the femoral implant and the related hip bones.

A medical product (100), preferably for use in treating, in particular filling and/or closing a bone cavity, wherein the product (100) comprises a plurality of interconnected members (110), wherein each member (110) has a peripheral boundary (120) and the boundaries (120) of adjacent members (110) engage with one another. Also, a method for producing the medical product (100) and a medical kit that comprises the medical product (100) and a securing element for securing the product (100) in a bone cavity and to a method for filling a bone cavity.

The improved endoprosthetic device surface treatment encourages soft tissue attachment thereto. A porous mesh surface treatment creates on an outer surface of the endoprosthetic device a three-dimensional surface structure similar to cancellous bone. Suture attachment features are provided at various locations around the treated surface structure to initially affix a vascularized soft tissue to the treated surface. As the patient heals the soft tissue grows and infiltrates the porous mesh surface to achieve an attachment strength substantially equal to the surrounding tissue.

A surgical implant device, comprising: a body portion defining a plurality of ports; a plurality of bone screws disposed partially through the plurality of ports defined by the body portion; a locking plate disposed over a head portion of at least one of the plurality of bone screws and engaging a plurality of recesses manufactured into a side of the body portion; and a screw operable for compressing the locking plate against the side of the body portion. Optionally, the surgical implant device further comprising: one or more surfaces comprising a plurality of protruding structures; wherein the body portion and the one or more surfaces comprising the plurality of protruding structures are integrally formed. The one or more surfaces comprising the plurality of protruding structures are formed by an additive manufacturing process.

An implantable prosthetic device for the repair of damaged cartilage including methods of implantation and repair. The prosthetic device is formed from a biocompatible pad having an open structure connected to a textile or non-woven sheet-like anchor. In one embodiment the anchor comprises legs that extend away from a perimeter region of the pad and spaced apart along their respective lengths such that an in unfolded orientation, the longitudinal edges of neighbouring legs are not in contact with one another and a spatial gap is provided between the anchoring legs. The anchor may also be provided in the form of strips to which anchorage sutures or other medical cords may be attached to fixate the device between connective tissue.

Computer implemented methods of producing a mesh implant having a compartment to enclose a bone material therein are provided. These methods include generating a 3D digital model of the mesh implant having the compartment, the 3D digital model including a virtual volume of the compartment and a virtual depth, thickness and volume of the mesh implant; generating a 3D digital model of a covering configured for closing the compartment of the mesh implant, the 3D digital model including a virtual volume of the covering for closing the compartment of the mesh implant; and instructing a 3D printer coupled to a computer to generate the mesh implant based on the 3D digital models. A computer system for making a mesh implant and a delivery system including the mesh implant are also provided.

Representative embodiments are disclosed for a spinal disc device which is implantable between adjacent vertebral bodies. A representative spinal disc device comprises: a first transverse plate member; a first arcuate extension extending longitudinally from the first transverse plate member and having a first configuration; a second transverse plate member; and a second arcuate extension extending longitudinally from the second transverse plate member and having a second, mating configuration with the first configuration of the first arcuate extension and slideably moveable with respect to the first arcuate extension, with the first and second arcuate extensions further arranged to form a central through-channel between the first and second transverse plate members to hold bone graft material. In various embodiments, the first and second configurations of the first and second arcuate extensions are each a partially spherical, convex shell configuration providing for movement in both the sagittal and coronal planes for deformity correction.