A slotted washer configured to secure a K-wire to a native bone, including: an upper arm with a screw hole; a lower arm with a screw hole; a connector connecting the upper arm with the lower arm; and a K-wire opening between the connector, lower arm, and upper arm configured to receive and compress the K-wire.

A flexible bone implant includes a proximal stem having a proximal end, a distal end, and a proximal conduit extending from the proximal end to the distal end of the proximal stem, whereby the proximal conduit is open at both the proximal and distal ends of the proximal stem. The implant includes a distal stem having a proximal end, a distal end, and a distal conduit extending from the proximal end to the distal end of the distal stem, whereby the distal conduit is open at both the proximal and distal ends of the distal stem. The implant includes a flexible hinge interconnecting the distal end of the proximal stem with the proximal end of the distal stem for allowing the proximal and distal stems to flex relative to one another. A proximal stem protective tube is disposed within the proximal conduit of the proximal stem and has a length that matches the length of the proximal conduit, and a distal stem protective tube is disposed within the distal conduit of the distal stem and has a length that matches the length of the distal conduit. The proximal stem, the distal stem and the flexible hinge comprise a unitary structure made of a polymer material.

A method of preparing a metatarsophalangeal joint for fusion may involve surgically accessing the metatarsophalangeal joint and separating the metatarsal from the opposed proximal phalanx at the joint. The technique may involve preparing an end of the metatarsal and preparing an end of the opposed proximal phalanx for fusion. With or without the aid of a bone positioner, the metatarsal may be moved in one or more planes, such as the frontal and transverse planes. The proximal phalanx may also be moved in one or more planes, for example relative to the moved metatarsal. Subsequently, a bone fixation device can be applied across or through the metatarsophalangeal joint separating the metatarsal from the opposed proximal phalanx.

The present invention relates to a device and system for surgical fixation of small bones, small bone fragments, and osteotomies and more particularly to compression screw having a threaded leading portion which is joined to a section that is free from threads, and which includes an angle or from 12° to 25° in a plane through the longitudinal axis of the screw and a portion which is joined to a head having a configuration that is intended to provide anti-rotational stability and compression through the device.

The invention relates to nails used for ankle deformities and joint disorders characterized in that it comprises, in order to form an ankle arthrodesis nail (1) acting as a fixing nail passing through inside the canals of calcaneus, talus and tibia bones (19, 18, 17), providing a more rapid recovery and reducing the infection risk, at least three and at least two screw holes in lockable structure in its distal part and in its proximal part, respectively, arthrodesis nail (1) providing the closure of the inter-bone gap and an easier fusion by means of the compression effect during being fastened upon the bones, protrusions (15) extending from its proximal to its distal, and slit (12) or slits (12) at the proximal tip of the arthrodesis nail (1) to decrease the stress cracks that might occur due to the tip of the arthrodesis nail (1).

A fixation system for coupling a first and a second portion of bone together. The fixation system includes a first fixation element, a second fixation element, and an interconnect. The first fixation element includes an external surface configured to engage the first portion of bone and a first tapered mating surface. The second fixation element includes an external surface configured to engage the second portion of bone and a second tapered mating surface. The interconnect includes a first and a second tapered surface disposed at generally opposite ends. The first and the second tapered surfaces are configured to frictionally engage the first and the second tapered mating surfaces of the first and the second element, respectively, to form frictional interference connections therebetween.

An intermedullary nail for targeted arthrodesis of the tibiotalar joint. The intramedullary nail may be advanced through a bore extending through the calcaneus, talus, and into the tibia. In an example, a distal end portion of the intramedullary nail is disposed proximal to the subtalar joint. It has been recognized that creation of a bore for introduction of the intramedullary nail does not significantly disrupt the articular surface area of the subtalar joint. Furthermore, locking fasteners used to secure the intramedullary nail may introduced laterally and/or anteriorly to facilitate benefits in relation to patient placement and manipulation during an operation. Furthermore, arthrodesis may be extended to adjacent anatomy through use of extension plates at least partially secured by locking fasteners also engaging the intramedullary nail.

A metatarsal hemi-arthroplasty implant may include a convex outer surface overlaying a concave inner surface wherein the convex outer surface is shaped to replace an articular surface of a distal end of a metatarsus. The implant may further include a stem that is configured to be inserted into an intramedullary canal of the metatarsus. The stem may extend from the concave inner surface along a longitudinal axis of the implant, and may have an outward-facing surface disposed at a first angle relative to the longitudinal axis, at least one flute extending along the length, and at least one radial groove formed in the outward-facing surface. The implant may further include a plurality of rib members distributed about the stem member to connect the stem to the inner concave surface. Each of the rib members may have a distally-facing surface disposed at a second angle relative to the longitudinal axis.

Described is a new bone healing method and class of bone fixation implants that change shape once implanted so as to minimize non-healing and speed the bone healing process. The bone fixation method involves shape changing implants that continuously hold the bones in apposition so that a gap does not form. Gaps in time allow non-bony tissue to infiltrate and stop healing. Furthermore, the implants actively compress bone to increase bone mass and strength. Bone cell pressure due to compression and electrical current flow due to bone deformation act to stimulate healing. The new implant designs also provide a scaffolding to conduct bone through the implant and across the healing bone interface. The methods and designs are applicable to but not limited to use for bone screws, plates, staples, rods, cylinders and external fixation devices.

An implant is provided for use in an ankle joint between reconditioned end surfaces established on a distal end of an upper tibia bone and an opposing lower talus bone. The implant comprises a substantially porous rigid component adapted to be anchored against the upper tibia reconditioned end surface and the lower talus reconditioned end surface. The component defining an opening therethrough. An intramedullary nail is configured to pass through the opening in the component when the nail is driven through the talus and into the tibia.