Systems for treating and/or preventing fractures include at least one needle sized and configured to be placed into target bone and at least one implantable pin configured to be releasably held in a first needle of the at least one needle. The systems also include at least one delivery device of injectable material configured to couple to the first needle while the first implantable pin is held in the first needle whereby the at least one delivery device and a respective needle cooperate to serially provide an external column of the injectable material about the at least one implantable pin.

The device has a body with holes to accept the bone screws. The bone screws have a layer of bioresorbable material on a surface portion of the head of the screw contiguous with the shaft. Engagement between the bone screws and the body is initially through the bioresorbable material, which engagement rigidly fixes the relative angular orientation between the bone screws and the body when the device is applied to a bone. As the bioresrobable material is resorbed the angular relation between the bone screws and the body is no longer rigidly fixed, thereby effecting a transformation from rigid osteosynthesis to flexible osteosynthesis to allow micromotion between the bone fragments which promotes healing.

The modified method of Biplane Double-supported Screw Fixation (Modified BDSF) (Calcar buttressed screw fixation) of femoral neck fractures is disclosed. BDSF is applied using three standard bone screws laid in two vertical oblique planes in the femoral neck: the inferior (distal) screw is placed at an obtuse angle in the posterior oblique plane, and touched on the inferior (distal) and on the posterior cortices of the femoral neck; the middle screw and the proximal screw are laid in the anterior oblique plane and in parallel to each-other, with the middle screw touched on the distal femoral neck cortex. With BDSF of the three screws, two are weight-bearing and act as console beams: the distal screw and the middle screw, each of them having two supporting points in the distal fragment: medial (on the distal femoral neck cortex), and lateral (in the place of screw entry into the lateral femoral cortex).

The modified method of Biplane Double-supported Screw Fixation (Modified BDSF) (Calcar buttressed screw fixation) of femoral neck fractures is disclosed. BDSF is applied using three standard bone screws laid in two vertical oblique planes in the femoral neck: the inferior (distal) screw is placed at an obtuse angle in the posterior oblique plane, and touched on the inferior (distal) and on the posterior cortices of the femoral neck; the middle screw and the proximal screw are laid in the anterior oblique plane and in parallel to each-other, with the middle screw touched on the distal femoral neck cortex. With BDSF of the three screws, two are weight-bearing and act as console beams: the distal screw and the middle screw, each of them having two supporting points in the distal fragment: medial (on the distal femoral neck cortex), and lateral (in the place of screw entry into the lateral femoral cortex).

A percutaneous method for removing an outer portion of the proximal end of a lag screw protruding from a fractured femur when embedded in the femur to stabilize an intramedullary nail implanted in the intramedullary canal using a multi-part cannulated driver wherein the lag screw comprises a distal section, an intermediate section including a channel formed in the proximal portion thereof with a driver recess formed at the distal end thereof, and a proximal section having a notch, groove or score mark formed on the exterior surface of the lag screw separating or between the intermediate section and the proximal section and the multi-part cannulated driver comprises a cannulated shaft including a first driver member formed thereon configured to engage the driver recess to prevent the distal section and intermediate section of the lag screw from rotating in the femoral head when torque is applied to the proximal section by a second driver member engaging the proximal section of the lag screw to separate the proximal section from the section and the intermediate section along the notch, groove or score mark.

The present disclosure provides an orthopedic implant that can include an intramedullary stem transition region that fits in the bony intramedullary canal. The transition region can run as a monolithic piece between the implant body and the intramedullary stem, with a squared cross-section away from the implant body and a circular cross-section close to the stem body. The transition region can allow for higher implant strength with reduced rotation for the implant.

A femoral fixation device may include a shaft and a helical thread disposed about the shaft between a first location and a second location along the shaft. The helical thread may include a concave undercut surface. The femoral fixation device may be configured such that, when the femoral fixation device is implanted within a neck and a head of a femoral bone: the first location, the second location, and the helical thread therebetween may be disposed within the head of the femoral bone; the concave undercut surface may be oriented toward a proximal end of the femoral fixation device; and the concave undercut surface may be configured to transmit at least one force from the head of the femoral bone to the neck of the femoral bone.

Intramedullary nails, systems, and methods. The intramedullary nail may include a generally elongate body extending from a first, distal end to a second, proximal end. The distal end may include one or more openings configured to receive one or more bone anchors that extend transversely through the distal end intramedullary nail, and thereby configured to secure the distal end of the nail. The proximal end may also include one or more openings configured to receive one or more bone anchors that extend transversely through the proximal end of the intramedullary nail, and thereby configured to secure the proximal end of the nail. In some embodiments, the proximal end may further include a cross-locking feature, which includes a second bone anchor that interlocks with a first bone anchor, for example, for enhanced bone purchase and bony fixation.

A bone plate comprises a body including an elongated opening extending therethrough, the opening being open at a distal end of the body and including a distal portion and a proximal portion, the distal portion having a width smaller than a width of the proximal portion, the width being a dimension between two longitudinal sides of the opening extending parallel to a longitudinal axis of the body, the body further including an insert including a head portion and a base portion, the base portion being shaped to be slidably mounted within the proximal portion of the opening, a diameter of the base portion being larger than a width of the distal portion of the opening such that the base portion is prevented from exiting the opening through the distal portion thereof, the insert further including a central fixation element receiving hole configured to receive a bone fixation element therethrough.

A decompression device and method for removing marrow and other fluid from an intramedullary canal. The decompression device includes a cannula having a channel that allows fatty marrow to pass therethrough. A first port extends from the device and is in operable connection to a vacuum source that creates suction for removing fluid from the intramedullary canal. In some embodiments, one or more fenestrations are disposed along the second end of the cannula to expedite the removal of the fluid. In operation, the cannula is inserted into the intramedullary canal of a femur. Once fatty marrow is removed from the intramedullary canal, the cannula is removed and a reaming device is inserted into the femur. In this way, the fatty marrow is removed prior to the reaming procedure in order to prevent these fluids from traveling to the lungs causing blockage that leads to severe cardiorespiratory and vascular dysfunction.