External fixing system (1) for orthopaedic exoskeleton; the fixing system (1) comprises two clamps (2, 6), which have clamping seats (5, 9) and respective knurled elements (13, 14) facing each other, and a spring (12) for pushing the clamps (2, 6) one against the other so that their relative rotation is prevented by the coupling of the two knurled elements (13, 14); in this way, in use, it is possible to obtain locking of the relative position of the clamps (2, 6) while the clamps (2, 6) are tightened by means of an Allen screw (23) arranged in an opposite position with respect to the clamping seats (5, 9).

The present disclosure provides an adjustable external fixator which can be utilized in bone transport or bone lengthening. The adjustable external fixator includes a body, a positioning member, a bone coupling member, and a threaded rod. The body includes a slideway. At least one of the positioning member and the bone coupling member is slidably coupled to the slideway of the body.

Surgical tools that increase surgical accuracy for orthopedic procedures involving long bone osteotomy with or without supplementation with allograft or autograft. Two clamps on the operative side are rigidly interconnected to one another with an adjustable rod that is locked into place, preserving length and rotation of the bone. A graft preparation device is used on the operative table. It enables alignment of the graft to preserve the desired mechanical and anatomic axes and to provide rigid fixation of the graft for cutting. Adjustable jigs ensure exact cuts.

The invention concerns an anatomically personalized and mobilizing external support configured to be arranged to support a physical joint between a first and a second bone group, which support comprises at least one first external auxiliary frame, which is configured to be attached to the first bone group using invasive attachment means, at least one second external auxiliary frame, which is configured to be attached to the second bone group using invasive attachment means, and at least one external auxiliary joint, which is fitted between the first and the second auxiliary frame. The external support is configured to permit a rotation of the second external auxiliary frame relative to the first external auxiliary frame about a rotational axis, sliding of the rotational axis relative to the first external auxiliary frame in a first direction, and sliding of the rotational axis or at least a portion of the second external auxiliary frame relative to the first external auxiliary frame in a second direction, which differs from the first direction.

A method of performing a bunion surgery may involve positioning a first portion of a bone positioning device over a first cuneiform and positioning a second portion of the bone positioning device over a first metatarsal with the bone positioning device extending across a joint separating the two bones. The second portion of the bone positioning device can be adjusted relative to the first portion about a first axis and about a second axis. The method may involve moving the second portion of the bone positioning device relative to the first portion of the bone positioning device about the first axis and the second axis, thereby moving the first metatarsal relative to the first cuneiform in a first plane and a second plane. The method may also involve fixing a position of the first metatarsal relative to the first cuneiform with a bone connector.

A method of performing a bunion surgery to correct an alignment between a first metatarsal and a first cuneiform may involve aligning a bone cutting guide with a joint between the first metatarsal and the first cuneiform. The bone cutting guide can have a joint plate offset from a guide feature, with the joint plate extending downwardly relative to the guide feature. The process of aligning the bone cutting guide with the joint may involve inserting the joint plate into the joint. The method may involve using the guide feature of the bone cutting guide to guide a cutting tool to cut a leading edge of the first metatarsal and adjusting an alignment of the first metatarsal relative to the first cuneiform using a bone positioning device. The method may also involve fixing a position of the first metatarsal relative to the first cuneiform with a bone connector.

Systems for bone fracture repair are disclosed. One system includes a biocompatible putty that may be packed about a bone fracture to provide full loadbearing capabilities within days. The disclosed putties create an osteoconductive scaffold for bone regeneration and degrade over time to harmless resorbable byproducts. Fixation devices for contacting an endosteal wall of an intramedullary (IM) canal of a fractured bone are also disclosed. One such fixation device includes a woven elongated structure fabricated from resorbable polymer filaments. The woven elongated structure has resilient properties that allow the woven structure to be radially compressed and delivered to the IM canal using an insertion tube. When the insertion tube is removed, the woven structure expands towards its relaxed cross-sectional width to engage the endosteal wall. The woven elongated structure is impregnated with a resorbable polymer resin that cures in situ, or in the IM canal.

A force measuring apparatus is described. The apparatus includes a force concentrator. The force concentrator is configured to attach to a loadbearing medical device and to produce a transverse force related to an eccentric axial force applied to the loadbearing medical device. A bending stiffness of the force concentrator is different from a bending stiffness of the loadbearing medical device.

A force measuring apparatus is described. The apparatus includes a force concentrator. The force concentrator is configured to attach to a loadbearing medical device and to produce a transverse force related to an eccentric axial force applied to the loadbearing medical device. A bending stiffness of the force concentrator is different from a bending stiffness of the loadbearing medical device.

An external distraction apparatus for performing a craniofacial distraction is disclosed. The external distraction apparatus may comprise a stationary member. The stationary member may be configured to be affixed to a head of a patient. The external distraction apparatus may also comprise laterally disposed distractors. The laterally disposed distractors may extend inferiorly from the stationary member and be moveable relative to the stationary member. The external distraction apparatus may comprise a motor and controller. The motor may be powered with the controller to perform a craniofacial distraction in an automated fashion.