Patent Description:
Document <CIT> relates to a short pin for taking care of epiphysis fractures.

Document <CIT> relates to a plate and cannulated transfixation screw system for a human implant.

Document <CIT> relates to a triceps-sparing olecranon fracture repair device and system.

Document <CIT> relates to bone pin-plate surgical device and method for promoting arthrodesis of the equine fetlock joint.

Document <CIT> relates to an osteosynthesis device.

Document <CIT> relates to an orthopedic spacer.

Document <CIT> relates to a nail plate and jig thereof.

Document <CIT> relates to a foot surgery bone plate for osteosynthesis and/ or fixation of foot-bone segments, with a plate-shaped bearing portion which has at least one through-opening extending from a top face of the bone plate to a bottom face of the bone plate and provided for a bone screw, which bearing portion is designed for external fixation on a first bone segment. An intramedullary portion is provided which has at least one through-opening extending from the top face of the bone plate to the bottom face of the bone plate and provided for a bone screw, which intramedullary portion is designed for introduction into a second bone segment.

There are several conditions, such as hallux valgus, or more commonly "bunions", which result from congenital deformation or which arise as a result of repeated use type injuries. Surgical intervention that includes surgical sectioning of bone or an "osteotomy" is often used to restructure the bones as a treatment for such conditions. For example, the chevron translational osteotomy, of the first metatarsal with which the present invention might be used, is typically used to treat a condition that is the result of adult acquired metatarsal deformity. The present invention is likewise useful for other conditions of the foot or hand that result from prior trauma, surgical intervention or defects from birth or that develop with age (such as rheumatoid arthritis).

Examples of some of the procedures with which the present invention could be used include hallus valgus and hallus rigidus corrections, and bunionectomies. Other applications which could use the present invention include first and fifth metatarsal chevrons, translational osteotomies, closing wedge osteotomies, pediatric femoral osteotomies, metacarpal and calcaneal rotational osteotomies, intraarticular osteotomies and hand and wrist realignment osteotomies.

In accordance with the present invention an implant system is provided which comprises the features of claim <NUM>. Further embodiments of the invention are set out in the dependent claims. In accordance with the present disclosure, an orthopedic intramedullary implant (as well as a surgical method which uses the implant) is provided which can be used to good advantage in an osteotomy. In a first embodiment, the implant has a body having an exterior continuous curved surface formed around a long axis and configured to lodge within the intramedullary channel of the associated bone so as to avoid rotation within the channel. The body preferably has a basic shape (meaning an outline exclusive of the optional flange, striation or groove meant to further stabilize the body in the intramedullary channel) which preferably forms a closed rounded cross-section including a circle or oval which can be the same dimension along the axis or not, to form a three dimensional figure such as a cylindrical, ellipsoid, torpedo, or egg shape. The body portion also has a first end that is tapered or sharpened for insertion, and a longitudinally opposing second end that either cooperates with or extends into a plate portion so as to form an integral substantially exclusive (meaning that the implant has only the body and the plate, and no other arms, or plate members) two member implant that further includes means for fastening to the cortical section of a bone. This first end (of the body member) includes a rounded or tapered chamfered edge such as a counterbore that promotes insertion into the bone. Between the first end and the second end, the implant includes at least one through hole so that the implant can be fixed through an extramedullary portion of a co-axial bone segment. Likewise, the plate portion includes one or more, and preferably two, offset through holes that receive cortical bone screws which are optionally locking bone screws (i. including threads on the head which cooperate with internal threads on the through holes of the plate portion).

The invention can be used in a variety of indications including for example, calcaneal osteotomies Dwyer osteotomy, cotton osteotomy, isolated TMT fusion, Navicular fracture, Evans osteotomy and metacarpal rotational osteotomies, or intraarticular osteotomies or hand and wrist realignment osteotomies. Other applications which could use the present invention include first and fifth metatarsal chevrons, translational osteotomies, and closing wedge osteotomies.

The invention is defined in appended claim <NUM>.

<FIG> shows a skeletal version of a foot from the top side illustrating a deformity with which the present implant could be used, and <FIG> shows the same version of the foot following the method of the present invention with an embodiment of the implant <NUM> of the present invention in place inserted into the intramedullary channel of the first metatarsal following an osteotomy and the translation of the distal portion of the metatarsal. Thus, <FIG> illustrates the implant used in a translational osteotomy of the first metatarsal for treatment of hallux valgus syndrome.

As viewed from the top in <FIG>, it can be seen that the first embodiment of the plate <NUM> has a body member <NUM> shaped for insertion into the intramedullary portion of the bone following the osteotomy with a first end <NUM> that extends into a plate portion <NUM> and an opposing cutting end <NUM> aligned along the longitudinal axis of the plate which further includes a cannulation <NUM> which extends through the body member to allow for the insertion or use of a k-wire. The body of the implant further includes a through hole <NUM> closer to the second end than the first which again is optionally threaded, for a screw <NUM> which is optionally a locking screw. The screw is intended to inhibit rotation of the implant in the channel. The body portion is sized and shaped for insertion into the intramedullary channel of a bone, for example, it may be cylindrical or ellipsoid, or have an elongate shape that is relatively round in cross-section but which is less regular than a cylinder or ellipse. The outer surface may be smooth, or may include one or more raised portions15 (illustrated in <FIG>), such as grooves, flutes or flanges which extend parallel to the cannulation part of all of the way down the length of the body member or which spiral around the body member) in order to inhibit the implant from rotating within the inner portion of the bone.

The plate portion <NUM> has a profile when viewed straight on in the widest dimension which is sized to accommodate the specific application, in this case so that it will best conform to the remaining head of the metatarsal, and further includes at least a first through hole <NUM> (optionally threaded) for a screw <NUM> (optionally locking) and preferably a second through hole <NUM> (also optionally threaded) for a second screw <NUM> (again optionally locking). Specifically, in the illustrated application for a bunionectomy, the plate portion has an outline viewed from the outer surface of a tab or partial egg shape, and the bone facing surface is curved so as to form a section of a cylinder (corresponding to an idealized shape of the head of the associated metatarsal).

<FIG> illustrate various embodiments of the implant <NUM>, in which the plate portion is offset to accommodate particular anatomical variations, of <NUM>/<NUM> of the distance across the diameter at the top surface of the implant in <FIG>, of <NUM>/<NUM> of the distance across the diameter at the top surface of the implant in <FIG>, and of <NUM>/<NUM> of the distance across the diameter at the top surface of the implant in <FIG>, and in <FIG>, the plate portion is angled at from <NUM>° to <NUM>°, and preferably from <NUM>° to <NUM>° relative to the axis of the body member to inhibit a Varus tilt. Further this drawing illustrates the body and plate as an assembly, as compared to the other integrally formed plate and body members. In <FIG>, the plate portion <NUM> extends from a threaded tap member <NUM> that is received in a threaded screw hole <NUM> in the body member. In this embodiment, various plate portions with varying degrees and/ or angles of offset can be used in the body member to simplify the inventory of the system.

<FIG> illustrate steps of the surgical procedure of the present invention where in <FIG> multiple incisions are made to the head and at about <NUM> down the neck of the metatarsal. Next, a tool is placed to translate the head of the metatarsal laterally and the remaining proximal portion of the bone is reamed in an Eichhorn shape as is shown in <FIG>. Next with pushing or drilling, a k-wire is placed in the metatarsal to the base, and the bone is reamed by power or hand. The guide wire is left in place. Then the implant is pushed into position over the guide wire and into the intramedullary channel using a cross-jig which is radiographically located. The screws are inserted into the plate portion, and the implant is pushed into the proximal portion of the bone to compress. The cross screw is inserted, the jigs are disassembled and the guide wire is removed, the medial ledge is removed, including a saw is used or a burr if a mini-incision is used. Graft is added as needed and the incision is closed.

The screws useful with the plate of the present invention are self-starting, self-tapping screws including the option of partial or full cannulation. The screws include a cutting end having multiple flutes, and preferably <NUM> or <NUM> flutes about a conical recess. The screws further include a partial taper of the inner diameter in the proximal end over the first several thread turns, for example over <NUM>-<NUM>, and preferably over <NUM>-<NUM> turns in order to increase the fatigue life of the screw as well as providing potential physiological advantages in use. The screws further include a torque driving recess. The screws have a threaded distal end and a head including a torque driving recess. The head of the locking screw includes locking means, such as a variable locking mechanism, which could be a bushing that mates with the screw head so as to lock the screw relative to the plate at a desired angle, or could include external screw threads that mate with internal threads in the locking screw hole at a pre-selected angle, in this instance, the screw axis is perpendicular to the longitudinal axis of the plate. The screw used in the anti-rotation slot has a rounded rear shoulder (such as a hemisphere, or a torroid) which mates with the edges of the slot.

The implant is formed of a biocompatible material, and preferably a metal such as surgical grade stainless steel, titanium or a titanium alloy or a cobalt chromium alloy. Preferably, the plate portion has a thickness of between about <NUM> and about <NUM> millimeters, more preferably between about <NUM> and about <NUM> millimeters, and most preferably between about <NUM> and about <NUM> millimeters. The body portion of the implant has a curved cross-section having a diameter defining a total thickness of about <NUM> and <NUM> millimeters, or roughly four times the width of the plate portion of the implant.

In addition, the implant can include additional small through holes sized to receive a K-wire or other similar guide wire.

During the surgery the joints are first prepped which may include de-articulation between the bones to be fused and removal of any bone as part of the osteotomy, and as necessary, the plate is bent to contour to the bone surface. A pilot hole or preferably, an Eichhorn shaped recess may be drilled into the bone into which the implant will be inserted. The implant is inserted into the implant recess in the driver and secured by tightening the implant upward in the holder using the holder. The implant is tamped into the cancellous portion of the bone fragment optionally by tapping the implant driver with a one pound mallet as is necessary to insert the body of the implant. The implant should be driven until it is fully seated. Once the implant is sunk, a drill guide is mated to the driver, and a hole is drilled for the transverse screw. The implant can be held in position using k-wires or olive wires (thru the non-locking hole and into the bone). The plate portion is located such that all of the screws are aimed into the targeted bones and away from the joint, fracture, or bone interface. The olive wire is removed if used, and a pilot hole is drilled at the end of the plate that includes the first hole and this hole is pinned or screwed. A second pilot hole may be drilled for the transverse. The plate is viewed radiographically, and the soft tissues are closed in the usual manner.

Claim 1:
An implant (<NUM>) system configured for the fixation of a long bone following a translational osteotomy of the long bone for treatment of the hallux valgus syndrome, comprising:
at least two plate portions (<NUM>) having a different configuration, each plate portion being a separate portion configured to cooperate with a cortical surface of the long bone, and including two locking through holes for two locking fasteners and
a body member (<NUM>) having a first end (<NUM>) and a longitudinally opposing second end (<NUM>) joined by a continuous curved exterior surface formed around a long axis and configured to lodge within the intramedullary channel of the long bone so as to avoid rotation within the channel and rotation about the osteotomy site, the first end (<NUM>) being tapered or sharpened for insertion into the long bone, and the second end (<NUM>) being configured to be assembled to any one of the plate portions (<NUM>) so as to form an integral two member implant (<NUM>) in advance of the surgery, and wherein any one of the plate portions (<NUM>) is offset from the long axis of the body member (<NUM>).