Patent Description:
Transverse fractures of bone are common. They typically occur in the shaft of the humerus, femur, radius, ulna, and metacarpal and metatarsal bones. They are characterized by a crack that extends across the bone, generally orthogonal to a longitudinal axis of the bone (<FIG>).

These are inherently unstable fractures, and while non-surgical management can be employed if there is no displacement of the fragments, there is not enough stability to allow for early mobilization of the limb. Therefore, these fractures are often surgically fixed, using either intramedullary nail (IMN) technique, or open reduction internal fixation (ORIF) using dynamic compression or locking plates.

IMN is a straightforward technique that is commonly employed in the humerus and especially the femur, and involves placement of an intermedullary nail through the medullary cavity of a bone. However, IMN does not allow for anatomical reduction of fracture fragments, and especially in the humerus, many surgeons prefer ORIF using plates, as the fracture has more chance of healing. In addition, plating is generally less expensive, and from a health economics perspective, for this reason, many institutions globally advocate plating.

Plating transverse fractures is difficult; trying to reduce the fragments and hold them reduced while the plate is applied is very difficult, as conventional methods such as temporary wire fixation or lag screw fixation are simply impossible. Bone reduction forceps are known and are generally scissors-like in that they comprise two arms pivotally attached to each other, one end of each arm generally includes a finger or palm engaging loop or handle, and the other end of the arms include counter-facing a bone-engaging jaws that are used to grasp the bone fragments. However, it is not possible to hold the fragments reduced with conventional bone reduction forceps as the bone-engaging jaws of the forceps prevent the application of a fixation plate to the bone when the forceps is holding the bone in a reduced position.

<CIT> describes a reduction forceps comprising pivotable first and second arms having respective jaws with contact points for contacting a bone or a bone plate. <CIT> describes an integrated reduction forceps having an upper clamp body, a lower clamp body and auxiliary assemblies in which the auxiliary assemblies and the upper clamp body are used cooperatively.

<CIT> discloses a compression clamp having a pair of engagement members adapted to engage the heads of the first and second reduction fasteners.

It is an object of the invention to overcome at least one of the above-referenced problems. It is a particular object of the invention to provide a bone reduction forceps that can hold the reduced bone in a reduced position while a bone fixation plate is fixed to the bone in an ORIF procedure.

The Applicant has addressed the problems of the prior art by providing a bone reduction and plate fixation forceps, capable of holding bone fragments in a reduced position while a bone fixation plate is fixed to the bone in an ORIF procedure. This is achieved by using a forceps in which one of the arms has a bifurcated distal end with two spaced-apart bone engaging jaws, where one and preferably both of the jaws has a distal to proximal bridge shape that can grip the bone while simultaneously providing a plate-receiving recess that allows passage of a bone fixation plate along the surface of the bone under one and generally both of the bridge shaped jaw(s). In this way, the reduced bone can be fixed in the reduced position using the forceps, and the plate can be positioned on a surface of the bone by inserting it under the bridge-shaped jaw(s) and fixed to the bone while the forceps maintains the bone in the reduced position. The forceps may be, for example, a <NUM>-point fixation or <NUM>-point fixation forceps with the first arm having at least two bone-engaging jaws and the second arm having at least one bone-engaging jaw. The bridge shaped jaw may be dimensioned to allow passage of a bone fixation plate along the bone (i.e. the opposed jaw parts may be sufficiently spaced apart to accommodate the full width of the plate) or it may be narrower than the ends of the plate and require the plate to be tilted to allow passage under the bridge shaped jaw. In this embodiment, the plate may have an inwardly tapered portion intermediate its ends which is sufficiently narrow to allow the plate fit between the jaw parts when flush against the bone but is required to be tilted away from a bone surface to facilitate the wider ends of the plate fitting between opposed jaw parts of the jaw. In another aspect, the distal part of one of the first or second arm includes a joint allowing rotational movement of the distal part about an axis of the distal part of the arm (rotational joint) during bone reduction and fixation. This allows the jaws of the arm pivot and adjust to allow engagement with bones having a different bone diameter on each side of a fracture. In another aspect, the forceps is configured to allow detachable attachment of the bifurcated part of the distal part to the forceps. This allows different bifurcated parts to be used in a modular fashion depending on the procedure and the anatomy of the bone.

provides a bone reduction and plate fixation forceps, comprising:.

characterized in that the first arm comprises a bifurcated distal part having a first fork with a first bone engaging jaw and a second fork with a second bone engaging jaw in which the first bone engaging jaw and second bone engaging jaw are configured to engage a first surface of a fractured bone on each side of the fracture, the second arm comprises a third bone engaging jaw and at least one of the first bone engaging jaws and second bone engaging jaws comprises a distal bone engaging jaw part connected to a proximal bone engaging jaw part by a raised bridging jaw part that defines a bone fixation plate receiving recess, and wherein the first bone engaging jaw and second bone engaging jaw are spaced apart by a distance of <NUM> to <NUM>.

At least one of the first bone engaging jaws and second bone engaging jaws typically has a proximal to distal bridge shape configured to allow during use passage of a bone fixation plate under the bridged shaped jaw when the jaw is engaged with the fractured bone.

Generally, both the first bone engaging jaw and second bone engaging jaw have a proximal to distal bridge shape configured to allow passage of a bone fixation plate under the bridged shaped jaws when the jaws are engaged with the fractured bone.

In any embodiment, the first fork part and second fork part diverge, typically at an angle of at least <NUM>°, <NUM>°, <NUM>° or <NUM>°. In any embodiment, the first fork part and second fork part diverge at an angle of greater than <NUM>°, for example <NUM>° to <NUM>° or <NUM>° to <NUM>°.

In one embodiment, the first bone engaging jaw and second bone engaging jaw are laterally spaced apart by a first distance D1.

In any embodiment, the third bone engaging jaw and fourth bone engaging jaw are laterally spaced apart by a second distance D2.

In any embodimentD1 is at least <NUM>% greater than D2. Thus, the bone-engaging jaws of the first and second arms are generally not counter-facing, with the jaws of the first arm typically more spaced apart than the jaws of the second arm.

In one embodiment, D1 is about <NUM>-<NUM>, or about <NUM>-<NUM>.

In one embodiment, D2 is about <NUM>-<NUM>, or about <NUM>-<NUM>.

In one embodiment, the distal part of the first or second arm includes a joint allowing rotational movement of a distal end of the distal part about an axis of the distal part of the arm (e.g. a rotational joint). This allows the jaws of the arm pivot and adjust to allow engagement with bones having different diameter on each side of a fracture, in a "see-saw" manner. It is illustrated in <FIG>. The joint is generally positioned at or proximal to where the distal arm bifurcates. Typically, the rotational joint is configured to allow limited rotational movement of a distal end of the distal part about an axis of the distal part of the arm, for example rotation about less than <NUM>° or <NUM>°, and generally rotation about <NUM>°-<NUM>°, <NUM>°-<NUM>° or <NUM>°-<NUM>°.

When the distal part of both the first and second arms are bifurcated (e.g. when both arms are distally bifurcated), one of the distal parts will include a rotational joint, typically the distal part of the second arm, whereas the other distal part is generally rotationally fixed (e.g. will not include a rotational joint). Thus, the jaw or jaws on the other distal part act as an anchor.

When the distal part of the first arm is bifurcated and the distal part of the second arm is not bifurcated, the distal part of the first arm will include the rotational joint. Typically, the rotational joint is disposed on the distal part of the arm between the first joint (where the first and second arms pivotally connect) and a bifurcation point of the arm. Typically, the rotational joint is disposed on the distal part of the arm just proximally of the point of bifurcation.

In one embodiment, the first or second arm is configured to allow detachable engagement of the bifurcated part of the distal part from the forceps. Typically the first or second arm may be configured to allow detachable engagement of the bifurcated part of the distal part from the forceps at the rotational joint. This allows different bifurcated parts to be used in a modular fashion depending on the procedure and the anatomy of the bone. Thus, in one embodiment, the invention provides a kit comprising (a) a bone reduction and plate fixation forceps according to the invention and (b) one or more modular bifurcated distal parts configured for detachable engagement to one of the distal arms at a rotational joint.

In one embodiment, the bifurcated distal part of the second arm is detachably attachable to the second arm. The invention provides a modular kit comprising a forceps according to the invention and a plurality of modular bifurcated distal parts detachably attachable to the second arm to form the forceps of the invention. This allows a user choose a specific bifurcated distal part depending on the bone to be treated and the type of break or fracture to the bone. For example, the plurality of bifurcated distal parts may differ from each other in any one of a number of aspects, for example the distance between the bone-engaging jaw parts, the length of the forms, the distance between the jaws, the configuration of the jaws (e.g. bridging jaws, non-bridging jaws), or rotational or non-rotational bifurcated distal part.

In one embodiment, the first and/or second bone engaging jaws have an arcuate profile. This allows the jaws to curve around the first surface of the bone and engage the bone at spaced-apart points across the first surface.

In one embodiment, the at least one bridged shaped bone engaging jaw comprises a distal bone engaging jaw part connected to a proximal bone engaging jaw part by a raised bridging jaw part that defines a plate receiving recess (e.g. in use is spaced apart from the first surface of the bone providing a bone fixation plate receiving recess).

In one embodiment, the distal and proximal bone engaging jaw parts are configured such that in use they are circumferentially spaced apart around the first surface of the bone by about <NUM>-<NUM>° (or about <NUM> to <NUM> or <NUM>-<NUM>).

In one embodiment, the distal bone engaging jaw part and proximal bone engaging jaw part are laterally spaced apart by a distance D1, wherein the raised bridging part is configured such that a distance D2 between one of the jaw parts and a top of the bridging part is greater than D1. This configuration allows a plate have ends with a width greater than D1 to be used with the forceps, where the plate can be passed under the bridge by tilting the plate upwardly and passing the wide end of the plate under the jaws in the tilted orientation when the jaws are clamped to the bone, and then placing the plate flush against the bone where it fits between the jaw parts due to the tapered central part of the plate. This is illustrated in <FIG>. In one embodiment, it is provided a forceps and a plate having an inwardly tapered section.

In one embodiment, the plate receiving recess of the first and/or second jaws has a height of <NUM> to <NUM>, <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM> or <NUM> to <NUM>.

In one embodiment, the bone engaging jaws comprise a plurality of teeth (for example, serrations or projections).

In one embodiment, the forceps includes a ratcheting mechanism (for example a ratcheting rack) attached to one of the first and second arms. In one embodiment, the forceps include counter-facing ratcheting racks to lock the two arms, relative to each other, and, thereby, maintain a force between the jaws of each arm to hold the bone fragments together after the forceps have been released from a surgeon's hand. Elastic deformation of the arms generally provides the force. In another embodiment, the forceps includes a leadscrew to maintain a set amount of force.

In another embodiment, it is provided a bone reduction and plate fixation forceps, comprising:.

In another embodiment, it is provided a bone reduction and plate fixation kit comprising:.

In any embodiment, the bone fixation plate is a dynamic compression plate.

In any embodiment, the bone fixation plate is a transverse fracture bone fixation plate.

In any embodiment the bone fixation plate has a first end, second end, and an inwardly tapered central part intermediate the ends. In any embodiment, at least one end (and generally both ends) of the plate is wider than a spacing defined between the jaw parts of the first and/or second bone engaging jaws. This provides the plate with ends that are wider than the central part (i.e. it is waisted), allowing the central part abut the bone to be treated under the proximal to distal bridge shape jaws while having a wider profile at one or both ends for improved fixation to the bone. Often the ends of the plate are too wide to be passed along the bone under the proximal to distal bridge shape jaws, and in these circumstances the plate can be angled obliquely (e.g. tilted away from the bone surface) so that the end of the plate can be passed under the bridge-shaped jaws, and then returned to the bone abutting position when the narrower part of the plate is disposed under the bridge shaped jaws. This is illustrated in <FIG>.

In another embodiment, it is provided a bone fixation plate, particularly a dynamic compression fixation plate, having an inwardly tapered central section. In one embodiment, the inwardly tapered central section has a width at its narrowest point that is at least <NUM>%, <NUM>%, <NUM>%, <NUM>% or <NUM>% narrower than a width of the plate at it ends. In one embodiment, the inwardly tapered central section has a width at its narrowest point that is <NUM>-<NUM>%, <NUM>-<NUM>%, <NUM>-<NUM>%, <NUM>-<NUM>%, <NUM>-<NUM>% or about <NUM>% narrower than a width of the plate at it ends. In one embodiment, the plate has width at one or both ends of <NUM>-<NUM> (for example <NUM>-<NUM> or <NUM>-<NUM>) and a width at its narrowest point inwardly tapered central section of <NUM>-<NUM> (for example <NUM>-<NUM> or <NUM>-<NUM>). In one embodiment, the plate has holes for receipt of bone fixing screws, typically counter-sunk holes.

As an example, it is described, but not claimed a method of fixing a bone fixation plate to a first surface of a bone having a fracture, comprising the steps of:.

In any embodiment, the bone fracture is a transverse or spiral oblique fracture.

In any embodiment, the bone fracture is a fracture of the diaphysis.

In any embodiment, the fractured bone is a long bone selected from a radius, ulna, humerus, femur, tibia, fibula, metacarpal or metatarsal.

In one example, the method includes the steps of:.

As an example, it is described, but not claimed a method of fixing a bone fixation plate to a first surface of a bone having a transverse fracture that employs a bone reduction and plate fixation kit according to the invention, comprising the steps of:.

Other and preferred embodiments of the invention are defined and described in the other claims set out below.

As used herein, the term "comprise," or variations thereof such as "comprises" or "comprising," are to be read to indicate the inclusion of any recited integer (e.g. a feature, element, characteristic, property, method/process step or limitation) or group of integers (e.g. features, element, characteristics, properties, method/process steps or limitations) but not the exclusion of any other integer or group of integers. Thus, as used herein the term "comprising" is inclusive or openended and does not exclude additional, unrecited integers or method/process steps.

As used herein, the term "proximal to distal" as applied to the bridge-shaped bone engaging jaw means that the jaw is configured to extend across the bone generally orthogonal to a longitudinal axis of the bone.

The term "bridge-shaped" as applied to a bone-engaging jaw means that the jaw has distal and proximal bone engaging jaw parts connected by a bridging jaw part that is configured to be spaced from the bone surface when the jaw is engaged with the bone providing a fixation plate receiving recess. Generally, the bridge-shaped jaw is configured such that the distal and proximal jaw parts are spaced apart by at least <NUM>-<NUM>, and the bridging jaw part has a height of at least <NUM>-<NUM> above the bone surface, to allow passing a fixing plate under the bridge shaped jaw when it is engaged with a bone.

The term "bifurcated" as applied to the distal part of the first or second arms means that the arm forks into two forks at a forking point. Generally, the forks diverge in a symmetrical manner. Typically, the forks are mirror images of each other. Although the embodiment described herein, show both first and second arms having a bifurcated distal part, it will be appreciated that the distal part of the second arm does not have to bifurcate, and may comprise a single arm with a done engaging jaw configured to span the fracture.

The term " bone fixation plate" refers to a plate used in orthopaedic surgery to attach to a fractured bone to provide structural support to the bone, keep the bone in an anatomically reduced position, and aid in the healing process. One example of a bone fixation plate is a dynamic compression plate. Generally, bone fixation plates include a number of holes that allow the plate to the fixed to the bone with screws. Often the holes are countersunk holes. The plate may be contoured to the shape of a specific bone. Generally, the plate is monoplanar. Examples of bone fixation plates include dynamic compression plates, locking plates, and combined locking compression-dynamic compression plates.

The term "handle" refers to formations on the proximal end of each arm, for example finger or palm engaging loop or handle that facilitate a surgeon holding and using the forceps.

The term "limited rotation" as applied to the rotational joint should be understood to mean that the rotational joint is not free to rotate fully about its axis of rotation but that rotation is limited to rotation about less than <NUM>° or <NUM>°, and generally rotation about <NUM>°-<NUM>°, <NUM>°-<NUM>° or <NUM>°-<NUM>° about its axis of rotation.

In the context of treatment and effective amounts as defined above, the term subject (which is to be read to include "individual", "animal", "patient" or "mammal" where context permits) defines any subject, particularly a mammalian subject, for whom treatment is indicated. Mammalian subjects include, but are not limited to, humans, domestic animals, farm animals, zoo animals, sport animals, pet animals such as dogs, cats, guinea pigs, rabbits, rats, mice, horses, camels, bison, cattle, cows; primates such as apes, monkeys, orangutans, and chimpanzees; canids such as dogs and wolves; felids such as cats, lions, and tigers; equids such as horses, donkeys, and zebras; food animals such as cows, pigs, and sheep; ungulates such as deer and giraffes; and rodents such as mice, rats, hamsters and guinea pigs. In preferred embodiments, the subject is a human. As used herein, the term "equine" refers to mammals of the family Equidae, which includes horses, donkeys, asses, kiang and zebra.

The invention will now be described with reference to specific Examples. These are merely exemplary and for illustrative purposes only: they are not intended to be limiting in any way to the scope of the monopoly claimed or to the invention described. These examples constitute the best mode currently contemplated for practicing the invention.

Referring to the drawings, and initially to <FIG> and <FIG>, a bone reduction and plate fixation forceps is described, indicated generally by the reference numeral <NUM>. The forceps comprises a first arm <NUM>, second arm <NUM>, and a pivot joint <NUM> providing pivoting scissors-like articulation of the arms.

The first arm <NUM> has a proximal section <NUM> with a handle 6A and a bifurcated distal end <NUM> with diverging forks 8A, 8B each terminated in a bone engaging jaw 9A, 9B. In use, the jaws 9A, 9B are used to grasp a first surface <NUM> of a fractured bone on each side of a fracture (as illustrated in <FIG>). In the embodiment shown, the jaws 9A, 9B are laterally spaced apart by about <NUM>, although it will be appreciated that the spacing may be varied according to the bone being treated and the type of fracture.

The second arm <NUM> has a proximal section <NUM> with a handle 6B and a bifurcated distal end <NUM> with diverging forks 12A, 12B each terminated in a bone engaging jaw 13A, 13B. In use, the jaws 13A, 13B are used to grasp a second surface <NUM> of a fractured bone on each side of a fracture <NUM> (as illustrated in <FIG>). In the embodiment shown, the jaws 13A, 13B are laterally spaced apart by about <NUM>, although it will be appreciated that the spacing may be varied according to the bone being treated and the type of fracture.

The pivot joint <NUM> is a conventional pivot joint used in orthopaedic forceps and will not be described in more detail.

The forceps <NUM> also includes a ratcheting mechanism comprising counter-facing ratcheting racks 15A, 15B to lock the two arms, relative to each other, and, thereby, maintain a force between the jaws of each arm to hold the bone fragments together after the forceps have been released from a surgeon's hand. Elastic deformation of the arms generally provides the force.

Referring to <FIG>, the bone engaging jaws 9A, 9B of the first arm <NUM> are described in more detail. As illustrated best in the sectional view of <FIG>, the jaws have a distal to proximal (right to left in <FIG>) bridge shape configured to grip the bone at spaced apart points across the first surface providing a recess <NUM> to receive a bone fixation plate when the jaws are engaged with the bone. The bridge shaped jaw comprises a distal jaw part 17A, a proximal jaw part 17B and an arcuate bridging jaw part 17C that define (along with the first surface of the bone during use) the plate-receiving recess <NUM>. In the embodiment shown, the bridge-shaped jaw is configured such that during use the distal and proximal jaw parts are circumferentially spaced around the top surface at an angle Ø of about <NUM>° as shown in <FIG>. In the embodiment shown, the recess has a height of about <NUM>.

A dynamic compression bone fixation plate <NUM> is shown in <FIG>, which has been placed in position after the bone fragments have been reduced and fixed in a reduced position with the forceps <NUM>, and then screwed to the bone across the fracture with screws <NUM>. Although not illustrated, the recesses <NUM> may be dimensioned to allow passage of the fixing plate <NUM> under the bridging jaws in a tight but sliding manner, which will facilitate the bridge-shaped jaws maintain the plate in position while it is being screwed to the bone across the fracture. The plate <NUM> may also be contoured to fit in the recess and conform to the contours of the top surface of the bone.

The bone engaging surfaces of the jaws comprises a series of serrated teeth <NUM> to facilitate the forceps grasping the bone.

In use, the forceps of the invention may be used to hold a fractured bone in a reduced position while fixing a bone fixation plate to a first surface of the bone across the fracture. The process includes the steps of the surgeon (at least partly) reducing the bone fragments to an anatomically correct position, and holding the bone fragments in the at least partly reduced configuration using the bone reduction and plate fixation forceps as described above. As illustrated in <FIG>, this leaves the first surface <NUM> of the bone on each side of the fracture exposed. The bone fixation plate <NUM> (a dynamic compression plate) is then passed along the first surface of the bone under the jaws 9A, 9B until the plate is positioned over a section of the first surface of the bone on each side of the fracture, as illustrated in <FIG>. The surgeon can then fix the bone fixation plate to the bone while the bone reduction and plate fixation forceps holds the bone fragments in the reduced configuration. Fixing comprises drilling holes in the bone through holes in the plate, and then fixing the plate to the bone with screws <NUM>. The holes in the plate may be countersunk holes. Once the plate has been screwed to the bone, the surgeon then releases and removes the forceps.

As an example, a method which do not form part of the claimed invention may involve partly reducing the bone fragments; holding the bone fragments in the partly reduced configuration using a bone reduction and plate fixation forceps <NUM>, further reducing the bone fragments while the bone fragments are held in place with the bone reduction and plate fixation forceps, and then adjusting the bone reduction and plate fixation forceps to fix the bone fragments in a fully reduced position.

Referring to <FIG>, an alternative embodiment of the forceps is illustrated, indicated generally by the reference numeral <NUM>, in which parts described with reference to the previous embodiment are assigned the same reference numerals. In this embodiment, the bifurcated distal end <NUM> of the first arm <NUM> has a proximal shaft <NUM> and a bifurcated part including the forks 8A, 8B connected by a joint <NUM>. The joint is a rotational joint, that allows the bifurcated part (e.g. forks 8A, 8B and jaws 9A, 9B pivot about a longitudinal axis of the shaft <NUM> allowing positional adjustment of the jaws to account for bones having a different diameter on opposite sides of a fracture site. <FIG> illustrates the positional adjustment of the jaws relative to a bone. The rotational joint may be any type of joint that allows this "see-saw" pivotal movement of the jaws relative to the forceps.

Referring to <FIG>, the joint <NUM> may be configured to allow detachable engagement of the bifurcated part and may include a male part <NUM> on the bifurcated part configured for detachable engagement with a female part <NUM> on the shaft <NUM> (or vica-versa). In use, the rotational joint allows positional adjustment of the jaws when the jaws are applied to a bone to account for bones having a different diameter on opposite sides of a fracture site. In this embodiment, the jaw (or jaws) of the second arm are not rotationally adjustable and act as an anchor for the forceps on the bone.

<FIG> are further illustrations of the detachable bifurcated part having a rotational hinge joint comprising a male part <NUM> on the bifurcated part configured for detachable engagement with a female part <NUM> on the shaft <NUM>.

<FIG> illustrates a bone fixation plate indicated generally by the reference numeral <NUM>. The plate is an elongated plate with a superior surface <NUM> and an anterior surface (not shown) with ends <NUM> and an inwardly-tapering central section <NUM> disposed between the ends. The ends of the plate have a width of about <NUM> and the inwardly tapered section has a width at its narrowest section of about <NUM>. The inwardly tapered section extends along about one half of the length of the plate and has a maximum width of <NUM> along at least one third of the length of the plate.

<FIG> illustrates a jaw of a forceps according to an alternative , indicated generally by the reference numeral <NUM>. Forceps including this type of jaw are configured for use with the tapered plate of <FIG>. The jaw <NUM> has a distal jaw part <NUM> and proximal jaw part <NUM> separated by a distance of <NUM> as illustrated. The bridging part <NUM> of the jaw is higher than jaws described previously and has a dimension between the jaw part <NUM> and a side <NUM> of the bridging part <NUM> of <NUM>. In this way, the plate <NUM> cannot be passed under the jaw while it is flush to the plate, and has to be tilted upwardly to fit. Once the leading end <NUM> of the plate <NUM> has passed under both jaws and the jaws are aligned with the inwardly tapered central section <NUM> of the plate <NUM>, the plate can be lowered to abut the plate where the inwardly tapered section fits between the jaw parts <NUM> and <NUM>. This embodiment allows the ends of the plate to be wider than otherwise allowed by the jaw configuration, allowing more secure fitting of the ends of the plate to the bone.

<FIG> show a conventional plate <NUM> and a tapered plate <NUM>.

The forceps of the invention may be employed to hold bone fragments in a reduced position while a bone fixation plate is fixed to the bone. It is particularly applicable for use with transverse fractures of long bones, for example the humerus, femur, radius, ulna, metacarpals and metatarsals. It is also particularly applicable for fractures in the diaphysis of long bones.

The embodiments illustrated show a <NUM>-point forceps (each arm is bifurcated and bears two bone-engaging jaws). However, it will be appreciated that the second arm does not have to be bifurcated and may bear a single elongated bone-engaging jaw configured to engage a bone across the fracture (i.e. a <NUM>-point forceps). Moreover, it will be appreciated that the first arm may includes one, two or more bridge-shaped jaws. At least two bridge-shaped jaws is preferable.

<FIG> illustrate an embodiment of the invention of a bone reduction and plate fixation forceps is described, indicated generally by the reference numeral <NUM>, in which parts described with reference to the previous embodiments are assigned the same reference numerals. The forceps comprises a first arm <NUM>, second arm <NUM>, and a pivot joint <NUM> providing pivoting scissors-like articulation of the arms. The pivot joint <NUM> is a conventional pivot joint used in orthopaedic forceps and will not be described in more detail.

The first arm <NUM> has a proximal section <NUM> with a handle 6A and a bifurcated distal end <NUM> with diverging fork parts 8A, 8B each terminated in an n-shaped bone engaging jaw 9A, 9B. As shown in <FIG>, the fork parts 8A, 8B diverge at a right angle to an axis of the proximal section of the first arm. In use, the jaws 9A, 9B are used to grasp a first surface <NUM> of a fractured bone on each side of a fracture (as illustrated in <FIG>). In the embodiment shown, the jaws 9A, 9B are laterally spaced apart by about <NUM>, although it will be appreciated that the spacing may be varied according to the bone being treated and the type of fracture.

The second arm <NUM> has a proximal section <NUM> with a handle 6B and a bifurcated distal end <NUM> with diverging forks parts 12A, 12B each terminated in a bone engaging jaw 13A, 13B. As shown in <FIG> and <FIG>, the fork parts 12A, 12B diverge at a right angle to an axis of the proximal section of the second arm. The distal end <NUM> comprises a rotational joint <NUM> allowing the bifurcated distal end <NUM> a degree of rotation about an axis of the second arm <NUM>. In use, the jaws 13A, 13B are used to grasp a second surface <NUM> of a fractured bone on each side of a fracture <NUM> (as illustrated in <FIG>). In the embodiment shown, the jaws 13A, 13B are laterally spaced apart by about <NUM>, although it will be appreciated that the spacing may be varied according to the bone being treated and the type of fracture.

Claim 1:
A bone reduction and plate fixation forceps (<NUM>), comprising:
a first arm (<NUM>) having a proximal part (<NUM>) comprising a handle (6A) and a distal part having a first bone engaging jaw (9A) configured to engage a first surface (<NUM>) of a fractured bone; and
a second arm (<NUM>) having a proximal part (<NUM>) comprising a handle (6B) and a distal part (<NUM>) comprising a bone engaging jaw (13A) configured to engage a second surface (<NUM>) of the fractured bone to clamp the bone between the first and second arm;
wherein the second arm is pivotally attached to the first arm by a first joint (<NUM>) disposed between the respective handles and the respective bone-engaging jaws of the first and second arms,
characterized in that the first arm (<NUM>) comprises a bifurcated distal part having a first fork (8A) with a first bone engaging jaw (9A) and a second fork (8B) with a second bone engaging jaw (9B) in which the first bone engaging jaw and second bone engaging jaw are configured to engage a first surface (<NUM>) of a fractured bone on each side of the fracture (<NUM>), the second arm comprises (<NUM>) a third bone engaging jaw (13A) and at least one of the first bone engaging jaws (9A) and second bone engaging jaws (9B) comprises a distal bone engaging jaw part (17A) connected to a proximal bone engaging jaw part (17B) by a raised bridging jaw part (17C) that defines a bone fixation plate receiving recess (<NUM>), and wherein the first bone engaging jaw (9A) and second bone engaging jaw (9B) are spaced apart by a distance of <NUM> to <NUM>.