Patent Description:
The clavicle or collarbone is a long bone that serves as a strut between the shoulder blade and the sternum. Humans have two clavicles, left and right. It is the most commonly fractured bone in the body, accounting for <NUM>% of all bone fractures. Approximately <NUM>,<NUM> clavicle fractures are reported daily on a global basis. The clavicle can be fractured due to direct impact on the bone, or due to impact to the shoulder from the force of falling on outstretched arm. When viewed from the front (anterior view), the bone has a generally straight appearance, and when viewed from above (superior view) it has a two-curve configuration from the sternal end to the acromial end, a so-called "lazy S" shape. About <NUM>% of clavicle fractures occur at the sternal end (medial fractures), <NUM>-<NUM>% occur at the acromial end (lateral fractures), and the vast majority of fractures occur in the midshaft (<NUM>-<NUM>%). Treatment of clavicle fractures include conservative treatments (treatment without surgery). This is a successful treatment for undisplaced <NUM>-part clavicle fractures. However, if the fracture is significantly displaced or comminuted (in more than <NUM> pieces), conservative treatment results in a higher incidence of non-union or malunion of the fracture, which can cause significant persistent weakness and disability even if the fracture heals. It is generally accepted that surgical treatment of fractures is indicated for comminuted fractures, widely displaced and shortened fractures, segmental fractures and "Z-type" fractures. The most common surgical treatment for serious clavicle fractures involves use of superior plate fixation or anteroinferior plate fixation. These are monoplanar plates having a series of holes for receipt of bone fixation screws. In order to have the required strength to resist torsional and bending stiffness, these plates have to have a thickness of at least <NUM> along their length, which is quite large for an implant in this area of the skeleton, and uncomfortable for the patient. In addition, it is possible to use a percutaneous intramedullary screw, which has gained some popularity in recent years.

In the case of comminuted fractures, segmental fractures and Z-type fractures, it is extremely difficult to reduce the bone fragments and fix them in place with a plate, and the fragments need to be reduced point-to-point while the fixation wires or screws are fixed in place. The deforming forces of the muscles often prevent the reduction holding in place, and it can be extremely difficult to fix the plate to the bone before the fracture displaces. Superior plate fixation is most commonly utilized because it makes the bone fragment reduction a little easier, but the plates tend to be weak in bending stiffness, and do not allow early mobilization of the shoulder, as there is a significant risk of the plate bending and the fixation failing. In addition, the plate is quite superficial and usually palpable through the skin. It is not uncommon for the patient to request removal of the plate once the fracture has healed.

Anteroinferior plate fixation provides better bending stiffness, as it increases the area moment of inertia, but it is extremely technically difficult to accurately reduce clavicle bone fractures unsing anterior plates. In addition, it is impossible to reduce the comminuted fragments once the plate has been applied. Anteroinferior plates also contribute to devascularisation of the bone at the fracture site. Intramedullary screw or pin fixation is also technically challenging, and it is particularly difficult to reduce the fracture. It is unsatisfactory in fixing comminuted fragments, as it does not provide adequate stability at the fracture site. Indeed, due to the difficulty of both superior and anteroinferior plate fixation, as well as intramedullary screw fixation, many orthopaedic surgeons elect a conservative, non-surgical treatment, which commonly lead to non-union or malunion. This has a detrimental effect on long-term shoulder girdle function.

Bone fixation and reduction plates are described in <CIT>, <CIT>, <CIT>, <CIT>, and <CIT>. <CIT> describes a clavicle repair plate having a Y-shaped or X-shaped profile with an elongate central trunk having a complex contour and terminal arms with screw holes for multiplanar fixation for fixing the repair plate in place.

It is the object of the invention to overcome at least one of the above-referenced problems.

The present invention addresses the need for a bone fracture reduction plate that facilitates reduction and fixing of bone fragments in a patient with a bone fracture, including a comminuted clavicular fracture, elbow (olecranon) fractures, and ankle (fibula) fractures. The device is an elongated contoured biplanar plate formed by two or more surfaces orientated at approximately <NUM>° to each other. Most or all of the device has an L-shaped profile that facilitates aligning bone fragments with the plate, allowing for easier and guided bone reduction, and allowing fixing screws to be introduced into the bone at right angles to each other.

The L shaped profile of the plate allows the plate to be thinner along most, substantially all, or all of its surface, for example about <NUM>-<NUM> (which is more comfortable for the patient), while allowing for greater bending and torsional stiffness (which allows for early and aggressive mobilisation of the shoulder), as the area moment of inertia is increased in both the coronal and axial planes. The plates typically comprise countersunk holes (although can also accommodate traditional headed screws) for receipt of fixing screws, which are generally configured so that the heads of the screws do not extend proud of the surface of the plates, and generally are flush with the plate surface. There will be the option of locking or non-locking screws.

In one embodiment (which is especially suited for reduction and fixing of clavicle fractures), the central section of the plate is uniplanar (i.e. not L shaped). This provides a "lag window" to allow comminuted fragments of bone to be fixed in place, typically via a lag screw technique, at the point of fracture. This will generally be achieved once the initial step of anatomical reduction has been achieved via the technique of reduction. It also allows for the healing bone fragments to be adequately vascularised, by avoiding devascularisation of the healing fragments due to compression on the microvasculature by the plate. This should theoretically improve the quality and rate of healing and hence return to function.

In embodiments where the central section does not have the strong L-shaped profile, the Applicant has discovered that this is an obvious point of weakness and potential failure, so the section of the surface forming the central part of the device will generally have an increased thickness, for example <NUM>, than the medial and lateral sections of the first plate for the length of the "lag window" to maintain bending and torsional stiffness. In one embodiment, to avoid stress concentrations on the plate, the increase in thickness of the first surface should be sloped and smooth, and not sharp and abrupt (in other words a gradient).

In use with a clavicle fracture, the plate should generally initially be fixed to the medial, or sternal-end fragment using either wires through <NUM> anteriorly-placed wire holes, or through screw fixation through an anterior oval shaped hole with a traditional / countersunk screw. Using a specialized custom-shaped holding clamp, the medial fragment is reduced onto the lateral, or acromial-end fragment, and the shape of the plate aids in the "capturing" of the lateral fragment. The superior surface then prevents the deforming vertical vector forces from displacing the lateral fragment while initial fixation can be achieved in the lateral fragment by wires or a countersunk screw into an oval fixation hole on the superior surface.

The combination of the anterior medially-based screw and superior laterally-based screw allows for manipulation of the fracture fragments into an anatomically reduced position by the slight loosening of fixation of these screws, allowing the bone fragments to "slide" on the plate up to approximately <NUM> on each side achieving anatomical reduction. Once this has been achieved, fixation of the plate to the clavicle can proceed with a plurality of screws both anteriorly and superiorly. Fixation of the plate with screws at <NUM>° to each other increases the load to failure of the plate.

According to the present invention, there is provided a bone reduction and fixation device comprising an elongated biplanar plate having an L-shaped profile along its length defined by a first plate and second plates in which the first and second plates each comprise one or more holes configured for receipt of bone-fixing screws,
characterised in that the biplanar plate comprises two biplanar L-shaped end sections and a monoplanar central section and is defined by a continuous first plate and two end second plates, in which the first plate at the monoplanar central section has a thickness at least <NUM>% greater than the thickness of the first plate at the L-shaped end sections, in which the central section comprises a central part of the first plate and no second plate, thus providing a lag window.

In one embodiment, the first and second plates comprise a plurality of countersunk holes configured for receipt of bone-fixing screws.

In one form, the device has an L-shaped profile along at least <NUM>% or <NUM>% of its length.

In one form, the plates (or most of the plates) of the biplanar plate have a thickness of less than <NUM> or <NUM>. In one form, at least <NUM>% or <NUM>% of the biplanar plate has a thickness of less than <NUM>. In one form, at least <NUM>% or <NUM>% of the biplanar plate has a thickness of about <NUM> to <NUM>. In one form, the first and second plates in the biplanar regions of the device have a thickness of less than <NUM> or <NUM>, for example <NUM>-<NUM>, or <NUM>-<NUM>, or about <NUM>.

In one form, the biplanar plate has an L-shaped profile along most or all of its length. This form is suitable for use in reduction and fixing fractured fibula or olecranon. Generally, in these forms, one or both of the first and second plates comprises an elongated slot (<NUM>).

In one form, the first plate is connected to the second plate along substantially all of its length (i.e. at least <NUM>%, <NUM>% or <NUM>% of its length). Thus, the join between the plates is continuous or almost continuous along the plate (i.e. the plates are not joined by struts or bars). This provides strength and stiffness to the plate, in comparison to devices of the prior art that include holes or slots along the join region that weaken the plate.

In another form, suitable for reduction and fixing clavicle fractures, the biplanar plate comprises two biplanar L-shaped end sections defined by end parts of the first plate and second end plates, and a monoplanar central section defined by a central part of the first plate, in which the central part of the first plate has a thickness greater than the end parts for example at least <NUM>%, <NUM>% or <NUM>% thicker than the other parts of the biplanar plate. This provides an access window (or "lag window") for the surgeon to access the fracture area and fix comminuted bone fragments via a "lagging" technique. It also provides for less devascularisation of the healing bone fragments.

Typically, the first and second plates in the end sections are joined along substantially all of its length (i.e. at least <NUM>%, <NUM>% or <NUM>% of its length). Thus, the join between the plates is continuous or almost continuous in the L-shaped end section. Typically, the plates are planar.

While not specifically claimed also described is a plate of unitary construction (i.e. a monoblock plate). This means that it is formed as a single plate, and the plate is not made up of a plurality of parts that are assembled after the parts are formed. Typically, the plate is cast in a mould as a single plate.

In any form, the plate is pre-contoured and is configured that the shape of the plate cannot be manipulated after formation due to the torsional stiffness imparted by the bi-planar design.

While not specifically claimed also described is a bone reduction and fixation device in which the second end plates and end parts of the first plate have a thickness of less than <NUM> or <NUM> (for example <NUM> to <NUM>) , and in which the central part of the first plate has a thickness of greater than <NUM>, (for example <NUM>-<NUM> mm).

In one form, the monoplanar central section extends along about <NUM>% to <NUM>% of the length of the device, typically about <NUM>% to about <NUM>% of the length of the device.

In one embodiment, the first plate and the or each second plate have a width of <NUM>-<NUM>.

In one form, the width of the first and/or second plate varies along it length. For example, the width of one or both plates may vary to correspond to conform to the shape of the bone that is being fixed. In the case of the biplanar plate for the fibula, the plates at one end of the device are widened to approximately conform to the end of the fibula.

In one form, the first plate and/or the or each second plate have a width of <NUM>-<NUM>. In one form, the first plate and/or the or each second plate have a width of <NUM>-<NUM>.

In one form, the first and second plates each comprise at least <NUM>, <NUM>, <NUM>, <NUM>, <NUM> or <NUM> countersunk holes (<NUM>).

While not specifically claimed also described is a bone reduction and fixation device in which the elongated biplanar plate is shaped to approximately correspond to conform a shape of a target bone. For example, with a device for reduction and fixing of a clavicle, the biplanar plate is curved to conform to a curve on an anterior surface of a human clavicle.

For example, the second (anterior) plate may be substantially flat and the first (superior or inferior) plate may be curved. In one embodiment, the elongated biplanar plate is pre-contoured and curved to approximately correspond to the shape and curve of the superior (or inferior) surface of a human clavicle.

In one form, the continuous first plate is contoured to match a sigmoid curve on a clavicle bone. In another embodiment, the plate is for reduction of a fracture of the humerous, and one or both plates of the biplanar plate may be contoured to match the surve in the distal part of the humerus.

In one form, at least one of the first and second plates comprises an elongated slot. The slot is configured to allow both lateral and medial movement of the plate with respect to the bone fragments when the screws are slightly loosened.

In one form, the central section of one of the plates comprises an exaggerated elongated slot.

In one form, both of the first and second plates comprise an elongated slot.

While not specifically claimed also described is a bone reduction and fixation device for a fractured fibula in which the first and second plates may increase in width towards a proximal end of the device to approximately conform to a shape of an end of a human fibula.

In this form, the proximal end of the device may comprise an elongated slot in each plate.

While not specifically claimed also described is a bone reduction and fixation device for a fractured olecranon in which a heel end of the biplanar plate may be configured to form an end plate dimensioned to abut an end of the olecranon. In this form, the first (sagittal) plate of the heel end of the biplanar plate may comprise a plurality of countersunk holes.

In one form, one or both of the first and second plates include small holes configured to receive fixing wires.

In one form, the elongated plate is formed from a metal or metal alloy. Suitable metals include stainless steel, titanium, cobalt, and chrome.

While not specifically claimed also described is a use of a bone reduction and fixation device of the invention, for reduction and fixation of a bone fracture. In one form, the bone fracture is a comminuted fracture, in which the device comprises a lag window. In one form, the fracture is a comminuted fracture of the clavicle or olecranon.

While not specifically claimed also described is a use of a bone reduction and fixation device of the invention, for reduction and fixation of a olecranon fracture. In one form, the bone fracture is a fracture of the ulna, in which the biplanar plate comprises an end plate, in which the end plate and anterior plate are dimensioned to conform to the shape of the end of the ulna.

While not specifically claimed also described is a use of a bone reduction and fixation device of the invention, for reduction and fixation of an elbow fracture. In one form, the bone fracture is a fracture of the fibula, in which distal ends of the plates are widened to approximately conform to lateral and posterior surfaces of the fibula.

While not specifically claimed also described is a method of reduction and fixation of a bone fracture (typically a fracture of the clavicle) that employs a bone fracture reduction and fixation plate of the invention, the method comprising the steps of:.

In one form, the fixation means is a fixing wire, although fixation screws may be employed for initial fixing. In one form, both end sections of the plate have an oval slot for receiving a fixation screw, anteriorly on the medial section, and superiorly on the lateral section, and the method involves fixation of the first bone fragment (medial) to the medial section of the plate with a screw through the slot, and once the fracture has been initially reduced fixation of the second bone fragment (lateral) to the lateral section of the plate with a screw through the slot, and then at this stage of the procedure loosening the two screws slightly to allow movement of the fragments relative to the plate by movement of the screws along the slots. This allows for fine adjustment of the position of the fragments relative to the plate. This allows for easier and more accurate point-to-point reduction of bone fragments.

In one form, the method includes an additional step of fixing the bone fragments to the plate with fixing screws.

In one form, the bone fracture is a comminuted fracture. In this form, the elongated plate generally has biplanar end sections and a monoplanar central section (i.e. has an access, or "lag" window), and the method includes an additional step of reducing and fixing smaller (comminuted) bone fragments after the plate has been fixed to the medial and lateral bone fragments. Alternatively, the comminuted bone fragments can be fixed to the lateral and medial fragments prior to reduction.

The embodiments which form part of the invention are illustrated in the <FIG>, <FIG> and <FIG>. The examples shown in the other figures do not form part of the invention but represent background art that is useful for understanding the invention.

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 open-ended and does not exclude additional, unrecited integers or method/process steps.

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, 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 "biplanar" as applied to the device of the invention means that the device has a substantially L-shaped profile along most or all of its length, and generally along at least <NUM>% of its length. Devices of the invention that include a lag window are generally monoplanar along a part of their length (generally along a central section) - these devices are suitable for reduction and fixiation of clavicle fractures, especially comminuted clavicle fractures where the lag window allows a surgeon access the smaller fragments of bone and reduce and fix the fragments. Other embodiments of the invention are biplanar along all or substantially all of their length, for examples the devices for reduction and fixing ankle or elbow fractures.

As used herein, the term "L-shaped" profile" as applied to the biplanar plate of the invention means that first plate is orthogonal or nearly orthogonal to the second plate along at least a part of its length, in particular the part of the plate that has holes for receiving bone-fixing screws. This provides structural rigidity and torsional stiffness to the plate, and also allows for fixing screws to be inserted in an orthogonal arrangement. It will be appreciated that the plates do not need to be exactly orthogonal provided that the angle between the plates serves to increase the stiffness of the device compared to monoplanar plates. Examples of L-shaped profiles applicable to the devices of the invention are illustrated in <FIG>. In any embodiment, a transition zone between plates may be L-shaped (<FIG>) or curved (<FIG>) to provide a smooth transition from a first plate to an orthogonal second plate. In some embodiments, an inner profile of a plate at a transition zone may be curved and an outer profile at the transition zone may be angular (<FIG>). All of these embodiments provide plates that are of increased torsional stiffness compared with monoplanar plates.

As used herein, the term "monoblock" as applied to a plate means that the plate is formed in one piece, generally by casting or moulding. It is distinct from plates that are formed in multiple parts and assembled or contoured after formation.

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>, there is illustrated a bone reduction and fixation device according to the invention suitable for reduction and fixation of a clavicle, and indicated generally by the reference numeral <NUM>. The device <NUM> has a central section <NUM>, medial end section <NUM> and lateral end section <NUM>. Each end section <NUM>, <NUM> has an L shaped profile defined by ends of a first (superior) plate 3A, 4A and two second (anterior) plates 3B, 4B. The central section comprises a central part of the first plate 2A and no second plate, thus providing a lag window <NUM> which provides a surgeon access to the bone fracture. The first and second plates at the end sections are joined together along the full length of the end section without any gaps in the join. The plate is formed as a pre-contoured monoblock (i.e. cast in one piece).

The plate is formed from stainless steel or titanium, and the second plates (3B and 4B), and end sections of the first plate (4A, 3A), each have a thickness of about <NUM>. The central section of the first plate (2A) has a thickness of about <NUM>, to provide greater bending stiffness at the central (monoplanar) section of the plate. The plate is approximately <NUM> in length, with the central section approximately <NUM> and end sections being each approximately <NUM>. The first and second plates each have a width of about <NUM>.

The central section 2A of the first plate has two countersunk screw-receiving holes <NUM>, and the end sections of each plate have <NUM> countersunk screw receiving holes <NUM>. Smaller wire-receiving holes <NUM> are provided on the plates in between the screw-receiving holes. Screws <NUM> are shown in the holes in some of the illustrations. In <FIG>, it can be seen that one of the holes on the second plate 3B has a slightly elongated configuration to form a slot 8A.

<FIG> is a superior view (from above) showing the device <NUM> attached to a fractured clavicle A, having a sternal end B and acromial end C, with a break D in the middle section of the bone. The plate <NUM> is designed to be attached to a clavicle in an superior-anterior orientation (which is best seen in <FIG> which is a view from above the clavicle), and has a slight pre-contoured curve along the anterior face which matches the curve on the anterior surface of the clavicle A. <FIG> is an anterior view (from the front). <FIG> is a cross-sectional sagittal view showing the L -shaped profile of the end sections of the plate, and how a bone fragment (in this case, the medial bone fragment) can nest within the apex of the L-shaped plate allowing easier alignment of the bone with the plate. <FIG> is an anterior view of the fractured bone and plate, showing how the medial fragment E can be first attached to the plate prior to attachment of the lateral fragment F.

In use, and referring to <FIG>, the medial fragment E is aligned with the medial end <NUM> of the plate, with the bone nestling in the L shaped profile as shown in <FIG>. Once in position, the bone is fixed to the plate by drilling a hole in the bone through the slot 8A, and inserting a screw into the hole and tightening to fix the medial end of the plate to the medial fragment. The lateral fragment F can then be manipulated to align it with the lateral end <NUM> of the plate, with the bone nestling in the L-shaped profile of the plate. Once aligned, the lateral position of the fragment F and plate <NUM> can then be easily adjusted until the fragments of bone reduce together. As the bone fragments both nestle within co-aligned L or C -shaped plates, the only adjustment necessary is lateral adjustment to bring the bones together to reduce. Once they are in position, the lateral fragment F can be fixed to the lateral end section <NUM> of the plate. At this point, or prior to fixing the lateral fragment of the plate, the position of the medial fragment E with respect to the plate can be fine adjusted by loosening the screw in the slot 8A and slightly adjusting the position of the medial fragment E and plate <NUM>.

<FIG> shows a comminuted clavicular fracture with a medial bone fragment E, lateral bone fragment F, and comminuted fragments G. The bone reduction and fixing device of <FIG> is shown attached to the fractured bone in <FIG>, with a medial end <NUM> of the plate <NUM> attached to the medial fragment E and a lateral end <NUM> of the plate <NUM> attached to the lateral fragment F with screws <NUM>. Additional lag screws <NUM> have been employed to fix the comminuted fragment G' to the end of the lateral fragment F and the comminuted fragment G" to the end of the medial fragment E. The use of this embodiment is substantially the same as that described with reference to <FIG>.

Referring to <FIG> an alternative embodiment of the invention is described, indicated generally by the reference numeral <NUM>, in which parts described with reference to the previous embodiment are assigned the same reference numerals. In the previous embodiments described with reference to <FIG>, the plate is configured to align with the clavicle in a superior-anterior orientation. In the embodiment of <FIG>, the plate is designed and contoured to align with a clavicle in an inferior-anterior orientation which is best illustrated in <FIG> which is a view from underneath the clavicle, or in <FIG> which are anterior views of the plate attached to the clavicle. In this embodiment, the plate has a slight pre-contoured curve along the anterior face which matches the sigmoid curve on the anterior surface of the clavicle A.

In use, and referring to <FIG>, the medial fragment E is aligned with the medial end <NUM> of the plate, with the bone nestling in the L-shaped profile as shown in <FIG>. Once in position, the bone is fixed to the plate by drilling a hole in the bone through a countersunk hole <NUM>, and inserting a screw into the hole and tightening to fix the medial end of the plate to the medial fragment. The lateral fragment F can then be manipulated to align it with the lateral end <NUM> of the plate, with the bone nestling in the L-shaped profile of the plate. Once aligned, the lateral position of the fragment F and plate <NUM> can then be easily adjusted until the fragments of bone reduce together. Additional lag screws <NUM> have been employed to fix the comminuted fragment G' to the end of the lateral fragment F and the comminuted fragment G" to the end of the medial fragment E. As the bone fragments both nestle within co-aligned L or C -shaped plates, the only adjustment necessary is lateral adjustment to bring the bones together to reduce. Once they are in position, the lateral fragment F can be fixed to the lateral end section <NUM> of the plate. At this point, or prior to fixing the lateral fragment of the plate, the position of the medial fragment E with respect to the plate can be fine adjusted by loosening the screw in the countersunk hole <NUM> and slightly adjusting the position of the medial fragment E and plate <NUM>.

<FIG> shows an undisplaced fractured clavicle with a break, or fracture in the midshaft. <FIG> shows an example of the bone reduction and fixation plate attached to the fractured clavicle of <FIG>, indicated generally by the reference numeral <NUM>, in which parts identified with reference to the previous embodiment are assigned the same reference numerals. In this embodiment, the device is biplanar along its length, and a central part 2B of the second (anterior) plate has an elongated slot <NUM> that allows surgical access to the ends of the bone fragments and allow vascularisation of the healing bone. The central part of the first plate 2A has the same thickness (about <NUM>) as the ends of the first plate, and second plate. The use of this embodiment is substantially the same as that described with reference to <FIG>. Although not illustrated, the central part of the first plate 2A may have a greater thickness than the end sections of the first plate 2A.

<FIG> shows a lateral fracture of the clavicle. While not forming part of the present invention, <FIG> shows an alternative form (not claimed) of the bone reduction and fixation plate of the invention attached to the fractured clavicle of <FIG>, indicated generally by the reference numeral <NUM>, in which parts identified with reference to the previous embodiment are assigned the same reference numerals. In this form, the device is biplanar along its length, and a central part 2B of the second (anterior) plate has an elongated slot <NUM> on the which allows surgical access to the ends of the bone fragments and allow vascularisation of the healing bone. The central part of the first plate 2A has the same thickness (about <NUM>) as the ends of the first and second plates. The use of this form is substantially the same as that described with reference to <FIG>.

The embodiments of <FIG> are especially suited to reduction and fixation of clavicles. The following embodiments describe devices which do not form part of the invention suitable for reduction and fixation of other bones, such as the ankle (<FIG> and <FIG>) and elbow (<FIG>).

<FIG> and <FIG> show an embodiment of the bone reduction and fixation plate of the invention for fixing the fibula, indicated generally by the reference numeral <NUM>, in which parts identified with reference to the previous embodiment are assigned the same reference numerals. In this embodiment, the device <NUM> is a biplanar plate having an L-shaped profile along its full length, and comprising a first (lateral) plate <NUM> and second (posterior) plate <NUM>. The plate is shown attached to an end of a fractured fibula A, and the other bones of the ankle, namely the tibia B, talus C, calcaneus D, navicular E and cuboid F are illustrated. A distal end 41A of the lateral plate <NUM> is widened (<FIG>) to approximately conform to a lateral surface of the fibula A, and includes an elongated slot 12A that in use overlies the fracture allowing access to it. Likewise, a distal end 42A of the posterior plate <NUM> is widened (<FIG>) to approximately conform to a posterior surface of the fibula A, and also includes an elongated slot 12B that in use also overlies the fracture allowing access to it, but also allowing the use of an interfragmentary lag screw. The end of the plates distal of the slots comprises three countersunk holes <NUM> and one wire-receiving hole <NUM>, and the end of the plates proximal of the slots comprises six countersunk holes <NUM> and three wire-receiving hole <NUM>. The use of this embodiment is substantially the same as that described with reference to <FIG>.

<FIG> show an embodiment of the bone reduction and fixation plate for fixing an olecranon (ulna bone), indicated generally by the reference numeral <NUM>, in which parts identified with reference to the previous embodiment are assigned the same reference numerals. In this embodiment, the device <NUM> is a biplanar plate having an L-shaped profile along its full length, and comprising a first (lateral) plate <NUM> and second (anterior) plate <NUM>. Both plates include a plurality of screw-receiving holes <NUM> and smaller wire holes <NUM>, and an elongated slot <NUM>. A proximal hooked end of the biplanar plate <NUM> comprises an end plate <NUM>, and the anterior plate <NUM> and end plate <NUM> are contoured to conform to the end of the ulna (as shown in <FIG>). In <FIG>, the plate is shown at the start of a reduction part of the procedure, attached to a first end <NUM> of a fractured ulna <NUM>, by wires (not shown). <FIG> shows the next stage of reduction in which the second end of the fractured ulna <NUM> is reduced to the first end using the L-shaped profile of the device as a guide. Once the bones have been reduced as shown in <FIG>, bone-fixing screws <NUM> are put in place, including a long intermedullary screw <NUM>. The use of this embodiment is substantially the same as that described with reference to <FIG>.

<FIG> shows another embodiment of the bone reduction and fixation plate of the invention for fixing an olecranon (ulna bone), indicated generally by the reference numeral <NUM>, in which parts identified with reference to the previous embodiment are assigned the same reference numerals. In this embodiment, the device <NUM> is substantially identical to the device described with reference to <FIG>, with the exception that the device includes a lag window <NUM> to allow access to reduce and fix comminuted bone fragments. The use of this embodiment is substantially the same as that described with reference to <FIG>.

Claim 1:
A bone reduction and fixation device (<NUM>, <NUM>) comprising an elongated biplanar plate having an L-shaped profile along its length defined by a first plate (3A, 4A) and second plates (3B, 4B) in which the first and second plates each comprise one or more holes (<NUM>) configured for receipt of bone-fixing screws (<NUM>),
characterised in that the biplanar plate comprises two biplanar L-shaped end sections (<NUM>, <NUM>) and a monoplanar central section (<NUM>) and is defined by a continuous first plate (3A, 4A) and two end second plates (3B, 4B), in which the first plate at the monoplanar central section (<NUM>) has a thickness at least <NUM>% greater than the thickness of the first plate at the L-shaped end sections (<NUM>, <NUM>), in which the central section comprises a central part of the first plate and no second plate, thus providing a lag window (<NUM>, <NUM>).