EP2061388A2

EP2061388A2 - A bone plate for fixation to a patient's vertebrae

Info

Publication number: EP2061388A2
Application number: EP07804161A
Authority: EP
Inventors: Chris Gowland; Dirk Uyttendaele; Bart Poffyn; Joseph De Roose; Marc Sanders
Original assignee: DePuy International Ltd
Current assignee: DePuy International Ltd
Priority date: 2006-09-08
Filing date: 2007-09-06
Publication date: 2009-05-27
Also published as: WO2008029143A3; GB0617709D0; WO2008029143A2

Abstract

A bone plate (2) for fixation to a patient's vertebrae which includes a pair of fixation pads (4, 6), each having at least one hole (16) in it for receiving a fixation screw, and a bridge portion (8) which extends between the fixation pads. At least one of the fixation pads comprises two pad portions (10, 12) which are hingedly connected to one another in such a way that the hinge portions are capable of relative movement so that the bone facing surface of the pad can conform to the surface of the vertebra to which the pad is to be fixed.

Description

A BONE PLATE FOR FIXATION TO A PATIENT'S VERTEBRAE

This invention relates to a bone plate for fixation to a patient's vertebrae.

The ability of the spine to carry loads can be compromised by degenerative diseases, the effects of tumours, and fractures and dislocations arising from physical trauma. Elongate rigid bone plates are commonly used to stabilise the spinal column. Such bone plates are fastened to vertebrae on adjacent sides of a defect so as to span the defect. The plates are commonly fastened to the vertebrae by means of bone screws which pass through respective fixation holes in the plate. It is common for two or more screws to be used when possible, but one screw might be used when the available space is limited

When bone plates are used to treat defects in cervical vertebrae, a surgeon can use an anterior approach or a posterior approach. The choice might depend on the spinal disorder or pathology to be treated. The anterior approach in techniques in which vertebrae are fused is now popular because of the ease of approach, and the good load bearing characteristics of the plate when fastened to the spine anteriorly, providing an intrinsically stable implant, whether applied mono-cortically or bi-cortically.

An anterior approach has advantages because of the absence of anatomical structures between the incision and the spine which can significantly obstruct access. This factor means that many anterior approach plating procedures can be carried out through small incisions. Multiple small incisions might be used, for example with one incision used to delivery a plate to the spine, and another used to provide access to the plate with a driver for fixation screws.

It can be important to obtain a good fit between a bone plate and the surface of the vertebra to which it is to be fastened, especially when the plate is to be fastened to the vertebra by means of two or more screws. Otherwise, localised stresses can arise which can give rise to damage to the screws or to the bone tissue or both. Achieving a good fit between a bone plate and the surface of the vertebra to which it is to be fastened can be made difficult when a procedure is performed through a small incision. The present invention provides a bone plate for fixation to a patient's vertebrae which includes a pair of fixation pads and a bridge portion which extends between the fixation pads, in which at least one of the fixation pads comprises two pad portions which are hingedly connected to one another

Accordingly, in one aspect, the invention provides a bone plate for fixation to a patient's vertebrae which includes a pair of fixation pads, each having at least one hole in it for receiving a fixation screw, and a bridge portion which extends between the fixation pads, in which at least one of the fixation pads comprises two pad portions which are hingedly connected to one another in such a way that the hinge portions are capable of relative movement so that the bone facing surface of the pad can conform to the surface of the vertebra to which the pad is to be fixed.

The bone plate of the invention has the advantage that the hinged fixation pad can be offered to the surface of the vertebra to which the plate is to be fixed, so that the hinged pad portions can move relative to one another so that the pad can conform to the surface of the vertebra. For example, when the surface of the vertebra is concave, the pad portions can adopt a configuration which might be described as a shallow "v", and when the surface of the vertebra is convex, the pad portions can adopt a configuration which might be described as a shallow "n". The bone plate of the invention therefore facilitates fixation with good surface to surface contact between the fixation pad of the plate and the surface of the bone, especially when the plate is being manipulated through a small incision.

Furthermore, the hinged construction of the fixation pad allows the pad to collapse to facilitate implantation through a small incision.

Preferably, the surface of at least one of the fixation pads which faces towards the surface of a vertebra to which the pad is to be fixed is rounded. This can help to optimise the surface to surface contact between the fixation pad and the vertebra.

It will often be preferred for the fixation pad to be generally rectangular in outline. Its sides might be approximately straight when the pad is viewed from above. It will generally be preferred that the edge of the fixation pad is rounded at its corners. It can be preferred for the two pad portions of a fixation pad to have approximately equal size.

The fixation pad will generally have at least two holes formed in it which can receive fixation screws or other fixation elements to extend through the holes into underlying bone tissue, approximately perpendicular to the tissue. Preferably, at least one such hole is provided in each pad portion. Preferably, the angle between the axis of the hole and the bone-engaging surface of the fact of the plate is at least about 60°, more preferably at least about 75° and often about 90°.

Preferably, each of the fixation pads comprises two pad portions which are hingedly connected to one another in such a way that the hinge portions are capable of relative movement so that the bone facing surface of the pad can conform to the surface of the vertebra to which the pad is to be fixed.

Preferably, the bridge portion is hingedly connected to at least one of the fixation pads. This can make it easier to use the bridge portion to manipulate the fixation pad as it is offered up to the surface of the vertebra to which it is to be fixed. Preferably, the fixation pad which the bridge portion is connected to comprises two pad portions. Preferably, the bone plate includes a hinge pin by which the pad portions are hingedly connected to one another and by which the bridge portion is connected to the pad.

Preferably, the bridge portion comprises first and second bridge portion parts which are connected to respective ones of the fixation pads, and which can be connected to one another. Preferably, each of the fixation pads to which the bridge portion parts are connected comprises two pad portions which are hingedly connected to one another.

Preferably, the bridge portion parts overlap one another in a lap joint arrangement when connected to one another. A preferred way to connect the bridge portion parts to one another can involve using at least one, especially at least two, threaded fasteners. For example, one of the bridge portion parts can have at least one hole formed in it which has an internal thread. A threaded fastener can then be inserted through the other bridge portion part so that it extends into the hole with the internal thread, to engage that thread and thereby to draw the bridge portion parts together.

Preferably, the bridge portion parts have interfitting formations on at least part of their facing surfaces, which allow the bridge portions to be connected to one another in one of a plurality of predetermined lengths. For example, a first one of the bridge portions can be shaped with a plurality of rounded bulbous portions spaced apart evenly along its length. The second bridge portions can define a channel with a plurality of rounded widened portions in its side wall spaced apart evenly along its length. The configuration of the bulbous portions of the first bridge portion can match the configuration of the rounded widened portions in the second bridge portion to provide a plurality of predetermined lengths of the mated bridge portions according to the number of bulbous portions which have been received in corresponding rounded widened portions. The predetermined lengths might also be provided by mating teeth on facing surfaces of the bridge portions. The interfitting formations are able to enhance the ability of the plate to withstand compressive and tensile loads.

When the bridge portion is not formed as two bridge portion parts, it can be fastened to one or each fixation pad after the fixation pads have been fastened to their respective vertebrae. For example, when the bridge portion is fastened hingedly to one of the fixation pads, it can then be fastened to the other fixation pad after it has been fastened to its vertebra. A bridge portion which is not fastened to either fixation pad prior to implantation can be fastened to each fixation pad after the pads have been fastened to their respective vertebrae. Preferably, the effective length of the bone plate can be selected by choosing the point at which the bridging portion is fastened to its fixation pad. This can be achieved when the bridging portion has a constant cross section (for example in the form of a rod or plate) by clamping the bridging portion. The bridging portion can have a plurality of spaced apart formations, and some or all of those formations can engage corresponding formations on the fixation pad at different positions to provide the different effective lengths of the bridging portion. The bridge portion will often be approximately straight along most of its length where it spans the vertebral defect. It can have a curved portion at its end where it is fastened to its fixation pad.

Components of the bone plate can be made from materials which are conventionally used in the manufacture of orthopaedic implants. Metals are generally preferred, for example titanium and certain of its alloys, and certain stainless steels.

The dimensions of the bone plate will be selected according to the intended application of the plate, including in particular the size of the vertebrae to which it is to be fastened and the distance between the vertebrae on opposite sides of the defect. Such design parameters are commonly taken into account in the design of bone plates for spinal applications.

The bone plate can be used in a surgical procedure which includes the steps of:

• fixing a first fixation plate to a first vertebra,

• fixing a second fixation plate to a second vertebra, providing a bridge portion which is fastened to the first and second fixation plates and which extends between the first and second vertebra.

When the bridge portion comprises first and second bridge portion parts, which are hingedly fastened to the first and second fixation plates respectively, the step of providing the bridge portion can involve connecting the first and second bridge portion parts to one another.

The method includes a step of applying a distracting or a compressing force to the vertebrae before the step of providing the bridge portion so that it extends between the first and second vertebrae. It can then be an advantage to use a bridge portion which has first and second bridge portion parts with interfitting formations on at least part of their facing surfaces, which allow the bridge portions to be connected to one another in one of a plurality of predetermined lengths. The bridge portion parts can then be connected to one another according to the spacing of the vertebrae which results from the application of the compressing or distracting force. Embodiments of the invention will now be described by way of example with reference to the accompanying drawings, in which:

Figure 1 is an isometric view from above of a bone plate according to the invention.

Figure 2 is a plan view of the bone plate shown in Figure 1.

Figure 3 is a side view sectional elevation through the bone plate shown in Figure 1.

Figure 4 is a side view of a part of the bone plate shown in Figure 1, showing collapsed hinge pads.

Figure 5 is a view along the anterior posterior axis of a spinal column on which a bone plate according to the invention has been fastened.

Referring to the drawings, Figures 1 to 3 show a bone plate 2 which comprises first and second fixation pads 4, 6 and a bridge portion 8 which extends between them. The first fixation pad 4 comprises first and second fixation pad portions 10, 12, which are hingedly connected to one another by means of a hinge pin 14. Each of the fixation pad portions 10, 12 has a fixation hole 16 in it. The fixation pad provided by the fixation pad portions is approximately square, with its corners rounded. The size of the fixation pad portions 10, 12 is approximately equal.

The bridge portion comprises first and second bridge portion parts 18, 20. Each of the bridge portion parts has a straight arm section and a curved section 22 at one end. Each of the bridge portion parts is connected at its curved end to a respective fixation pad by means of the same hinge pin 14 by which the fixation pad portions are fastened to one another.

The first bridge portion part 18 is channel shaped when viewed in cross-section along its length so that the second bridge portion part 20 can be fitted into the channel. The shape of the side walls of each of the first and second bridge portion parts 18, 20 has a wave pattern, with regular series of peaks and troughs, which enable the first bridge portion part to receive the second bridge portion part within the channel but prevent relative longitudinal movement when so received. The first bridge portion part has threaded holes 24 formed in it. The second bridge portion part has non-threaded holes 26 formed in it. Screws 28 can be inserted through the holes in the second bridge portion part to engage the threaded holes 24 in the first bridge portion part. The holes 26 can have a conical shape when viewed in cross-section from one side to allow the angular orientation of the screws to be adjusted.

Optionally, the second bridge part can have a slit 29 provided in it which extends between its holes 26. This can allow the bridge part to be compressed transversely provided that there are no screws in the holes. This can allow the effective length of the bone plate to be adjusted telescopically when the second bridge part is received within the first bridge part, prior to fixation of the length of the plate by placing screws in the aligned holes 24, 26 in the bridge portion parts.

The second fixation pad 6 also comprises first and second fixation pad portions 10, 12 in the same manner as the first fixation pad 4.

Figure 4 shows the second bridge portion part 20 from one side, where the wave pattern of the side wall is visible. The fixation pad portions 10, 12 are shown in a configuration in which they are approximately perpendicular to one another. This can facilitate insertion of the bridge portion part into a body cavity through a small incision. When the bridge portion part contacts a vertebra, the two fixation pad portions will move relative to the hinge pin 14 so that they conform to the surface of the vertebra.

Figure 5 shows a spinal column with a bone plate 2 according the invention fastened to two vertebrae 30, 32. The bone plate can be implanted using a minimally invasive anterior approach. Each of the bridge portion parts 18, 20 can be offered to the spinal column through a small incision with the fixation pad portions in a collapsed configuration as shown in Figure 4. The fixation pad portions of each fixation pad move relative to their respective hinge pins so that they conform to the bone. Each of the fixation pads can then be fastened to their respective vertebrae by means of bone screws which are passed through the fixation holes 16 in the fixation pad portions. Distracting or compressive forces can be applied to the vertebrae 30, 32 and displacement which is imparted to the vertebrae can be retained by engagement of the wave formations of the first bridge portion part with the wave formations on the second bridge portion part and locking the bridge portion parts together by means of screws in the aligned holes 24, 26 in the bridge portion parts.

Claims

CLAIMS:

1. A bone plate for fixation to a patient's vertebrae which includes a pair of fixation pads, each having at least one hole in it for receiving a fixation screw, and a bridge portion which extends between the fixation pads, in which at least one of the fixation pads comprises two pad portions which are hingedly connected to one another in such a way that the hinge portions are capable of relative movement so that the bone facing surface of the pad can conform to the surface of the vertebra to which the pad is to be fixed.

2. A bone plate as claimed in claim 1, in which each of the fixation pads comprises two pad portions which are hingedly connected to one another in such a way that the hinge portions are capable of relative movement so that the bone facing surface of the pad can conform to the surface of the vertebra to which the pad is to be fixed.

3. A bone plate as claimed in claim 1, in which the bridge portion is hingedly connected to at least one of the fixation pads.

4. A bone plate as claimed in claim 3, in which the fixation pad which the bridge portion is connected to comprises two pad portions.

5. A bone plate as claimed in claim 4, which includes a hinge pin by which the pad portions are hingedly connected to one another and by which the bridge portion is connected to the pad.

6. A bone plate as claimed in claim 1 , in which the bridge portion comprises first and second bridge portion parts which are connected to respective ones of the fixation pads, and which can be connected to one another.

7. A bone plate as claimed in claim 6, in which the bridge portion parts overlap one another in a lap joint arrangement when connected to one another.

8. A bone plate as claimed in claim 6, in which the bridge portion parts have inter- fitting formations on at least part of their facing surfaces, which allow the bridge portions to be connected to one another in one of a plurality of predetermined lengths.