MODULAR EXTERNAL FIXATOR AND METHOD OF ITS USE

Abstract

The invention relates to an external fixator device and a method of its use in treating bone fractures and in orthopedic interventions, such as corrective osteotomies.

Claims

1. A device for the external fixation of bones comprising: (i) at least one external support element (1), (ii) a plurality of bone pins (2), (iii) at least one fixing element (100) for fixing a bone pin to the support element, and (iv) optionally at least one connecting element to connect several external support elements to each other.

2. The device of claim 1, wherein the fixing element (100) is adapted to allow a stiffness modulation, wherein a low degree of stiffness is adjusted during a first phase of the healing period, a higher degree of stiffness is adjusted during a subsequent phase of the healing period, and optionally a low degree of stiffness is adjusted during the final phase of the healing period.

3. The device of claim 1 or 2, wherein the fixing element (100) is shaped as a clamp around a bone pin (2) and a support element (1).

4. The device of claim 1, wherein the fixing element (100) comprises a top plate (4), a bottom plate (6), a plurality of wire elements, e.g. flexible wire elements (3a, 3b), wherein the top plate (4) and the bottom plate (6) are spaced part to receive a bone pin (2) between them, wherein the bottom plate (6) is in contact with the support element (1), and wherein the wire elements (3a, 3b) are fixed into the top plate (4), slidingly pass through the bottom plate (6) and are adapted to fit around the support element (1).

5. The device of claim 4, wherein the fixing element (100) further comprises a pin disc (5) between the top plate (4) and the bottom plate (6) for receiving a bone pin (2) between the pin disc (5) and the bottom plate (6).

6. The device of claim 5, wherein the exterior circumference of the pin disc (5) is within the wire elements (3a, 3b).

7. The device of claim 4, wherein the bottom plate (6) has a transverse recess (7) on the side facing the support element (1).

8. The device of claim 5, wherein the bottom plate (6) has a roughened surface (11) on the side facing the bone pin (2).

9. The device of claim 5, wherein the pin disc (5) has one or more transverse recesses (8, 9) on the side facing the bone pin (2).

10. The device of claim 4, wherein the top plate (4) comprises an adjusting element (10), e.g. a set screw which is adapted to allow a stiffness modulation.

11. The device of claim 1, comprising at least three bone pins (2) for insertion into the bone on each side of the fracture to be fixed, wherein first and second bone pins are adapted for insertion parallel to each other and a third bone pin is adapted for insertion at oblique angle to the first and second bone pin.

12. The device of claim 11, wherein the first and second bone pins are for fixation to opposite sides of the external support element.

13. The device of claim 11 or 12, wherein the first and second bone pins are for fixation perpendicular to the external support element.

14. A method for external fixation of a bone, comprising applying a device according to claim 1 to a subject in need thereof.

15. The method of claim 14, comprising modulating the stiffness of the device during the healing period, wherein a low degree of stiffness is adjusted during a first phase of the healing period, a higher degree of stiffness is adjusted during a subsequent phase of the healing period, and optionally a low degree of stiffness is adjusted during the final phase of the healing period.

Description

[0028] In the following, preferred embodiments of the invention are described in reference to the accompanying Figures.

[0029] FIG. 1 shows a perspective view of the external fixator clamp 100 according to the present invention showing a segment of the tube 1 and a bone pin 2 clamped together with the clamp.

[0030] FIG. 2 shows an exploded view of the components of the external fixator.

[0031] The clamp 100, FIG. 1, of the present invention is made from mechanically rather simple elements shown separately on FIG. 2: [0032] (1) two wire elements 3a and 3b, e.g. flexible wire elements, bent to fit around the tube 1 and connected, preferably by welding, to a top plate 4 with a threaded hole 13 in the center, resulting in a yoke shaped member; [0033] (2) an additional bottom plate 6 in contact with the tube which may have holes, e.g. four holes 12 for passage of the bent wires of the yoke and a transverse recess 7 on one face to fit over the tube and make two lines of contact with it—in the following also designated as tube plate; [0034] (3) a disc 5 that fits between the top plate 4 of the yoke and the tube plate 6, within the wires 3 of the yoke, with transverse recesses 8, 9 adapted to different bone pin diameters—in the following also designated as pin disc; [0035] (4) a set screw 10 in the top plate of the yoke, tightening of which will compress the pin disc 5, the bone pin 2, the tube plate 6 and the tube 1, all at once, within the yoke 100.

[0036] A clamp comprising the elements as described above allows a very stable clamping of the bone pin to the tube. On the upper surface of the tube plate, facing the pin, a ring 11 of small teeth, or otherwise roughened surface, provides even a stronger grip on the pin to prevent its rotation or sliding against the tube plate 6. Before the clamping is effected by tightening of the set screw, the bone pin and the tube have 5 degrees of freedom of relative movement. Thus, the stiffness of the construct can be modulated by tightening and loosening of the set screw allowing dynamization or reverse dynamization as indicated above.

[0037] Production costs of such a clamp are much lower than of the conventional external fixator clamps and thus should be affordable in undeveloped world, where currently only conservative treatments by splinting or casting are viable options of fracture treatment.

[0038] In much of the developed world the unpredictable outcomes of conventional external fixation in comparison to plating or nailing have reduced its use to only temporary stabilization of the open fractures, followed by internal fixation. However, if the external fixation by reverse dynamization finds it way from research into clinical practice, reliable and fast healing by external fixation could significantly reduce the cost and the morbidity of multiple interventions currently practiced.

[0039] FIG. 1 shows a perspective view of the external fixator clamp according to the present invention. The clamp 100 is comprised of two identical, U-shaped wires 3a and 3b fixed to the top plate 4 of the clamp. Fixation of the wires 3a and 3b into the top plate 4 can be accomplished by means of welding, hard soldering, brazing or riveting, particularly orbital riveting. This construct has a mechanical function of a yoke. A bottom plate 6 contacting the support element 1 is provided with four through-holes 12 and is free to slide along the wires 3a and 3b. The bottom plate 6 on its support element-facing side may have a transverse groove 7 that provides improved contact to the support element 1, for example along two parallel lines if trapezoidally shaped. A bone pin 2 is placed between the pin disc 5 and the bottom plate 6. On its bone pin facing side the pin disc 5 may have one or more transverse recesses 8, 9, which accommodate bone pins of different diameters.

[0040] FIG. 2 shows an exploded view of the tube, pin and the clamp parts. The clamp components 3a, 3b, 4, 5, 6 and 10 may be manufactured from a suitable metal, such as a stainless steel, a titanium alloy or a high strength aluminium alloy. Titanium or aluminium alloys are preferred to stainless steels because they are compatible with MRI, which can be used to assess the progress of fracture healing. The tube 1 has sufficient strength when made from aluminium alloys such as 7075 and of large diameter.

[0041] Mechanical testing of the external fixator according to this invention with one large diameter tube and 6 clamps, has been performed to compare it to a conventional, Hoffman-type fixator with two rods and six pins clamped to the rods with 12 clamps. The strength and the stiffness exceeded the values of the conventional construct.

[0042] Of some importance is also the reduced weight of the complete frame, even if stainless steel is used; use of titanium or aluminum alloys brings an additional weight reduction of factor two to four. While this is of only minor clinical importance, reduced weight has direct impact on the manufacturing costs.

[0043] The key contributing factor and inventive technical aspect of the solution to weight and cost reduction is the use of two thin wires 3a and 3b to form the yoke structure of the clamp, which can effectively sustain the tensile loads imposed by compressing the pin 2 to the tube 1 via tube plate 6 by tightening of the set screw 10.