Drill guide with angle verification
A method and instrument is used for inserting a bone screw into a hole in a bone plate and into bone at a maximum angulation of a bone screw central longitudinal axis with respect to a central axis of the hole. The maximum angulation is that which places the head of the bone screw at or below an outwardly facing surface of the bone plate. The instrument has a distal end including a gauge element, spaced proximally from an end surface of the distal end when in contact with a counterbore surrounding the plate hole. The space is less than or equal to a distance from the counterbore surface to the outwardly facing surface of the bone plate. The instrument is tilted with respect to a central axis of the bone plate hole to an angle wherein the gauge element remains at or below the outwardly facing surface of the bone plate adjacent the counterbore. A hole is drilled in the bone through a guide bore in the instrument.
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The invention relates to an angle guide for orienting a bone screw in a bone plate. More particularly, the invention relates to an instrument for insuring the position of the head of a bone screw located within a bone plate hole.
It is often necessary when utilizing bone plates either for fracture fixation or such as tibial base plates to couple the bone plates to bone via a screw extending through a hole in the plate. When the screw is angled, surgeons have had to eye the correct angle specified by the device manufacturer indicated by the surgical situation. If the bone screw is put in at too great an angle the bone screw head would sit proud of the bone plate which in some situations is undesirable. The surgeon would then either continue to torque the bone screw until the bone screw's cutting flutes soften the bone in the area and allowed it to sit properly or the bone screw would be backed out and the surgeon would attempt to reinsert the bone screw at a shallower angle.
The surgeon often had difficulty eyeing the correct angle especially where there was a plurality of bone screws to be inserted, since the correct angle is relatively small i.e. zero to ten degrees. Normally, the surgeon drills a pilot hole in the bone prior to inserting the bone screw and it has been difficult to drill the pilot hole at the correct angle so that the bone screw would seat properly. For example, when using a tibial base plate, it is typical to utilize a polyethylene bearing surface snapped onto the base plate which has been implanted on a prepared tibia. Consequently, if the pilot hole and subsequent bone screw are inserted at an incorrect angle the head of the bone screw could impinge on the distal surface of the polyethylene bearing implant which is undesirable. Such. an impingement could lead to metal or polyethylene debris which has been known to cause osteolysis.
If the surgeon saw that the bone screw did not seat properly or was not at the specified depth, he could continue to torque the bone screw. However, since most bone screws include cutting flutes at the leading ends thereof continued rotation of the cutting flutes causes the bone to degrade and allows more play in the screws positioning. While this may allow the bone screw to seat properly, it reduces the compressive forces holding the plate to the bone by decreasing the holding ability of the screw.
Alternately, if the surgeon noticed the bone screw did not seat properly or is not at the correct depth, he might reverse the screw and drill a new pilot hole at a slightly different angle. This method may not always be successfully since the drill and screw will have a tendency to follow the original drilled hole. Even if the surgeon is capable of resetting the new desired angle, there is still damage to the bone in the originally drilled area which may cause fracture propagation. Consequently, there has been a long felt need to provide an instrument which can indicate the angle which is not to be exceeded for proper positioning of the bone screw in the bone plate. This instrument will verify that the final implant positioning is accurate and allows the head of the bone screw to be properly located.
BRIEF SUMMARY OF THE INVENTIONThe instrument of the present invention is a drill guide for use in orthopedic surgery. It is intended to specify the maximum angle of a pilot hole drilled in bone when using bone screws for fixation of an orthopedic implant such as a bone plate. The instrument consists of several main features which include a handle which allows a surgeon to maneuver the instrument. A mating feature allows the device to interface with a corresponding implant, such as a bone plate, especially in an area surrounding a hole therein for accommodating a bone screw. This feature may be a part-spherical convex surface for rotating on a similar part-spherical concave surface surrounding the screw hole. A body having an appropriately sized through hole for guiding a drill and includes a circumferential visual reference delineating the amount of angulation a surgeon can put into a pilot hole drilled for receiving the bone screw.
The visual reference may be a reduction in diameter, a protrusion, an etched line or a laser marked line. Also color and surface finish could be used as visual indicators. Additionally, two or three visual references could be used indicating different angle markings i.e. 5°, 10° or 15°. Thus two or three lines could be used at different levels with the lower line corresponding to the greater angle. The visual reference may be observed by the surgeon and indicates to him that the pilot hole angle he or she is about to drill through the device is compatible with the orthopedic implant, such as a bone plate, and the bone screw securing it. The instrument allows the proper pilot hole angle to be drilled through the device and the implant and allows a bone screw to have the proper angulation and therefore seat properly within the recess hole in the device so that the bone screw head sits correctly in reference to the plate, or in the case of a tibial baseplate below the surface of the plate.
An instrument is provided for determining the position of a bone screw head with respect to a bone plate outer surface having a concave surface surrounding a screw hole in the plate. The instrument has a shaft having a leading end with a convex surface including a gauge element spaced from the end of the concave surface of the shaft. The gauge element is spaced a distance from the end surface of the shaft equal to or less than a distance from an outwardly facing surface of the bone plate, opposite a bone contacting surface, to the countersunk screw head seating surface surrounding the hole. Preferably the leading end of the shaft has a convex part-spherical portion for engaging a concave part-spherical countersunk surface on the bone plate. The gauge element is a mark extending around an outer circumference of the leading end of the shaft. The gauge element preferably is a circular line or indentation located intermediate the part-spherical portion and a cylindrical portion of the leading shaft end. The shaft leading end has a central bore therethrough for guiding a drill. The bore preferably has a central axis extending perpendicular to a plane containing the circumferential mark.
A method is taught for inserting a bone screw through a hole in a bone plate and into bone at a maximum angulation of a bone screw central longitudinal axis with respect to a central axis of the hole. The method includes placing a bone plate having at least one screw hole surrounded by a concave counterbore on an outwardly facing surface of the bone plate on a bone surface. Thereafter inserting the instrument having a distal end including the gauge element into the counterbore. The gauge element is spaced proximally from an end surface of the distal end. In one embodiment, the spacing is less than or equal to a distance from the counterbore surface to the outwardly facing surface of the bone plate. Alternatively, the gauge element can be greater than or equal to a distance from the counterbore surface to the outwardly facing surface of the bone plate. The instrument is tilted with respect to a central axis of the bone plate hole to an angle wherein the gauge element remains at or below the outwardly facing surface in the first scenario and at or above the bone plate in the second scenario. Then the hole is drilled in the bone through a guide bore in the instrument. The instrument is removed from the bone plate and the bone screw is inserted into the bone plate screw hole. The gauge element may be a circular ring mounted on the instrument on a circular line around the instrument. The tilting of the instrument is up to a maximum angle that maintains the circular ring or line at or below the outwardly facing surface of the bone plate surrounding the counterbore. Design intent guides the location of the gauge element from the distal end of the instrument which determines the corresponding maximum angle intended by the designer. An angled handle attached to the distal end of the instrument is used to tilt the distal end of the instrument. The distal end of the instrument is preferably part-spherical in shape matching the shape of the counterbore. The bore in the distal end extends perpendicular to a plane containing the gauge element.
As used herein when referring to bones or other parts of the body, the term“proximal” means close to the heart and the term“distal” means more distant from the heart. The term“inferior” means toward the feet and the term “superior” means toward the head. The term“anterior” means toward the front part or the face and the term“posterior” means toward the back of the body. The term“medial” means toward the midline of the body and the term“lateral” means away from the midline of the body. When referring to the instrument, distal means further from the user.
A more accurate appreciation of the subject matter of the present invention and the various advantages thereof can be realized by reference to the following detailed descriptions which makes reference to the accompanying drawings in which similar reference numerals relate to similar elements throughout several views:
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Alternately, as will be described below, a protrusion, such as a ring, may protrude outwardly from the distal instrument tip to provide a tactile reference for the surgeon to know that the device is at or past its maximum angle. For example, an embodiment having a hard stop may be provided for limiting the maximum angle but allowing freedom to position the device until that angle is reached. These features can be put on a spherical or non-spherical drill guide that is meant to enter a spherical or non-spherical hole. A spherical drill guide can be matched with a non-spherical hole or visa-versa if desired.
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Also, should it be acceptable for the screw head to sit above the outwardly facing surface of the bone plate then the gauge element may be located at a distance from the bottom end, of the shaft which contacts the counterbore surface which is greater than the distance from the outer plate surface to the bottom of the counterbore.
Although the invention herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and applications of the present invention. Specifically the drill guide can be used with any plate being attached to a subsurface, such as a metal plate to wood, to insert the head of the screw is at or below the top surface of the plate when the screw is inserted at an angle. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present invention as defined by the appended claims.
Claims
1. An instrument for determining the position of a bone screw head with respect to a bone plate outer surface, the surface surrounding a screw hole in the plate, the instrument comprising:
- a shaft having a guide bore at a leading end, the leading end including a gauge element spaced from an end surface of the shaft, the gauge element spaced a distance from the end surface of the shaft equal to or less than a distance from an outwardly facing surface of the bone plate, opposite a bone contacting surface, to a countersunk screw head seating surface surrounding the screw hole.
2. The instrument as set forth in claim 1 wherein the leading end of the shaft has a part-spherical portion for engaging a part-spherical countersunk surface on the bone plate.
3. The instrument as set forth in claim 2 wherein the gauge element is a mark extending around an outer circumference of the leading end of the shaft.
4. The instrument as set forth in claim 3 wherein the gauge element is a circular ring located intermediate the part-spherical portion and a cylindrical portion of the leading shaft end
5. The instrument as set forth in claim 3 wherein the shaft leading end has a central bore therethrough for guiding a drill.
6. The instrument as set forth in claim 5 wherein the bore has a central axis extending perpendicular to a plane containing the circumferential mark.
7. A method for inserting a bone screw through a hole in a bone plate and into bone at a maximum angulation of a bone screw central longitudinal axis with respect to a central axis of the hole, comprising:
- placing a bone plate having at least one screw hole surrounded by a counterbore on an outwardly facing surface of the bone plate on a bone surface;
- inserting an instrument having a distal end including a gauge element, the gauge element spaced proximally from an end surface of the distal end into the counterbore surrounding the plate hole, the spacing less than or equal to a distance from the counterbore surface to the outwardly facing surface of the bone plate;
- tilting the inserted instrument with respect to a central axis of the bone plate hole to an angle wherein the gauge element remains at or below the outwardly facing surface of the bone plate adjacent the counterbore;
- drilling a hole in the bone through a guide bore in the instrument;
- removing the instrument from the bone plate; and
- inserting a bone screw into the bone plate screw hole.
8. The method as set forth in claim 7 wherein the gauge element is a circular ring mounted on the instrument.
9. The method as set forth in claim 8 further comprising tilting the instrument to a maximum angle that maintains the circular ring at or below the outwardly facing surface of the bone plate surrounding the counterbore.
10. The method as set forth in claim 9 wherein the maximum angle of instrument tilt is 10°.
11. The method as set forth in claim 8 wherein the instrument is tilted by manipulating a handle attached to the distal end of the instrument.
12. The method as set forth in claim 7 wherein the distal end of the instrument is part-spherical in shape.
13. The method as set forth in claim 12 wherein the gauge element is a ring extending around the circumference of the distal end of the instrument.
14. The method as set forth in claim 13 wherein the bore in the distal end extends perpendicular to a plane containing the gauge element.
15. The instrument as set forth in claim 13 wherein the ring has a diameter greater than a diameter of the distal end of the instrument.
16. The method as set forth in claim 13 further comprising contacting the counterbore in the plate with the ring to provide a tactile indication of the angle of the guide bore with respect to the central axis of the bone plate hole.
17. The instrument as set forth in claim 1 wherein the gauge element includes a protrusion for contacting the plate and providing a tactile indication of the angle of the guide bore with respect to a central axis of the screw hole.
Type: Application
Filed: Dec 23, 2008
Publication Date: Jun 24, 2010
Applicant: Howmedica Osteonics Corp. (Mahwah, NJ)
Inventor: Mohamed Soliman (Piscataway, NJ)
Application Number: 12/317,703
International Classification: A61B 17/58 (20060101);