US 20050251113 A1
A computer assisted surgery system for positioning a surgical implant within a patient's body that includes a localizing device configured to measure a pose of the surgical implant, an imaging device adapted for acquiring images of the surgical implant, and a computer adapted for calculating an adjusted pose for the surgical implant based on information developed from the images so as to compensate for deformation of the surgical implant or inaccuracies in localization.
1. A computer assisted surgery system for positioning a surgical implant within a patient's body, said system comprising:
a localizing device configured to measure a pose of the surgical implant;
an imaging device adapted for acquiring images of the surgical implant; and
a computer adapted for calculating an adjusted pose for the surgical implant based on information developed from the images so as to compensate for deformation of the surgical implant or inaccuracies in localization.
2. The system of
3. The system of
4. The system of
5. The system of
6. The system of
7. A method for positioning a surgical implant within a patient's body, wherein the surgical implant has one or more holes, the method comprising:
calculating an adjusted pose for the surgical implant based on information developed from acquired images of the surgical implant so as to compensate for deformation of the surgical implant or inaccuracies in localization.
8. The method of
9. The method of
measuring a pose of a surgical instrument; and
displaying a graphic representation of a trajectory of the surgical instrument relative to a graphic representation of the surgical implant, based on the measured pose of the surgical instrument and the adjusted pose of the implant.
10. A computer program product for positioning a surgical implant within a patient's body, wherein the surgical implant has one or more holes, said computer program product comprising:
instructions for calculating an adjusted pose for the surgical implant based on information developed from acquired images of the surgical implant so as to compensate for deformation of the surgical implant or inaccuracies in localization.
11. The computer program product of
12. The computer program product of
This application is a continuation of U.S. application Ser. No. 10/756,020, entitled “Computer Assisted Intramedullary Rod Surgery System With Enhanced Features,” which was filed Jan. 12, 2004 (the “'020 application”), which is in turn a continuation of U.S. application Ser. No. 09/683,107, entitled “Computer Assisted Intramedullary Rod Surgery System With Enhanced Features,” which was filed Nov. 19, 2001, now U.S. Pat. No. 6,718,194 (the “'194 patent”), which claims the benefit of U.S. Provisional Application No. 60/249,697, which was filed Nov. 17, 2000 (the “'697 application”). The '020 application, the '194 patent, and the '697 application are hereby incorporated by reference in their entireties.
This invention relates to a computer assisted surgery system for use in inserting interlocking screws in an intramedullary rod.
A current surgical treatment for fractures of the shaft of long bones (e.g., femur and tibia) is the insertion of an intramedullary rod (IM rod). These devices are relatively rigid devices inserted into one end of the bone and down the center canal of the bone shaft, such that the fracture site is bridged. Transverse holes in either end of the IM rod receive screws inserted transversely through the bone in order to lock the two bone fragments relative to one another. The insertion of the screws farthest from the IM rod insertion hole is currently a difficult and time consuming procedure requiring numerous x-ray images. An intraoperative x-ray machine (C-arm) is repeatedly fired and reoriented until it is exactly aligned with the transverse holes as evidenced by x-ray images displaying the holes as “perfect circles”. To establish a starting point, the surgeon uses further x-ray images to align the drill tip with the images of the holes. The surgeon then uses the source-to-receiver axis of the C-arm as an external reference frame along which the long axis of the drill is oriented. Even after this, several attempts may be required to drill the holes into the bone and through the transverse holes.
Several alternative approaches have been employed in an attempt to speed this process. External jigs have been tried with little success because inaccuracies in the jig, inaccuracy of the mounting between jig and IM rod, and deformation of the IM rod accumulate to cause the final jig hole positions to be unreliably aligned with the IM rod holes. Radiolucent drills and drill guides and laser sighting devices have been developed which, in the best cases, improve the speed and accuracy of hole placement, but still require a significant number of x-ray images to be obtained in order to first achieve a C-arm orientation that produces “perfect circles” in the images.
Image-guided approaches have been developed, but these too require the “perfect circle” alignment of the C-arm. Most image guided systems display the drill trajectory over “perfect circle” images of the IM rod. One system assists the surgeon in correctly orienting the C-arm to obtain “perfect circles”: “Surgical Navigation Based on Fluoroscopy Clinical Application for Computer-Assisted Distal Locking of Intramedullary Implants”, Suhm, et. al., Computer Aided Surgery 5:391-400, 2000. Another difficulty with existing image guided systems is that the surgeon must align the drill guide while viewing an “end on” representation of the drill guide, which can be quite challenging.
Several devices have been described (U.S. Pat. Nos. 5,411,503, 5,540,691, 6,074,394, 6,081,741) in which an emitter is inserted into the IM rod, down to the level of the interlocking holes, and transducers on the drill guide report the position of the drill trajectory relative to the holes. These devices, however, require equipment dedicated to this one surgical task, require the extra step of inserting an emitter to the level of the hole, and typically provide only rudimentary “end on” representations of the drill trajectory.
U.S. Pat. No. 6,285,902, incorporated herein by reference, entitled “Computer Assisted Targeting Device for Use in Orthopaedic Surgery” describes a system in which, preferably, orthopaedic surgical tools outfitted with infrared LEDs are tracked by an optical localizing device. The poses of these tools are determined and graphic representations of the tools are superimposed on standard intraoperative x-ray images. This allows the surgeon to view, in real time, the position of the tool or tools with respect to an imaged body part or another tool or tools. In the preferred embodiment, a drill guide outfitted with infrared LEDs is tracked and the trajectory of its bore is displayed on the x-ray image of the involved bone. This allows a surgeon to accurately predict the trajectory of a guide pin that passes through the bore of the drill guide. The guide pin, once inserted, is used as a reference for the insertion of implantable cannulated screws.
An alternative embodiment of the previous invention, described in the referenced patent, allows its use in the insertion of distal interlocking screws in an intramedullary (IM) rod by displaying the drill guide trajectory relative to a computer generated representation of a cross-section of the IM rod. The current invention is an enhancement to the previous invention that adjusts the graphic representations of the IM rod based on information developed from the x-ray images. This facilitates the more accurate alignment of a drill through the holes and eliminates the need to align the x-ray beam with the holes in the IM rod. This can significantly reduce the amount of radiation involved in the procedure and reduce the time required to insert the screws.
Accordingly, one objective of the present invention is to provide a computer assisted surgery system for positioning an instrument relative to a portion of a surgical implant. More specifically, it assists a surgeon in drilling a hole through a long bone and through transversely oriented holes in an intramedullary rod (IM rod) during a fracture fixation procedure regardless of deformation of the IM rod.
Another objective of the invention is to provide a technique and apparatus for accurately displaying the trajectory of the drill relative to the holes of the IM rod.
Still another objective of the invention is to provide a technique and apparatus for using x-ray images of the IM rod to accurately determine the locations of the holes.
These and other objects of the present invention are achieved by the use of a computer assisted surgery system, including a computer, a localizing device and a display monitor. The system also includes a tracked adapter attached to the IM rod and a drill guide, both of which have their poses determined by the localizer. With the IM rod inserted in a long bone, and the tracked adapter attached to the exposed end of the IM rod the pose of the adapter and the IM rod are measured by the localizing device. Two approximately orthogonal x-ray images are then obtained of the IM rod in the vicinity of the holes. Image processing techniques are used to accurately determine the location of the IM rod from the x-ray images and an adjusted pose is calculated for the IM rod. A graphic representation of the drill trajectory is displayed superimposed over the images of the IM rod and over a graphic representation of the IM rod, in order to assist the surgeon in placing the drill in the proper position relative to the IM rod holes.
An embodiment of the image guided system of U.S. Pat. No. 6,285,902 teaches a system for placing distal interlocking screws in an IM rod. As shown in
The current invention improves upon the previous invention by providing greater accuracy in generating the graphic representations (124) of the IM rod (130) relative to the drill guide (128), regardless of bending of the IM rod (130) or minor errors in attaching the adapter (129) to the IM rod (130). This improvement allows the surgeon to use these relative graphic representations (124 and 123) alone to exactly align the drill guide (128) in the axial plane. While the surgeon still uses the AP view (126) to align the drill guide (128) in the coronal plane, there is no longer a need to rely on the lateral view (125), thus avoiding the difficulty of positioning a drill guide (128) using an “end-on” representation, during the axial alignment of the trajectory. It also eliminates the need for the surgeon to estimate the required anteroposterior position of the drill guide tip based on the distance between the IM rod and the femoral shaft cortex and the amount of axial rotation of the IM rod. In the preferred embodiment, the IM rod (130) is inserted in the long bone (133) in the usual manner. While the invention will be preferably described for drilling holes in the bone (133) for the interlocking holes (131) in the end of the IM rod farthest from the exposed end, the system may be alternately used for all interlocking screws and associated implants. As shown in
With the tracking device (129) attached to the IM rod (130) and its pose being read by the localizing device, a graphic representation of the IM rod (130) is projected onto the picture plane (138) defined by coordinate frame G. Because the picture plane (138) is defined to be substantially perpendicular to the long axis of the IM rod (130), the image projected on it will be an “end-view” of the IM rod graphic representation. This end-view image is projected onto the picture plane (138) and, as shown in
If the acquired image is determined to be an AP view then, as shown in
If the acquired image is determined to be a lateral view then the software will optionally generate a lateral version of the graphic representation (144) of the transverse holes (131). This graphic representation (144) comprises two circles representing the openings of the two holes. It is overlaid on the transverse holes (141) seen in the lateral image (125) to improve the surgeons ability to identify the starting point for the drill. However, this is of less importance when compared to the utility of the cross-sectional graphic (127).
Alternatively, the graphic representation (124, 144 and 145) of the IM rod (131) may take other forms including 3-D surface models, bitmaps, or other wireframe models. Any version of the graphic representations (124, 144 and 145), regardless of view orientation, that provides the surgeon with sufficient information to orient the drill guide (128) relative to the IM rod (130) in a given plane may be used without departing from the instant invention.
Additionally, as each image is acquired, adjustment of the position of the graphic representation (124, 144, and 145) of the IM rod (130) is performed to correct for any deviation due to flexure of the IM rod (131) or inaccuracies in attachment of the tracking device (129) or other conditions leading to inaccuracies in localizing the IM rod (130). Turning to
When the difference value for AP, lateral, or both images have been processed, the corresponding Z frame x-axis and y-axis components are calculated by techniques known in the art. These difference components are then used to develop an adjustment transformation. Returning to
Alternately, the overlay of the graphic representations (124, 144 and 145) may be corrected by the translation of coordinate frame A instead of by rotation. Or, instead, the graphic representations (124, 144 and 145) could be altered to effect the correction. For example, if the total difference is attributed to bending of the rod, the coordinate frame A could be left unchanged and the graphic representations (123, 144 and 145) could be altered to simulate the flexure of the IM rod (130). Any correction means that uses the difference between the expected and actual positions of the IM rod (130) to modify its graphic representation in such a way to make it more accurate may be used without departing from the instant invention.
In summary, the software steps required are shown in
While the above description relates to the placement of interlocking screws in intramedullary rods placed in long bones, persons skilled in the art will recognize the applicability of this invention to other devices in other locations of the body such as the insertion of screws into other implantable devices. Any procedure wherein a first device is positioned relative to a second device at a position that is not known with sufficient accuracy by use of a localizing device can be performed in a more accurate manner with this invention.