STUDY DESIGN: A computer-assisted system allowing precise preoperative planning and real-time intraoperative image localization of surgical instruments is tested in a laboratory setup. OBJECTIVES: The purpose of this study is to assess the applicability, functionality, and accuracy of this transpedicular spinal fixation technique. SUMMARY OF BACKGROUND DATA: Most techniques in transpedicular spinal fixation rely on the identification of predefined targets with the help of anatomic landmarks and on the intraoperative use of image intensifiers. Various studies report considerable screw misplacement rates which may lead to serious clinical sequelae such as permanent nerve damage. METHODS: The proposed system was tested in an in vitro setup drilling 20 pedicle pilot holes in lumbar vertebrae. The accuracy was assessed using precision cuts through the pedicles and simulation of a 6-mm pedicle screw insertion. RESULTS: An ideal screw position was found in 70 of 77 cuts, and in no case was an injury to the pedicular cortex observed. CONCLUSIONS: The presented technique provides a safe, accurate, and flexible basis for transpedicular screw placement in the spine. This approach should be further evaluated in clinical applications.
STUDY DESIGN: A computer-assisted system allowing precise preoperative planning and real-time intraoperative image localization of surgical instruments is tested in a laboratory setup. OBJECTIVES: The purpose of this study is to assess the applicability, functionality, and accuracy of this transpedicular spinal fixation technique. SUMMARY OF BACKGROUND DATA: Most techniques in transpedicular spinal fixation rely on the identification of predefined targets with the help of anatomic landmarks and on the intraoperative use of image intensifiers. Various studies report considerable screw misplacement rates which may lead to serious clinical sequelae such as permanent nerve damage. METHODS: The proposed system was tested in an in vitro setup drilling 20 pedicle pilot holes in lumbar vertebrae. The accuracy was assessed using precision cuts through the pedicles and simulation of a 6-mm pedicle screw insertion. RESULTS: An ideal screw position was found in 70 of 77 cuts, and in no case was an injury to the pedicular cortex observed. CONCLUSIONS: The presented technique provides a safe, accurate, and flexible basis for transpedicular screw placement in the spine. This approach should be further evaluated in clinical applications.
Authors: Ilker Hacihaliloglu; David R Wilson; Michael Gilbart; Michael A Hunt; Purang Abolmaesumi Journal: Int J Comput Assist Radiol Surg Date: 2012-05-25 Impact factor: 2.924