Real-time catheter tracking for high-dose-rate prostate brachytherapy using an electromagnetic 3D-guidance device: a preliminary performance study.

PURPOSE In order to increase the accuracy and speed of catheter reconstruction in a high-dose-rate (HDR) prostate implant procedure, an automatic tracking system has been developed using an electromagnetic (EM) device (trakSTAR, Ascension Technology, VT). The performance of the system, including the accuracy and noise level with various tracking parameters and conditions, were investigated. METHODS A direct current (dc) EM transmitter (midrange model) and a sensor with diameter of 1.3 mm (Model 130) were used in the trakSTAR system for tracking catheter position during HDR prostate brachytherapy. Localization accuracy was assessed under both static and dynamic analyses conditions. For the static analysis, a calibration phantom was used to investigate error dependency on operating room (OR) table height (bottom vs midposition vs top), sensor position (distal tip of catheter vs connector end of catheter), direction [left-right (LR) vs anterior-posterior (AP) vs superior-inferior (SI)], sampling frequency (40 vs 80 vs 120 Hz), and interference from OR equipment (present vs absent). The mean and standard deviation of the localization offset in each direction and the corresponding error vectors were calculated. For dynamic analysis, the paths of five straight catheters were tracked to study the effects of directions, sampling frequency, and interference of EM field. Statistical analysis was conducted to compare the results in different configurations. RESULTS When interference was present in the static analysis, the error vectors were significantly higher at the top table position (3.3 ± 1.3 vs 1.8 ± 0.9 mm at bottom and 1.7 ± 1.0 mm at middle, p < 0.001), at catheter end position (3.1 ± 1.1 vs 1.4 ± 0.7 mm at the tip position, p < 0.001), and at 40 Hz sampling frequency (2.6 ± 1.1 vs 2.4 ± 1.5 mm at 80 Hz and 1.8 ± 1.1 at 160 Hz, p < 0.001). So did the mean offset errors in the LR direction (-1.7 ± 1.4 vs 0.4 ± 0.5 mm in AP and 0.8 ± 0.8 mm in SI directions, p < 0.001). The error vectors were significantly higher with surrounding interference (2.2 ± 1.3 mm) vs without interference (1.0 ± 0.7 mm, p < 0.001). An accuracy of 1.6 ± 0.2 mm can be reached when using optimum configuration (160 Hz at middle table position). When interference was present in the dynamic tracking, the mean tracking errors in LR direction (1.4 ± 0.5 mm) was significantly higher than that in AP direction (0.3 ± 0.2 mm, p < 0.001). So did the mean vector errors at 40 Hz (2.1 ± 0.2 mm vs 1.3 ± 0.2 mm at 80 Hz and 0.9 ± 0.2 mm at 160 Hz, p < 0.05). However, when interference was absent, they were comparable in the both directions and at all sampling frequencies. An accuracy of 0.9 ± 0.2 mm was obtained for the dynamic tracking when using optimum configuration. CONCLUSIONS The performance of an EM tracking system depends highly on the system configuration and surrounding environment. The accuracy of EM tracking for catheter reconstruction in a prostate HDR brachytherapy procedure can be improved by reducing interference from surrounding equipment, decreasing distance from transmitter to tracking area, and choosing appropriated sampling frequency. A calibration scheme is needed to further reduce the tracking error when the interference is high.

[1]  W. Richard Fright,et al.  The Effects of Metals and Interfering Fields on Electromagnetic Trackers , 1998, Presence.

[2]  Bradford J. Wood,et al.  Real-time tracking of liver motion and deformation using a flexible needle , 2010, International Journal of Computer Assisted Radiology and Surgery.

[3]  Assessment of the cervical range of motion over time, differences between results of the Flock of Birds and the EDI-320: a comparison between an electromagnetic tracking system and an electronic inclinometer. , 2008, Manual therapy.

[4]  Ziv Yaniv,et al.  Electromagnetic tracking in the clinical environment. , 2009, Medical physics.

[5]  L. Wilson,et al.  Surgery Versus Implant for Early Prostate Cancer: Results From a Single Institution, 1992–2005 , 2007, Cancer journal.

[6]  R. Peschel,et al.  Surgery, brachytherapy, and external-beam radiotherapy for early prostate cancer. , 2003, The Lancet. Oncology.

[7]  Franz Kainberger,et al.  Quantitative analysis of factors affecting intraoperative precision and stability of optoelectronic and electromagnetic tracking systems. , 2002, Medical physics.

[8]  Frank-André Siebert,et al.  Imaging of implant needles for real-time HDR-brachytherapy prostate treatment using biplane ultrasound transducers. , 2009, Medical physics.

[9]  W. Kalender,et al.  Robot arm based flat panel CT-guided electromagnetic tracked spine interventions: phantom and animal model experiments , 2010, European Radiology.

[10]  Gabriel Zachmann,et al.  Distortion correction of magnetic fields for position tracking , 1997, Proceedings Computer Graphics International.

[11]  H Bergmann,et al.  Systematic distortions in magnetic position digitizers. , 1998, Medical physics.

[12]  Suzanne LaScalza,et al.  Effect of metal and sampling rate on accuracy of Flock of Birds electromagnetic tracking system. , 2003, Journal of biomechanics.

[13]  P. Ludewig,et al.  Comparative shoulder kinematics during free standing, standing depression lifts and daily functional activities in persons with paraplegia: considerations for shoulder health , 2008, Spinal Cord.

[14]  M Bolla,et al.  EAU guidelines on prostate cancer. , 2001, European urology.

[15]  John G. Hagedorn,et al.  Correction of Location and Orientation Errors in Electromagnetic Motion Tracking , 2007, PRESENCE: Teleoperators and Virtual Environments.

[16]  Marco A. Zenati,et al.  A Miniature Mobile Robot for Navigation and Positioning on the Beating Heart , 2009, IEEE Transactions on Robotics.

[17]  Gabor Fichtinger,et al.  Characterization of ultrasound elevation beamwidth artifacts for prostate brachytherapy needle insertion. , 2011, Medical physics.

[18]  Evaluation of a novel 4D in vivo dosimetry system. , 2009, Medical physics.

[19]  Kyle B. Reed,et al.  Mechanics of Flexible Needles Robotically Steered through Soft Tissue , 2010, Int. J. Robotics Res..

[20]  J. Peters,et al.  Task-specific rehabilitation of finger-hand function using interactive computer gaming. , 2008, Archives of physical medicine and rehabilitation.

[21]  Raúl San José Estépar,et al.  Towards scarless surgery: An endoscopic ultrasound navigation system for transgastric access procedures , 2007, Computer aided surgery : official journal of the International Society for Computer Aided Surgery.

[22]  Wolfgang Birkfellner,et al.  Evaluation of a miniature electromagnetic position tracker. , 2002, Medical physics.

[23]  Bernard D. Adelstein,et al.  Dynamic Response of Electromagnetic Spatial Displacement Trackers , 1996, Presence: Teleoperators & Virtual Environments.

[24]  A. Renshaw,et al.  Biochemical Outcome after radical prostatectomy, external beam Radiation Therapy, or interstitial Radiation therapy for clinically localized prostate cancer , 1998 .

[25]  Hartmut Dickhaus,et al.  Quantification of the segmental kinematics of spontaneous infant movements. , 2008, Journal of biomechanics.