PURPOSE: In external-beam radiation therapy, existing on-board x-ray imaging chains orthogonal to the delivery beam cannot recover 3D target trajectories from a single view in real-time. This limits their utility for real-time motion management concurrent with beam delivery. To address this limitation, the authors propose a novel concept for on-board imaging based on the inverse-geometry Scanning-Beam Digital X-ray (SBDX) system and evaluate its feasibility for single-view 3D intradelivery fiducial tracking. METHODS: A chest phantom comprising a posterior wall, a central lung volume, and an anterior wall was constructed. Two fiducials were placed along the mediastinal ridge between the lung cavities: a 1.5 mm diameter steel sphere superiorly and a gold cylinder (2.6 mm length × 0.9 mm diameter) inferiorly. The phantom was placed on a linear motion stage that moved sinusoidally. Fiducial motion was along the source-detector (z) axis of the SBDX system with ±10 mm amplitude and a programmed period of either 3.5 s or 5 s. The SBDX system was operated at 15 frames per second, 100 kVp, providing good apparent conspicuity of the fiducials. With the stage moving, detector data were acquired and subsequently reconstructed into 15 planes with a 12 mm plane-to-plane spacing using digital tomosynthesis. A tracking algorithm was applied to the image planes for each temporal frame to determine the position of each fiducial in (x,y,z)-space versus time. A 3D time-sinusoidal motion model was fit to the measured 3D coordinates and root mean square (RMS) deviations about the fitted trajectory were calculated. RESULTS: Tracked motion was sinusoidal and primarily along the source-detector (z) axis. The RMS deviation of the tracked z-coordinate ranged from 0.53 to 0.71 mm. The motion amplitude derived from the model fit agreed with the programmed amplitude to within 0.28 mm for the steel sphere and within -0.77 mm for the gold seed. The model fit periods agreed with the programmed periods to within 7%. CONCLUSIONS: Three dimensional fiducial tracking with approximately 1 mm or better accuracy and precision appears to be feasible with SBDX, supporting its use to guide radiotherapy.
PURPOSE: In external-beam radiation therapy, existing on-board x-ray imaging chains orthogonal to the delivery beam cannot recover 3D target trajectories from a single view in real-time. This limits their utility for real-time motion management concurrent with beam delivery. To address this limitation, the authors propose a novel concept for on-board imaging based on the inverse-geometry Scanning-Beam Digital X-ray (SBDX) system and evaluate its feasibility for single-view 3D intradelivery fiducial tracking. METHODS: A chest phantom comprising a posterior wall, a central lung volume, and an anterior wall was constructed. Two fiducials were placed along the mediastinal ridge between the lung cavities: a 1.5 mm diameter steel sphere superiorly and a gold cylinder (2.6 mm length × 0.9 mm diameter) inferiorly. The phantom was placed on a linear motion stage that moved sinusoidally. Fiducial motion was along the source-detector (z) axis of the SBDX system with ±10 mm amplitude and a programmed period of either 3.5 s or 5 s. The SBDX system was operated at 15 frames per second, 100 kVp, providing good apparent conspicuity of the fiducials. With the stage moving, detector data were acquired and subsequently reconstructed into 15 planes with a 12 mm plane-to-plane spacing using digital tomosynthesis. A tracking algorithm was applied to the image planes for each temporal frame to determine the position of each fiducial in (x,y,z)-space versus time. A 3D time-sinusoidal motion model was fit to the measured 3D coordinates and root mean square (RMS) deviations about the fitted trajectory were calculated. RESULTS: Tracked motion was sinusoidal and primarily along the source-detector (z) axis. The RMS deviation of the tracked z-coordinate ranged from 0.53 to 0.71 mm. The motion amplitude derived from the model fit agreed with the programmed amplitude to within 0.28 mm for the steel sphere and within -0.77 mm for the gold seed. The model fit periods agreed with the programmed periods to within 7%. CONCLUSIONS: Three dimensional fiducial tracking with approximately 1 mm or better accuracy and precision appears to be feasible with SBDX, supporting its use to guide radiotherapy.
Authors: Taly Gilat Schmidt; Josh Star-Lack; N Robert Bennett; Samuel R Mazin; Edward G Solomon; Rebecca Fahrig; Norbert J Pelc Journal: Med Phys Date: 2006-06 Impact factor: 4.071
Authors: Michael A Speidel; Brian P Wilfley; Josh M Star-Lack; Joseph A Heanue; Michael S Van Lysel Journal: Med Phys Date: 2006-08 Impact factor: 4.071
Authors: Michael A Speidel; Brian P Wilfley; Josh M Star-Lack; Joseph A Heanue; Timothy D Betts; Michael S Van Lysel Journal: Med Phys Date: 2006-08 Impact factor: 4.071
Authors: Catherine A McBain; Ann M Henry; Jonathan Sykes; Ali Amer; Tom Marchant; Christopher M Moore; Julie Davies; Julia Stratford; Claire McCarthy; Bridget Porritt; Peter Williams; Vincent S Khoo; Pat Price Journal: Int J Radiat Oncol Biol Phys Date: 2005-12-15 Impact factor: 7.038
Authors: H Shirato; S Shimizu; K Kitamura; T Nishioka; K Kagei; S Hashimoto; H Aoyama; T Kunieda; N Shinohara; H Dosaka-Akita; K Miyasaka Journal: Int J Radiat Oncol Biol Phys Date: 2000-09-01 Impact factor: 7.038
Authors: S Shimizu; H Shirato; K Kitamura; N Shinohara; T Harabayashi; T Tsukamoto; T Koyanagi; K Miyasaka Journal: Int J Radiat Oncol Biol Phys Date: 2000-12-01 Impact factor: 7.038
Authors: Mark Oldham; Daniel Létourneau; Lindsay Watt; Geoffrey Hugo; Di Yan; David Lockman; Leonard H Kim; Peter Y Chen; Alvaro Martinez; John W Wong Journal: Radiother Oncol Date: 2005-06 Impact factor: 6.280
Authors: Charles R Hatt; Michael T Tomkowiak; David A P Dunkerley; Jordan M Slagowski; Tobias Funk; Amish N Raval; Michael A Speidel Journal: Med Phys Date: 2015-12 Impact factor: 4.071