Jenghwa Chang1,2. 1. Department of Radiation Medicine, Northwell Health and Hofstra Northwell School of Medicine at Hofstra University, 450 Lakeville Road, Lake Success, NY, 11042, USA. 2. Department of Physics and Astronomy, Hofstra University, 151 Hofstra University, Hempstead, NY, 11549, USA.
Abstract
PURPOSE: To develop a statistical model that incorporates the treatment uncertainty from the rotational error of the single isocenter for multiple targets technique, and calculates the extra PTV (planning target volume) margin required to compensate for this error. METHODS: The random vector for modeling the setup (S) error in the three-dimensional (3D) patient coordinate system was assumed to follow a 3D normal distribution with a zero mean, and standard deviations of σx , σy , σz . It was further assumed that the rotation of clinical target volume (CTV) about the isocenter happens randomly and follows a three-dimensional (3D) independent normal distribution with a zero mean and a uniform standard deviation of σδ . This rotation leads to a rotational random error (R), which also has a 3D independent normal distribution with a zero mean and a uniform standard deviation of σR equal to the product of σδπ180 and dI⇔T, the distance between the isocenter and CTV. Both (S and R) random vectors were summed, normalized, and transformed to the spherical coordinates to derive the Chi distribution with three degrees of freedom for the radial coordinate of S+R. PTV margin was determined using the critical value of this distribution for a 0.05 significance level so that 95% of the time the treatment target would be covered by the prescription dose. The additional PTV margin required to compensate for the rotational error was calculated as a function of σR and dI⇔T. RESULTS: The effect of the rotational error is more pronounced for treatments that require high accuracy/precision like stereotactic radiosurgery (SRS) or stereotactic body radiotherapy (SBRT). With a uniform 2-mm PTV margin (or σx = σy = σz = 0.715 mm), a σR = 0.328 mm will decrease the CTV coverage probability from 95.0% to 90.9%, or an additional 0.2-mm PTV margin is needed to prevent this loss of coverage. If we choose 0.2 mm as the threshold, any σR > 0.328 mm will lead to an extra PTV margin that cannot be ignored, and the maximal σδ that can be ignored is 0.45° (or 0.0079rad ) for dI⇔T = 50 mm or 0.23° (or 0.004rad ) for dI⇔T = 100 mm. CONCLUSIONS: The rotational error cannot be ignored for high-accuracy/-precision treatments like SRS/SBRT, particularly when the distance between the isocenter and target is large.
PURPOSE: To develop a statistical model that incorporates the treatment uncertainty from the rotational error of the single isocenter for multiple targets technique, and calculates the extra PTV (planning target volume) margin required to compensate for this error. METHODS: The random vector for modeling the setup (S) error in the three-dimensional (3D) patient coordinate system was assumed to follow a 3D normal distribution with a zero mean, and standard deviations of σx , σy , σz . It was further assumed that the rotation of clinical target volume (CTV) about the isocenter happens randomly and follows a three-dimensional (3D) independent normal distribution with a zero mean and a uniform standard deviation of σδ . This rotation leads to a rotational random error (R), which also has a 3D independent normal distribution with a zero mean and a uniform standard deviation of σR equal to the product of σδπ180 and dI⇔T, the distance between the isocenter and CTV. Both (S and R) random vectors were summed, normalized, and transformed to the spherical coordinates to derive the Chi distribution with three degrees of freedom for the radial coordinate of S+R. PTV margin was determined using the critical value of this distribution for a 0.05 significance level so that 95% of the time the treatment target would be covered by the prescription dose. The additional PTV margin required to compensate for the rotational error was calculated as a function of σR and dI⇔T. RESULTS: The effect of the rotational error is more pronounced for treatments that require high accuracy/precision like stereotactic radiosurgery (SRS) or stereotactic body radiotherapy (SBRT). With a uniform 2-mm PTV margin (or σx = σy = σz = 0.715 mm), a σR = 0.328 mm will decrease the CTV coverage probability from 95.0% to 90.9%, or an additional 0.2-mm PTV margin is needed to prevent this loss of coverage. If we choose 0.2 mm as the threshold, any σR > 0.328 mm will lead to an extra PTV margin that cannot be ignored, and the maximal σδ that can be ignored is 0.45° (or 0.0079rad ) for dI⇔T = 50 mm or 0.23° (or 0.004rad ) for dI⇔T = 100 mm. CONCLUSIONS: The rotational error cannot be ignored for high-accuracy/-precision treatments like SRS/SBRT, particularly when the distance between the isocenter and target is large.
Authors: Nzhde Agazaryan; Steve Tenn; Chul Lee; Michael Steinberg; John Hegde; Robert Chin; Nader Pouratian; Isaac Yang; Won Kim; Tania Kaprealian Journal: Radiat Oncol Date: 2021-11-17 Impact factor: 3.481