Dmitri Nichiporov1, Wen Hsi, Jonathan Farr. 1. Indiana University Integrated Science and Accelerator Technology Hall, Bloomington, IN 47408, USA. nichipor@indiana.edu
Abstract
PURPOSE: To compare clinically relevant dosimetric characteristics of proton therapy fields produced by two uniform scanning systems that have a number of similar hardware components but employ different techniques of beam spreading. METHODS: This work compares two technologically distinct systems implementing a method of uniform scanning and layer stacking that has been developed independently at Indiana University (IU) and by Ion Beam Applications, S. A. (IBA). Clinically relevant dosimetric characteristics of fields produced by these systems are studied, such as beam range control, peak-to-entrance ratio (PER), lateral penumbra, field flatness, effective source position, precision of dose delivery at different gantry angles, etc. RESULTS: Under comparable conditions, both systems controlled beam range with an accuracy of 0.5 mm and a precision of 0.1 mm. Compared to IBA, the IU system produced pristine peaks with a slightly higher PER (3.23 and 3.45, respectively) and smaller, symmetrical, lateral in-air penumbra of 1 mm compared to about 1.9/2.4 mm in the inplane/crossplane (IP/CP) directions for IBA. Large field flatness results in the IP/CP directions were similar: 3.0/2.4% for IU and 2.9/2.4% for IBA. The IU system featured a longer virtual source-to-isocenter position, which was the same for the IP and CP directions (237 cm), as opposed to 212/192 cm (IP/CP) for IBA. Dose delivery precision at different gantry angles was higher in the IBA system (0.5%) than in the IU system (1%). CONCLUSIONS: Each of the two uniform scanning systems considered in this work shows some attractive performance characteristics while having other features that can be further improved. Overall, radiation field characteristics of both systems meet their clinical specifications and show comparable results. Most of the differences observed between the two systems are clinically insignificant.
PURPOSE: To compare clinically relevant dosimetric characteristics of proton therapy fields produced by two uniform scanning systems that have a number of similar hardware components but employ different techniques of beam spreading. METHODS: This work compares two technologically distinct systems implementing a method of uniform scanning and layer stacking that has been developed independently at Indiana University (IU) and by Ion Beam Applications, S. A. (IBA). Clinically relevant dosimetric characteristics of fields produced by these systems are studied, such as beam range control, peak-to-entrance ratio (PER), lateral penumbra, field flatness, effective source position, precision of dose delivery at different gantry angles, etc. RESULTS: Under comparable conditions, both systems controlled beam range with an accuracy of 0.5 mm and a precision of 0.1 mm. Compared to IBA, the IU system produced pristine peaks with a slightly higher PER (3.23 and 3.45, respectively) and smaller, symmetrical, lateral in-air penumbra of 1 mm compared to about 1.9/2.4 mm in the inplane/crossplane (IP/CP) directions for IBA. Large field flatness results in the IP/CP directions were similar: 3.0/2.4% for IU and 2.9/2.4% for IBA. The IU system featured a longer virtual source-to-isocenter position, which was the same for the IP and CP directions (237 cm), as opposed to 212/192 cm (IP/CP) for IBA. Dose delivery precision at different gantry angles was higher in the IBA system (0.5%) than in the IU system (1%). CONCLUSIONS: Each of the two uniform scanning systems considered in this work shows some attractive performance characteristics while having other features that can be further improved. Overall, radiation field characteristics of both systems meet their clinical specifications and show comparable results. Most of the differences observed between the two systems are clinically insignificant.
Authors: Dmitri Nichiporov; Keith Solberg; Wen Hsi; Mark Wolanski; Anthony Mascia; Jonathan Farr; Andries Schreuder Journal: Med Phys Date: 2007-07 Impact factor: 4.071
Authors: J B Farr; A E Mascia; W C Hsi; C E Allgower; F Jesseph; A N Schreuder; M Wolanski; D F Nichiporov; V Anferov Journal: Med Phys Date: 2008-11 Impact factor: 4.071
Authors: F M Khan; K P Doppke; K R Hogstrom; G J Kutcher; R Nath; S C Prasad; J A Purdy; M Rozenfeld; B L Werner Journal: Med Phys Date: 1991 Jan-Feb Impact factor: 4.071
Authors: Wen C Hsi; Michael F Moyers; Dmitri Nichiporov; Vladimir Anferov; Mark Wolanski; Chris E Allgower; Jonathan B Farr; Anthony E Mascia; Andries N Schreuder Journal: Med Phys Date: 2009-06 Impact factor: 4.071