PURPOSE: The unique dosimetric features of proton radiotherapy make it an attractive modality for normal tissue sparing. We present our initial experience with protons for three-dimensional, conformal, external-beam accelerated partial breast irradiation (3D-CPBI). METHODS AND MATERIALS: From March 2004 to June 2005, 25 patients with tumors < or =2 cm and negative axillary nodes were treated with proton 3D-CPBI. The prescribed dose was 32 Cobalt Gray Equivalents (CGE) in 4 CGE fractions given twice daily. One to three fields were used to provide adequate planning target volume (PTV) coverage and dose homogeneity. RESULTS: Excellent PTV coverage and dose homogeneity were obtained in all patients with one to three proton beams. The median PTV receiving 95% of the prescribed dose was 100%. Dose inhomogeneity exceeded 10% in only 1 patient (4%). The median volume of nontarget breast tissue receiving 50% of the prescribed dose was 23%. Median volumes of ipsilateral lung receiving 20 CGE, 10 CGE, and 5 CGE were 0%, 1%, and 2%, respectively. The contralateral lung and heart received essentially no radiation dose. Cost analysis suggests that proton 3D-CPBI is only modestly more expensive (25%) than traditional whole-breast irradiation (WBI). CONCLUSION: Proton 3D-CPBI is technically feasible, providing both excellent PTV coverage and normal tissue sparing. It markedly reduces the volume of nontarget breast tissue irradiated compared with photon-based 3D-CPBI, addressing a principle disadvantage of external-beam approaches to PBI. As proton therapy becomes more widely available, it may prove an attractive tool for 3D-CPBI.
PURPOSE: The unique dosimetric features of proton radiotherapy make it an attractive modality for normal tissue sparing. We present our initial experience with protons for three-dimensional, conformal, external-beam accelerated partial breast irradiation (3D-CPBI). METHODS AND MATERIALS: From March 2004 to June 2005, 25 patients with tumors < or =2 cm and negative axillary nodes were treated with proton 3D-CPBI. The prescribed dose was 32 Cobalt Gray Equivalents (CGE) in 4 CGE fractions given twice daily. One to three fields were used to provide adequate planning target volume (PTV) coverage and dose homogeneity. RESULTS: Excellent PTV coverage and dose homogeneity were obtained in all patients with one to three proton beams. The median PTV receiving 95% of the prescribed dose was 100%. Dose inhomogeneity exceeded 10% in only 1 patient (4%). The median volume of nontarget breast tissue receiving 50% of the prescribed dose was 23%. Median volumes of ipsilateral lung receiving 20 CGE, 10 CGE, and 5 CGE were 0%, 1%, and 2%, respectively. The contralateral lung and heart received essentially no radiation dose. Cost analysis suggests that proton 3D-CPBI is only modestly more expensive (25%) than traditional whole-breast irradiation (WBI). CONCLUSION: Proton 3D-CPBI is technically feasible, providing both excellent PTV coverage and normal tissue sparing. It markedly reduces the volume of nontarget breast tissue irradiated compared with photon-based 3D-CPBI, addressing a principle disadvantage of external-beam approaches to PBI. As proton therapy becomes more widely available, it may prove an attractive tool for 3D-CPBI.
Authors: Laura E G Warren; Cynthia L Miller; Nora Horick; Melissa N Skolny; Lauren S Jammallo; Betro T Sadek; Mina N Shenouda; Jean A O'Toole; Shannon M MacDonald; Michelle C Specht; Alphonse G Taghian Journal: Int J Radiat Oncol Biol Phys Date: 2014-01-07 Impact factor: 7.038
Authors: Xiaochun Wang; Richard A Amos; Xiaodong Zhang; Phillip J Taddei; Wendy A Woodward; Karen E Hoffman; Tse Kuan Yu; Welela Tereffe; Julia Oh; George H Perkins; Mohammad Salehpour; Sean X Zhang; Tzou Liang Sun; Michael Gillin; Thomas A Buchholz; Eric A Strom Journal: Int J Radiat Oncol Biol Phys Date: 2010-08-12 Impact factor: 7.038
Authors: Chia-Chun Wang; Aimee L McNamara; Jungwook Shin; Jan Schuemann; Clemens Grassberger; Alphonse G Taghian; Rachel B Jimenez; Shannon M MacDonald; Harald Paganetti Journal: Int J Radiat Oncol Biol Phys Date: 2020-03-30 Impact factor: 7.038
Authors: Douglas W Arthur; Kathryn Winter; Robert R Kuske; John Bolton; Rachel Rabinovitch; Julia White; William F Hanson; Raymond M Wilenzick; Beryl McCormick Journal: Int J Radiat Oncol Biol Phys Date: 2008-03-04 Impact factor: 7.038