PURPOSE: The radiation doses received by erectile tissue may contribute to erectile dysfunction after treatment of prostate cancer. This is the first description of the ability to limit the dose received by the penile bulb (PB) and corporal bodies (CB) using intensity-modulated radiotherapy (IMRT). METHODS AND MATERIALS: Twenty-three patients with palpation Stage T1c-T2bN0M0 prostate cancer received IMRT alone. The dose prescribed to the planning target volume was 74-78 Gy. All patients underwent CT and MRI simulation to define the target and normal structures. Three plans with identical beam arrangements and energy were generated for each patient, with varying dose constraints for the PB and CB: no dose constraint, intermediate-dose constraint (20 Gy and 15 Gy, respectively) and low-dose constraint (15 Gy and 7 Gy, respectively). All plans were normalized, such that 95% of the planning target volume received at least 100% of the prescribed dose. For each plan, the ability to meet prostate dose homogeneity criteria (PHC; prostate maximal dose </=120% prescribed dose) and rectal tolerance dose-volume histogram criteria (RTC; </=35% and </=17% of rectal volume received 40 Gy and 65 Gy, respectively) was determined. The D(90), V(50), and V(75) were determined for both PB and the CB, where D(i) was the dose received by i% of the target volume and V(i) was the target volume receiving i% of the prescribed dose. RESULTS: The median PB D(90), V(50), and V(75) for the plans with no dose, intermediate-dose, and low-dose constraints was 20.8 Gy, 33.8%, and 9.9%; 8.0 Gy, 1.7%, and 0%; and 7.1 Gy, 0.1%, and 0%, respectively. The median CB D(90), V(50), and V(75) for plans with no dose, intermediate-dose, and low-dose constraints was 10.2 Gy, 3.8%, and 0%; 6.0 Gy, 0%, and 0%; and 4.9 Gy, 0%, and 0%, respectively. Overall differences in the D(90), V(50), and V(75) among the groups were significant for both the PB and the CB (p <0.0001). All plans with no dose constraint met the PHC and RTC. Twenty plans with an intermediate-dose constraint met the PHC and 21 met the RTC. Eighteen plans with a low-dose constraint met the PHC and 19 met the RTC. No statistically significant difference was found in the number of beam segments for the three groups (median of 51, 55, and 53; p = 0.8). CONCLUSION: In the vast majority of cases, it is possible to limit the dose to erectile tissue with IMRT, usually by >/=50% without significantly compromising the PHC, RTC, or treatment duration. A Phase III randomized trial has been designed to test the clinical significance of the erectile tissue-sparing technique described here.
RCT Entities:
PURPOSE: The radiation doses received by erectile tissue may contribute to erectile dysfunction after treatment of prostate cancer. This is the first description of the ability to limit the dose received by the penile bulb (PB) and corporal bodies (CB) using intensity-modulated radiotherapy (IMRT). METHODS AND MATERIALS: Twenty-three patients with palpation Stage T1c-T2bN0M0 prostate cancer received IMRT alone. The dose prescribed to the planning target volume was 74-78 Gy. All patients underwent CT and MRI simulation to define the target and normal structures. Three plans with identical beam arrangements and energy were generated for each patient, with varying dose constraints for the PB and CB: no dose constraint, intermediate-dose constraint (20 Gy and 15 Gy, respectively) and low-dose constraint (15 Gy and 7 Gy, respectively). All plans were normalized, such that 95% of the planning target volume received at least 100% of the prescribed dose. For each plan, the ability to meet prostate dose homogeneity criteria (PHC; prostate maximal dose </=120% prescribed dose) and rectal tolerance dose-volume histogram criteria (RTC; </=35% and </=17% of rectal volume received 40 Gy and 65 Gy, respectively) was determined. The D(90), V(50), and V(75) were determined for both PB and the CB, where D(i) was the dose received by i% of the target volume and V(i) was the target volume receiving i% of the prescribed dose. RESULTS: The median PB D(90), V(50), and V(75) for the plans with no dose, intermediate-dose, and low-dose constraints was 20.8 Gy, 33.8%, and 9.9%; 8.0 Gy, 1.7%, and 0%; and 7.1 Gy, 0.1%, and 0%, respectively. The median CB D(90), V(50), and V(75) for plans with no dose, intermediate-dose, and low-dose constraints was 10.2 Gy, 3.8%, and 0%; 6.0 Gy, 0%, and 0%; and 4.9 Gy, 0%, and 0%, respectively. Overall differences in the D(90), V(50), and V(75) among the groups were significant for both the PB and the CB (p <0.0001). All plans with no dose constraint met the PHC and RTC. Twenty plans with an intermediate-dose constraint met the PHC and 21 met the RTC. Eighteen plans with a low-dose constraint met the PHC and 19 met the RTC. No statistically significant difference was found in the number of beam segments for the three groups (median of 51, 55, and 53; p = 0.8). CONCLUSION: In the vast majority of cases, it is possible to limit the dose to erectile tissue with IMRT, usually by >/=50% without significantly compromising the PHC, RTC, or treatment duration. A Phase III randomized trial has been designed to test the clinical significance of the erectile tissue-sparing technique described here.
Authors: Robin Krol; Robert Jan Smeenk; Emile N J T van Lin; Eric E K Yeoh; Wim P M Hopman Journal: Int J Colorectal Dis Date: 2013-10-23 Impact factor: 2.571
Authors: Lanea M M Keller; Mark K Buyyounouski; Dennis Sopka; Karen Ruth; Tracy Klayton; Alan Pollack; Deborah Watkins-Bruner; Richard Greenberg; Robert Price; Eric M Horwitz Journal: Urology Date: 2012-06-29 Impact factor: 2.649
Authors: Natasha C Townsend; Karen Ruth; Tahseen Al-Saleem; Eric M Horwitz; Mark Sobczak; Robert G Uzzo; Rosalia Viterbo; Mark K Buyyounouski Journal: J Natl Compr Canc Netw Date: 2013-07 Impact factor: 11.908
Authors: Carri K Glide-Hurst; Eric S Paulson; Kiaran McGee; Neelam Tyagi; Yanle Hu; James Balter; John Bayouth Journal: Med Phys Date: 2021-07 Impact factor: 4.071
Authors: Olusola Obayomi-Davies; Leonard N Chen; Aditi Bhagat; Henry C Wright; Sunghae Uhm; Joy S Kim; Thomas M Yung; Siyuan Lei; Gerald P Batipps; John Pahira; Kevin G McGeagh; Brian T Collins; Keith Kowalczyk; Gaurav Bandi; Deepak Kumar; Simeng Suy; Anatoly Dritschilo; John H Lynch; Sean P Collins Journal: Radiat Oncol Date: 2013-11-01 Impact factor: 3.481