Dose-Volume Parameters to the Urinary Tract Sub-Volumes and Predictors of Genitourinary Acute Toxicity in a Phase 2 Clinical Trial Assessing MRI-Guided Prostate Boost for Localized Prostate Cancer - The Miami BlastM Trial.

Abstract

The relationship between radiotherapy dose to the sub-volumes of the genitourinary (GU) tract and GU toxicity is poorly understood, particularly in prostate cancer patients treated with an intraprostatic dominant lesion (IDL) boost. While the use of IDL boost improves outcomes, it results in higher doses to GU structures and potentially increased toxicity. We investigated the association between dose-volume histogram (DVH) parameters for urinary tract sub-volumes and GU toxicity in the context of IDL boost in patients enrolled in the Miami BlastM Trial. DVH data were assessed for patients enrolled in the Miami BlastM, a randomized phase 2 trial (NCT20140627) evaluating upfront versus integrated IDL boost. IDL GTV boost consisted of either 12-14 Gy administered on day 1 or integrated boost of 2.4 Gy per fraction (91.2 Gy total, 98.5 Gy 2.0 Equiv), with the prostate receiving 76 Gy in 38 fractions. Bladder trigone (BTg) and urethra sub-volumes were contoured retrospectively on planning CT scans. GU toxicity was assessed using Common Toxicity Criteria for Adverse Events (CTCAE) version 4 and International Prostate Symptom Score (IPSS). DVHs of the bladder, BTg, bladder minus BTg, prostatic urethra, and bulbomembranous urethra were examined. The primary composite endpoint was CTCAE GU acute toxicity grade (G) ≥2 and/or IPSS increase of ≥10 from baseline. Secondary endpoints were GU acute toxicity G≥2, GU late toxicity G≥2, and IPSS increase of ≥10 from baseline. Univariable and multivariable logistic regression analyses were performed. A total of 129 patients treated between February 2015 and January 2022 were eligible for analysis. One hundred and one (78%) patients developed either GU acute toxicity G≥2 (68%) and/or an IPSS increase of ≥10 from baseline (30%). Less than 2% of patients developed GU toxicity G≥3. BTg V30 Gy was significantly associated with IPSS increase ≥10 (p = 0.046). The bulbomembranous urethral maximum dose was significantly associated with GU acute toxicity G≥2 and GU late toxicity G≥2 (p <0.05 for both). Average maximum and mean urethral doses were 88.9 and 81.5 Gy, respectively. The BTg maximum dose, V20 Gy, V30 Gy, and V40 Gy were not significantly associated with the primary composite endpoint (p = 0.56, 0.75, 0.89, 0.82, respectively). On multivariable analysis, a higher bulbomembranous urethral maximum dose was significantly associated with GU acute toxicity G≥2 and/or IPSS increase of ≥10 from baseline (p = 0.019). Our data suggest a dose-effect relationship between maximum doses to the bulbomembranous urethra and GU toxicity. A better understanding of RT-related changes to specific sub-volumes of the urethra and strategies to mitigate urethral dose could enhance the therapeutic ratio in prostate cancer patients treated with MRI-guided IDL boost.