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PurposeNodal recurrent prostate cancer (PCa) represents a common state of disease, amenable to local therapy. PSMA-PET/CT detects PCa recurrence at low PSA levels. The aim of this study was to evaluate the outcome of PSMA-PET/CT-based salvage radiotherapy (sRT) for lymph node (LN) recurrence.MethodsA total of 100 consecutive patients treated with PSMA-PET/CT-based salvage elective nodal radiotherapy (sENRT) for LN recurrence were retrospectively examined. Patients underwent PSMA-PET/CT scan due to biochemical persistence (bcP, 76%) or biochemical recurrence (bcR, 24%) after radical prostatectomy (RP). Biochemical recurrence-free survival (BRFS) defined as PSA < post-RT nadir + 0.2 ng/ml and distant metastasis-free survival (DMFS) were calculated using the Kaplan–Meier method and uni- and multivariate analysis was performed.ResultsMedian follow-up was 37 months. Median PSA at PSMA-PET/CT was 1.7 ng/ml (range 0.1–40.1) in patients with bcP and 1.4 ng/ml (range 0.3–5.1) in patients with bcR. PSMA-PET/CT detected 1, 2, and 3 or more LN metastases in 35%, 23%, and 42%, respectively. Eighty-three percent had only pelvic, 2% had only paraaortic, and 15% had pelvic and paraaortic LN metastases. Cumulatively, a total dose converted to EQD21.5 Gy of 66 Gy (60–70 Gy) was delivered to the prostatic fossa, 70 Gy (66–72 Gy) to the local recurrence, if present, 65.1 Gy (56–66 Gy) to PET-positive lymph nodes, and 47.5 Gy (42.4–50.9 Gy) to the lymphatic pathways. Concomitant androgen deprivation therapy (ADT) was administered in 83% of patients. One-, 2-, and 3-year BRFS was 80.7%, 71.6%, and 65.8%, respectively. One-, 2-, and 3-year DMFS was 91.6%, 79.1%, and 66.4%, respectively. In multivariate analysis, concomitant ADT, longer ADT duration (≥ 12 vs. < 12 months) and LN localization (pelvic vs. paraaortic) were associated with improved BRFS and concomitant ADT and lower PSA value before sRT (< 1 vs. > 1 ng/ml) with improved DMFS, respectively. No such association was seen for the number of affected lymph nodes.ConclusionsOverall, the present analysis shows that the so far, unmatched sensitivity and specificity of PSMA-PET/CT translates in comparably high BRFS and DMFS after PSMA-PET/CT-based sENRT for patients with PCa LN recurrence. Concomitant ADT, duration of ADT, PSA value before sRT, and localization of LN metastases were significant factors for improved outcome.

Background This paper describes the rationale and design of the RECOVER study. Currently, there is no consensus regarding the optimal treatment for high-risk, non-metastatic prostate cancer (PCa). The study primarily aims to evaluate and compare the impact of treatment with robot-assisted radical prostatectomy (RP) versus external beam radiation therapy (EBRT) with androgen deprivation therapy (ADT) for men with high-risk, non-metastatic PCa regarding health-related quality of life (HRQoL) and functional outcomes. Secondary objectives are progression-free survival (PFS), distant metastasis-free survival (DMFS), costs and cost-effectiveness. Methods The RECOVER study is a comparative effectiveness study that prospectively includes newly diagnosed high-risk (cT3a-bN0M0, ISUP-grade ≥ 4 and/or PSA > 20 ng/mL), non-metastatic PCa patients. Four Dutch prostate cancer networks, comprising 29 hospitals, are currently participating in the study. Patient reported outcomes are collected before treatment initiation, 12 months and 36 months after treatment initiation and include the EORTC-QLQ-C30, the EPIC-26, an adapted version of the SCQ, an adapted version of the iMTA Productivity Cost Questionnaire and several specific questions regarding patient characteristics, treatment of PCa specific complaints and health resources used. Clinical data regarding patient-, tumor- and treatment characteristics and oncological outcomes are collected up to 5 years after diagnosis. For sufficient power, patient reported outcomes of 471 patients must be collected 36 months after treatment initiation. Descriptive statistics and mixed-effects models are used to assess differences in HRQoL and functional outcomes over time between the patients treated with radical prostatectomy versus EBRT (+ ADT). Inverse probability of treatment weighting or the g-formula are used to adjust for confounding covariates associated with treatment. Secondary endpoints PFS and DMFS are evaluated using a competing risk analysis and cost-utility and budget-impact analyses will be performed to determine cost and cost-effectiveness. Discussion An observational prospective design was chosen since a randomized controlled trial comparing surgery and radiotherapy was not deemed feasible. This study evaluates effectiveness of treatment in a routine clinical setting (with adjustment for confounding) and its findings will enhance patients’ and healthcare professionals’ awareness for the impact of both treatment modalities on (long-term) daily functioning and HRQoL and aid treatment decision making. Trial registration This study is registered at ClinicalTrials.gov (NCT05931419).

In the ProtecT trial, over 1600 men with PSA-detected localized prostate cancer were assigned to active monitoring, prostatectomy, or radiotherapy. Although more patients assigned to active monitoring had disease progression, overall survival was similar in the three groups. The management of clinically localized prostate cancer that is detected on the basis of prostate-specific antigen (PSA) levels remains controversial. In the United States alone, an estimated 180,890 cases will be diagnosed in 2016, and 26,120 men will die from the disease. 1 The widespread use of PSA testing has resulted in a dramatic increase in the diagnosis and treatment of prostate cancer, but many men do not benefit from intervention because the disease is either indolent or disseminated at diagnosis. Prostate cancer often progresses slowly, and many men die of competing causes. In addition, interventions for prostate cancer can have . . .

The addition of abiraterone, a drug that blocks endogenous androgen synthesis, to standard androgen-deprivation therapy in patients with newly diagnosed, metastatic prostate cancer significantly increased overall survival, with a low rate of adverse effects.

In this study involving 2103 men with elevated PSA levels, the use of both MRI-targeted and 12-core systematic biopsies was more effective at detecting clinically significant prostate cancers than either biopsy method alone.

At 23 years of follow-up in the SPCG-4 trial, mortality among men who underwent radical prostatectomy was 11.7 percentage points lower than that among men whose condition was managed by watchful waiting. Radical prostatectomy was associated with a mean of nearly 3 years of extra life.

Purpose We investigated the oncologic effect of palliative transurethral resection of the prostate (pTURP) in patients with prostate cancer who received primary androgen deprivation therapy. Methods We reviewed 614 patients, including 83 who underwent pTURP; those with incidental prostate cancer were excluded. Patients were divided into the TURP group and non-TURP group. Propensity score matching was performed for comorbidity, initial prostate-specific antigen (PSA), TNM stage, and Gleason score (GS). The Kaplan–Meier method was used to confirm castration-resistant prostate cancer (CRPC), cancer-specific survival (CSS), and overall survival (OS). Cox regression was performed to confirm factors affecting CSS. Results Before matching, the TURP group had a worse TNM stage ( p  < 0.01) and GS ( p  = 0.028) and larger prostate volume (50.1 vs. 39.0 cc, p  = 0.005) than the non-TURP group. The most common reason for pTURP was acute urinary retention. After matching, the TURP group showed worse outcomes in CRPC ( p  = 0.003), CSS ( p  = 0.003), and OS ( p  = 0.026). In multivariate analysis, factors for predicting CSS were a positive core percent [hazard ratio (HR) 1.015, p  = 0.0272], GS (10 vs. ≤8; HR 6.716, p  = 0.0008), and TURP within 3 months after biopsy (HR 2.543, p  = 0.0482). The resection weight (HR 1.000, p  = 0.9730), resection time (HR 1.000, p  = 0.3670), and blood transfusion (HR 0.630, p  = 0.1860) were not associated with CSS. Conclusions The oncologic effect of pTURP as cytoreductive operation seems to be limited. Patients who had to receive pTURP due to cancer-related symptoms, especially early necessity of pTURP (within 3 months after biopsy), showed worse clinical courses; therefore, they should be treated more carefully and actively.

Based on previous findings, we hypothesised that radiotherapy to the prostate would improve overall survival in men with metastatic prostate cancer, and that the benefit would be greatest in patients with a low metastatic burden. We aimed to compare standard of care for metastatic prostate cancer, with and without radiotherapy. We did a randomised controlled phase 3 trial at 117 hospitals in Switzerland and the UK. Eligible patients had newly diagnosed metastatic prostate cancer. We randomly allocated patients open-label in a 1:1 ratio to standard of care (control group) or standard of care and radiotherapy (radiotherapy group). Randomisation was stratified by hospital, age at randomisation, nodal involvement, WHO performance status, planned androgen deprivation therapy, planned docetaxel use (from December, 2015), and regular aspirin or non-steroidal anti-inflammatory drug use. Standard of care was lifelong androgen deprivation therapy, with up-front docetaxel permitted from December, 2015. Men allocated radiotherapy received either a daily (55 Gy in 20 fractions over 4 weeks) or weekly (36 Gy in six fractions over 6 weeks) schedule that was nominated before randomisation. The primary outcome was overall survival, measured as the number of deaths; this analysis had 90% power with a one-sided α of 2·5% for a hazard ratio (HR) of 0·75. Secondary outcomes were failure-free survival, progression-free survival, metastatic progression-free survival, prostate cancer-specific survival, and symptomatic local event-free survival. Analyses used Cox proportional hazards and flexible parametric models, adjusted for stratification factors. The primary outcome analysis was by intention to treat. Two prespecified subgroup analyses tested the effects of prostate radiotherapy by baseline metastatic burden and radiotherapy schedule. This trial is registered with ClinicalTrials.gov, number NCT00268476. Between Jan 22, 2013, and Sept 2, 2016, 2061 men underwent randomisation, 1029 were allocated the control and 1032 radiotherapy. Allocated groups were balanced, with a median age of 68 years (IQR 63–73) and median amount of prostate-specific antigen of 97 ng/mL (33–315). 367 (18%) patients received early docetaxel. 1082 (52%) participants nominated the daily radiotherapy schedule before randomisation and 979 (48%) the weekly schedule. 819 (40%) men had a low metastatic burden, 1120 (54%) had a high metastatic burden, and the metastatic burden was unknown for 122 (6%). Radiotherapy improved failure-free survival (HR 0·76, 95% CI 0·68–0·84; p<0·0001) but not overall survival (0·92, 0·80–1·06; p=0·266). Radiotherapy was well tolerated, with 48 (5%) adverse events (Radiation Therapy Oncology Group grade 3–4) reported during radiotherapy and 37 (4%) after radiotherapy. The proportion reporting at least one severe adverse event (Common Terminology Criteria for Adverse Events grade 3 or worse) was similar by treatment group in the safety population (398 [38%] with control and 380 [39%] with radiotherapy). Radiotherapy to the prostate did not improve overall survival for unselected patients with newly diagnosed metastatic prostate cancer. Cancer Research UK, UK Medical Research Council, Swiss Group for Clinical Cancer Research, Astellas, Clovis Oncology, Janssen, Novartis, Pfizer, and Sanofi-Aventis.

The optimal timing of radiotherapy after radical prostatectomy for prostate cancer is uncertain. We aimed to compare the efficacy and safety of adjuvant radiotherapy versus an observation policy with salvage radiotherapy for prostate-specific antigen (PSA) biochemical progression. We did a randomised controlled trial enrolling patients with at least one risk factor (pathological T-stage 3 or 4, Gleason score of 7–10, positive margins, or preoperative PSA ≥10 ng/mL) for biochemical progression after radical prostatectomy (RADICALS-RT). The study took place in trial-accredited centres in Canada, Denmark, Ireland, and the UK. Patients were randomly assigned in a 1:1 ratio to adjuvant radiotherapy or an observation policy with salvage radiotherapy for PSA biochemical progression (PSA ≥0·1 ng/mL or three consecutive rises). Masking was not deemed feasible. Stratification factors were Gleason score, margin status, planned radiotherapy schedule (52·5 Gy in 20 fractions or 66 Gy in 33 fractions), and centre. The primary outcome measure was freedom from distant metastases, designed with 80% power to detect an improvement from 90% with salvage radiotherapy (control) to 95% at 10 years with adjuvant radiotherapy. We report on biochemical progression-free survival, freedom from non-protocol hormone therapy, safety, and patient-reported outcomes. Standard survival analysis methods were used. A hazard ratio (HR) of less than 1 favoured adjuvant radiotherapy. This study is registered with ClinicalTrials.gov, NCT00541047. Between Nov 22, 2007, and Dec 30, 2016, 1396 patients were randomly assigned, 699 (50%) to salvage radiotherapy and 697 (50%) to adjuvant radiotherapy. Allocated groups were balanced with a median age of 65 years (IQR 60–68). Median follow-up was 4·9 years (IQR 3·0–6·1). 649 (93%) of 697 participants in the adjuvant radiotherapy group reported radiotherapy within 6 months; 228 (33%) of 699 in the salvage radiotherapy group reported radiotherapy within 8 years after randomisation. With 169 events, 5-year biochemical progression-free survival was 85% for those in the adjuvant radiotherapy group and 88% for those in the salvage radiotherapy group (HR 1·10, 95% CI 0·81–1·49; p=0·56). Freedom from non-protocol hormone therapy at 5 years was 93% for those in the adjuvant radiotherapy group versus 92% for those in the salvage radiotherapy group (HR 0·88, 95% CI 0·58–1·33; p=0·53). Self-reported urinary incontinence was worse at 1 year for those in the adjuvant radiotherapy group (mean score 4·8 vs 4·0; p=0·0023). Grade 3–4 urethral stricture within 2 years was reported in 6% of individuals in the adjuvant radiotherapy group versus 4% in the salvage radiotherapy group (p=0·020). These initial results do not support routine administration of adjuvant radiotherapy after radical prostatectomy. Adjuvant radiotherapy increases the risk of urinary morbidity. An observation policy with salvage radiotherapy for PSA biochemical progression should be the current standard after radical prostatectomy. Cancer Research UK, MRC Clinical Trials Unit, and Canadian Cancer Society.

With a median follow-up of 13 years, a randomized comparison of radiotherapy with or without antiandrogen therapy in patients with a rising PSA level after prostatectomy showed that 2 years of antiandrogen therapy resulted in a significantly higher overall survival rate. Patients with localized prostatic cancer are often treated with radical prostatectomy. More than 30% of such patients will subsequently have recurrence. This recurrence manifests first as a rising serum level of prostate-specific antigen (PSA), 1 – 3 termed biochemical recurrence. Large, retrospective studies suggest that salvage radiation therapy after biochemical recurrence may be associated with long-term freedom from cancer recurrence. 4 , 5 However, 50% of the patients who are treated with salvage radiation therapy will have further disease progression, particularly when there are aggressive disease features. 4 – 7 The combination of radiation therapy and either androgen-deprivation therapy or antiandrogen therapy prolongs survival among some . . .