Prospective evaluation of probabilistic dose-escalated IMRT in prostate cancer
Article Category: Research Article
Published Online: Dec 22, 2020
Page range: 88 - 96
Received: Aug 31, 2020
Accepted: Nov 02, 2020
DOI: https://doi.org/10.2478/raon-2020-0075
© 2021 Daniel Wegener, Bernhard Berger, Zhoulika Outtagarts, Daniel Zips, Frank Paulsen, Martin Bleif, Daniela Thorwarth, Markus Alber, Oliver Dohm, Arndt-Christian Müller, published by Sciendo
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
Cure- and toxicity rates after intensity modulated radiotherapy (IMRT) of prostate cancer are dose-dependent.1 Dose-escalated radiotherapy (RT) up to 80 Gy is a standard RT-technique2 and performed with (daily) image-guided RT (IGRT) combined with rapid treatment administration using volumetric modulated arc therapy (VMAT) or comparable techniques.2, 3, 4 Current improvements in regard to outcome and toxicity focus either on dose escalation or margin adaption. Dose escalation can be performed by using hypofractionated schedules of the whole prostate or of the dominant lesion alone5, Margin adaption
Also, planning target volume (PTV) margins still need to account for intra- and interfraction prostate motion to prevent target miss, while respecting the surrounding organs at risk (OAR), especially bladder and rectum. Therefore, alternative concepts which are applicable in width and which combine both dose escalation and toxicity reduction are of interest.
A promising concept to achieve a favorable PTV-coverage while individually sparing OARs represents Coverage probability based IMRT which does not need daily imaging due to its pre-adaptive planning approach.7, 8, 9 We studied the potential for Organ at Risk (OAR) sparing and compensation of tumor movement of the Coverage probability (CovP) concept within a prospective study and report 7-year outcome and toxicity rates.
The coverage probability concept was investigated within a prospective study to evaluate in intermediate-risk prostate cancer patients’ feasibility, toxicity and outcome parameter. The study was approved by the research board of the University Clinic of Tuebingen on 06/27/2007 (project-number: 257/2007B01).
Inclusion criteria were histopathologically confirmed adenocarcinoma of the prostate, intermediate-risk in D`Amico classification, age ≤ 85 years at enrollment, Karnofsky-performance-status ≥ 70%, localized disease (bone scan, abdominal/pelvic CT) and informed consent. Exclusion criteria were prior prostatectomy, prior transurethral resection (TURP) or previous irradiation of pelvis, a second malignancy or another severe, clinically prominent illness (
A planning CT (pCT; SOMATOM Sensation 64, Siemens Healthcare, Erlangen) was performed daily over three days with a rectum- and bladder protocol in use. The pCT`s were registered with Oncentra Masterplan® (Theranostic GmbH, Solingen, Germany), then target volume and organ at risks (OAR’s) were contoured in each pCT. The clinical target volume’s (CTV) of each pCT (prostate + 1 cm seminal vesicle) were merged to create a CTVunion, which was expanded by 7 mm to define an internal target volume (CovP-internal target volume [ITV]). The same margin of 7 mm was added to the merged OARs (rectum and bladder) to create planning OAR volumes (PRV). The coverage-probability approach uses spatially variable weight factors for “cost functions” for both ITV and OAR’s. These weight factors are based on the probabilities of systematic organ shifts, estimated by the three planning CTs. For RT planning, “class solutions“ were employed including OAR constraints, aimed target doses, optimal gantry angles as described elsewhere.7, 8, 9 (Figure 1).
Figure 1
Coverage probability (CovP) concept: an example case is shown to indicate CovP-internal target volume (ITV) and planning organ at risk volumes (PRVs).
RT was performed as step-and-shoot IMRT with 78 Gy in 39 fractions. Planning software were Hyperion® versions 2.2.5, 2.2.6 and 2.3 (University Tuebingen, Germany; based on Monte Carlo algorithm). All patients were treated in supine position on a 15 MV linear accelerator (Elekta Synergy S, Elekta Oncology Systems®, Crawley, UK) equipped with a 4 mm multileaf collimator. Cone-beam CT (CBCT) was initially performed daily for three days and then the average positioning error was calculated and corrected for the next fraction. Thereafter, CBCT was routinely performed twice weekly to account for random positioning errors. In case of a positioning error of >3 mm, CBCT was repeated at the next RT treatment. Additional short term androgen deprivation therapy (ADT) for six months was recommended according to national guidelines. Further treatment specifications are given elsewhere.9,10
For each patient, baseline parameters for genitourinary (GU) and gastrointestinal (GI) functions were assessed and acute- and late toxicities were scored by a physician using common terminology criteria for adverse events (CTCAE)10 and/or Radiation Therapy Oncology Group (RTOG) Classification.11 Initially, CTCAE version 2.0 was used, which was transferred in 2009 into version 4.0 for comparability.12 A physical examination, combined with scoring of late toxicity and measurement of features prostate-specific antigen (PSA)-level, was performed three months after RT and then once a year.
Primary outcome parameter was relapse-free survival (biological no evidence of disease, bNED). Biochemical relapse was defined by the Phoenix-criteria.13 Secondary outcome parameters were overall survival (OS), prostate-cancer specific survival (PCSS) and distant metastasis-free survival (DMFS). The outcome parameters were calculated from start of radiotherapy.
Descriptive statistics were performed with Microsoft Excel 2010 (Version 14.0.7145.5000). Further calculations, graphs and Kaplan-Meier estimations were performed with SPSS (Statistical Package for Social Sciences ‘IBM SPSS Statistics for Windows, Version 24.0 (IBM Corp., Armonk, N.Y., USA)).
Twenty-eight patients were treated between 09/2008 and 10/2010 in this prospective study. Patient characteristics are given in Table 1. Dose escalation to 78 Gy was performed in all patients, the coverage probability concept was realized in 27/28 patients. In one patient, the study therapy was not accomplished due to unknown reasons (but a “standard” step-and shot IMRT to 78 Gy was performed based on one pCT). Neoadjuvant ADT was administered to 78.6% of patients with a mean duration of 8.9 months.
Patient characteristics of the study cohort
| Parameter | Mean (min.- max.) | Median | n (%) |
|---|---|---|---|
| Age at treatment (years) | 70 (56–83) | 70 | |
| Duration of radiotherapy (weeks) | 7.9 (7.4–8.7) | 7.9 | |
| Gleason-Score (n, %) | |||
| 6 | 4 (14.3 %) | ||
| 7a (3+4) | 15 (53.6 %) | ||
| 7b (4+3) | 9 (32.1 %) | ||
| cTNM (n, %) | |||
| cT1c | 8 (28.6 %) | ||
| cT2a | 8 (28.6 %) | ||
| cT2b | 3 (10.7 %) | ||
| cT2c | 9 (32.1 %) | ||
| Neoadjuvant ADT (n, %) | 22 (78.6 %) | ||
| Duration of ADT (months, range) | 8.9 (3.0–27.0) | 6.0 | |
| Initial PSA peak in ng/ml (range) | 9.1 (1.9–19.8) | 8.3 | |
| PSA-peak by subgroup | |||
| 0 < x ≤ 5 | 3 (10.7 %) | ||
| 5 < x ≤ 10 | 15 (53.6 %) | ||
| 10 < x ≤ 15 | 8 (28.6 %) | ||
| 15 < x ≤ 20 | 2 (7.1 %) |
ADT = androgen deprivation therapy; PSA = prostate-specific antigen
Median follow-up (FU) time was 7.4 years (range 0.7–9.3 years; mean 7.1 years). Median FU for PSA-control was 7.0 years (range 3.3–9.1 years; mean 6.8 years). PSA-nadir was reached on average after 2.7 years (min.: 0.2 years; max.: 8.3 years; median: 1.3 years). Biochemical control is shown in Figure 2. Two patients developed a biochemical recurrence. PCSS and DMFS after 7 years were 100% each. One patient died after a FU of 4.5 years due to a metastatic GIST which was detected 51 months after RT and located outside of the treated RT-field. Another patient was lost to FU.
Figure 2
Survival outcomes: Kaplan-Meier curves of biochemically no evidence of disease (bNED), overall survival (OS), distant metastasis-free survival (DMFS) and prostate-cancer specific survival (PCSS).
Acute toxicity was defined as toxicity occurring from start of RT until the first FU-investigation ≤ 90 days after end of RT. Weekly RTOG scoring results as well as maximum toxicity scores for GI-and GU-toxicity are given in Supplement Figure 3. 46.4% of patients developed acute GU toxicity of maximum grade 1 and 42.9% developed acute GU toxicity of maximum grade 2. No higher graded toxicity occurred. Acute GI toxicity of maximum grade 1 and 2 was found in 46.4% and 35.7% of patients, respectively. No higher graded GI-toxicity occurred. Maximal GI- and GU-toxicity was seen in week 7 and 8 of radiotherapy. Additionally, CTCAE urinary incontinence was assessed: most patients (n = 22; 78.6%) did not develop incontinence. At first FU, two patients (7.1%) reported grade 1 toxicity (no pads necessary) and no higher toxicity was reported. Skin erythema of RTOG grade 1 or 2 was present towards the end of radiotherapy in 78.6% (n = 22) of patients and no higher graded skin toxicity occurred. At first FU, only one patient still suffered from RTOG grade 1 skin toxicity.
Figure 3
Late genitourinary (GU) toxicity items
Y-axis: percentage of patients reporting the toxicity item. Top X-axis: number n of patients with data available. Lower X-axis: years after radiotherapy. Right column: maximum late toxicity summed up by grade
Long-term toxicity was evaluated in 26/28 patients after a median FU of 7.4 years (range 0.7–9.3 years; mean 7.1 years). Toxicity was scored as cumulative maximum over study period and as toxicity at last follow-up (LFU).
Most late GU-toxicity occurred 3–5 years post RT and seemed to decrease in prevalence towards LFU. Mild late bladder toxicity (RTOG G1) at LFU was observed in 14.3% of patients and no higher toxicity occurred (Figure 3). At LFU, 14.3% and 10.7% of patients reported urinary frequency of CTC grades 1 and 2, respectively and no higher toxicity occurred. A urinary retention of CTC grade 1 and 2 was seen in 21.4% and 7.1% of patients at LFU (Figure 3). Urinary urgency of CTC grade 1 and 2 at LFU was present in 10.7% and 3.6% of patients showing no increase in prevalence over time. Urinary incontinence of CTC grade 1 (no pads needed) was reported by 21.4% of patients at LFU. Incontinence peaked 4–5 years after RT and then showed a decrease over time (supplement data).
Late rectal toxicities (RTOG) at LFU of grade 1 (7.1% of patients) and of grade 2 (3.6%) were observed (Figure 4). A peak in late GI-toxicity (RTOG) of grade 1 was seen 4 years post RT and then seemed to decrease again in prevalence. Gastrointestinal grade 3 toxicity, presenting with rectal bleeding, was observed in two patients (RTOG GI late, CTC rectal hemorrhage and CTC proctitis due to overlapping toxicity scoring). Both patients had pre-existing hemorrhoids and hemorrhoidal operations in their medical history. This occurred 9 months and 19 months post RT, respectively. After treatment with Argon-Plasma-Coagulation, no further grade 3 toxicity occurred in these two patients or others. Mild rectal hemorrhaging (CTC grade 1) was present in 14.3% of patients at LFU. Proctitis of CTC grade 1 (2) was present in 10.7% (7.1%) of patients at LFU (Figure 4). Diarrhea of CTC grade 1 and 2 were present in 10.7% and 3.6% of patients, respectively. While diarrhea symptoms subsided 2 years post RT, it was reported again in one patient 8 years after radiotherapy (supplement data). Fecal incontinence of grade 1 and 2 occurred each in one patient (3.6%), undulating over the FU period with no increase of severity of the symptom (supplement data).
Figure 4
Late gastrointestinal (GI) toxicity items
Y-axis: percentage of patients reporting the toxicity item. Top X-axis: Number n of patients with data available. Lower X-axis: years after radiotherapy. Right column: maximum late toxicity summed up by grade.
Mean V70 PRV-bladder was 11.08% with this approach (accepted threshold: V70 bladder <35%). Mean V70 PRV-rectum was 13.03% (accepted threshold: V70 rectum <15%). These constraints were based on the QUANTEC data and adjusted according to house standard. Due to these constraints, the mean CovP-ITV dose was 75.40 Gy (V78 = 26.77%).
In this prospective study, we report the feasibility and safety of a probabilistic planning concept for radiotherapy of intermediate risk prostate cancer patients based on the coverage probability. Dose-escalation to 78 Gy was aimed with this technique showing very high long-term biochemical control rates and excellent survival rates. The toxicity profile was moderate with 85% of patients presenting without any GU/GI-toxicity at last follow-up indicating that CovP is a robust plan optimization achieving both low toxicity and favorable outcome.
In the planning phase of this study in 2007, dose escalation to 78 Gy was a novel concept in need of evaluation of safety and superiority to the former “standard” therapies of 3D-RT or IMRT of the prostate up to 70 Gy. Meanwhile, several studies could show a benefit to PCSS of dose escalation14, 15, 16, 17 and a total dose of 74 to 80 Gy is the current standard of care and recommended in national guidelines.2,3 Our study concept on probabilistic treatment planning is substantiated by excellent bNED-rates of 95.5% after 7.1 years (DMFS: 100%, OS: 96.4%). Two patients developed a biochemical recurrence. In one of these two patients, PSMA-PET-CT showed a local recurrence in the prostate. This patient had not received ADT due to cardiac diseases. In the other patient, a biochemical recurrence occurred at LFU and no further information on staging was available at the time of analysis of this study. Large studies of similar patient cohorts reached bNED-rates of 55–90% and DMFS of 88-100% (in the dose-escalated study arms treated with normofractionated RT with 74-86.4 Gy total dose) after 5 years of FU.14, 15, 16, 18,19, 20 Compared to the 7.1 years FU of this study, only the M.D. Anderson trial could provide a longer FU period of 8.7 years in the mean.16 Our results are especially interesting in regard to the achieved mean ITV-dose of 75.40 Gy (V78 = 26.7%) because this dose is in the lower dose range of the mentioned studies. Therefore, it could be hypothesized that robust treatment planning implementing probabilities of target volumes and OARs might be more relevant than dose-escalation to at least 78 Gy. And the standard one-CTV/PTV approach might be more at risk for target miss compared to a robust ITV concept, as was examined in another publication by our deparmenten.9 However, there are restrictions in comparability due to differences in the included tumor stages, ADT (no information about ADT in the study of Goldner
The toxicity of this treatment approach is a central quality parameter, especially considering the potentially larger target volume (CovP-ITV) compared to a one-pCT approach. Acute GU-and GI-toxicity was acceptable with only grade 1 and grade 2 (RTOG, CTC scores) and no grade 3+ toxicity. While certain items showed a peak after 3 weeks of RT (RTOG bladder acute) or 5 weeks (CTC urinary Incontinence, RTOG GI acute), most items showed an increase of toxicity prevalence towards the end of RT and the early peaks most likely origin in coincidental accumulation due to the limited patient size of the study. Towards the first FU-examination 3 months post RT, mostly grade 1 toxicity persisted. It is noteworthy that using the CTC-classification probably overestimates the item urinary incontinence in comparison to other studies since for example in the PROTECT-study, incontinence of grade 1 was defined as need of ≥1 pad per day which equals CTC incontinence of grade 2.21 In contrast, CTC incontinence of grade 1 – as measured in this study - is defined as occasional incontinence (pressure, coughing) not requiring pads.
Interestingly, late GU-toxicity of grade 1 or 2 (RTOG bladder late, CTC incontinence, CTC urgency) occurred only temporarily in this study population and decreased in prevalence after 5 years after RT. To date, consensus understanding of radiation biology is the continuous increase of late effects over time.22 No further data describing decreasing late toxicity after pelvic radiation is known to the authors.23,24 Due to the small sample size, random distribution of data and/or psychological factors such as patient habituation or recall bias cannot be ruled out.
Late GI-toxicity also showed no sign of increment over time and was generally rare: At LFU RTOG grade 2 toxicity was only present in one patient. Regarding rectal hemorrhaging, we suppose that the predisposition of hemorrhoids in those patients who developed this toxicity can be regarded as the (established) major risk factor.25 Taken together, the low toxicity rates in this cohort compare well to larger studies and demonstrate a favorable therapeutic window of the CovP-concept.14, 15, 16, 18,20,23,26,27 The coverage concept has been described before in detail.7,8,9 The advantages include a safe margin with high PTV coverage, based on the individual OAR- and prostate motion of each patient, and measured by three planning-CTs. The idea behind the concept is a foreseen adaption of intra- and interfractional motion and deformation and therefore reduced verification intervals are needed. The efficacy of this method could be demonstrated in this study. Additionally, toxicity rates were not increased compared to standard techniques. The CovP-concept with 7 mm margin does not require daily image guidance due to its robustness as shown elsewhere.9 This might save radiation dose and on-table time for the department. Especially in patients who cannot undergo fiducial implementation or other invasive procedures such as rectum spacers4,28 or patients with larger positional variation of the prostate, this technique presents a useful and safe alternative.7
This study has several limitations: Further evaluation of outcome data in a larger study population is necessary. Additionally, there was no control group to compare toxicity and outcome to. In one patient, the study therapy was not accomplished due to unknown reasons. Three planning-CTs are necessary for this method, causing extra burden on staff and patient, including additional radiation dose for the latter. However, we believe that the benefits, especially the reduced need for image verification or implantation of fiducials
Coverage probability-based IMRT was feasible in a clinical study. Dose escalation with the CovP-concept was associated with a low rate of toxicity and a high efficacy regarding local and distant control, comparing well to studies with similar patient cohorts. Benefits include reduced target miss due to inclusion of potential inter- and intrafraction motion and reduced radiation dose due to less need for verification images. Utilization in other tumor entities and/or with contemporary RT techniques is being currently tested (NCT03617133).