LDR brachytherapy (LDRBT) monotherapy across risk groups

New registry data from the Cleveland Clinic shows good oncological control with low dose rate brachytherapy (LDRBT) monotherapy, at least for low risk and low-intermediate risk groups. This is the first time I’ve seen LDRBT monotherapy data for higher risk groups. We expect the lower dose/tighter margin monotherapy to reduce toxicity over combination treatment with external beam radiation and a brachy boost. The question is whether the trade-off with oncological control is worthwhile.

Recent clinical trials have focused on whether the addition of combination of EBRT with a brachy boost was better than EBRT alone. The ASCENDE-RT trial showed it did, at least for the higher risk groups. Other studies have looked at the benefit of adding ADT. They found that adding ADT conferred a bigger benefit than adding EBRT among “unfavorable intermediate risk” patients.  Herbert et al. found that 6 months of ADT with LDRBT on Gleason 7 patients led to 5-year “no biochemical evidence of disease” of 95% independent of the predominant Gleason pattern  (3 or 4) even without EBRT. But in the modern era of dose-escalated LDRBT, we do not yet have any randomized comparisons of combination therapy to monotherapy. RTOG 0232 will address this question, at least for intermediate risk patients, when we get its results in 2017. The Cleveland Clinic data do not directly answer that question, but by providing monotherapy data for high risk patients, they help us understand the trade-offs.

In the Cleveland Clinic series, analyzed by Kittel et al., ADT was included for many in the high risk group, but external beam was not. From 1996 to 2009, 1,989 patients were treated with LDR I-125 brachytherapy monotherapy. Treatment guidelines were as follows:

• ·      Prescribed dose was 144 Gy
• ·      18.2% received ADT:

o   10% among low risk, 20% among intermediate risk, 64% among high intermediate risk and 81% among high risk patients

o   ADT use decreased over time: 56% in 1997, 9% in 2004

• ·      Baseline urinary function and prostate volume were not used to exclude patients
• ·      Urethral dose <150%
• ·      Intra-operative planning
• ·      Cold spots allowed in the anterior/superior region
• ·      Margins were 3mm to 5mm
• ·      Wider margins increased to 5mm- 1 cm for high risk cases
• ·      Seeds avoided within 3-5mm of rectal wall
• ·      Stranded seeds used on the periphery
• ·      CT within 4 weeks to check dosimetry
• ·      F/U every 6 months for 3 years, then annually
• ·      Classified into NCCN risk groups
• ·      Intermediate risk sub-classified into “low intermediate” if only one intermediate risk factor (i.e., either PSA between 10 and 20 or Stage T2b/c or Gleason Score=7), otherwise “high intermediate.”
• ·      Median follow-up was 6.8 years

As an aside, it’s worth noting that the intermediate risk sub-stratification they used, sometimes known as the “Zelefsky stratification”, was developed in the 1990s when brachytherapy protocols and outcomes were considerably inferior to what they are today. Dr. Zelefsky now advocates the “Zumsteg stratification” of intermediate risk as we recently discussed here and here.

The 5- and 10-year biochemical relapse-free survival (bRFS) by risk group are summarized in the following table.

Risk Group	# of patients	5-yr bRFS (percent)	10-yr bRFS (percent)
Low Risk	1,219	95	87
Low Intermediate Risk	592	90	79
High Intermediate Risk	90	81	*
High Risk	88	68	*
TOTAL	1,989	92	82

* small sample

The authors reported acute toxicity in a previous report, which I do not have. They did not report late-term Grade 1 and Grade 2 toxicity. Genitourinary (GU) toxicity was Grade 3 or higher in 7.6%, while gastrointestinal (GI) toxicity was Grade 3 or higher in 0.8%. The part of the data I saw did not break out separately what the toxicity was for high risk patients, whose margins were wider. The authors note that the observed toxicity rates were lower than those reported for combination therapy in other series.

Men with prostate length of 5 cm or more were 2.4 times more likely to suffer serious GU complications, while the association with prostate volume was not clinically significant. Men aged 70 or over were 71% more likely to suffer from significant GU problems. These risk factors should be taken into account in counseling men considering LDRBT.

Unfortunately, the authors did not track patient-evaluated quality-of-life outcomes, and there is no data on potency preservation.

Low Risk

Because this was not a randomized comparative trial of monotherapy vs. combined therapy, it is impossible to draw conclusions as to its relative efficacy. The control among low risk patients is good, although based on recent findings about active surveillance, many might be better served by deferred treatment.

High Risk

The control among high risk patients seems to be somewhat less than in other recent trials where combination therapy with EBRT was used instead:

• ·      In the ASCENDE-RT trial, the 7-year biochemical control was 83%.
• ·      At Memorial Sloan Kettering, the 5-year biochemical control was 80%. At Schiffler Cancer Center and UMichigan, the 8-year biochemical control was 86%.
• ·      Liss et al. reported 5-year biochemical control was 85% among men with Gleason pattern 5.

I think most men diagnosed with high risk prostate cancer would be willing to pay the cost of increased toxicity to get the additional oncological control from added EBRT, but that is certainly a matter of personal preference. The brachy monotherapy biochemical control for high risk is similar to what we might expect from surgery; however, the toxicity is quite a bit lower with LDRBT.

Intermediate Risk

The real controversy is in the intermediate risk category. The patient diagnosed with “favorable intermediate risk” prostate cancer is faced with a bewildering array of alternatives, including active surveillance, any of several kinds of focal ablation, surgery, SBRT, IGRT/IMRT, LDRBT monotherapy, HDRBT monotherapy, PBT,  (LDR or HDR)BT+IMRT, LDRBT+SBRT,  or PBT+IMRT. Piling on the radiotherapies has the potential to pile on side effects as well. Intermediate risk readers interested in brachytherapy will be interested in reading Spratt and Zelefsky’s argument for combined therapy, Stone’s counterargument, and Spratt and Zelefsky’s rebuttal. There are points of agreement. They agree that “favorable intermediate risk” patients do not need combined therapy. They also agree that treatment with high enough radiation dose is critical to success.

Aside from the references they cited, here are a few more for intermediate risk patients treated with combination therapy (including ADT):

• ·      ASCENDE-RT 7-yr bRFS: 94%
• ·      CALGB 99809 6-yr bRFS: 85%
• ·      RTOG 00-19  8-yr bRFS: 82% 

While the control rates look excellent, none of those studies divide the intermediate risk group into separate sub-categories. The Cleveland Clinic outcomes for “low-intermediate risk” are certainly within this range (the weighted average bRFS for the entire intermediate risk group was 89% at 5 years), but were accomplished without the potential for extra toxicity from the added external beam radiation.

The Cleveland Clinic data demonstrates the very disparate outcomes within the intermediate risk sub-groups. It would be interesting to see their outcomes, as well as the outcomes of the other cited studies, stratified according to the Zumsteg criteria. Lacking that, and pending the definitive randomized clinical trial data from RTOG 0232 in 2017, the decision about whether to add EBRT or ADT to LDRBT for intermediate risk patients should involve a close analysis of his individual risk factors and his attitudes about potential side effects.

 note: thanks to Dr. Jay Ciezki  for making the full text of the article available to me.

External beam radiation therapy (EBRT) with a low dose rate brachytherapy (LDRBT) boost provides superior cancer control compared to EBRT alone.

Numerous retrospective analyses have suggested that the combination of external beam radiation therapy (EBRT) with a low dose rate brachytherapy (LDRBT) boost is highly effective in controlling prostate cancer in unfavorable risk patients. For the first time, to my knowledge, we have a randomized comparative trial confirming that. An abstract was presented at the GU Conference and there is a press release about it.

ASCENDE-RT was a randomized clinical trial among 122 intermediate and 276 high risk patients treated in 6 Canadian centers from 2002-2011. The treatment specifications were:

• All patients received:
• Whole pelvis EBRT of 46 GY
• 8 months of neoadjuvant ADT + 4 months of concurrent and adjuvant ADT
• The EBRT-only group of 200 patients received an additional 32 Gy to the prostate (total = 78 Gy)
• The LDRBT-boost group of 198 patients received an additional boost of 115 Gy I-125 seeds in the prostate.
• Median follow up was 6.5 years, and was as long as 9 years for 65 patients.

The researchers found:

• After 9 years, the biochemical progression-free survival  (bPFS) was 83% for the LDRBT-boost group compared to 62% for the EBRT-only group.
• bPFS deteriorated by about 6% per year for the EBRT-only group.
• bPFS was fairly stable for the LDRBT-boost group after reaching 89% at 5 years.
• After 7 years, LDRBT-boost had better bPFS than EBRT-only both among intermediate risk men (94% vs. 80%), and among high risk men (83% vs. 72%).
• Median PSA at latest follow up was 0.02 ng/ml for the LDRBT-boost group and 0.24 ng/ml for the EBRT-only group.
• Reflecting the long natural history of disease progression, there were no significant differences in metastasis-free survival, prostate cancer-specific survival, or overall survival. Differences may emerge with longer follow up.

The improved oncological control came at the expense of increased toxicity for the combination therapy.

• Late term Grade 2 or higher genitourinary (GU) toxicity was higher for the LDRBT-boost group. Late term Grade 3 GU toxicity reached 19% for the LDRBT-boost group vs. 5% for the EBRT-only group.
• Late term gastrointestinal (GI) toxicity was similarly mild for both groups
• This early report did not include an analysis of acute toxicity, or an analysis of erectile function.

I look forward to the full analysis of the data when published. I hope they will break out the results separately for favorable and unfavorable intermediate risk patients to the extent that sample size may allow. Perhaps the favorable intermediate risk patients can be spared the extra toxicity of the LDRBT-boost treatment while still enjoying oncological control.

For the high risk patients especially, this study establishes LDRBT-boost therapy as the preferred treatment compared to EBRT-only, unless pre-existing urinary issues rule it out. It is unclear whether the 12 months of ADT and the whole-pelvis radiation would be necessary for all patients.

In an earlier randomized clinical trial (Sathya et al.), high dose rate brachytherapy (HDRBT) boost was shown to reduce the biochemical and clinical failure rate by 50% compared to EBRT-only (66 Gy). Other randomized clinical trials of HDRBT-boost (Hoskin et al., Guix et al.) also found that the boost improved outcomes. It is unclear whether boost with HDRBT, LDRBT, or treatment with SBRT alone will eventually emerge as the preferred treatment for unfavorable risk patients, or whether it will make a difference.

Is overall survival a useful endpoint for evaluating therapies for intermediate risk patients?

In a recent commentary, we looked at the utility of surrogate endpoints in evaluating therapies. In an abstract presented at ASCO, Malouf et al. examined the large National Cancer Data Base to determine whether there is an association between the use of brachytherapy (BT), external beam radiation (EBRT), or a combination of both (CT) and overall survival in intermediate risk patients.

They found records on 122,405 patients treated from 2004-2013 who were staged IIA. IIA is an AJCC risk category that is similar to the NCCN intermediate risk category, except that it excludes those clinically staged with cancer in both lobes (stage T2c). The average age of the patients at diagnosis were:

• ·      EBRT: 69 years of age
• ·      BT and CT: 66 years of age

The study provides no information about the radiation doses used.

The average survival, and the percent who survived 10 years were:

• ·      EBRT: 109 months, 61.5%
• ·      BT: 116 months, 72.9%
• ·      CT: 116 months, 73.1%

Survival differences were statistically significant between EBRT cohort and those who received the two other therapies.

The authors conclude:

“The method of radiotherapy used contributes to the survival of patients with stage IIA prostate cancer, with brachytherapy with or without EBRT having improved survival. Careful selection of the proper treatment regimen should be used.”

Now, when we look at US actuarial tables, we see the expected survival for a 66 year-old man is 16.93 years (203 months), and 14.81 years for a 69 year-old man (177 months). So the men treated with EBRT should have lived 26 months less; yet they lived only 7 months less – a relative survival gain for some unknown reason. It is also unknown why overall survival in both cohorts was so much less than actuarial expectations.

Using the Memorial Sloan Kettering nomogram for life expectancy where intermediate risk cancer has been diagnosed but not yet treated, and assuming no significant co-morbidities or risk factors, and allowing only for the difference in age, the expected 10-year survival statistics for untreated prostate cancer are as follows:

Among the 66 year old men (BT and CT cohorts):

• ·      71% would still be alive, which is close to the observed 73% among those who were treated
• ·      20% would have died of other causes
• ·      9% would have died of prostate cancer

Among the 69 year old men (EBRT cohort):

• ·      67% would still be alive, which is somewhat higher than the observed 63% among those who were treated
• ·      25% would have died of other causes
• ·      8% would have died of prostate cancer

What we learn from this is that for a man who has a life expectancy of ten years or less, watchful waiting may be a better choice than radical treatment.

We see that it is impossible to attribute the difference in the overall survival to prostate cancer, let alone to any of the treatments received. What we needed to know is prostate cancer-specific mortality, and we have no idea from their analysis how, if at all, it was affected. Because of the very low rate of prostate cancer-specific mortality at 10 years, even in untreated patients, it takes a very long time to be able to detect differences in the efficacy of various treatments based on this endpoint; hence, the importance of surrogate endpoints. The authors’ conclusions are completely unfounded based on the data they presented.

For very high-risk patients, EBRT + BT is superior to surgery or EBRT only

A retrospective analysis of oncological outcomes among modern-era patients with a Gleason score of 9 or 10 demonstrates a clear advantage to a combination of external beam radiation therapy (EBRT) with a brachytherapy (BT) boost to the prostate and short–term androgen deprivation therapy (ADT).

Kishan et al. reported on 487 patients with biopsy Gleason scores of 9 or 10 who were consecutively treated between 2000 and 2013 at the University of California Los Angeles and Fox Chase Cancer Center. The patient characteristics were as follows:

• 170 were treated with radical prostatectomy (RP).
• 230 were treated with EBRT only.
• 87 were treated with EBRT + BT, and most of the BT was high dose rate.
• All patients were Gleason 9 or 10 on biopsy.
• RP patients were younger (median 62 years of age) compared to all radiation patients (median 70 years of age).
• RP patients had more favorable disease characteristics: lower initial PSA, and lower clinical stage.

The patient characteristics by treatment category are listed below.

For the RP patients:

• 11% had pre-surgery ADT or chemotherapy.
• 55% had adjuvant or salvage radiation therapy (68 Gy).
  • 39% of them had adjuvant ADT with radiation for a median of 22 months if adjuvant radiation, 12 months if salvage radiation.
• 85% with biochemical recurrence and no detected distant metastases had salvage radiation.
• 21% had a lower Gleason score (7 or 8) on final pathology, but 91 percent had any Gleason pattern 5 on final pathology.
• 78% were stage T3 or T4 on final pathology (vs. 12 percent clinically).
• 41% had positive surgical margins.
• 16% had positive lymph nodes
  • Among those, 64% received no immediate treatment because of patient preference.

For the EBRT patients:

• Median dose of radiation was 76.4 Gy.
• 94% had ADT starting before EBRT.
  • The median duration of ADT was 24 months.
• 76% had pelvic lymph nodes treated.
• 2 patients received salvage cryotherapy.

For the EBRT + BT patients:

• The median equivalent dose of radiation was 88.7 Gy
• 86% had ADT starting before radiation.
  • The median duration of ADT was 8 months.
• 78% had pelvic lymph nodes treated.
• 1 patient received salvage cryotherapy.

After a median follow-up of 4.6 years, the oncological outcomes were as follows:

• The 10-year biochemical recurrence rates (BCRs) were
  • 84% for RP
  • 40% for EBRT
  • 30% for EBRT + BT
  • Differences between RP and EBRT and between RP and EBRT + BT were statistically significant.
• Percentages of patients who began lifelong ADT after therapy failure were
  • 31% for RP
  • 21% for EBRT
  • 16% for EBRT + BT
  • Differences between RP and EBRT and between RP and EBRT + BT were statistically significant.
• The 10-year rates of distant metastases were
  • 39% for RP
  • 33% for EBRT
  • 10% for EBRT + BT
  • Differences between EBRT + BT and the two others were statistically significant, while the differences between RP and EBRT were not.
• The 10-year rates of prostate cancer-specific mortality were
  • 22% for RP
  • 20% for EBRT
  • 12% for EBRT + BT
  • None of the differences were statistically significant.
• The 10-year rates of overall survival were
  • 75% for RP (they were younger and healthier)
  • 65% for EBRT
  • 59% for EBRT + BT
  • None of the differences were statistically significant.

The authors conclude:

These data suggest that extremely dose-escalated radiotherapy with ADT might be the optimal upfront treatment for patients with biopsy GS 9–10 prostate cancer.

It will come as no surprise to readers that EBRT + BT boost has better outcomes than EBRT alone (see this link and this one). Dose escalation has been found to improve outcomes, and the use of ADT to radiosensitize the cancer, and to systemically clear up micrometastasis, seems to improve outcomes still further. However, ADT for as long as 2 years could not compensate for the lower radiation dose of EBRT used by itself. Longer duration of ADT was not associated with improved outcomes after accounting for the dose effect.

Those who were treated with EBRT + BT were at a considerable disadvantage in this study: they were older, had worse disease characteristics, and were given less local salvage, yet they performed much better. When controlling for those disparities, the total radiation dose emerged as the single most important variable, affecting biochemical recurrence, metastases-free survival, and prostate cancer-specific survival. No other variable – neither duration of ADT nor adjuvant/salvage radiation – was statistically significant.

Prostate cancer-specific mortality rates were cut in half by combining EBRT with a BT boost. While the combination therapy did not make a statistically significant difference in prostate cancer-specific survival, the study was probably under-powered to detect that with statistical significance. The survival curves between EBRT + BT and the other two therapies did consistently diverge throughout the follow-up period, so the difference might well be statistically significant on a larger sample size or longer follow-up.

Not everyone in this study received optimal therapy. The EBRT-only dose was sometimes low by today’s standards, salvage radiation was under-utilized, use of concurrent ADT with adjuvant/salvage radiation was low (see this link) and of too-short duration.  However, most were treated according to the standards of care. The authors looked at the subset of patients who were treated optimally and found no difference in conclusions. The conclusions were robust even excluding those who were lymph-node positive.

What is new here is the comparison of the three potentially curative treatments for very high-risk prostate cancer in the 21st Century. There have been several long-term database analyses that compared surgery to radiation therapy as offered in the 1990s, when radiation doses were often inadequate to achieve cures. We recently saw a comparative benefit to radiation over surgery in the modern era among high-risk patients at the University of Alabama Birmingham (see this link). Ideally, we would like to see a randomized comparative trial between surgery and radiation, but that is unlikely to occur. Meanwhile, this kind of analysis is about the best we have to inform our treatment decisions.

We understand that a future, expanded analysis will include data from other institutions, including Harvard, the Cleveland Clinic, and Memorial Sloan-Kettering Cancer Center. That analysis will also include toxicity data. We will certainly report on that when it is published.

note: Thanks to Drs. King and Kishan for allowing me to see the full text of this analysis, and responding to questions.