Declining use of RT in treating clinical stage T3 patients and those with adverse pathology after surgery

Patients clinically diagnosed with prostate cancer outside of the prostate capsule (stage cT3), are increasingly treated with radical prostatectomy (RP) rather than with primary radiation therapy (RT). In addition, patients who have adverse pathological features after first-line surgery (stage pT3 and/or positive margins) are increasingly not receiving either adjuvant or early RT.

Nezolosky et al. looked at the SEER database records of 11,604 patients clinically diagnosed with stage T3 prostate cancer from 1998 to 2012. They found:

• ·      RP use increased from 12.5% to 44.4%.
• ·      RT use decreased from 55.8% to 38.4%
• ·      “No treatment” decreased from 31.7% to 17.2%
• ·      For extracapsular extension (stage T3a), RP use was 49.8% vs. 37.1% for RT in 2012.
• ·      For seminal vesicle invasion (stage T3b), RP use was 41.6% vs. 42.1% for RT in 2012.
• ·      RT use exceeded RP by 59% if the biopsy Gleason score was 8-10.
• ·      RT use exceeded RP by 3% among those with higher PSA, and by 7% among older patients.

This trend is troubling because RP for cT3 is often not curative. The following biochemical recurrence-free survival rates have been reported and are very consistent:

• ·      Mitchell et al. (Mayo Clinic): 41% after 20 years for cT3 patients.
• ·      Freedland et al. (Johns Hopkins): 49% at 15 years for cT3a patients.
• ·      Carver et al. (Memorial Sloan Kettering): 44% at 10 years for cT3 patients.
• ·      Hsu et al. (Leuven, Belgium): 51% at 10 years for cT3a patients.
• ·      Xylinas et al. (Paris, France): 45% at 5 years for cT3 patients.

The rates are similar among those diagnosed with stage T3 at pathology. Hruza et al. reported bRFS of 47% and 50% for those staged pT3a and pT3b respectively. Pagano et al. reported bRFS of 40% for those staged pT3b. Watkins et al. found that 40% of pT3 surgical patients had already biochemically relapsed after a median of 18 months.

There are other factors that affect recurrence prognosis after surgery. Age, a high pre-treatment PSA, high Gleason score, positive surgical margin (including its size and Gleason score at the margin), and the length of extraprostatic extension (EPE) are all risk factors (see Fossati et al., Djaladat et al., Ball et al., Jeong et al.). In the Watkins et al. study, patients with EPE and negative surgical margins biochemically relapsed at the rate of 0%, 28% and 63% for Gleason scores of 6, 7 and 8-10, respectively. However, if the surgical margins were also positive, the relapse rates were significantly worse: 33%, 50%, and 71% for Gleason scores of 6, 7 and 8-10, respectively. Briganti et al. found that the 5-year bRFS was 55.2% among surgical patients categorized as high risk, which includes stage T3, Gleason score 8-10 or PSA>20 ng/ml.

Can primary radiation alone do any better? I haven’t seen breakdowns for stage cT3 patients specifically, but we have long-term follow up in many clinical trials where high-risk patients were treated with radiation and ADT. Here are some bRFS results we discussed recently:

• ·      HDR brachy monotherapy: 77 – 93% (3-8 years)
• ·      HDR brachy boost + EBRT: 66 - 96% (5-10 years)
• ·      LDR brachy monotherapy: 68% (5 years)
• ·      LDR brachy boost + EBRT:  83% (9 years)
• ·      EBRT monotherapy: 71 - 88% (5 years)

While primary radiation typically does about 50-100% better than primary surgery at controlling the cancer, urologists often argue that adjuvant or salvage RT will bring the numbers into line. There is an ongoing randomized clinical trial (NCT02102477) among men diagnosed with stage T3 comparing initial radiation treatment to prostatectomy plus salvage radiation. While we wait for those results, we have to rely on retrospective studies. In many of the studies cited above, about a quarter of the patients received salvage/adjuvant RT following surgery. In the Mayo study, 72% were recurrence-free after 20 years, which does bring the combination close to what radiation alone often delivers. However, that comes at a cost. Adjuvant and salvage RT usually has worse quality-of-life outcomes than the patient would have suffered had he had radiation to begin with.

This brings us to the second alarming trend: adjuvant and early salvage RT rates have been declining among men with adverse pathology after prostatectomy. We discussed this previously (see this link). So not only are T3 patients receiving a therapy upfront that is less likely to control their cancer, they also may not be receiving the adjuvant or salvage RT that might control it if used early enough.

It is especially troubling that there has been no corresponding shift to later salvage RT. Sineshaw et al. conjecture as to the reasons for the trend:

“This pattern of declining use could be due to multiple factors, including patient preference, physician and referral bias, concern about toxicity, lack of a consistent survival benefit seen in the updated randomized trials, or a growing preference for salvage radiation at time of biochemical failure, rather than immediate adjuvant RT. With respect to the last point, our data did not show a rise in RT use after 6 mo and within the first 5 yr post-RP, suggesting that a shift to salvage RT does not likely entirely explain the declining use of immediate (within 6 mo) postoperative RT.” [emphasis added]

I’d like to believe that the decline in salvage radiation utilization is attributable to better selection of patients. Utilization was higher in those with positive surgical margins and those with Gleason scores 8-10. However, Dr. Sandler may very well be right in attributing the drop-off to urologists who don’t immediately refer patients with adverse pathology to radiation oncologists. In my experience, many patients making the primary therapy decision also never consult with a radiation oncologist. High-risk patients are especially needful of guidance from the first doctor they see – almost always a urologist – to seek second opinions. It would be unconscionable if they are not receiving that guidance.

Proton Hypofractionation

We have recently seen Level 1 evidence that IMRT hypofractionation (fewer, more intense treatments) is no worse than conventional fractionation. The same may hold true for proton therapy.

Proton therapy has come under fire because of its high cost and lack of proven benefit compared to photon IMRT. We are, therefore, interested in changes to the treatment protocol that may reduce costs and increase patient convenience, as long as efficacy and safety are not compromised. Vargas et al. reported the interim patient-evaluated quality-of-life scores of a small randomized pilot trial (NCT01230866) to determine whether proton therapy can be completed in just five treatments (similar to SBRT). Low risk patients were randomized to receive either:

• ·      38 RBE in 5 treatments (49 patients), or
• ·      79.2 RBE in 44 treatments (33 patients)

After 18 months median follow up:

• ·      Urinary, rectal, and sexual function scores were not different at 3, 6, 12, 18 or 24 months after treatment.
• ·      At 12 months, American Urological Association (AUA) Symptom Index Score was low, but slightly worse (8/35) for the hypofractionated therapy than for the conventionally fractionated therapy (5/35).
• ·      Scores remained low and equivalent for both groups in all other time periods.
• ·      There was no grade 3 or higher toxicity at any time in either group.

Kim et al. reported on a trial among 83 patients treated with five different fractionation schedules ranging from 60 CGE in 20 fractions to 35 CGE in 5 fractions. There was no significant difference in 4-yr biochemical failure for any of the treatment schedules within any risk group. Toxicity was low in all groups.

The low toxicity is certainly encouraging, and larger scale trials seem warranted based on this. In addition to the ongoing trial of the 5-treatment protocol, prospective patients may want to investigate the following (some include ADT for higher risk patients):

• ·      Loma Linda and Provision Center for Proton Therapy in Tennessee have ongoing clinical trials, (NCT00831623) and (NCT02198222), respectively, of a 20-treatment protocol .
• ·      MD Anderson is testing a 15-treatment protocol (NCT01950351).
• ·      The University of Florida is testing a mild hypofractionation schedule (NCT01368055).

Intra-operative Electronic Brachytherapy (IOBT)

When the pathology report indicates that prostatectomy alone was insufficient to control locally advanced prostate cancer, we often turn to adjuvant radiation. However, there is a delay with adjuvant radiation of 3 to 6 months to allow tissues to heal, but that may allow the cancer to metastasize. Electronic brachytherapy is an experimental technique for killing the prostate cancer remnants during the operation.

It’s called electronic brachytherapy because it includes a miniature device that produces high dose rate but low energy X-rays electronically. It’s brachytherapy because a small bulb with the X-ray emitter is placed inside the pelvic cavity from which the prostate has just been removed. The high dose rate X-rays can kill the cancer in surrounding tissues, but their low energy means they can’t penetrate very deeply to places where it might cause toxicity. The patient is thus treated one time for 20 or 50 minutes during surgery. The clinicians need only some minimal shielding for protection.

While this is an experimental technology for prostate cancer, its efficacy and safety have been demonstrated for other cancers. For breast cancer after a lumpectomy, it’s standard care to treat the entire breast with external beam radiation. A recent large (n=1,721) randomized trial, “TARGIT-A” conducted at 33 centers in 11 countries, demonstrated that such single dose targeted intra-operative radiotherapy was not inferior in its cancer control to fractionated external beam radiotherapy, and complications like skin reactions and cardiac mortality were significantly reduced. Electronic brachytherapy has also been used for skin cancer, endometrial cancer, and spinal metastases.

There is some evidence that the intra-operative application of radiation may be safe for prostate cancer as well. Rocco et al. reported on 33 patients treated intra-operatively with a portable electron beam unit that delivered 12 Gy to the prostate area. They compared outcomes to 100 matched pairs of patients treated with adjuvant external beam radiation, and found no differences in peri-operative complications, continence, acute or late toxicity. The biochemical progression-free survival was also no different, but there were only 16 months median follow up. Krengli et al. reported similar low complications on 38 patients treated intra-operatively with electron beam therapy, and also showed that external beam radiation could be added afterwards without high toxicity.

In a proof-of-concept study, Buge et al. experimented on 9 cadavers and conducted a simulation study using the MRIs obtained from 34 patients. They looked at two IOBT models, one was the Axxent eBx™ system from Xoft, the other was the Intrabeam™ system from Zeiss. They both can be used during open prostatectomy, but the Axxent™ system with an inflatable bulb and longer stem was more amenable to laparoscopic and robotic surgery.  All were found to make good contact with the surrounding tissues where most recurrences are found, especially the anastomosis of the urethra, the neurovascular bundles, the bladder neck, and apical margins. The bulb was not able to come close enough to the seminal vesicles to provide adequate treatment, and is therefore not recommended for stage T3b. It is also unsuitable for treatment of pelvic lymph nodes. They were able to deliver 20 Gy to surfaces in direct contact, and at least 12 Gy to a depth of 5 mm. This corresponds to a very curative equivalent IMRT dose of 123 Gy to any cancer it touches. Their simulations demonstrated a very low probability of normal tissue complications for the bladder and rectum. Furthermore, the bulbs could be used to treat a wide variety of prostate sizes and shapes.

Among the possible uses are:

• ·      Guaranteed neurovascular bundle-sparing surgery (i.e., they are treated with IOBT).
• ·      Earliest possible treatment when extraprostatic extension is discovered during RP.
• ·      Planned treatment for clinically discovered extracapsular extension.
• ·      Earliest possible treatment when frozen sections reveal positive margins.
• ·      Initial single-dose adjuvant radiation that still allows for repeat treatment with fractionated external beam radiation if needed.
• ·      In conjunction with a prostate index tumor  “lumpectomy” as a kind of focal therapy.
• ·      As salvage therapy after a local radiation failure.

We must learn whether it is effective and safe in actual clinical practice on live patients. Of course this is very preliminary and, hopefully, clinical trials will be conducted.

Hypofractionated Radiation Therapy: Same results in less time

The largest yet randomized clinical trial comparing hypofractionated (fewer treatments or fractions) to normally fractionated IMRT has proved that oncological outcomes and late-term toxicities were the same for both treatment schedules.

The results of the CHHiP study were reported in an abstract by Dearnaly et al. delivered at the European Cancer Congress this week. There was also an interim toxicity analysis in 2012. There were 3,216 patients treated at 71 centers in the UK between 2002 and 2011. All patients were stage T1b-T3a, with <30% probability of seminal vesicle involvement. Patients were randomly assigned to one of three IMRT treatment schedules, for which I also show the relative biologically effective dose (BED) for oncological control compared to normal fractionation:

1.     74 Gy =2 Gy x 37 fractions (normal fractionation)

2.     60 Gy = 3 Gy x 20 fractions; relative BED: +4%

3.     57 Gy = 3 Gy x 19 fractions; relative BED: -1%

ADT began 3 months prior to the start of IMRT, and continued through treatment. The 2012 analysis showed that 93% of patients in each group received ADT.

Patient characteristics were as follows:

• ·      NCCN risk groups:

o   Low risk: 15%

o   Intermediate risk: 73%

o   High risk: 12%

• ·      Median age: 69 years
• ·      PSA: 10.1 ng/ml

After a median follow-up of 63.2 months, the 5-year progression-free (either biochemical or clinical) survival (PFS) rates were:

• ·      74 Gy: 88%
• ·      60 Gy: 91%
• ·      57 Gy: 85%

The difference in PFS for the 57 Gy vs. the 60 Gy schedule was statistically significant; the other differences were not statistically significant.

The toxicity outcomes reported as those with RTOG toxicity grades of 2 or higher were as follows:

• ·      Acute GI toxicity was lower with normal fractionation:

o   74 Gy: 25%

o   60 Gy: 39%

o   57 Gy: 38%

• ·      Acute GU toxicity was not significantly different among groups.
• ·      2-year GI toxicity was lower with hypofractionation in the 57 Gy group:

o   74 Gy: 4%

o   60 Gy: 3%

o   57 Gy: 2%

• ·      5-year GI toxicity was not significantly different among groups.

o   74 Gy: 1%

o   60 Gy: 2%

o   57 Gy: 2%

• ·      Neither 2-year nor 5-year GU toxicities were different among groups.

It is important to note that the normal fractionation schedule used in this trial (2 Gy x 37 fractions) is low compared to the current standard of care (2 Gy x 40 fractions), but was standard when this trial began in 2002. The 60 Gy schedule comes close to the current standard of care in terms of its biologically effective dose. Given this, it is not surprising that only the 60 Gy schedule achieved 5-year progression-free survival levels over 90%. The lowest dose schedule is on the steep part of the dose/response curve where even small increases in dose achieve large increases in cancer control.

While acute GI toxicity was higher at first with hypofractionation, the effect was transient, and had disappeared by 2 years. Lasting GI toxicity was negligible, and there were no differences at any time in GU toxicity.

Based on all this, the authors state, “Modest hypofractionated RT using 60Gy/20f appears effective and safe and may be recommended as a new standard of care.”

We should be clear that this is not SBRT; it is only IMRT with an accelerated dosing schedule. There are some important differences. SBRT typically uses doses of 6-8 Gy per fraction and just 4 or 5 fractions. Because of the extreme hypofractionation, it becomes critical to track prostate motion during each fraction and not just between fractions. Treatment margins are typically narrower with SBRT and may be as low as 0 on the rectal side. These differences are what make SBRT safe. In the current study, there was no allowance made for intra-fractional prostate motion and the margins were not altered, so it is not very surprising that rectal toxicity was higher at first, but it was perhaps surprising that there were no lasting differences.

We should also note a few similar randomized comparative trials in the last year. One, at Fox-Chase (n=333), looked at 76 Gy delivered in 38 fractions of 2 Gy each (normal fractionation) compared to 70 Gy delivered in 26 fractions of 2.7 Gy each (hypofractionated) among intermediate and high-risk patients. The 5-year biochemical and/or clinical disease failure rate was the same -- 21% for normal fractionation, 23% for hypofractionation -- and there was no difference in late term toxicity, except among men with compromised urinary function.

An M.D.Anderson study (n=203) compared the late toxicity of a normally fractionated schedule (76 Gy in 1.8 Gy fractions) to a hypofractionated schedule (72 Gy in 2.4 Gy fractions). As in the UK study, there were no differences in GU toxicity. There was an increase in GI toxicity in the hypofractionated group, although it was not statistically significant. Unsurprisingly, the authors found it was related to the volume of the rectum that received high doses.

A multi-institutional study from the Netherlands among intermediate and high-risk men (n=820) reported on the acute toxicity of a normally fractionated schedule (78 Gy in 2 Gy fractions) compared to a hypofractionated schedule (65 Gy in 3.4 Gy fractions). At 3 months, there was no difference in GI or GU toxicity. At 6 months, there was no difference in GU toxicity, but GI toxicity was higher in the hypofractionated group (42% vs. 31%).

We also saw recently (see: Can salvage radiation therapy be safely and effectively completed in less time?) that a shortened treatment schedule appeared to be safe and effective for salvage IMRT. However, this UK study is more compelling because it is a randomized comparative trial of great size.

The only impediment seems to be the higher rate of acute rectal side effects. The patient will have to decide if it is worth accepting those transient symptoms in exchange for the convenience of a 4-week treatment schedule. Given the lower rate of patient-reported adverse outcomes and the high rate of oncological control with SBRT, however, it would seem that the 10-day schedule (5 fractions, every other day) is a better alternative on all counts.

SBRT for Oligometastatic Recurrence

Although the theory of the existence of a temporarily stable oligometastatic stage in prostate cancer is more than 20 years old, it remains unknown whether there is any benefit to pursuing curative or progression-delaying radiation if there are only a few metastases detected at recurrence. All of the studies so far have been very small, single-institution studies, lacking randomization, control groups, or consistent treatments. Ost et al. have pooled much of the existing data into a meta-analysis focusing only on those patients whose few metastases at recurrence were treated with SBRT.

In all, they identified 119 patients from 6 studies with the following characteristics:

• ·      3 or fewer metastases were identified at recurrence any time after radical treatment.

o   One in 72%, two in 19%, three in 9%

o   163 metastases detected

o   Median time from diagnosis to detection: 4.7 years

• ·      Primary metastasis sites were nodal (60%), bone (36%), or visceral (4%).
• ·      Detection was via Choline PET/CT (77%), FDG PET/CT (20%), and MRI (3%).
• ·      Median PSA at detection was 4.0 ng/ml, with a doubling time of 5.6 mos.
• ·      Adjuvant ADT was used in half the cases for a median of 2 months (range: 1-8 mo.)

o   Excluded if ADT>12 months or ongoing at time of metastasis detection.

• ·      Primary therapy was RP only (18%), RT (25%), or RP+aRT/sRT (57%).

After a median follow up of 3 years after SBRT treatment of metastases:

• ·      Distant progression was detected in 61%.

o   Distant progression-free survival was 31% at 3 years, 15% at 5 years.

o   Median distant progression-free survival was 21 months.

o   70% had 3 or fewer metastases at time of progression.

• ·      Median time to start of palliative ADT was 28 months.

o   Half received a second course of SBRT.

• ·      Local progression-free survival was 93% at 3 years; 92% at 5 years.

o   Local progression was significantly greater at lower SBRT doses.

o   Local progression occurred at 18 months without adjuvant ADT, 25 months with adjuvant ADT, but the difference wasn’t statistically significant.

• ·      Overall survival was 95% at 3 years, 88% at 5 years.
• ·      Late Grade 2 GI toxicity was 3%, none greater.

The metastasis-directed SBRT treatment did an excellent job at eradicating the specific metastases at which it was directed, and the toxicity was remarkably low. However, that did not halt the cancer’s progression, except in 15% at 5 years, and presumably in fewer after longer follow up. The question remains, however, did the treatment slow down the cancer, allowing for many extra months and perhaps years of survival, and especially of symptom-free survival? After all, we were happy to get even a few months of extra survival out of our newest drugs like Xtandi, Zytiga, and Jevtana. There was no distant progression in these closely watched patients for almost 2 years, and even then, the metastatic burden was low. Given that there was almost no toxicity risk, should routine SBRT treatment of oligometastases at recurrence be a new standard of care?

That’s a very hard question to answer, even with the pooled data in this study. The problem is that we don’t know what would have happened had they not been treated. Were these patients really slow to progress, or do they only appear to be because they were so closely watched with advanced imaging from a very early point (lead-time bias)?

Some have theorized that there is a type of slowly metastasizing prostate cancer that these studies are selecting for – in that case, it is just a characteristic of that particular type of low-metastases prostate cancer and not the treatment that is slowing progression. We have seen so far in the CHAARTED trial that low-burden metastatic disease progresses and responds differently to docetaxel and ADT compared to polymetastatic prostate cancer. One study found that there is a microRNA that may distinguish between the oligometastatic type and the polymetastatic type. This hints at a distinct phenotype that may be particularly amenable to oligometastatic treatment. If so, perhaps we will eventually be able to identify biomarkers to select candidates for it.

On the other hand, a recent study that found that cancer often spreads from metastasis to metastasis bolsters the claim that oligometastatic treatment may be at least partially effective in all cases. To determine which hypothesis is true we’ll need clinical trials. Almost all of the studies on SBRT for oligometastases are very small, and have taken place in Europe. I am not aware of any planned clinical trial in the US. There are only a few Phase 2 trials in Spain, Germany, and Canada.

Because most of the detected oligometastases were in the pelvic lymph nodes, there is a special opportunity for lymph node-only treatment. Arguably, the entire pelvic lymph node area, and not just individual detected nodes, ought to be treated, and this was done in about 40% of the cases. There may be micrometastases that are too small to be detected in the pelvic lymph system. That area is typically not treated during primary radiation therapy, or during adjuvant/salvage radiation treatment. It may, in some cases be amenable to additional radiation if previous treatment was not too wide, was long ago, and anatomic considerations (e.g., visceral fat) allow for it. Recent analyses by Rusthoven et al. and by Abdollah et al. found a survival benefit to such whole pelvic salvage radiation (type unspecified), but Kaplan et al. failed to find a benefit. Salvage SBRT whole pelvic treatment for recurrent patients with positive nodes has yet to be explored in sufficient numbers of patients to draw conclusions about it.

With the growing number of test sites for the new generation of high-accuracy PET scans (e.g., C-11 Choline, Ga-68-PSMA, PET/MRI, etc.), it may become increasingly possible to detect advanced prostate cancer in the oligometastatic stage. SBRT treatment centers are also increasingly available, and the treatments are brief (typically 1-3 fractions), relatively inexpensive, and apparently very safe. As long as patient expectations are reasonable – that treatment may be able to delay, but not cure - it’s hard to argue against its use.

HDR Brachy Boost and Monotherapy for High-Risk Prostate Cancer

Three randomized clinical trials (Sathya et al. 2005, Hoskin et al.2012, and Guix et al.2013) established combination therapy of external beam radiation (EBRT) with a high dose rate brachytherapy (HDRBT) boost as a standard of care in the treatment of high-risk prostate cancer. In all three of those trials, the outcomes exceeded those from EBRT alone, but at a cost of higher toxicity.

In previous studies of this combination therapy for high-risk patients, freedom from biochemical relapse have ranged from 67-97% at 5 years, and from 62 -74% at 10 years. Late term genitourinary (GU) grade 3 toxicity ranged from 0-14.4% (median 4.5%); gastrointestinal (GI) grade 3 toxicity ranged from 0-4.1% (median .5%); chronic incontinence ranged from <1%-3.8%; urethral strictures ranged from .9-7.4% (median 4.5%); and erectile dysfunction ranged from 10-51% (median 31.5%).

It may be helpful to understand how large the effective doses of radiation were that were used in all of the aforementioned studies. The term “biologically effective dose” (BED) enables us to compare the cancer-killing power of the absorbed radiation across different radiation modalities. To provide a point of comparison, I show the BED as a % of the BED of a typical modern IMRT schedule, 80 Gy in 40 fractions (fx), which has a BED of 187 Gy.

Table 1 – Improved recurrence-free survival, but higher GU toxicity from boost therapy

Study	Modalities	Dose Schedule	BED Compared to 80 Gy IMRT	Freedom from recurrence among high risk	Follow up	Late grade 3 GU toxicity
Sathya et al. (2005)	HDRBT + EBRT	35 Gy over 48 hrs. +40 Gy/20 fx	-6%	71%	8.2 yrs median	14%
	EBRT only	66 Gy/33 fx	-17%	39%	8.2 yrs median	4%
Hoskin et al. (2012)	HDRBT + EBRT	17 Gy/2 fx + 35.75 Gy/13 fx	+15%	66%	7 yrs	11%
	EBRT only	55 Gy/20 fx	-17%	48%	7 yrs	4%
Guix et al. (2013)	HDRBT + EBRT	16 Gy/2 fx + 46 Gy/23 fx	+12%	98%	8 yrs	NA
	EBRT only	76 Gy/38 fx	-5%	91%	8 yrs	NA

Could equal oncological outcomes be accomplished but with less toxicity by using high dose rate brachytherapy as a monotherapy? The maturing of data from a clinical trial in Japan suggests it can be.

Yoshioka et al. (2015) have used HDRBT monotherapy on 111 high-risk patients treated from 1995 to 2012. Almost all of them (94%) received ADT as well. They evaluated 3 dosing schedules: 48 Gy/8 fractions, 54 Gy/9 fractions, or 45.5 Gy/7 fractions inserted over 4 to 5 days. 

With a median of 8 years of follow up, the authors report:

• ·      Biochemical no evidence of disease – 77%
• ·      Metastasis-free survival – 73%
• ·      Overall survival – 81%
• ·      Cause-specific survival – 93%
• ·      Late GU grade 3 toxicity – 1%
• ·      Late GI grade 3 toxicity – 2%

Unfortunately, they haven’t reported rates of erectile dysfunction. Other monotherapy series report ED rates of about 25%, and there’s no reason to suppose it would be particularly different for high-risk patients. They report no significant differences in oncological control or toxicity according to total dose or dose schedule used.

The biochemical control rates are well within the range seen for combination therapy at 5 to 10 years after treatment. At the same time, the rates of serious late term GU and GI side effects seem to be improved by the monotherapy.

Other recent studies have reported excellent results for HDRBT monotherapy for high-risk patients. Zamboglou et al. (2012) reported the monotherapy outcomes of 146 high-risk patients treated between 2002 and 2009. 60% received ADT as well. They evaluated 3 dosing schedules: 38 Gy in four fractions in one implant, 38 Gy in four fractions in two implants, and 34.5 Gy in three fractions in three implants. After 5 years, biochemical control was 93%, late grade 3 GU toxicity was 3.5%, and late grade 3 GI toxicity was 1.6%. The differences in toxicity among the dosing schedules were not statistically significant. Among previously potent men, only 11% lost potency sufficient for intercourse. The highest dose schedule did not have better oncological control or worse toxicity than the lower dose schedules.

Hoskin et al. (2012) reported the monotherapy outcomes of 86 high-risk patients treated between 2003 and 2009. Almost all of them (92%) received ADT as well. They evaluated 4 dosing schedules: 34 Gy in four fractions, 36 Gy in four fractions, 31.5 Gy in three fractions, and 26 Gy in two fractions. After 4 years, biochemical control was 87%, late grade 3 GU toxicity was 12%, and late grade 3 GI toxicity was 1%. It is not clear why GU toxicity was higher than in the other two studies. They did not report erectile dysfunction. Although higher rates of strictures, ranging from 3-7%, and urinary toxicity occurred on the most aggressive dosing schedules, the differences were not statistically significant on this sample size. Similarly, the difference in recurrence-free survival at the lowest dose was not statistically significant.

Table 2. Clinical trials of HDRBT monotherapy for high risk

Study	Dose Schedule	BED Compared to 80 Gy IMRT	Freedom from recurrence among high risk	Follow up	Late grade 2+ GU toxicity	Late grade 3+ GU toxicity
Yoshioka et al. (2015)	48 Gy/8 fx	+29%	77%	8 yrs	NA	1%
	54 Gy/9 fx	+45%			7%
	45.5 Gy/7 fx	+30%			6%
Zamboglou et al. (2012)	38 Gy/4 fx/1 implant	+49%	97%*	5 yrs	9% retention 9%incontinence	3% retention 1% incontinence
	38 Gy/4 fx/2 implants	+49%	94%*	5 yrs	7% retention 5% incontinence	2% retention <1%incontinence
	34.5 Gy/3 fx/3 implants	+60%	95%*	3 yrs	5% retention 8% incontinence	1% retention 1% incontinence
Hoskin et al. (2012)	34 Gy/4 fx	+21%	77%	5 yrs (median)	33%	3%
	36 Gy/4 fx	+35%	91%	4.5 yrs (median)	40%	16%
	31.5 Gy/3 fx	+35%	87%	2.8 yrs(median)	34%	14%
	26 Gy/2 fx	+35%	NA	.5 yrs (median)	NA	NA

*across all risk groups, high risk only was 93%

Within all three published studies, there were no statistically significant dose-response relationships in terms of either oncological control or toxicity. However, looking across the three, it may be that the higher doses provided better control at the cost of some higher toxicity. I hope someone will do a meta-analysis on the full data sets to confirm that. Larger studies will be needed to determine whether toxicity increases with the more aggressive dosing schedules. All the control rates were within the range of the combination therapies, and all of the toxicities were acceptable. Evidently, all of the studies applied enough radiation to effectively kill the high-risk cancer. Nor did the dosing schedule used have an impact on results. HDR brachy monotherapy as currently practiced uses anywhere from a single fraction to nine fractions, and anywhere from a single implant to three implants.

It is difficult to draw conclusions about the use of ADT. All three studies utilized high rates of adjuvant ADT – over 90% in two of the studies. The study with the lowest rate of ADT utilization, Zamboglou et al., at 60%, also used the highest radiation doses. Although Demanes et al. found that ADT had no incremental benefit when used with combination therapy, that study was in the early years (1991-1998) when relatively low radiation doses were used. Until there is a randomized clinical trial of its use with HDRBT monotherapy, it will be hard to walk away from using ADT.

Unlike low dose rate brachytherapy (seeds), HDRBT can treat areas outside of the prostate, including the prostate bed and the seminal vesicles. However, to my knowledge, it has not been used to treat pelvic lymph nodes, which would be impossible to find using current imaging technology. In all three studies, patients were screened for evidence of lymph node involvement. Clearly, HDRBT monotherapy is not a good choice if LN involvement is suspected. There are calculators for predicting such risk based on Gleason score, PSA and cancer volume. High-risk patients may have a statistically high risk for LN involvement without showing evidence, but even the “high risk” levels are not very high, so treatment remains controversial. One clinical trial (Lawton et al.) demonstrated a benefit to full-pelvic IMRT coupled with neoadjuvant ADT, and there is a current clinical trial that allows for a brachy boost (RTOG 0924) that may confirm that finding.

SBRT is radiologically identical to HDRBT, and as discussed in a recent article, its use for high-risk patients is also being explored. Both of these treatments have the potential to provide excellent cancer control while minimizing the side effects of treatment, and with a considerable time and cost advantage over IMRT-combo treatments. I encourage high-risk patients to enroll in clinical trials for both alternatives. HDRBT monotherapy for high risk is part of a clinical trial at Stanford (NCT02346253).