Showing posts with label clinical trial. Show all posts
Showing posts with label clinical trial. Show all posts

Monday, November 28, 2016

Dose Escalation for Salvage Radiation


In the late 1990s and early 2000s, the advent of more accurate linear accelerators (linacs) and image-guidance technology for delivering therapeutic X-rays to prostate cancer changed the dose that could be safely given. In the late 1980s, the typical dose was only in the mid-60 Gy range. By the early 2000s most of the top prostate cancer treatment centers were delivering 80 Gy (at 1.8 or 2.0 Gy per treatment) with higher cure rates and lower toxicity. Dose escalation for primary treatment of prostate cancer was a resounding success and became the standard of care.

However, dose escalation was not utilized appreciably in salvage radiation treatment (SRT) after prostatectomy. The reasons doses were kept lower in the salvage setting were that:

  • Toxicity might be higher because radiation could be especially damaging when applied to tissue that had been cut or stressed by surgery.
  • Without the shielding effect of the prostate in place, sensitive structures like the bladder neck, the rectum, the penile bulb, and the urethra would receive the full brunt of the radiation.
  • Unlike the relatively large tumors in an intact prostate, the cancer in the prostate bed was small or microscopic and didn’t need as large a dose of radiation to eradicate it.

Current guidelines by the American Urological Association (AUA) and The American Society of Radiation Oncologists (ASTRO) establish a minimum dose of 64-65 Gy for SRT, but do not establish an optimum dose, citing lack of available evidence. At the top treatment centers, radiation oncologists routinely deliver doses as high as 70 Gy, but seldom higher. The outstanding question is: what is the optimum dose for SRT? That is, what dose offers the best chance at a cure with acceptable toxicity?

The Dose/Response Curve

Radiation oncologists talk about an S-shaped “dose/response curve.” At the bottom of the “S,” we know that at very low radiation doses there is very little “response,” meaning very few cancer cells are killed. At a certain radiation level, a lot more cancer cells are killed, and even a small increase in dose will kill a lot more cancer cells. This is called the “steep” part of the dose/response curve. After the steep part, adding more dose doesn’t kill a lot more cancer cells, but it begins to kill off healthy cells, increasing toxicity. The optimal dose is reached just before this happens at the top of the steep part. Below is what a dose/response curve looks like:


The Study

Dr. Christopher King (see this link) analyzed data from 71 studies, representing 10,034 patients treated who received SRT between 1996 to 2015 to see if the data conformed to a dose/response curve. He found an excellent fit:
  • SRT dose was the single most important factor correlated with recurrence-free survival
  • PSA at the time of SRT was the second most important factor
  • Other factors (stage, Gleason score, positive margins, lymph node invasion, and use of adjuvant ADT) were less important.
  • At an SRT dose of 66 Gy, half the patients were recurrence-free after SRT
  • Recurrence-free survival increased by 2 percentage points for each additional Gy of SRT dose.
  • The dose/response curve for SRT fit almost perfectly to the dose/response curve for primary RT.
Because the curves seem to be identical whether it was for primary therapy or for salvage therapy, it implies that even the microscopic prostate cancer cells lingering in the prostate bed require as much radiation to finish them off as the larger tumors within the prostate. This radioresistance will not surprise those of us who have noticed the improved cancer control patients get with a brachytherapy boost given for primary radiation therapy.

How much better cancer control can we expect?

It’s hard to know how high recurrence-free survival can get if the dose is increased. The statistics suggest that increasing the SRT dose from 66 Gy to 76 Gy will increase recurrence-free survival from 50% to 70% at 5 years of follow-up. But this is unknown territory, and in some patients, undetectable distant metastases will have already occurred. Of the 71 studies reviewed in this meta-analysis, only 4 included doses above 70 Gy. Dr. King is proposing a clinical trial where patients are randomized to receive 66 Gy or 76 Gy.

76 Gy for SRT – is that safe?

Only one study included a dose this high. Ost et al. treated 136 patients. 5-year biochemical recurrence-free survival was 56%, but patients were treated fairly late – median PSA had already reached 0.8 ng/ml by the time SRT began, and most had adverse pathology findings. They report reasonable late toxicity: 4 patients (3%) suffered a grade 3 urinary event, and 1 case of a grade 3 rectal adverse event. However, they do note that a lot of the grade 2 toxicity seemed to be chronic rather than transient. 39% suffered long-lasting grade 2 urinary toxicity, and 18% suffered from long-lasting grade 2 rectal toxicity. I assume patients will be excluded from Dr. King’s clinical trial if they still have urinary issues from surgery. There is no data on the effect of dose escalation on erectile dysfunction.

There has been one randomized clinical trial of SRT dose escalation in the modern era. The SAKK 09/10 trial found little difference in acute toxicity symptoms at 70 Gy compared to 64 Gy, but patient-reported urinary symptoms worsened.

Can SBRT be used instead of IMRT?

There have been a few clinical trials of hypofractionated SRT that seem promising (see this link). UCLA will be starting a trial next year as well. An IMRT dose of 76 Gy is biologically equivalent in its cancer control to 5 SBRT treatments totaling 33 Gy.

The challenges for SBRT are greater than for IMRT. Because the dose per treatment is so high, even a small “miss” can increase toxicity and reduce effectiveness. It is difficult to use fiducials in the prostate bed, and the soft tissue is highly deformable and subject to motion from the bowels and bladder. The radiation oncologist will have to use soft tissue landmarks and site them multiple times per treatment. A filled bladder and good bowel prep are important, as is a very fast linac. Careful planning and strict adherence to dose constraints to organs at risk are essential.

Implications for pelvic lymph node treatment

If prostate cancer in the prostate bed requires almost 80 Gy, what can we infer about microscopic cancer that has spread to pelvic lymph nodes? It would seem that that cancer would be equally radioresistant. The pelvic lymph nodes area is often treated with a dose of about 50 Gy. Unfortunately, as the radiation field increases to extend to the entire pelvic area, many more organs are subject to toxic reactions. The enteric tissue of the small bowel is particularly prone to late reactions. In a database analysis at Fox Chase Cancer Center, patients treated with 56 Gy to the whole pelvis for high-risk prostate cancer may have had gastrointestinal reactions as long as 9 years later. We await the findings of randomized clinical trials (RTOG 0534 and PRIAMOS1) to tell us whether such treatment is effective.

Discuss with your radiation oncologist

Although Dr. King’s meta-analysis is impressive in the amount of data represented, it is not a randomized trial that would change clinical standards on its own. Even so, it is certainly worth discussing with one’s radiation oncologist before committing to a treatment plan. There are many considerations for the patient  - especially his current status with regard to urinary and erectile function. For patients with few adverse pathology findings (e.g., long PSA doubling time, low Gleason score, no obvious capsular penetration), the risk of extra toxicity may not be worthwhile. It’s a judgment each patient must make for himself.



Note: Thanks to Dr. Christopher King for allowing me to see the full text of his study.




Saturday, September 17, 2016

Patient-reported outcomes from ProtecT - the first randomized trial comparing surgery, radiation, and active surveillance

While there were no differences in 10-year mortality when patients were randomized to surgery (RP), external beam radiotherapy (EBRT), and active surveillance (AS) (see this link), the side effects patients suffered from those treatments differed markedly. Johnson et al. have published the patient-reported outcomes of the ProtecT trial in the New England Journal of Medicine (see this link).

In the ProtecT trial, all participants (or actually 85% of them) filled out a series of validated questionnaires (EPIC and others) that probed issues of urinary function, rectal function, sexual function, and general health. I will ignore the overall health, vitality and mental status questions for now. Suffice it to say that they did not differ among therapies, nor were they very much affected by them. Questionnaires were filled out before the biopsy (the baseline), and at 6 and 12 months after randomization, and annually thereafter until 6 years from the initial biopsy.

What is especially interesting is seeing how equivalent patients (they are equivalent because they were randomized to the 3 treatments) did over the 6 years after receiving each treatment. This means that, for the first time, the side effect profiles are completely comparable (well, almost) and almost without bias.

Some messy data

I say "almost" because there was some switching of treatments that did occur. 22% of the men did not get the therapy they were originally randomized to, and they self-selected some other therapy or no therapy. However, in the analysis they are treated as if they got therapy that they were originally intended to get. Strange, huh?

In addition, they may have received salvage therapy after biochemical failure, and 55% of those assigned to AS did get a radical therapy eventually. So for each intended therapy:
  • Among those 291 men who started on AS but got radical treatment: 49% had surgery, 33% had radiation as specified, and 18% had another kind of radiation or HIFU
  • Among those 391 men who started on RP, 14 (4%) had adjuvant or salvage radiation, and 1 went on lifelong androgen deprivation therapy (ADT) within a year.
  • Among those 405 men who started on EBRT,  3 had salvage RP, 14 (3%) went on lifelong ADT, and 1 had HIFU.
Whether men had the assigned therapy or not, and irrespective of any other therapy they had, they are included with the group they were originally assigned to. It's messy.

Fortunately, there's hope in sight. In one of the Appendices (Section S3), they added the note:
"In future analyses, we intend to present patient-reported outcomes according to treatment received and an economic evaluation including assessment of therapies received for treatment impacts, as well as details about the reasons for change of management in the active monitoring arm to further inform individual and clinical decision-making"

That will give us a much truer picture of the side effects associated with the treatments they actually received.

The treatments

RP was open and nerve sparing. While most men now have robotic surgery rather than open surgery, it seems to make little difference, except for some higher incidents of issues arising during the operation (see this link).

AS did not have required follow-up biopsies, so their side effects may be a little better than on contemporary AS programs. Biopsy complications are never long-lasting anyway.

EBRT was different from contemporary standards. The dose was lower (74 Gy vs. 80 Gy), so there may have been fewer complications due to dose. They used an older delivery technique (3D-CRT vs IMRT) which had higher rates of side effects. And it was given together with short term (3-6 months) of ADT, which would certainly increase the early sexual side effects. ADT is seldom given to favorable risk patients today.

note: all of the patient-reported outcomes include the effect of whatever remedies they used to treat them.

1. Urinary Adverse Outcomes

a. Incontinence

This was a big issue for RP, of course, but not for AS or EBRT. The percent using one or more pads per day is one commonly used measure. As one can see in the following table, incontinence was highest at the 6-month time point, but had gotten somewhat better by the end of the first year. 20% were incontinent by the end of two years, with little improvement from that point.

For EBRT, incontinence peaked at 5% at 6 months. Remember, this was 3D-CRT - a technology that has greater toxicity than the IMRT predominantly in use now. It hovered around 3-4% thereafter.

For AS, incontinence also peaked at 4% at 6 months, and stayed at that level for the next couple of years. From then, it steadily rose to 8% by the end of the 6 year study. Remember that for the purposes of this trial, men were still included in the AS cohort whether they were eventually treated or not. By 6 years, more than half the men had been treated, primarily with surgery.

Table 1. Incontinence: The percent who used one or more pads per day

Time point
AS
RP
EBRT
Baseline
0%
2%
0%
6 months
4%
46%
5%
1 year
4%
26%
4%
2 years
4%
20%
4%
3 years
5%
20%
3%
4 years
7%
17%
4%
5 years
7%
17%
3%
6 years
8%
17%
4%


b. Urinary Irritation/Obstruction

The researchers examined the question of whether urination become more difficult or more frequent after therapy. One way to look at this is a set of questions on the EPIC questionnaire asking about urinary frequency and retention. On that questionnaire, a score of 100% means that function is perfect in that regard, no issues whatever.

On this dimension only EBRT had a clinically detectable effect, and it was only at the 6 month mark. EPIC score dropped from 93% to 84%. After that, it returned quickly to baseline levels.

Table 2. Urinary Irritation/Obstruction EPIC scores, where 100% would be the best possible score.

Time point
AS
RP
EBRT
Baseline
93%
92%
94%
6 months
92%
89%
84%
1 year
93%
93%
93%
2 years
92%
93%
93%
3 years
91%
93%
93%
4 years
91%
94%
93%
5 years
92%
94%
93%
6 years
92%
94%
93%

2. Rectal Adverse Outcomes

The researchers asked the trial participants about their bowel function at baseline and after treatment. There were no discernable effects of AS or RP. Bowel function among the men enrolled for EBRT declined by 6 months (from a score of 93% to 86%). Thereafter, bowel function scores returned to near baseline levels. Other than the 6 month time point, there were no significant differences among the 3 treatments.

Table 3. Bowel function EPIC scores, where 100% would be the best possible score.

Time point
AS
RP
EBRT
Baseline
92%
91%
93%
6 months
91%
92%
86%
1 year
92%
93%
90%
2 years
92%
93%
90%
3 years
92%
93%
91%
4 years
92%
93%
91%
5 years
92%
93%
90%
6 years
92%
92%
91%

3. Sexual Adverse Outcomes

This is one of the few trials that asked men detailed questions about their sexual function at baseline and for 6 years thereafter. One of the key measures of sexual function is the ability to have erections firm enough for intercourse. At baseline, about two-thirds of these 62 year old men (range 50-69), some with other comorbidities like diabetes, cardiovascular disease, and smoking, had suitable erectile function. 

None of the questionnaires asked about perceptions of penile shrinkage in length and girth, climacturia (urination at orgasm), or Peyronie's (abnormal penile curvature), which are often symptoms that affect sexual function post-prostatectomy. Nor do they ask about how the loss of ejaculate has affected sex. That is a certainty with surgery, a near-certainty after radiation, and is not affected by AS. Their definition of erectile function includes the effect of any erectile function aids (e.g. ED meds, injections, pumps, or implants) they may have been using.

For those randomized to RP, erectile function was reduced to 12% at 6 months (remember: they all had nerve-sparing surgery). It recovered somewhat to as much as 21% at 3 years but did not recover beyond that. At every time point, their erectile function was significantly worse than the other treatment cohorts.

For the AS cohort, erectile function declined by 6 months and continued to deteriorate thereafter as they elected to have radical therapies, predominantly surgery. 11% of this cohort had already elected to have radical treatment by the 6-month mark.

For the EBRT cohort, erectile function had dropped to a minimum value of 22% at 6 months. This may be largely attributable to the fact that all of the men in the EBRT cohort had 3-6 months of ADT. It is unknown how much, if any, of their testosterone came back after that and how long it took to recover. Erectile function snapped back a bit post-ADT, getting as high as 38% at 1 year, and declined to 27% by 6 years. Again, this was based on the 3D-CRT technology, and is below the rates usually seen for this age group with IMRT, brachytherapy, or SBRT.

Table 4. Erectile function - the percent who had erections firm enough for intercourse

Time point
AS
RP
EBRT
Baseline
68%
65%
68%
6 months
52%
12%
22%
1 year
49%
15%
38%
2 years
47%
19%
34%
3 years
41%
21%
34%
4 years
37%
20%
32%
5 years
35%
20%
27%
6 years
30%
17%
27%


Myths Exploded by this study:

Myth #1: The side effects end up about the same for surgery or radiation

That's clearly not true for incontinence or erectile function, It is true for urinary irritation and rectal function, which are at baseline levels and similar in all cohorts at 6 years.

Myth #2: With surgery, you get the side effects all at once and steadily recover; with radiation, the side effects come on steadily and may hit you many years later.

What we've seen here belies that myth. There is some recovery of continence up to two years later, but not thereafter. After radiation, incontinence was a minor symptom (except to those who had it, of course), but it did not increase over the years. Urinary irritation/obstruction increased at 6 months for EBRT, but returned to baseline permanently thereafter. Rectal function scores also permanently returned to baseline levels after the 6-month time point.

Myth #3: Over time, erectile function is about the same for surgery and radiation. 

As we've just seen, erectile function is much worse after surgery, and it never recovers much beyond 2 years. It is worth tracking this myth down to its source. I have even heard John Mulhall, the eminent Memorial Sloan Kettering sex specialist quote this myth.

I believe this myth started with the PROSTQA study published in 2008. Until the ProtecT trial, it was our best source of patient-reported outcomes after the various treatments. The patients were not randomly assigned, however, and differed markedly in their characteristics. Those characteristics, especially age, varied greatly with the treatments they chose. In the following table, hidden in an appendix (all the good stuff is usually back there), we can extract the following table:

Table 5. Percent with preserved erectile function sufficient for intercourse 2 years after treatment, broken down by age at treatment 



Age
RP
EBRT
BT
<50
55
100*
75*
50-59
43
52
67
60-69
27
39
44
70+
8*
30
24
Total
35
37
43
Median Age
60 years
70 years
66 years

small sample size

Although the potency doesn’t seem to vary much between treatments in total (range 35% to 43%), it is only because the men who received EBRT and BT were older than the men who were treated with RP. Within every age group, potency preservation was higher with radiation.

There are other differences between the two studies, such as: 
• this table only includes men who were potent before therapy, which would exclude about a third of men in the ProtecT trial. This would lower all the percentages in Table 5 relative to Table 4. 
• ProtecT included only men in the 50-69 age range, while half of the findings in ProstQA came from men treated with radiation over the age of 70. 
• Finally, ProtecT didn't yet report erectile function according to the therapy or therapies they actually received.

It is gratifying to see these myths shattered. Patients are the beneficiary.