After nearly 20 years of follow-up among men
with localized prostate cancer, surgery was not associated with significantly
lower all-cause or prostate-cancer mortality than observation. Surgery was
associated with a higher frequency of adverse events than observation but a
lower frequency of treatment for disease progression, mostly for asymptomatic,
local, or biochemical progression.
Put aside the adverse events since it is well
known that any surgery has such a risk. We would focus on survival alone. The
authors continue:
In conclusion, radical prostatectomy was not
associated with significantly lower all-cause or prostate-cancer mortality than
observation through 20 years of follow-up among men with localized prostate
cancer that was diagnosed during the early era of PSA testing. Absolute
differences remained below 6 percentage points. Death from prostate cancer was
very uncommon among men with low-risk disease who were assigned to observation.
Surgery may be associated with decreased mortality among men with intermediate risk
prostate cancer, depending on the pathological classification. Surgery resulted
in substantially greater long-term urinary incontinence and erectile and sexual
dysfunction than observation and was associated with a significantly lower risk
of disease progression and additional treatments, most for local or
asymptomatic biochemical progression.
The problem with this analysis is as follows:
1. It is clinically well known that a small
percentage of all PCa is of a highly aggressive form.
2. The highly aggressive form almost always
results in death.
3. The highly aggressive form occurs early in
the onset of the disease and metastasis is almost immediate.
4. The specific genetic makeup of this highly
aggressive form is currently undetermined. Moreover there may be a pleiomorphic
genetic presentation.
5. However, whenever it is suspected, such as
presented in the above paper, the detailed genetic makeup of the cancer cells
should and must be determined. It was not apparently done here. Not all PCa is
the same.
Thus we examine the data from the perspective
of the putative existence of a highly aggressive form.
The Press does take this report to arguable
extremes as is usually the case. Science Daily states[1]:
Prostate cancer surgery offers negligible
benefits to many men with early-stage disease, a major 20-year study
demonstrates. In such men, who account for most cases of newly diagnosed
prostate cancer, surgery did not prolong life and often caused serious
complications such as infection, urinary incontinence and erectile dysfunction…In
men with early prostate cancer, the study compared surgery with observation.
With the latter, men only were treated if they developed bothersome symptoms,
such as urinary difficulty or bone pain. Such symptoms may indicate progression
of the cancer.
Many men in the observation group received no
treatment at all because early-stage prostate cancer often grows slowly and
rarely causes symptoms. To evaluate any potential benefits of surgery,
the researchers randomly assigned 731 men in the U.S. with localized prostate
cancer to receive either surgery or observation at one of 44 Department of
Veteran Affairs Health Care Centers or eight academic medical centers,
including Washington University. The average age of men in the study was 67 at
the time of enrollment. Of the men who had prostate cancer surgery, 223 (61
percent) died of other causes after up to 20 years of follow-up, compared with
245 men (66 percent) in the observation group -- a difference that is not
statistically different. Further, 27 (7 percent) men in the surgery group died
of prostate cancer, compared with 42 men (11 percent) in the observation group,
but that difference also is not statistically significant.
However, the data show that surgery may have a
mortality benefit in some men, particularly those with a long life expectancy
and intermediate-risk prostate cancer. (Such men generally have PSA scores of
10-20 ng/ml and a Gleason score of seven. The latter score signifies tumor aggressiveness.)
One of the major concerns here is that there is
a limited amount of data on each patient. Since the progression of PCa can be
dramatically different depending upon a plurality of factors at presentation,
it is essential that such details be incorporated in such an analysis.
Moreover, if such an incorporation were included then the size of the sample is
easily an order of magnitude larger than what was done here.
Herein we examine some of the elements of this
paper and consider critiques which require some attention. All too often papers
like this end up as significant elements of policy and limiting care to men who
require it. The definitive conclusions are in my opinion at best speculative.
Let us begin with several definitions used and
referred to in the paper. Namely the definitions of risk. The Table below is
from Rodrigues et al and presents a list of Low, Intermediate and High risk
criteria.
The D'Amico specific criteria are summarized
below.
Institution/
organization
|
Low risk
|
Intermediate risk
|
High risk
|
D'Amico
|
T1-T2a, Gleason less than 6, PSA less than 10 | T2b, Gleason equal to 7, PSA between 10 and 20 | Greater than T2c, Gleason between 8 and 10, and PSA greater than 20 |
Note that for the low case we have Gleason score of less
than 6 which is quite low and no Mets and a PSA less than 10. Most urologists
are aware that even here there may be a small number, say 5%, who despite this
favorable set of measurements go on to an aggressive cancer.
Let us also briefly summarize the issue of Staging[2].
This we do below:
Primary
tumor (T)
- TX: Main tumor cannot be measured.
- T0: Main tumor cannot be found.
- T1, T2, T3, T4: Refers to the size and/or extent of the main tumor. The higher the number after the T, the larger the tumor or the more it has grown into nearby tissues. T's may be further divided to provide more detail, such as T3a and T3b.
Regional
lymph nodes (N)
- NX: Cancer in nearby lymph nodes cannot be measured.
- N0: There is no cancer in nearby lymph nodes.
- N1, N2, N3: Refers to the number and location of lymph nodes that contain cancer. The higher the number after the N, the more lymph nodes that contain cancer.
Distant
metastasis (M)
- MX: Metastasis cannot be measured.
- M0: Cancer has not spread to other parts of the body.
- M1: Cancer has spread to other parts of the body.
We summarize these in the following Table. Note
that for th prostate HG PIN is considered CIS. This is despite the fact that
some HG PIN resolve uneventfully to a benign state. This has been noted in
other cancers as well such as breast and melanoma.
Stage
|
What it means
|
Stage 0
|
Abnormal cells are present but have not spread to nearby tissue. Also
called carcinoma in situ, or CIS. CIS is not cancer, but it may become
cancer.
|
Stage I, Stage II, and Stage III
|
Cancer is present. The higher the
number, the larger the cancer tumor and the more it has spread into nearby tissues.
|
Stage IV
|
The cancer has spread to distant parts of the body.
|
Let us begin by examining the Wilt et al data.
Our focus is on Table 2. Cumulative Incidence of Death from Prostate Cancer
through 19.5 Years. The data for that Table can be summarized as below:
Radical
Prostatectomy
|
Observation
|
|||||
Low
|
Medium
|
High
|
Low
|
Medium
|
High
|
|
Total
|
148
|
129
|
77
|
148
|
120
|
80
|
Mean
|
4.100
|
8.500
|
13.000
|
5.400
|
15.800
|
18.800
|
Low
|
1.900
|
4.800
|
7.200
|
2.800
|
10.400
|
11.700
|
High
|
8.600
|
14.600
|
22.300
|
10.300
|
23.400
|
28.700
|
Sigma
|
1.675
|
2.450
|
3.775
|
1.875
|
3.250
|
4.250
|
We have added percent numbers to the data for
clarity. They are percent mortality.
Let us examine a simple case. First for the Low
Risk we have a mean death from PCa as 4.1%. In the Observation class the death
was 5.4% The probability density for these are shown below:
There clearly is a greater risk in just
Observation. Now consider the High risk case. This we show below:
Again there is a substantially high rate of death.
Assume there are two distinct types of PCa. In
each generic class there are these two genetic classes. We first limit to one
class of patients, say the Low Risk Class. This can be readily generalized to
include all. Our goal is to try to determine how large a sample we need to
determine the two means from a sample containing a mix of the two. We further
assume we do not know the genetic difference that makes one in a class.
A Simple Example
Thus consider the following simple thought experiment.
Let us assume we have 100 cases of Low Risk PCa. Let us assume that 5% of these
or 5 cases are of the highly aggressive form. Namely no matter what one does
they will lead to death. Let us further assume that we can perform a
prostatectomy or observe.
Then if after some period, say 20 years, we
find the following:
a.
Prostatectomy yields 5 deaths.
b.
Observation yields 8 deaths.
Then we could say that even if we were to
remove the tumor, in the 5 cases after prostatectomy the patient would still
die of the disease.
In contrast in observation, in a similar 100
cases, 5 also would die of the disease as well as an additional 3 because of non-treatment.
The question then is; can we use the data to
examine such a hypothesis? Secondly; how does the inclusion of such a
hypothesis change the results from the NEJM paper?
Thus let us consider the data as follows.
Assume that in the Low Risk Prostatectomy case we have a percent death caused
by PCa as given but assume that is due to a genetic only risk of highly
aggressive tumors. Then remove that from the samples and consider what remains.
The data we show below.
Radical
Prostatectomy
|
Observation
|
|||||
Low
|
Medium
|
High
|
Low
|
Medium
|
High
|
|
Total
|
148
|
129
|
77
|
148
|
120
|
80
|
Initial
Data
|
4.100
|
8.500
|
13.000
|
5.400
|
15.800
|
18.800
|
Mean
|
0.000
|
4.400
|
8.900
|
1.300
|
11.700
|
14.700
|
Low
|
1.900
|
4.800
|
7.200
|
2.800
|
10.400
|
11.700
|
High
|
8.600
|
14.600
|
22.300
|
10.300
|
23.400
|
28.700
|
Sigma
|
1.675
|
2.450
|
3.775
|
1.875
|
3.250
|
4.250
|
The conclusions from the above seem to be:
1. If you do not have a genetically aggressive
form, then the risk of dying from a Low Grade PCa is about 2.5%
2. If, however, you have a High Grade form at presentation,
and not an aggressive form, then you have a 7% chance of dying from PCa versus
an 18% chance with Observation alone.
3. The question is; are you willing to forego a
2.5:1 risk while avoiding surgical issues?
Observations
The data presented in the paper raises more
questions than can be answered. For example:
Mortality is Lower
If we examine the data as presented and look at
Prostatectomy vs Observation, for each of the three risk categories there is a
clear advantage in lowered mortality in a prostatectomy. The authors further
state:
Reducing overtreatment is needed. Men with
low-risk and PSA based screening–detected disease can safely avoid harms and
costs of early radical intervention or of biopsy-guided active surveillance
with delayed radical treatment. Observation, PSA-based monitoring, and active
surveillance with delayed radical intervention remain infrequently used, even
among older men, despite a frequency of metastatic progression of less than 3%,
prostate cancer mortality of 1% or less, and cost-effectiveness that is
superior to that with early radical intervention. PSA-based monitoring and
biopsy based active-surveillance programs should reduce the frequency of
surveillance biopsy and increase biopsy and PSA thresholds that trigger radical
interventions.
We now comment on this conclusion.
It is not at all clear that the data
makes any sense.
Let us examine total mortality, namely from any
cause, over the 20 year period. This is summarized below:
Prostatectomy
|
Observation
|
|||
Events
|
Percent
|
Events
|
Percent
|
|
Low (Local)
|
82/148
|
55.4
(47.4 to 63.2)
|
83/148
|
56.1
(48.0 to 63.8)
|
Intermediate
|
77/129
|
59.7
(51.1 to 67.8)
|
89/120
|
74.2
(65.7 to 81.2)
|
High
|
55/77
|
71.4 (60.5 to 80.3)
|
59/80
|
73.8
(63.2 to 82.1)
|
Low (Central)
|
58/111
|
52.3
(43.0 to 61.3)
|
67/122
|
54.9
(46.1 to 63.5)
|
Intermediate
|
97/155
|
62.6
(54.7 to 69.8)
|
99/139
|
71.2
(63.2 to 78.1)
|
High
|
55/78
|
70.5
(59.6 to 79.5)
|
63/85
|
74.1
(63.9 to 82.2)
|
Note that almost 75% of the High Risk patients
died of something in the 20 year period. Not knowing the age data and normal
mortality data this is relatively meaningless. In contrast these deaths in the
High Risk cohort due solely to PCa are between 19% and 26%. Thus the other
causes of death are 3 to 4 times greater. One wonders what that means. The
Table below is the PCa death only data.
Prostatectomy
|
Observation
|
|||
Events
|
Percent
|
Events
|
Percent
|
|
Low (Local)
|
6/148
|
4.1
(1.9 to
8.6)
|
8/148
|
5.4
(2.8 to
10.3)
|
Intermediate
|
11/129
|
8.5
(4.8 to
14.6)
|
19/120
|
15.8
(10.4 to
23.4)
|
High
|
10/77
|
13.0
(7.2 to
22.3)
|
15/80
|
18.8
(11.7 to
28.7)
|
Low (Central)
|
1/111
|
0.9
(0.2 to
4.9)
|
8/122
|
6.6
(3.4 to
12.4)
|
Intermediate
|
14/155
|
9.0
(5.5 to
14.6)
|
12/139
|
8.6
(5.0 to
14.5)
|
High
|
10/78
|
12.8
(7.1 to
22.0)
|
20/85
|
23.5
(15.8 to
33.6)
|
Here one wonders that those with High Grade at
presentation have a disease cause mortality of such a small rate over this
period. It is a large Gleason grade plus Mets! One knows that PCa Mets rapidly
to the bone and from there one all too often sees IDC occurring which is fatal.
Moreover, if a patient presents with >T2c, or
PSA >20, or GS 8-10, then one would expect a rather dire result from the
PCa. Instead we see after 20 years a modest death rate. This data does not
conform to certain realities.
There is clearly a complex underlying dynamic
at play here and it clearly demands a deeper analysis.
How Big is Big
The size of the samples is small, just over 100
patients. In view of the potential for an even smaller size of the subset of
aggressive types which would be as small as 5%, then frankly a much larger
sample is demanded.
What is the Genetic Makeup?
The results are totally devoid of any genetic
makeup of the cancers. Not only is the nature of the spread missing but the
genetic makeup is now considered as an essential element of any analysis. What
genetic flaws were in the cells of the patients who died of PCa and what in
those who survived.
Dynamics of Survival
There is a somewhat complicated analysis on
survival or mortality. If as this study states, for example, only 20% of the
patients died of PCa but 80% died of any cause, then depending when this
occurred, the percent of PCa deaths could be misrepresented. Namely if the 80%
occurred short term, then the size of the sample is reduced by that number and
if the 20% died when the 80% were dead then the death rate would be much
higher. The denominator would be lower. Without such dynamic data one is hard
put to understand the results.
A Bayesian Analysis
Any analysis of PCa must include a Bayesian
analysis. Namely one must consider disease caused death subject to underlying
facts. First important fact is that not all PCa is identical. There are
genetically different classes and any analysis that disregards this fact is
fundamentally flawed. Namely if we have several classes then we need to have
mortality by class. This has been grossly neglected in this analysis and it
thus provides results which are fatally flawed.
For example. If for each patient one had;
family history, PSA velocity, previous biopsy history, and the like, then one
could segment the results to ascertain some reasonable a priori risk factors.
Secondly the same would be the case if the tumors were sequenced for a set of
reasonably well know genetic markers. Third, the time to death, that is from diagnosis
to death is essential. Fourth, the tumor status of those surviving, over time,
is also essential.
Devoid of any of this data the results are in
my opinion of questionable use.
1.
D'Amico et al, Biochemical Outcome After
Radical Prostatectomy, External Beam Radiation Therapy, or Interstitial
Radiation Therapy for Clinically Localized Prostate Cancer, JAMA, September 16,
1998—Vol 280, No. 11
2.
Hald, Statistical Theory, Wiley (New York) 1953
3.
McGarty, T., Prostate Cancer, A Systems
Approach, DRAFT 2014 http://www.telmarc.com/Documents/Books/Prostate%20Cancer%20Systems%20Approach%2003.pdf
4.
Rodrigues et al, Pre-treatment risk
stratification of prostate cancer patients: A critical review, Can Urol Assoc J
2012;6(2):121-7.
5.
Wilt, et al, Follow-up of Prostatectomy versus
Observation for Early Prostate Cancer, NEJM, 377;2 July 13, 2017
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