A podcast on statistical science and clinical trials.
Explore the intricacies of Bayesian statistics and adaptive clinical trials. Uncover methods that push beyond conventional paradigms, ushering in data-driven insights that enhance trial outcomes while ensuring safety and efficacy. Join us as we dive into complex medical challenges and regulatory landscapes, offering innovative solutions tailored for pharma pioneers. Featuring expertise from industry leaders, each episode is crafted to provide clarity, foster debate, and challenge mainstream perspectives, ensuring you remain at the forefront of clinical trial excellence.
Judith: Welcome to Berry's In the
Interim podcast, where we explore the
cutting edge of innovative clinical
trial design for the pharmaceutical and
medical industries, and so much more.
Let's dive in.
Scott: Welcome everybody back to In The
Interim Uh I am your cohost today Scott
Berry and I'm joined by my uh uh my common
cohost Kurt Vielli here and we we are
here to talk about something And and and
Kurt will occasionally say Oh I've got
a good topic for the podcast and usually
it's something that's uh beneath the
crawl a little bit maybe uh wi wi within
the the the pet peeve But a really I I
think a really important topic a really
important misunderstood topic and that is
bias in early stopping in clinical trials
So welcome back to In The Interim Kurt
Kert Viele: Thank you
Scott: All right So so we are in the
interim and we're talking about bias
of interims Uh sort of an interesting
aspect of this I I thought I'd introduce
the topic by uh uh telling a a bit of
an old story and um this this happened
relatively early So I I started designing
trials in 2000 Uh before that I did a
little bit of clinical design but uh this
was early in Berry Consultants and was
working with a medical device company
And they they had an estimate of their
effect size but thought that they could
be quite a bit better than that So an
adaptive sample size with early stopping
for superiority made a lot of sense for
the trial So fairly standard two interim
analyses for early success could go to the
final analysis Medical device uh nothing
controversial in in the trial design We
can control type one error It's not the
issue Pretty straightforward And so we're
working on the design and then I got
word from the the company that there's a
problem um with stopping And the company
was associated with a group that was gonna
run the trial and they had an issue with
potentially stopping the trial I thought
Okay that's that that's odd You know
let's let's talk to them about it So the
the concern was the bias in the estimate
that comes out of the trial and it's
important for medical decisionmaking to
have good estimates of of the effect And
the concern was that the early stopping
biases that estimate And so ookay that's
great and one of the wonderful things
about simulation is we can simulate the
bias So it was a response outcome uh
success and failure And I simulated the
trial under a number of potential true
effects and calculated the bias of the
trial And it was really relatively small
It was approximately one percent in a in
a rate of success of We're we're looking
for thirty forty fifty percent success
rates and it was a an s a bias of about
one percent which I thought was a minor
Thing relative to the benefits of sample
size patients time to get a success should
the effect size be that large And um they
the individual I was talking to and I
was actually talking to two people one
one senior member and I'll tell you who
the senior member was in a bit But uh at
the time I had no idea e either of these
people Uh and one was a statistician It
turns out the statistician doesn't say
anything during this conversation Um and
uh the the person says Oh we're seeing
biases larger than that And um asks What
is the bias if you restrict to trials
that uh hit the early success And I said
Well but that's not bias Bias is when
you look at all the trials what is the
average effect relative to the truth If
you restrict it to trials that hit that
early success that in and of itself is
is is a bias Surely you're gonna get much
larger effect cause you have to have a
large effect to win Um and and showed what
that was but you know that's not bias He
says Well I I don't actually know what
the mathematical definition of bias is but
that seems really problematic to me And
it was sort of strange uh in that I said
Well any i if you look at any trial if
you look at a fixed trial and look at only
those that are successful you're you're
gonna see much higher estimates claiming
success You know it it has the same sort
of bias What was fascinating about it
was it got the the the advice and the the
group running the trial was very closely
associated with the device company and
needed the approval of the group Turns
out they had to get rid of all the early
successes It was very weird I thought
th th this is really strange uh uh you
know in in the whole thing So um the the
individual that I was talking to I met for
the first time was Gordon Guyatt and we're
gonna come back to that story But Kurt
this is a this is a thing that I think
a number of people know that this is a
potential issue the bias and think it's a
big issue with potentially stopping early
Kert Viele: So I think, I, uh,
you know, one of the key things
you brought out about that is
what is the definition of bias?
What are you worried about?
And, you know, ordinarily, when
we take this in cla- you know, a
class in undergrad or so on, we
do-- we talk about all trials.
Everything that could
happen, average them.
On average, you get the right
answer, the right response rate.
you cherry-pick, you're going
to generate some kind of bias
because you're cherry-picking.
I do have a little more sympathy, I think,
maybe than you do on this, that if I know
I stopped at the first interim, I stopped
at half the planned sample size, I know
these are the situations where I might
see the high part of the distribution.
know, is that a concern, and
how big of a concern is it?
I certainly can see people
wanting to compute that.
So this is gonna be a key part
of our story going forward
Scott: Yeah yeah So so we'll come back
to that And there's no question that
trials that show statistical significance
overestimate the treatment effect I I
think we all understand that um uh in
it A trial that stops early is going to
provide likely an overestimate Um and
it all depends on what you think the the
potential range of effects are But but
let's come back to the the definition
I think that that this is so important
the definition of bias um uh in it So
what we think of it is what's a biased
estimator An unbiased estimator would
be one that when you run your experiment
and you you have an estimate of what
it is whatever it is you're trying
to estimate the the success rate of a
treatment If on average that estimate is
the real answer we call that unbiased So
the the expected value of the estimator
we're using within our experiment is
equal to the thing the estimand we're
trying to estimate We call that unbiased
Kert Viele: And so we're,
we're, we're thinking about
everything that could happen.
I mean, this is all-- If I do
an interim, I don't just have
early stopping for success, I've
got early stopping for futility.
So I'm averaging, you know, I,
I stopped at fifty for success.
I stopped at fifty for futility,
stopped at seventy-five success
and futility, went to the end,
stopped for success or futility.
All of those things average together.
If those all average out to the
right answer, we're unbiased.
And now we're gonna get into, you
know, do we need to look at each
of those six things separately?
Scott: Yep Yep Okay So um um and we know
we can calculate that if you do early
superiority what happens is within the
trials you could run those trials that
hit early superiority are are depending on
the the the real parameter the real truth
likely are overperforming within that And
you stop at the point it's overperforming
and it doesn't go the rest of the trial
and regress towards the parameter So w
it when those trials stop and you report
that we know that's that's biased By the
way my pet peeve and I know we generally
have one of Kert's pet peeves but one
of my pet peeves is bias means you can't
use it That that all of a sudden it's
it's uh oh it it it's done Bias is okay
Um we can adjust for it We understand it
We want to know what is the size of the
bias uh in the circumstance It's just
bias doesn't mean you can't do it And I
think there's there's this Oh bias you
you can't do it So we understand there's
bias So let's talk a little bit about
that Kurt Where like you know within a
toy example let's talk about you know
what what what is the size of this bias
Kert Viele: Well, and so let, let's
start back up a little bit further, and
Scott: Okay
Kert Viele: start for a fixed trial,
just a straightforward I run a
trial, and my toy example here is
I just have straight normal data.
I'm estimating a mean.
I've arranged a trial.
Sample size is 100.
I'm gonna run a Z test at the end.
Everything is as basic as it could be
Scott: The one randomized
experimental to con placebo
Kert Viele: Yep, standardized effect
size of one here just to make things
Scott: Yep Yep
Kert Viele: so if I, if I take all
trials and the truth is one, so I
come in with what I powered for.
The truth's one, I look at all
trials, I get an average of one.
It's unbiased.
They're the same.
Scott: Futility no superiority
100 patients read it out Yep
Kert Viele: Yep.
so now if I-- Now all of those
trials that were unbiased as
a whole, I can split them.
I can talk about the ones that won,
you know, p less than zero point zero
two five, and the ones that lost.
if I look at the ones that won, they have
an average of about one point zero six.
So they're biased high.
They're one point zero six.
They're compensated for
by the ones that lost.
And so this is-- you have to
have this compensation going on.
In fact, if you make the p-value the
stronger the evidence, if you make
the p-value less than zero point
zero zero zero one, for example,
so you're like, "Oh, look, I won.
This is great.
I have a great drug," and so on.
Somebody could come
back and go, "Oh, wait."
you focus on the trials with p less
than zero point zero zero zero one,
average effect is one point three four.
It's thirty-four percent bias
compared to the truth of one.
So you want to be careful to go, "Oh,
you know, I can't accept anything that's
biased," because you're essentially
saying the stronger the evidence,
the less I believe it or something.
Scott: Okay so under under the
truth that the the real effect is
one where your trial is 90 powered
for one so most of the trials win
Kert Viele: Yeah
Scott: and only 10 of the trials don't
hit 05 If you restrict a calculation
of what's the average effect for those
that win you get 106 So there's a 6
bias just in successful trials in that
scenario Now if you were to do this
under the null the bias would be enormous
Kert Viele: Yeah, you
Scott: for successful trials
Kert Viele: yeah, you need about 0.6
to win.
Usually a 90% powered trial, you
need about 60% of the powered effect.
So your bias has to be at least 0.6
in those cases under the null
Scott: So bias depends on the truth of
of the the the effect If the effect is
three you you you're unbiased because
every trial wins and there's there's
no bias to that So it d so so we're
addressing you know power for the effect
of one uh within that scenario So the
Kert Viele: and if you go the other way,
sorry to interrupt you, but if you go
the other way, if the true effect was 1.5
or two, it's higher, then you have 100%
power and you get no bias whatsoever.
So it definitely depends
on the true effect
Scott: Yep What happens if
I uh if I add futility Uh
Kert Viele: So then you're gonna
end up where, um, now of course,
futility in a fixed trial, you
just have the winners and losers.
But if we start to add into the group
sequential, we add futility, that's
gonna be a compensating mechanism for
the bias, or the upward bias will get
Scott: Okay
Kert Viele: get
Scott: Okay But we have I I forgot
we've done fixed trials All we did
was restrict in the you have this 6
bias of successful trials Now what
if I do uh so you added into this
O'BrienFleming stopping at 50 and 75
Kert Viele: Yep.
And so s- if, so if I do that and I
don't have any futility, so futility is
important here 'cause it does compensate,
then I'm gonna end up overall, I'm
about-- I get an effect about one point
one five as opposed to one, so 15% up.
So that's certainly meaningful.
Um, you gotta weigh that against the fact
that I'm stopping early to help patients,
and I don't know the effect is one.
It might actually really be good.
Um, if I, if the true effect is one and
I stop at 50 in that half the sampleâ¦
Yeah
Scott: make sure I There's this So
so over all possible trials you run
Kert Viele: 1.15
Scott: some of them stop at 50 some
stop at 75 some stop at 100 Not on not
just successful trials but all trials
Kert Viele: trials
Scott: All trials that the the average
Kert Viele: sorry.
All trials is 1.07,
so
Scott: Yeah
Kert Viele: correcting me
Scott: okay Oh so so 107 is that So
the bias in a group sequential O'Brien
Fleming um design there's a 7 bias
Kert Viele: Yes, with
Scott: that Yep yep So the question
is iif we just look at that that's
the bias of adding it into the trial
uh uh within that scenario Now w
Kert Viele: different than the
fixed trial that we just had.
That was at six,
so we're
Scott: but that was restricting to only
successful trials Yep Uh so the the If
somebody if the if a FDA says you're
running this group sequential design
what is the bias of adding in those early
analyses Assuming that your effect size
is one it would be 107 There would be a
7 uh uh difference from from the truth
of that uh in that Now we can you can
adjust the estimate for that There are
statistical ways to do that uh within that
But even that bias now we are we are able
to suc correctly claim superiority perhaps
halfway through the experiment 75 of the
way through the experiment The savings
in patients and times to get the right
answer at the cost of this 7 bias that's
that's the sort of question And usually
that seems like a nobrainer tradeoff
to me uh uh within that uh in those
scenarios uh for that Okay But now what
happens if you only look at trials that
are suc that win in a group sequential
Kert Viele: so only the
ones that won, you get 1.15.
So it's gonna be a little
bit higher because you don't
Scott: Yeah
Kert Viele: losers at the end
Scott: And that includes the probability
you win at 50 at 75 or you go to
the end and you're successful at the
end uh within that And so there is
that increase Uh winning trials in
a fixed trials were 106 now it's 115
Kert Viele: Yes
Scott: that Now what if I only
look at trials that win at 50
Kert Viele: Now that one's big.
That's 1.5
Scott: 15 yep Now that's not bias right
Kert Viele: It's not
biased by the definition.
I have a little more sympathy at
kind of a little uncomfortable
Scott: Good Okay But that so that in that
scenario and of course in the scenario
where you need to see that larger effect
size uh uh you know on average 15 uh to to
win that to be statistically significant
in that scenario if you only look at
those scenarios you get biased because
the truth is one and you have to have a
value bigger than that Now if the truth
is two that's that bias is gonna be
Kert Viele: Basically z-
Scott: almost zero Right Right Yeah So
one of the points I think you would make
is if you knew the effect was one you
wouldn't do an interim at 50 you know
in that scenario Or if it's incredibly
unlikely that the scenario's as big
as 15 you wouldn't do that interim
Kert Viele: Yeah, we always, when,
when we show this to clients or
when we do this, we back solve
what effect do you need to stop for
success and futility at each interim?
And we often ask clients directly,
especially on the futility side, "Are
you comfortable stopping the trial here?
Would you be willing to
basically give up at this point?"
That applies for success.
"Would you believe this result?"
If the answer is no, then I have a lot
of concerns about doing the interim.
Again, unless there's some public
health, you know, thing we need to have
this answer as quickly as possible.
I still trust the drug
works, uh, in that case,
Scott: Yeah
Kert Viele: I do
worry
that maybe it doesn't work that well
Scott: Yeah And and so the estimate of
that So a very common situation and the
common the situation I was in in the
device trial is that y the the company
might believe in a the 15 is right but
they wanna make sure their trial is
powered for one because it's clinically
is still a valuable device It's good for
patients And so they power the trial at
90 at the maximum for the one but they
really think they their device could be
as good as 15 175 or two in that scenario
And then these the the bias under those
scenarios is much smaller and it's a
much more reasonable thing to have a
variable sample size They actually think
their effect is 15 and they wanna run a
trial that's only 70 but they go to 100
potentially to still hit a clinically
meaningful effect uh within that scenario
And then you're talking about biases of
7 by by doing this even under the one
It's much smaller in the the 15 scenario
Kert Viele: And I think this is where
you really-- this is where I really
put on my Bayesian hat, so to speak,
even though I'm computing biases.
When I see that data,
it's stopped at, at fifty.
I've got an effect size
around one point five.
You know, all of these bias calculations
assume that you know the truth.
When I get the data, I
don't know the truth.
I gotta figure it out.
And so if, if I knew in my head it
can't be bigger than one, then of
course I don't trust the one point five.
But if I've walked into the trial
where this might not work at all,
it might be one, it might be two, it
could be any of those, then I start
thinking to myself, "Okay, if it were
a null, it hardly would ever stop."
So it just-- I don't see many of these.
I know they're biased, but they
just don't happen very often.
Happen very rarely.
If it's one, it still doesn't
happen all that often.
I don't stop at fifty a ton.
If it's two, I stop at fifty all the time.
So when I see that one point five,
it's more likely to be one of
the twos and is the right answer
than it's one of the biased ones.
It's more likely to be an unbiased
truth than one of the biased falsehoods.
And that, that gives me a lot of comfort
Scott: Yeah You'd probably make
a small adjustment like 7 I think
it's probably not quite you know
15 of what was observed yeah
Kert Viele: I'd,
Scott: that scenario
Kert Viele: I'd, adjust by my prior.
There's a
Scott: Yep
Kert Viele: Bayesian answer to
Scott: Yes Yeah
Kert Viele: we've had our
frequentist hat on, but
Scott: Yeah
Kert Viele: would just compute
the posterior and it works.
It
Scott: Yep
Kert Viele: bias automatically
Scott: Yep Okay so we can calculate
the bias uh for that And as we do more
complicated designs and you could add
response adaptive randomization you whi
which we've done a recent uh episode of
We could add arm dropping in here We could
add patient changing We can do all this
We can calculate the exact bias under
a number of scenarios It's one of the
really nice things about simulation So
we can calculate bias and we know what
it is Mathematically we can calculate it
Kert Viele: And we should certainly
emphasize this is one of the
things that in the regulatory
world we've been doing a lot more.
The last five, six, seven years,
regulators have been paying a lot
more attention to this, asking for it.
And so this is-- we, we've been
providing these and for the most
part, things are going fine, but
we have found a few examples, and
we've changed the designs in response
Scott: And and it it the FDA draft
guidance uh the FDA guidance on adaptive
designs the ICH E20 adaptive designs
uh that's draft They they all mention
calculating the bias uh in it I uh I
don't know if we have submitted a design
over 27 years of doing this to the agency
where they've had an issue with the bias
Kert Viele: That sounds fair to me,
Scott: I think yes if we were to
do a sample if we were to do an
interim at 10 patients in your 100
patients example um uh th th there
could be a an issue with that Yeah
Kert Viele: cherry-picking because
we don't actually let it get to that
point or at least
Scott: So we wouldn't submit that design
when we calculate the bias We say Wow
if I were a regulator I'd have a problem
with that sort of thing So I it you
know it's something that they understand
they recognize when they have to write
an FDA label I think there's comfort
there with it um in it Uh and we can
calculate that exactly Okay so I keep
saying that over and over again and
people are w w you know Why why does he
keep saying that We can calculate that
sort of thing Coming back to my story
Kert Viele: I think this is, this is
definitely your pet peeve episode.
Scott: Yeah Okay All right I'll I'll take
that I'll take that Um but you brought
it on You you said Hey we should do an
episode Oh and I I I remember this story
Kert Viele: triggering Scott
is a p- is a hobby of mine
Scott: Yes So um Gordon Guyatt you may not
know care Gordon Guyatt What happened is
uh within a few months of that interaction
a paper came out uh in JAMA and the
lead author is uh Bassler Uh and this
is Bassler et al The senior author in it
is Gordon Guyatt and it's on behalf of
something called the STOPIT Study Group
STOPIT 2 Study Group And the paper is So
this is uh y uh this comes out in March
of 2010 and in JAMA and it is Stopping
Randomized Trials Early for Benefit
and Estimation of Treatment Effects A
Systematic Review and MetaRegression
Analysis So I'll read you the conclusion
of the paper and then describe a little
bit about what they do And by the way
I I will say this as I'm I'm describing
this that uh in in in this many years I
I think this paper is just wrong I think
it's misleading I think it's JAMA should
have never published it Uh but we'll
come more to that But just to sort of
set the scenes for it So the conclusion
is truncated randomized clinical trials
were associated with greater effect sizes
than randomized clinical trials that's
not stopped early That's the conclusion
um uh within this But one of the
sentences in the paper says Statistical
modeling suggest that randomized clinical
trials stopped early for benefit and
they call these truncated randomized
clinical trials will systematically
overestimate treatment effects And
empirical data demonstrate that truncated
randomized clinical trials often show
implausibly large treatment effects
So a lot of people reading this paper
looking at it come away with You
shouldn't do interim analyses It creates
implausibly large bias This is bad You
know the name of their group is STOPIT
Um and I don't think they mean trials
I think they mean it And he literally
in that example prevented a company
from doing a group sequential design um
because of this issue Okay so what did
they do Uh what what A and their goal
was understanding we can mathematically
calculate bias but what do we actually
see out there for bias So they went out
and they found through a a a search they
found trials that were stopped early
truncated early for superiority And you
can go to their their uh CONSORT diagram
They originally found 195 trials that were
stopped early Then they looked for trials
of the same question other randomized
trials of the same question and they were
gonna compare the effect of these other
trials to the ones that were truncated
early And by the way in their search of
where they had 195 trials stopped early
and then they looked for other trials
they found some more that were stopped
early They moved those over to this
calling them truncated And then yeah
Kert Viele: if you replicated the
result, you moved it back over and
it didn't count as a replication
But yeah
Scott: you got early truncated
Kert Viele: Yes,
Scott: then yeah
Kert Viele: if you repeated the
experiment, it-- you didn't get
credit for the replication of
it 'cause you truncated it early
Scott: Yep yep You go into th
they're gonna create a largely a
treatment group of trials which were
ones that were stopped early and
then the other group are the same
question that were not stopped early
Kert Viele: And some
of them could have been
Scott: Some of them could have been
Um some of them were statistically
significantly successful some were not
Kert Viele: And it's wor-
Scott: within the
Kert Viele: it's worth mentioning
that if you could stop early and you
don't, those trials are biased low.
So you're-- they're-- we mathematically
know they're gonna be a low group
Scott: So there they and this was their
empirically what happens out there So
they took this set of trials that were
stopped early and then they compared to
the same question that were not stopped
early And they found that the difference
was about a 30 difference in the estimate
of the effect They did a r a relative
risk and it was 71 So a 29 relative
difference in the effect of those stopped
early versus those that were not And
they jump up and down and say This is
enormous A 30 effect So in your particular
example we had that effect of one If we
did something that created an average
effect of say 13 we might be concerned
that that experiment provides bias
and that was that was their experiment
that they did in this comparison and
they published the results of that
Kert Viele: And we actually,
so we have that result.
So the, if you look in our-- the example
we gave, the one hundred sample size and
so on, if you look at the trials that went
to the end and won, average effect is only
zero point eight seven compared to one.
They're biased low by a fair
amount, thirteen percent
Scott: Yep So in a way they they present
this result and think you're you're all
clinical trial people and you understand
that we we in a clinical trial as simple
as twoarm trial we have a treatment group
and a control group and we randomize
people into those groups and we compare
their results They took this group that
the trial was truncated early and they
call that group one and then they take
trials that were not stopped early If it
was stopped early they moved it over into
group one that were not stopped early and
they called that group two And they said
Wow group one's got a better treatment
effect than group two And but it by the
way if you ran a clinical trial like this
it would be that you run a trial and you
have patients and the ones that respond
well you put them in treatment one and if
they don't respond well you put them in
treatment two and you say Wow treatment
one is better than treatment two That
would never get into JAMA but somehow
this got into JAMA Interestingly when this
was published there were many letters to
the editor Uh I was a part of one of them
with Brad Carlin and Jason Connor where
we point out that this is this is faulty
and wrong Uh but the names of the people
that wrote in saying this was wrong was
somewhat impressive Another one was Steve
Goodman Don Berry My father wrote a a
letter to the editor a different one than
the one I was on Uh w and Janet Wittes
uh was on were on that one Another one
of these letters was Ed Corn and Margaret
Mooney Another one was Susan Ellenberg
Dave Demetz and Tom Fleming also pointing
out the faults of this And so there were
a lot of people that pointed out that this
was a bad study uh in it but yet still
to A and by the way think about it that
you go in and you take trials early If
they would've done the same thing where
they went out and found trials that were
statistically significant And then they
went out and found trials that a a any
other trials run even some that were
statistically significant they would
see that that's biased uh within that
and that's largely the bias that they
saw in that And we know there's a bias
to stopping early We can calculate it
mathematically So when their conclusion
was This is implausibly large I think they
understood the mathematical calculation
of 7 and we're seeing 30 They even
study things like did the DSMB have some
investment in it You know all the Looking
for chicanery here or something like that
within this and it wa it's like no this
had to happen You you know if you if you
ran an experiment where you took the the
biased sampling that they did you would
see this 30 bias This is this is nothing
Kert Viele: I, I'm laughing, Scott,
because I, I was truly successful
about getting you riled up today
Scott: Yeah yeah So uh th th this paper's
sort of number one on my list You know
others uh we'll do other podcasts of
other ones uh within the scenario But
uh and it was kind of amazing at the
time because I I tried with w w with
fault to explain this to to Dr Guyatt
uh in that I was unsuccessful The paper
came out and I think there was nobody
that sort of said this is odd He did
a debate with Steve Goodman after this
paper came out where Goodman explained
this and I think he largely I'm not sure
he sort of understood the intricacies
and largely it was like their rebuttal
to these responses that Well boy look
this is big Yeah it by by definition
you bias sampled in a way that created
this Nobody should be surprised by that
Kert Viele: And I, I mean, to
be-- make sure we summarize
this properly, we certainly are
claiming there's, there's bias.
So there is some bias.
We can compute what it is.
Um, it, that has to be
balanced versus the advantages.
We stop early for reasons.
We have-- we want to protect patients.
The DAWN trial, for example, this
is a trial that thrombectomy, great
effect, interim at 200 patients,
maximal sample size, I think
500 Am I remembering that right?
Scott: Yep
Kert Viele: So,
you know, d--
Scott: stopped at f 200
Kert Viele: stopped at 200 So enormous
effect that's panned out in practice.
This is, you know, this is
the standard of care now.
If that trial doesn't stop
at 200 it years before this.
There are other trials with thrombectomy.
I don't want to claim it's years
before that reaches the market,
but it's years before that evidence
is actually in front of people
Scott: Yeah Uh and and so there's
there's huge benefits And also by the
way it allows you to have a wider range
to have a higher powered trial where
you wouldn't run that single maximum
because you think it's wasted cause
you don't need that many There's a huge
benefit to having a flexible sample size
And this painting it Oh it's biased is
uh you shouldn't do it ignores all of
these important factors to trial design
Kert Viele: And I do think you have to
incorporate that entire range of evidence,
the entire range of possibilities.
I can't just compute bias on suppose the
null is true, suppose this effect is true.
the range?
What's the bias for each of these?
What's the likelihood I'm
actually gonna see these?
It's like a doctor
getting a diagnostic test.
Here's what's in front of me.
Is this a unbiased, basically unbiased
real result, or is this biased high?
And, uh, if it's plausible, it's probably
a reasonably unbiased real result
Scott: Yep All right
I I
Kert Viele: You
Scott: I'm trying to make sure
Kert Viele: You need,
a second to calm down?
Scott: Yeah I'm calmed
down I'm calmed down
Kert Viele: All right
Scott: Yep yep uh in this one All right So
and I I'm not lost the the the bit of the
irony that uh we're talking about bias of
interims and here we are in the interim
uh in this scenario But uh yep that's the
the the world we live in here I I I would
encourage you to go look at the Bassler
paper Um you know if if if you have your
study groups and read it I think you
should read it and talk about the paper
whether you think it's reasonable Read
the uh comments as well I think you'll
you'll enjoy the various people commenting
Kert Viele: And, look, look at your
interims when you're doing them.
They're not-- every, every
interim shouldn't be there.
So feel free to compute these
quantities and to what's reasonable
Scott: Yep Yep All right Well I I
appreciate you bringing this topic
to me Kurt and see what other neat
topics we have coming uh uh there And
we're gonna stop this we're gonna stop
this episode a little early here Kurt
Kert Viele: Okay
Scott: I think, that's appropriate Uh it's
a little early and and we are biased here
uh and we will be biased next time So uh
thank you all for joining us and until
next time We will be here in the interim
Kert Viele: Thanks, Scott