Jello Jacob,
Someone genious just helped me. Tlag can be used. How did I miss such
simple solution?
I was talking about multiple doses. There are cases AUC is better
predictor than concentration (for example, long duration of treatment is
needed; very slow but good drug effect), but when it comes to multiople
doses, it does not work well because it is necessary to predict drug
withdrawal. If "moving average"-like approach is used, the drug effect
disappears slowly, which can be the case.
Of course this approach has to tested for some unexpected results and
adjusted if possible.
Thanks,
Pavel
On Wed, Jan 15, 2014 at 07:49 AM, Ribbing, Jakob wrote:
Hi Pavel,
I agree with you it is not uncommon to have AUC drive efficacy or safety
endpoints.
However, you seem to have the impression this is commonly done using
cumulative AUC and I can assure you that is rarely the case.
I have only seen that for safety endpoints where it has been justified
(treatment is limited to a few cycles due to accumulation of side effect
which for practical purposes can be regarded as irreversible).
Even for cases where treatment/disease is completely curative it is not
a standard approach to use cumulative AUC to drive efficacy (e.g.
antibiotics, where infection may be eradicated, but the
bacterial-killing effect wears off after the drug has been eliminated;
so even if disease does not come back the actual drug effect has worn
off).
At steady state multiple dosing, AUC over a dosing interval (or Cav,ss)
can sometimes be used to drive steady-state efficacy or safety.
However, it seems in your case you have fluctuations in drug response
even at steady state?
Otherwise, this AUC can be expressed as an analytical solution or added
as an input variable in your dataset, in case you are concerned about
run times.
But with that approach you would not see a fluctuation in drug response
at steady state, so in your case maybe better to use concentrations to
drive efficacy?
For a “moving average” it would sometimes be possible to calculate AUC
analytically.
However, a moving average AUC would rarely be a mechanistic description
of effect delay. Leonid provide one possible solution (like an effect
compartment).
However, there are many alternatives and it is not possible to say which
is the best in your specific case(s), without more information, e.g.
· Are you thinking about single dose, multiple dosing, and in
the latter case is it sufficient to describe your endpoint at stead
state?
· And is the effect appearing with great delay over many
days/weeks or it rather fluctuates with fluctuating concentrations?
(e.g. at multiple dosing for a low dose, do you have fluctuations over a
dosing interval in your efficacy endpoint that are due fluctuations in
PK, i.e. aside from any circadian variation?)
· Does a higher dose reach its efficacy-steady state faster than
a lower dose (time to efficacy-steady state; not the level of response
which should be different)?
· What is the mechanisms for effect delay (i.e. the delay in on
and offset of effect that is not due to accumulation of PK at start of
treatment)
Are you aware of the standard models for effect delay that one would
commonly consider and why did you dismiss these?
Best regards
Jakob
From: owner-nmus...@globomaxnm.com [mailto:owner-nmus...@globomaxnm.com]
On Behalf Of Pavel Belo
Sent: 14 January 2014 18:45
To: Bauer, Robert
Cc: nmusers@globomaxnm.com
Subject: [NMusers] backward integration from t-a to t
Dear Robert,
Efficacy is frequently considered a function of AUC. (AUC is just an
integral. It is obvious how to calculate AUC any software which can
solve ODE.) A disadvantage of this model of efficacy is that the effect
is irreversable because AUC of concentration can only increase; it
cannot decrease. In many cases, a more meaningful model is a model
where AUC is calculated form time t -a to t (kind of "moving average"),
where t is time in the system of differential equations (variable T in
NONMEM). There are 2 obvious ways to calculate AUC(t-a, t). The first
is to do backward integration, which looks like a hard and resource
consuming way for NONMEM. The second one is to keep in memory AUC for
all time points used during the integration and calculate AUC(t-a,t) as
AUC(t) - AUC(t-a), there AUC(t-a) can be interpolated using two closest
time points below and above t-a.
Is there a way to access AUC for the past time points (<t) from the
integration routine? It seems like an easy thing to do.
Kind regards,
Pavel