2. Population pharmacokinetics: study of drug absorption
and disposition characteristics in a population or distinct
subset of population.
The information obtained is then summarized using
mathematical models.
Population models address variability arising from
o Inter-individual variability
o Explainable
o Unexplainable
o Intra-individual variability
o Measurement errors
INTRODUCTION
3. POPULATION PHARMACOKINETIC
METHODS
TRADITIONAL METHODS NEWER METHODS
1. Start with the individuals then progress
to the population.
1. Goes directly to the population without
evaluating the individuals.
2. Random errors from all sources are
combined (inter-individual variability,
intra-individual variability, measurement
errors).
2. Separate the unexplainable inter-
individual variability from the residual
random errors.
3. E.g. Traditional standard two stage
Method, Naïve pooling method
3. E.g. Parametric method: Mixed effect
modelling
Non parametric method: NPML,
NPEM, SNP, I2S
5. It is a traditional method.
It involves study of relatively small number of
individuals subjected to intense sampling.
The period of the study is short, since the individuals
are usually instutionalised.
TRADITIONAL STANDARD TWO
STAGE METHOD
6. It consists of two stages:
Stage 1: Each individuals data is analysed on a case by
case basis using weighed or extended nonlinear least
square regression to determine the individual
pharmacokinetic parameters.
Stage 2: The individual pharmacokinetic parameters
are pooled to determine measures of central
tendency and variability for the population. The
association between specific pharmacokinetic
parameters and demographic characters are studied.
7. It provides reliable and robust estimates when extensive
numbers of samples are available for each individual.
It is a simple method.
It is a well tried and straightforward method to implement.
Many software packages are available for this method.
Statistics are straightforward and are familiar to the
investigators.
It is capable of producing estimates of typical values for
members of a population that are similar to those found with
direct population approaches.
It is considered to be the golden standard in case of rich data.
ADVANTAGES
8. Being a controlled study design, it is very expensive
and requires careful planning and implementation.
It gives unreliable results in case of sparse data.
It is difficult to study a sufficiently large number of
individuals to adequately represent the population.
There are ethical issues to obtain extensive samples
from a fragile subpopulation.
DISADVANTAGES
9. It is a traditional method.
In this method, the data from all individuals are
pooled and analysed simultaneously without
consideration of the individual from whom the
specific data were obtained.
NAIVE POOLING METHOD
10. It may be the only viable approach in certain
situations, for e.g. in case on animal data, where each
animal provides only one data point.
ADVANTAGES
11. This method is generally considered the least
favourable.
It is susceptible to bias.
It produces inaccurate estimates of pharmacokinetic
parameters.
DISADVANTAGES
13. Mixed effect modelling is a parametric method which
assumes a specific distribution of pharmacokinetic
parameters prior to estimation.
It is considered as the optimum population model
method.
MIXED EFFECT MODELLING
14. It is a direct method in which the population
parameters are determined in a single stage of
analysis applied simultaneously to the data from
many individuals.
This method recognises which data arise from the
same individual and which do not.
15. “Effects” are factors that contribute to the variability
of the measured observation.
They are of two types:
o fixed
o random
16. E.g.
Cp = D/Vd . e –Cl/Vdt
Cp = concentration of drug in the plasma (dependent
variable)
D = dose (fixed effect)
t = time
17. Fixed effects are components of the structural
pharmacokinetic model.
They do not include any unexplainable variation
either between or within individuals.
Fixed effect parameters are represented by the
symbol theta.
18. Each individual in a population will have a specific
value for their pharmacokinetic parameter, which will
differ from the population typical value due to
unexplainable variability.
This variability is represented by the symbol eta (?).
19. The manner in which an individual’s eta relates the
individual’s pharmacokinetic parameter to the
population typical value is given by the error model.
A variety of error models can be chosen, depending
upon the visual inspection of data, experience, trial
and error.
20. The most well-known method for applying mixed
effect method in NONMEM (non linear mixed effect
modelling).
The output from NONMEM includes estimates of
mean variances and covariances of the parameters.
21. It is useful for sparse and randomly collected data.
It is able to derive population models when only a few
samples are available from each individual.
Individuals are still identifiable, which permits repeated
measures for individuals in spite of the data being pooled
into a single data set.
Inclusion of covariates during elimination procedure
offsets unbalanced data.
It is ideal for studying population such as very old, very
young or very sick which are difficult to study using STS.
ADVANTAGES
22. Study design does not call for collection of samples at
specific times, resulting in imprecise estimates.
Therefore some thought should be given to the
optimal collection time.
Biased estimates have been reported especially when
data contain large amount of random error.
DISADVANTAGES
23. Non parametric methods do not assume any specific
distribution of parameters about the population
values, but rather allow for many possible
distributions.
In this method, the entire population distribution of
each parameter is estimated from the population
data.
This permits visual inspection of distribution before
committing to one.
NON PARAMETRIC METHODS
24. Different non parametric methods are:
Non parametric maximum likelihood [NPML]
Non parametric expectation maximization [NPEM]
Semi/ smooth non parametric method [SNP]
25. This method permits all forms of distributions
including those containing sharp changes, such as
discontinuities and kinks.
It uses maximum likelihood as estimator.
NON PARAMETRIC MAXIMUM
LIKELIHOOD [NPML]
26. This method is preferred to any parametric method
when there is an unexpected multimodal or non-
normal distribution of atleast one of the nodal
parameters.
It eliminates the need for initial guesses which are
required for nonlinear least square procedure.
It is preferable to traditional method in case of sparse
data.
It uses expectation maximization as the estimator.
NON PARAMETRIC EXPECTATION
MAXIMIZATION [NPEM]
27. This method places some restrictions on the type of
parametric distributions considered.
Functions that are not permitted include those
containing sharp edges and discontinuities.
SEMI/ SMOOTH NON PARAMETRIC
METHOD [SNP]
28. I2S method may be used with rich data, a mixture of
rich and sparse data or only sparse data.
To initiate the procedure an approximate prior
population model is required.
Source for these population value include literature,
naïve pooled data method, STS method etc.
ITERATIVE TWO STAGE METHOD
29. This population model is subjected to Bayesian
estimation of individual parameters for all patients,
both rich and sparse in data (stage 1).
The population parameters are recalculated with
these new individual parameters in order to form new
set of priori distribution (stage 2).
30. The Bayesian estimation step is performed again
using the new population model to find more
accurate estimates of individual parameters.
This is carried out until the difference between the
new and old prior distribution is essentially zero.
This method yields both individual and population
parameters.
32. Development of dosage regimen.
Determination of dosage requirements in special populations
Predicting outcomes of various forms of drug administration
like multiple doses, special patient groups, and controlled
release formulations.
Investigating potential disease and drug interactions.
Studying drug concentration- acute toxic effect relationships.
Construction of population pharmacokinetic model.
Evaluating pharmacokinetic versus pharmacodynamics
variability.
PRE APPROVAL PHASE
(drug development phase)
33. Application of the population average dose for an
individual, depending on the variability of
pharmacokinetic and pharmacodynamics parameters.
Dose individualisation for individuals whose
pharmacokinetic parameters are most likely to deviate
from the population typical values.
Dose individualisation for drugs with narrow therapeutic
index.
Stochastic control of drug therapy.
POST APPROVAL PHASE