Multi-Compartment Models PDF

Summary

This document describes multi-compartment models used to understand how drugs distribute and are eliminated from the body. It focuses on the two-compartment open model, discussing the central and peripheral compartments, and the factors influencing drug distribution and elimination rates.

Full Transcript

Most common model
Body tissues two broad
categories:
Group of tissues which
equilibrate instantaneously

are supposed to reside in
central compartment

Sampled compartment ( though such sampling is
not always necessary).
iver,
Highly perfused tissues :

lungs,
kidney etc.

TWO COMPARTMENT OPEN
MODEL

Contains slowly equilibrating
tissues

Central Compartment:

Drug requires some length of
time for equilibration.

Peripheral or Tissue
Compartment:

This model assumes
Drug eliminated from central
compartment.
Part of an organ in the central
compartment
Rest in the tissue compartment.

Possible to have:

Determining factor for classification Rate of
equilibration.
Categorization of two
compartment model

Depending upon the compartment from
which the drug is eliminated

Two compartment model with elimination
from central compartment
Two compartment model with elimination
from peripheral compartment
Two compartment model with elimination
from both the compartments.
Types of Two compartment
model

Other:
After an intravenous injection

Are:

Decline in plasma conc. :

Biexponential

Distribution

Two disposition processes

Elimination

Distribution into more slowly
perfused tissues.

Rapid decline due to

Initial rapid decline in the central
compartment

Graph:

distribution phase of the curve.
pseudo-distribution equilibrium achieved
between two compartments
State of equilibrium between
central compartment

After sometime:

and more poorly perfused tissue
compartment.
loss of drug from central compartment appears
to be single first-order process

After this equilibrium is
established:

overall processes of elimination
of drug from the body.

It is due to:
The second, slower rate
process

elimination phase.

Two compartment model
assumes:

t = 0 there is no drug in the
tissue compartment.

Two compartment kinetics

The tissue drug level will
eventually peak

Tissue drug level curve after a
single intravenous dose of drug
shown in fig.

start to decline as conc. gradient between
two compartment narrows
total amount of drug remaining
in the body at any time.

Theoretical tissue conc.
together with the blood
conc.,IDEA OF :

This information would not be
available without using:

pharmacokinetic models.

Distribution Phase
Elimination phase

Samples of blood removed from
central compartment analyzed
for presence of drug:

Distribution phase may take
minutes or hours
may be missed entirely if blood
is sampled too late after
administration of the drug.
K12 and K21 : first order rate
constants
Depict drug transfer between central
and peripheral compartments.

Rate of Drug change in
tissues:

In the model depicted above

1.

Notes:

2.

3.
Single compartment
pharmacokinetic calculations
relatively simple.

PHARMACOKINETIC
PARAMETERS

Situations HAVING two, and
occasionally more than two
compartments
drug distribution, elimination
and pharmacologic effect.
smaller, rapidly equilibrating
volume,
usually made up of plasma or
blood and

First compartment

those organs or tissues that
have high blood flow
Initial Volume of Distribution
(volume : Vi)

are in rapid equilibrium with the
blood or plasma drug conc.
Equilibrates over a somewhat
longer period.
Second compartment

This volume referred to as V t
or tissue volume of distribution.

Half life for distribution phase

alpha half life

Half life for drug elimination !
Notes

Multi-Compartment
Models

beta half life.

Sum of Vi and Vt : apparent
volume of distribution (V).
Drugs are assumed to enter into
and be eliminated from Vi.
Any drug that distributes into tissue compartment (Vt )
must re- equilibrate into Vi before it can be eliminated.
Some time required for a drug
to distribute into:

Effects of a Two – Compartment
Model on the loading dose and
plasma conc.( C ):

Since Vt have slowly equilibriating
(tissue components)

Vt:

Rapidly administered loading
dose calculated on the basis of
V ( Vi+ Vt)

Can effect certain body parts
negatively
Must be given slowly
Loading dose?

Affect heart, even tho no
relation

If fast?
higher than predicted
Result in an initial C
Why ?

initial volume of distribution (Vi)
is always smaller than V total

Whether target organ behaves
as though it were located in Vi
or Vt.
Consequences of an inaccurate
prediction depend on:

Examples:

Lidocaine, Phenobarbital,
procainamide, and theophylline

exert therapeutic and toxic
effects on target organs

when loading doses are
calculated based on the:
In these instances

that behave as though they are
located in Vi.

total volume of distribution,

conc. of drug delivered to the
target organs could be:

much higher than expected

produce toxicity if loading dose
is:

not administered appropriately.

First calculating loading dose based on the
total volume of distribution ( V ),
Then administering the loading dose at a rate slow
enough to allow for drug distribution into Vt.
1st approach:

This approach is common in
clinical practice,
principle of two-compartment
modeling with

Guidelines for rates of drug
administration are often based
on:

( toxic or therapeutic)
responding as though they were
located in Vi.

Receptors for clinical response
To administer loading dose in
sufficiently small individual
bolus doses
such that C in Vi

does not exceed some
predetermined critical conc.
with the end-organ being
located in Vi.

Problem can be circumvented
by:

Its cardiac effects parallel the
plasma conc.

Potassium is a good example of a drug that follows
this principle of two-compartment modeling

In addition, there is slow equilibrium between
plasma and tissue potassium concs.
Potassium is primarily an
intracellular electrolyte

When potassium is given
intravenously:

rate of administration must be
carefully controlled
serious cardiac toxicity and
death will occur

if patient experiences excessive
plasma (Vi) concs.

Concept of two compartment modeling also important
in evaluating the offset of drug effect.
Rapid achievement of a
therapeutic response

2nd approach:

Followed quickly by loss of
therapeutic response

For drugs with end organ for
clinical response located in Vi:

drug being distributed into
larger volume of distribution
may be the result of:

rather than drug being
eliminated from the body.

e.g. digoxin, lithium
high C, which may be observed before
distribution occurs, is not dangerous.
will not reflect the tissue conc.
at equilibrium.

However plasma concs that are
obtained before distribution is
complete

These plasma samples cannot be used to predict
therapeutic or toxic potential of these drugs.
Clinicians usually wait for 1-3 hours after an intravenous
bolus dose of digoxin before evaluating the effect
so that the full therapeutic or
toxic effects of a dose can be
observed.

Digoxin to distribute to site of
action (myocardium)
When the drug’s target organ is
in second or tissue
compartment, Vt:

Slow drug distribution into the tissue compartment can pose
problems in accurate interpretation of drug conc. when a drug is
given by intravenous route.

This delay allows:

Generally not a problem when a
drug is given orally.
Rate of absorption is usually slower than the rate of
distribution from Vi to Vt.
Digoxin and lithium are
exceptions to this rule.
several hours required for
complete absorption and
distribution.
Plasma samples obtained less
than 6 hours after an oral dose

Digoxin

oral dose of lithium less than 12

lithium

hours : questionable value.

These drugs given orally:

Receptors in end-organs behave as though they are
located in more slowly equilibrating tissue compartment

For these two drugs:

Plasma concs obtained during the distribution phase
( before equilibrium with the deep tissue compartment
is complete)
Pharmacologic response will be
much less than the plasma
concs would indicate.

Only when attached to
receptors

Alpha phase for most drugs represents
distribution of drug from Vi into Vt
Relatively little drug eliminated
during distribution phase.
Drugs that behave in this way
are generally referred to as:

non- significant two
compartment drugs.
If patient not harmed by initially
elevated drug conc. in alpha
phase and
no drug samples are taken in
alpha phase,
Drug can be successfully
modeled as one-compartment
drug
Then:

DRUGS WITH SIGNIFICANT AND NON- SIGNIFICANT
TWO COMPARTMENT MODELING:

Non-significant means:

(i.e only the elimination or beta
phase is considered).
Increased drug plasma concs
during the alpha phase can be
clinically significant
serious toxicity
Why?

For some drugs,

If end organ behaves as though
it lies within the:

These drugs considered to
exhibit “nonsignificant ” two
compartment modeling only
after:
Plasma samples obtained for
pharmacokinetic modeling only
during:

Drugs with “ significant ” two
compartment modeling:

alpha phase or distribution has
been completed.

beta or elimination phase.

Those eliminated to significant
extent during initial alpha phase.
alpha phase cannot be thought
of simply as distribution,

Methotrexate
Example:
Why?

Significant elimination occurs as
well.

lithium & lidocaine.

Drugs that border on having significant two
compartment modeling:

When a one-compartment model is used
for drugs that exhibit

significant drug elimination in
the alpha phase,

Actual trough concs will be lower than those
predicted by one- compartment model.
Two-compartment computer models are available for
therapeutic drug monitoring.

initial volume of distribution (Vi)

If care taken to avoid obtaining
samples in distribution phase,
Very similar pharmacokinetic interpretations are usually
arrived at using simpler one-compartment model.

Vt.

will be increased,