Biopharmaceutics and Pharmacokinetics Lecture 8 PDF

Summary

These lecture notes cover biopharmaceutics and pharmacokinetics, focusing on fundamental pharmacokinetic parameters, intravenous bolus administration, and the volume of distribution. The document also discusses factors affecting drug distribution, such as tissue permeability and drug binding.

Full Transcript

Biopharmaceutics
and
Pharmacokinetics

LECTURE 8
Fundamental Pharmacokinetic Parameters

Apparent
Elimination rate
Volume of
constant (K)
Distribution (Vd)

Elimination half
Clearance (Cl)
life (t1/2)

19
Intravenous bolus administration: monitoring drug in plasma
(one-compartment model)
▪ The one-compartment open model with IV bolus administration is the simplest
pharmacokinetic model to study the fundamental pharmacokinetic parameters of a
drug.

Pharmacokinetic model for a drug administered by rapid intravenous injection.
DB = drug in body; VD = apparent volume of distribution; k = elimination rate constant.

▪ The one-compartment open model with IV bolus dosing assumes that the drug is
uniformly distributed within a single hypothetical compartment volume from which the drug
concentration can be sampled and assayed easily.

3
 1. Volume of Distribution
Distribution of Drugs

After entry into the systemic circulation, either by intravascular injection (IV) or by
absorption from any extravascular sites (EV), the drug is subjected to several
processes called disposition processes.
Disposition is defined as the processes that tend to lower the plasma concentration of
drug.
The two major drug disposition processes are –
1. Distribution which involves reversible transfer of a drug between compartments.
2. Elimination which causes irreversible loss of a drug from the body.
Elimination is further divided into two processes :
(a)Biotransformation (metabolism)
DINA.M.MAHDY, PHD 7th December 2023 (b)Excretion. 4
 Distribution is the reversible transfer of a
drug between the blood and the
extravascular fluids and tissues.
Steps in Drug Distribution
Distribution of a drug present in the systemic
circulation to the extravascular tissues involves the
following steps:
1.Permeation of free unbound drug present in
the blood through the capillary wall and entry
into extracellular/ interstitial fluid (ECF)
(occurs rapidly)
2. Permeation of drug present in the ECF
through the membrane of tissue cells and
into the intracellular fluid.

DINA.M.MAHDY, PHD 7th December 2023 5
Factors Affecting the Distribution of Drugs
1. Tissue permeability of the drug:
a.Physicochemical properties of the drug like molecular size, pKa, and o/w
partition coefficient.
b.Physiological barriers to the diffusion of drugs
2. Organ/tissue size and perfusion rate:
3. Binding of drugs to tissue components:
a.Binding of drugs to blood components
b.Binding of drugs to extravascular tissue proteins
Apparent Volume of Distribution
❑It is defined as the hypothetical body fluid volume into which a drug should be
dissolved or distributed to have the same concentration as the plasma concentration.
❑It is called apparent volume because all body parts equilibrated with the drug do not
have equal concentration.
DINA.M.MAHDY, PHD 7th December 2023 6
❑ The volume of distribution is a fundamental pharmacokinetic parameter that
describes how a drug distributes throughout the body relative to the concentration
of the drug in the plasma i.e. It can indicate the extent of drug distribution into body
fluids and tissues.

❑It is important to determine proper drug dosing regimens and interpret drug
behavior in different physiological and pathological states.

❑Generally, dosing is proportional to the volume of distribution.
For example, the larger the volume of distribution, the larger the dose required to
achieve the desired target concentration.

DINA.M.MAHDY, PHD 7
❑ To understand how distribution occurs, you must have a basic
understanding of body fluids and tissues
❑ The fluid portion (water) in an adult makes up approximately 60% of
total body weight (~ 40- 42 L)
and is composed of intracellular fluid (35%) (~ 22- 25 L) and
extracellular fluid (25%) (~ 15-18 L)
❑ Extracellular fluid is made up of plasma (4%) (~ 4-6 L)and interstitial
fluid (21%) (~10-12L)
❑ Interstitial fluid surrounds cells outside the vascular system.
❑ These percentages vary somewhat in a child.

❑ The body water is made up of 3 distinct compartments as shown in the Table
❑The volume of each of these real physiologic compartments can be determined by use of specific
tracers or markers

DINA.M.MAHDY, PHD 8
1. If a drug has a volume of distribution of approximately 15–18 L in a 70-kg person, we might assume
that its distribution is limited to extracellular fluid, as that is the approximate volume of extracellular
fluid in the body.
2. If a drug has a volume of distribution of about 40 L, the drug may be distributed into all body water
because a 70-kg person has approximately 40 L of body water (70 kg
× 60%)
3. If the volume of distribution is much greater than 40–50 L, the drug is probably concentrated in
tissue outside the plasma and interstitial fluid.
4. If a drug distributes extensively into tissues, the volume of distribution calculated from plasma
concentrations could be much higher than the actual physiologic volume in which it distributes.
For example, by measuring plasma concentrations,

❑ It appears that digoxin distributes in approximately 400-500 L in an adult. Because digoxin binds
extensively to muscle tissue, plasma levels are lower than concentrations in muscle tissues.

❑For other drugs, tissue concentrations may be lower than plasma concentration, so it may appear that
these drugs are distributed in a relatively small volume (low volume of distribution).
DINA.M.MAHDY, PHD 9
 Determinatation of Vd
Drug concentration in a compartment is defined as
the amount of drug in a given volume, such as mg/L:
During the entire time that the drug is in the body, elimination is
taking place. So, if we consider the body as a tank with an open
outlet valve, the concentration used to calculate the volume of
the tank would be constantly changing.
One way to calculate the apparent volume of drug
distribution in the body is to measure the plasma
concentration immediately after intravenous administration of
bolus injection before elimination has had a significant effect.
The concentration just after intravenous administration (at
time zero, t0) is abbreviated as C0
The volume of distribution can be calculated using the
equation:

DINA.M.MAHDY, PHD 11
❑C0 can be determined from a direct measurement
or estimated by back extrapolation
from concentrations determined at any time after the
dose.
❑ If two concentrations have been determined,
back extrapolation of a line containing the two
values and extending through the y-axis can be
drawn on semilog paper.

❑The point where that line crosses the y-axis gives
an estimate of C0.
❑ Both the direct measurement and back-
extrapolation approaches assume that the drug
distributes instantaneously into a single
homogeneous compartment
DINA.M.MAHDY, PHD 12
Example: If 100 mg of drug is administered intravenously and the plasma concentration is determined to
be 5 mg/L just after the dose is given, then calculate Vd.

Vd= X / C
V is the volume of distribution
X is the amount of drug in body

C is the concentration in the plasma
Vd= 100 / 5 = 20L
N.B volume of distribution can vary considerably from one person to another because of
differences in physiology or disease states.

DINA.M.MAHDY, PHD 13
For drugs administered extravascularly
𝐹 𝑋0
Vd=
𝐾𝑒 𝐴𝑈𝐶

where, Xo = dose administered, and F = fraction
of drug absorbed into the systemic circulation.
F is equal to one i.e. complete availability when the drug is administered
intravenously.
Ke: elimination rate constant
AUC: area under concentration-time curve.
 Volume of distribution (V) is an important indicator of the extent of
drug distribution into body fluids and tissues.
V relates the amount of drug in the body (X) to the measured
concentration in the plasma (C).
A large volume of distribution usually indicates that the drug
distributes extensively into body tissues and fluids and vice versa.
Two drugs can have the same volume of distribution, but one may
distribute primarily into muscle tissues, whereas the other may
concentrate in adipose tissues.

DINA.M.MAHDY, PHD 15
 Expressions of VD

The apparent VD is a volume term that can be expressed as:
a simple volume: (L) or
standardized in terms of body weight: (L/kg) or
in terms of percent of body weight: (%)
▪ In expressing the apparent VD in terms of percent of body weight, a 1-L volume is
assumed to be equal to the weight of 1 kg.
▪ For example, if the VD is 3500 mL for a subject weighing 70 kg, the VD expressed as
percent of body weight is
3.5Kg /70Kg x 100= 5% of body weight
▪ If VD is a very large number—>100% of body weight—then it may be assumed
that the drug is concentrated in certain tissue compartments.
▪ VD of digoxin is 7.0 L/kg (estimated at 700% of body weight).

Prof. Nabila Boraie 16
❑ Approximate volumes of distribution for some commonly used drugs are shown in
the Table below.
❑When V is many times the volume of the body, this indicates high drug
concentrations in some tissues much greater than that in plasma (tissue binding).
❑ Examples include digoxin, diltiazem, imipramine, labetalol, metoprolol, meperidine,
and nortriptyline.
❑The smallest volume in which a drug may be distributed is the plasma volume.

Vd=42 L or 0.6 L/Kg (no binding)
Vd> 42 L or 0.6 L/Kg (tissue binding)
Vd< 42 L or 0.6 L/Kg (plasma protein binding)

DINA.M.MAHDY, PHD 17
▪ The apparent volume of distribution
is
a constant for a given drug.
independent of the administered
dose and
independent of route of drug
administration.

▪ The values of.Cp0 (y-axis intercept)
are directly proportional to the
administered dose of a drug (5, 10 and
25 mg dose); however, the ratio of Semilogarithmic plot of plasma concentration
dose (DB0) over the initial plasma (Cp) versus time following three different doses
concentration, Cp0 remains of drug as an intravenous bolus. Note the
unchanged: deference in the intercepts, which are the initial
plasma concentrations,(.Cp)0.

Prof. Nabila Boraie 18
 Significance of the Apparent Volume of Distribution
▪ The apparent volume of distribution is usually a property of a drug rather than of a
biological system.
▪ It describes the extent to which a particular drug is distributed in the body tissues.
▪ The higher the value of the apparent volume of distribution, the greater is the extent
to which the drug is distributed in the body tissues and or organs.
▪ The more lipophilic the nature of the drug, the greater will be the value of the
apparent volume of distribution and the smaller will be the initial plasma concentration
(e.g.,digoxin, diltiazem and metoprolol).
▪ Basic drugs, including tricyclic antidepressants and antihistamines, are extensively
bound to extravascular tissues and are also taken up by adipose tissues. Their
apparent volumes of distribution are large, often larger than the total body space; for
example,
▪ The apparent volume of distribution of amphetamine is approximately 200 L (~ 3 L kg-
1). The relatively small doses and large volumes of distribution together produce low
plasma concentrations, making quantitative
Prof. Nabila Boraie détection in plasma
19 a difficult task.
▪ Conversely, if the drug is hydrophilic, the drug will penetrate to a lesser extent into
tissue and, consequently its plasma concentration will be higher, and its volume of
distribution will be smaller.
▪ Many acidic drugs, including salicylates, sulfonamides, penicillins, and
anticoagulants, are either highly bound to plasma proteins or too water soluble to
enter into cellular fluid and penetrate into tissues to a significant degree. These
drugs, therefore, have low volumes of distribution and low tissue-to-plasma
concentration ratios.
▪ Consequently, the binding of a drug to peripheral tissues or to plasma
proteins will significantly affect the VD.
▪ Theoretical limits for the apparent volume of distribution will be as low as
≈ 5% of BW (equivalent to the volume of the plasma if the drug totally fails to
penetrate the tissues or the drug is extremely hydrophilic) to as high as 10000 L or
even greater.

Prof. Nabila Boraie 20
 VD in relation to body fluids
Body water VD % of Comment
BW
compartment
Plasma 4L 5.7 Drugs highly bound to plasma protein
(Warfarin). High MW hydrophilic
drugs (heparin)
Extracellular fluids 14 L 20 Drugs distributed to extracellular fluids
e.g. aminoglycosides
Intracellular fluids 28L 40 Drugs distributed to intracellular fluids
(more lipophilic low MW drugs
Whole body fluids 42L 60 Drugs distributed to the whole-body fluids
( small water-soluble molecules e.g.
alcohol)
> 100 L >100 Drugs distributed to deep tissues( e.g.
digoxin) or bound fat (phenobarbitone)

Prof. Nabila Boraie 21
Certain generalizations can be made regarding the apparent volume of distribution of certain
drugs:
1. Drugs that bind selectively to plasma proteins or other blood components, e.g. warfarin (i.e. those
that are less bound to extravascular tissues), have an apparent volume of distribution smaller than
their true volume of distribution.
The Vd of such drugs lies between blood volume and TBW volume (i.e. between 6 to 42 litres)
for example, warfarin has a Vd of about 10 litres.

2. Drugs which bind selectively to extravascular tissues, e.g. chloroquine (i.e. those that are less
bound to blood components), have apparent volume of distribution larger than their real volume of
distribution. The Vd of such drugs is always greater than 42 litres or TBW volume;
for example, chloroquine has a Vd of approximately 15,000 litres
Such drugs leave the body slowly and are generally more toxic than drugs that do not distribute
deeply into body tissues.
The Vd of various drugs ranges from as low as 3 litres (plasma volume) to as high as
40,000 litres (much above the total body size)

DINA.M.MAHDY, PHD 7th December 2023 22
BINDING OF DRUGS TO BLOOD COMPONENTS (Plasma
Protein-Drug Binding)
▪Following entry of a drug into the systemic circulation, the main
interaction of drug in the blood compartment is with the plasma
proteins which are present in abundant amounts and in large
variety.
▪The binding of drugs to plasma proteins is reversible.
▪The extent or order of binding of drugs to various plasma proteins
is:
Abumin > α1-Acid Glycoprotein > Lipoproteins > Globulins
Binding of Drugs to Human Serum Albumin
▪Human serum albumin (HSA), is the most abundant plasma protein
(59 % of total plasma) with a large drug-binding capacity

DINA.M.MAHDY, PHD 7th December 2023 23
TISSUE BINDING OF DRUGS (TISSUE LOCALIZATION OF DRUGS)
The body tissues, comprise 40% of the body weight Hence, tissue-drug binding is much more significant
than thought to be
Importance of Tissue-drug binding
1.It increases the apparent volume of distribution of drugs in contrast to plasma protein binding which
decreases it.
This is because the parameter is related to the ratio of the amount of drug in the body to the plasma
concentration of free drug and the latter is decreased under conditions of extensive tissue binding of drugs
2.Tissue-drug binding results in the localization of a drug at a specific site in the body (with a subsequent
increase in biological half-life).

This is more so because a number of drugs bind irreversibly with the tissues (contrast to plasma protein-
drug binding); for example, oxidation products of paracetamol, phenacetin, chloroform, carbon
tetrachloride and bromobenzene bind covalently to hepatic tissues.
Factors influencing localization of drugs in tissues include:
❑ lipophilicity and structural features of the drug
❑ perfusion rate, pH differences, etc
DINA.M.MAHDY, PHD 7th December 2023 24
 Factors affecting Vd
The physicochemical properties of the drug (lipophilicity, partition coefficient, M W,
molecular size, degree of ionization, etc)
Degree of tissue and protein binding
Body composition and Blood flow
Age, Pregnancy, and Diseases
Importance and applications of Vd
Calculation of the total amount of drug in the body relative to Cp.
Calculation of loading dose when the target Cp is known to reach
required therapeutic plasma concentration quickly
Estimation of feasibility of hemodialysis in cases of drug overdose or in renal failure
Dialysis is not useful for drugs with high Vd because of extensive tissue distribution. Dialysis
is useful for drugs with low Vd where most of the drug is in circulation. 25
Thank you