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Ionisation of drug molecules
Drug liberation, absorption and distribution
The first three stages of the pharmacokinetic process are:

Liberation 1 – release of the medicinal drug from a formulated medicine.

Absorption 2 – movement of the liberated drug into the bloodstream.

Distribution3 – passage of the drug from the bloodstream to body tissues and organs.
As a rule of thumb, molecular compounds are less soluble in water than in non-polar solvents,
while ionic compounds are more soluble in water than in non-polar solvents.
In the body there are two distinct environments. One, such as blood plasma, is aqueous and so
ionic compounds are more likely to be soluble in blood than are molecular compounds.
The other is the cell membrane which is mainly composed of non-polar lipids (phospholipids,
glycolipids and cholesterol). The central part of the membrane, therefore, consists mainly of long
chain hydrocarbons and so molecular compounds are more likely to be soluble in cell membrane
than are ionic compounds.
Aqueous
environment
inside and
outside of the
cell
Phospholipid
bilayer of a
cell
membrane
H3C
H3C
O
O
HO
H
P
O
O
CH3
+
O
N
O
Figure 1 A typical phospholipid molecule. The
hydrocarbon tails of these molecules make up the bulk of
a cell membrane, with the phosphate end at the surface
of the membrane.
CH3
H3C
O
An effective drug needs to be sufficiently soluble in water to dissolve in blood plasma and be
carried around the body while also being sufficiently soluble in non-polar lipids to pass through cell
membranes into cells.
1
2
3
Pharmacokinetic processes: liberation.
Pharmacokinetic processes: absorption.
Pharmacokinetic processes: distribution.
1
Ionisation
Most drug molecules ionise in aqueous solution to give weakly acidic or basic solutions.
Naproxen is a non-steroidal anti-inflammatory drug (NSAID). It is used to relieve pain and
inflammation in, for example, rheumatic disease, sprains, strains, backache, gout, and period
(menstrual) pain.
A naproxen molecule has a carboxylic group and so is a weak acid. It ionises in water to give an
equilibrium solution that contains a mixture of unionised molecules, carboxylate ions and
hydroxonium ions (figure 2).
CH3
CH3
CH
OH
C
H3C
CH
+ H2O
⇌
O
H3C
O
−
OH
+
C
+ H3O
O
O
Figure 2 The dissociation of naproxen in aqueous solution.
Fenoprofen and penicillin G (benzylpenicillin) are drug molecules that also contain carboxylic acid
groups. Both compounds partially ionise in aqueous solution.
HO
OH
O
O
CH3
H3C
NH
S
O
O
O
N
CH3
CH3
O
O
Aspirin
HO
O
Penicillin G
Fenoprofen
Figure 3 These three medicinal drugs also form weakly acidic solutions in water.
The general reaction may be represented by
HA + H2O ⇌ H3O+ + A−
where,
HA = acid (the drug molecule);
H2O = base;
A− = conjugate base (the drug anion);
H3O+ = conjugate acid.
Diphenhydramine is a first generation antihistamine used to treat allergic symptoms such as hay
fever though it does have an sedating effect. More recently developed antihistamines are not
sedating. The sedating properties of diphenhydramine explain its use to treat insomnia and travel
sickness (cars, boats and planes).
2
A diphenhydramine molecule has an amine group and so is a weak base. It ionises in water to give
an equilibrium solution that contains a mixture of unionised molecules, quaternary ammonium ions
and hydroxide ions (figure 4).
CH3
CH3
H3C
N
+
N
H
CH3
O
O
+ H 2O
+ OH−
⇌
Figure 4 The ionisation of diphenhydramine in water.
The general reaction may be represented by
B + H2O ⇌ BH+ + OH−
where,
B = base (the drug molecule);
H2O = acid;
OH− = conjugate base (the drug anion);
BH+ = conjugate acid.
Other drugs which are bases include adrenaline, ephedrine, atropine and tetracycline.
OH
CH3
OH
H3C
N
OH
CH3
OH
HN
HO
CH3
NH2
HN
CH3
OH
OH
OH
Adrenaline
CH3
Ephedrine
O
OH
O
O
Tetracycline
Figure 5 These three medicinal drugs form weakly basic solutions in water.
Finding out
The pH of aqueous solutions in which a drug is dissolved determines the form in which the drug is
present – molecule or ion.
This is particularly important for drugs taken orally as pH varies through the gastrointestinal tract.
What are the pH values for fluids in different sections of the gastrointestinal tract?
Based on this information, where in the gastrointestinal tract will the following drugs be absorbed
from the bloodstream most quickly? (a) aspirin, (b) ephedrine.
3