Lecture 3-5 Pharmacokinetics I-III PDF

Summary

This document is a lecture on pharmacokinetics, covering topics such as drug absorption, distribution, metabolism, and excretion. It provides foundational knowledge for students in pharmacology and related disciplines.

Full Transcript

Dr. Rani Qasem
Susan Posky

Pharmacokinetics
Pharmacokinetics I, III,and
II andIIIIII

Dr. Tariq Alqahtani
Dr. Rani Qasem & Dr Mai Ajaji
Dr. Rawan Alnafisah

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah 1
Lecture Learning Outcomes
At the end of the lectures, the students should be able to:
1. Recall the factors that influence drug absorption.
2. Illustrate the methods by which drug absorption can be manipulated.
3. Explain the factors that influence drug distribution.
4. Highlight the importance of drug metabolism for elimination.
5. Define the major chemical pathways of metabolism: oxidation, reduction,
hydrolysis, and conjugation.
6. Describe the concept of detoxication versus bioactivation.
7. Know the major sites of drug elimination: liver, kidney, lungs, and first-pass
effects.
8. Explain the concept of drug clearance as a combination of metabolism and
excretion.
9. Recognise the effects of age, renal disease, and liver disease on drug
elimination.

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah 2
 Pharmacokinetics
Pharmacokinetics is concerned with factors that
directly affect the amount of drug that will arrive
at the target site, which will determine the
intensity of drug action and the duration of action.
Pharmacokinetics deals with the ADME Factors:

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah 3
The Fate of Drugs in the Body

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah 4
Drug Absorption

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Absorption
Absorption?is the passage of a drug from its site of
application (administration) to the bloodstream
(plasma).

For drugs that act locally ?(e.g. inhalation of a
bronchodilator aerosol to treat asthma), absorption
is not required.

The mere presence of a drug in the blood does not
lead to a pharmacological response.

– To be effective,? the drug must leave the vascular space and
enter the intercellular or intracellular spaces or both.
PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
Drug Routes of Administration

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Absorption
Absorption is important for all routes of
administration except3for intravenous (IV) injection
A. Mechanisms of absorption of drugs from the GI
tract:

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Factors Affecting Drug Absorption
B. Factors affecting the absorption of a drug are:3
3
Water solubility (rate of dissolution)
-

2
Lipid or fat solubility
-

3
pH Partitioning
&

4
Surface area
-

S
Blood flow
-

6
Availability of transport mechanisms
-

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah 9
 Rate of Dissolution
All drugs must be in solution (dissolve) before they can be
absorbed
All body fluids are water-based. Therefore, a drug must be
soluble in water in order to be absorbed
Dissolution of the drug in aqueous solution is dependent
on:? 56 I
--

1. Disintegration of the drug
– Disintegration increases the surface area of a drug
-
5 4

– Sometimes, the manufacturer tries to hasten disintegration of
-

tablets by adding starch that swells upon contact with water
&

2. pH of the solution

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Rate of Dissolution
2. The pH of the solution
The relative acidity or basicity of the fluids into
which a drug is placed will affect how rapidly the
drug will dissolve.
– The pH of the stomach can be as low as 1.0,
The pH of the small intestine can range from 6.9 to
7.4,
while the pH of the plasma is approximately 7.4.
– Weakly acidic drugs (e.g. aspirin) are more soluble in a
-

basic or alkaline solution like the small intestine.
-

– Weakly basic drugs (e.g. tetracycline) are more soluble
-

in an acidic solution like the stomach.
-

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Lipid or Fat Solubility
Highly lipid-soluble drugs are absorbed more rapidly than
drugs with low lipid solubility?because lipid-soluble drugs can
[]
readily cross the biological membranes.
To reach its site of action, a drug must
cross a number of biological barriers
and membranes.
All body membranes are lipid in
nature, which are selectively
permeable. These membranes will only
allow the unionised particles (neither
positive nor negative charge) to pass
through them.
PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 pH Partitioning

The degree of ionisation of drugs depends on?the local
pH of the solution in which the drug is dissolved, which
influences their lipid–water partition coefficient and M

hence their ability to diffuse through membranes.
Ionisation is the process whereby a substance breaks
down into positively and negatively charged particles.
HA * H+ + A-
has to be(weak)
Drug
in order to be reversable
B + H+ BH+
Therefore, the drugs can exist in either a charged or uncharged form.

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 a
Other Factors Affecting Drug Absorption
Absorption
&Surface area: The larger the surface area, the
faster absorption will be.
–[Orally administered drugs are usually absorbed from
the small intestine rather than from the stomach.J
Absorptiona
Blood flow: Drugs are absorbed most rapidly from
sites where blood flow is high.
Availability of transport mechanisms:
Channels and pores
Transport systems
Direct penetration of cell membrane (diffusion).

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
X

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
X
Bioavailability and Bioequivalence
C. Bioavailability and Bioequivalence

Bertram-Ralph E, Amare M. Factors affecting drug absorption and distribution. General bioequivalence profile of generic vs brand products.
Anaesthesia & Intensive Care Medicine. 2023 Feb 17. Mastan S, Latha TB, Ajay S. The basic regulatory considerations and prospects for
conducting bioavailability/bioequivalence (BA/BE) studies–an overview. Comparative
Effectiveness Research. 2011 Mar 22:1-25.

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
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Drug Distribution

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Distribution
Distribution,1drug movement from the blood to
the interstitial space of tissue and into cells.

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Distribution
Once a drug has entered the blood, the rate at which it
penetrates tissues and other body fluids depends on:?
1. Blood flow to tissue (perfusion
rate):
Normally, most tissue is well
perfused.
In certain pathological conditions
(e.g. abscesses & tumours), there
is a limited blood supply.
2. The ability of a drug to exit the
vascular system.
PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Exiting the Vascular System

Drugs in the vascular system
leave the blood at the capillary
bed, which depends on:

1. Capillary permeability:
– Capillaries of the CNS (BBB).
– Agents that affect capillary
permeability (e.g. histamine)
or capillary blood-flow rate
(e.g. norepinephrine).

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Exiting the Vascular System
2. Extent of plasma protein and specific organ
binding
– Drugs can form reversible bonds with various proteins in
the body (plasma albumin, large molecule = 69000 D)
– Drugs can exist in the blood as either bound or unbound
(free)
– Bound drugs are?pharmacologically inactive -

– Bound drugs are considered as drug reservoirs -

– Anionic (weak acid) and hydrophobic drugs
– Protein binding restricts drug distribution
– Source of drug interactions
e.g. warfarin (99%), gentamicin (10%)
&
Active unbound
:.
PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Y

-

Talevi, A., Bellera, C.L. (2021). Drug Binding to Plasma Proteins. In: The
ADME Encyclopedia. Springer, Cham. https://doi.org/10.1007/978-3-030-
51519-5_53-1

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Drug Elimination

Drug elimination?is the irreversible loss of drugs
from the body.
Drug elimination occurs by two processes:
– Metabolism:? involves enzymatic conversion of one
chemical entity to another
– Excretion:2consists of elimination from the body of a
chemically unchanged drug or its metabolites

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
Drug Metabolism

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Drug Metabolism

Drug Metabolism -Biotransformation ?
It is the process by which the drug is
chemically converted to a metabolite.
&

The liver is the chief organ?of drug
-
metabolism.

It is richly supplied with blood, of which 1100

X
ml is received each minute from the intestines
through the portal vein and 350 ml through the
hepatic artery, comprising nearly 1/3 of cardiac
output.

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Drug Metabolism
1

The main purpose of drug metabolism?is to ‘detoxify’
2

drugs and render them less pharmacologically
active.
Important exceptions:
– Where the metabolite is more active (prodrugs)
e.g. Erythromycin-succinate (less irritation of GI) → Erythromycin
– Where the metabolite is toxic (e.g. acetaminophen
metabolites)
– Where the metabolite is carcinogenic

If the drug metabolism is delayed, drug accumulation
may occur.
PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Drug Metabolism
There is a close relationship between drug
metabolism and the normal biochemical processes
occurring in the body:
– Drug metabolism involves many pathways associated
with the synthesis of endogenous.
– Many of the enzymes involved in drug metabolism are
principally designed for the metabolism of endogenous
compounds.
– These enzymes metabolise drugs only because the
drugs resemble the natural compound.
PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Drug Metabolism
The liver is the principal site
of drug metabolism:
*
Doesn't need metabolize
Hydrophilic -
↳ can be metabolized
– Hydrophilic vs. lipophilic drug

Other sites2of drug metabolism
include the gut, lungs, skin,
---

kidneys and others.
-

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Drug Metabolism
For orally administered compounds:
– Intestinal metabolism
– Liver metabolism: ‘First-pass effect’
– Enterohepatic recycling
– Gut microorganisms

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Read
Consequences of Drug Metabolism

1. Inactivation of drugs
2. Promotion of renal excretion by increasing drug
polarity (water solubility)
3. Increased effectiveness of drugs
4. Activation of ‘prodrugs’
5. Increased drug toxicity

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Consequences of Drug Metabolism
A.
2 Active drug → inactive metabolites
8
B. Inactive drug → active/enhanced activity
X e.g. Cyclophosphamide → liver →
aldophosphamide
→ liver → carboxyphosphamide
I → tumor → phosphoramide mustard and
acrolein
&
C. Active drug → active metabolites
X e.g. Phenacetin → Acetaminophen (paracetamol)

O
D. Active drug → toxic metabolites
X e.g. Isoniazide → Acetylisoniazide
PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Read
Special Considerations in Drug Metabolism

Age; the liver is not fully developed in infants
Induction or inhibition of drug-metabolising
enzymes
First-pass effect, rapid hepatic inactivation of
certain oral drugs (e.g. Nitroglycerine 99.9%,
Propranolol 70%)
Nutritional status, cofactors
Competition between drugs

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Phases of Drug Metabolism
o Drug metabolism involves two kinds of
biochemical reactions,7 which usually decrease lipid -
-

solubility, thus increasing renal elimination:
-
-

Phase I reactions are? catabolic (e.g. oxidation,
reduction or hydrolysis).
Phase II reactions are3synthetic (anabolic).

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Phase I Reactions
Phase I reactions involveSmodification of the chemical
structure of the drug by adding or exposing a small polar
functional group (-OH, -SH, -NH2, -COOH, etc.), a process
known as---
‘functionalisation’.

– It involves a hepatic microsomal mixed function oxidase system
(cytochrome P450).
– Metabolites are often inactive and sufficiently polar (hydrophilic)
&

to be excreted readily. &

– However, some metabolites are more chemically reactive (i.e.
more toxic or carcinogenic).
– The functional group serves as the point for the phase II
reactions.

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 X Cytochrome P450
Humans have 18 families of cytochrome P450 genes and 43 subfamilies:
– CYP1 drug metabolism (3 subfamilies, 3 genes, 1 pseudogene)
– CYP2 drug and steroid metabolism (13 subfamilies, 16 genes, 16 pseudogenes)
– CYP3 drug metabolism (1 subfamily, 4 genes, 2 pseudogenes)
– CYP4 arachidonic acid or fatty acid metabolism (5 subfamilies, 11 genes, 10 pseudogenes)
– CYP5 Thromboxane A2 synthase (1 subfamily, 1 gene)
– CYP7A bile acid biosynthesis 7-alpha hydroxylase of steroid nucleus (1 subfamily member)
– CYP7B brain-specific form of 7-alpha hydroxylase (1 subfamily member)
– CYP8A prostacyclin synthase (1 subfamily member)
– CYP8B bile acid biosynthesis (1 subfamily member)
– CYP11 steroid biosynthesis (2 subfamilies, 3 genes)
– CYP17 steroid biosynthesis (1 subfamily, 1 gene) 17-alpha hydroxylase
– CYP19 steroid biosynthesis (1 subfamily, 1 gene) aromatase forms estrogen
– CYP20 unknown function (1 subfamily, 1 gene)
– CYP21 steroid biosynthesis (1 subfamily, 1 gene, 1 pseudogene)
– CYP24 vitamin D degradation (1 subfamily, 1 gene)
– CYP26A retinoic acid hydroxylase, important in development (1 subfamily member)
– CYP26B probable retinoic acid hydroxylase (1 subfamily member)
– CYP26C probable retinoic acid hydroxylase (1 subfamily member)
– CYP27A bile acid biosynthesis (1 subfamily member)
– CYP27B Vitamin D3 1-alpha hydroxylase activates vitamin D3 (1 subfamily member)
– CYP27C unknown function (1 subfamily member)
– CYP39 7 alpha hydroxylation of 24 hydroxy cholesterol (1 subfamily member)
– CYP46 cholesterol 24-hydroxylase (1 subfamily member)
– CYP51 cholesterol biosynthesis (1 subfamily, 1 gene, 3 pseudogenes) lanosterol 14-alpha demethylase

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Drug Metabolism - Oxidation

Oxidation reactions NOT catalysed by Cytochrome
P450:
– Flavin-containing monoxygenase system
Present mainly in liver but some in gut and lung
Oxidises compounds containing sulfur and nitrogen
– Alcohol and aldehyde dehydrogenase
– Xanthine oxidase
– Monoamine oxidase (MAO)
Catalyses oxidative deamination of endogenous catecholamines
(epinephrine)

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Phase II Reactions
Phase II reactions involve addition or conjugation
--

of the functional group of phase I
with endogenous molecules to produce inactive
and more water-soluble metabolites that can be
readily excreted from the body.
– Conjugation with
Glucuronic acid (glucuronide)
Sulfuric acid
Acetic acid
Amino acids
PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Phase I and II Reactions
&Exam

Phase I reactions usually precede phase II
reactions.
In some cases, the xenobiotic already has a -

functional group that can be conjugated in a
-

phase II reaction without going through a phase I
reaction.

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Drug Metabolism - Phase II

Glucuronidation (α-d-glucuronic acid):
&

– The quantitatively most important phase II pathway
-

for drugs and endogenous compounds
– Enterohepatic recycling may occur due to gut
glucuronidases.
– Requires enzyme UDP-glucuronosyltransferase (UGT)
itemen

– Genetic family of enzymes with approximately 16
isoforms in human

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Prior Knowledge
Drug Metabolism - Phase I and II
Products (metabolites) are generally more water
soluble.
These reactions products are ready for (renal)
excretion.
There are many complementary, sequential and
competing pathways.
Phase I and phase II metabolisms form a coupled
interactive system interfacing with endogenous
metabolic pathways.
PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
X
Phase I and II Reactions

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
Drug Excretion

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
* Exam (clearance Excretion
Excretion, the movement of a drug and/or its
metabolites out of the body.
-

The kidney as excretory organ: most drugs are
eliminated in urine either chemically unchanged
or as metabolites.
Non-renal routes of drug excretion
– Bile, faeces (enterohepatic circulation)
– Lungs
– Sweat
– Saliva
– Breast milk
PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 Renal Excretion
1. Glomerular filtration: Free drug (not bound to
albumin) having molecular weights < 5000 flows -

through the capillary into the glomerular filtrate.
2. Passive tubular reabsorption: The drug, if
uncharged, may diffuse out of the nephric lumen,
back into systemic circulation.
– Manipulating the urinary pH to increase the
ionised form of the drug in the lumen to minimise
the amount of back-diffusion.
– [Weak acids3can be eliminated by alkalinisation of
-

the urine,
– whereas elimination of weak bases may be
-

increased by [acidification of the urine.3
3. Active tubular secretion: Secretion of drugs that
were not filtered occurs by energy-intensive active
transport systems.
PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah
 #
ready discussed
Other Routes of Drug Clearance
This includes via the intestines, the bile, the lungs
and breast milk in nursing mothers, among others.
– The faeces are primarily involved in elimination of
-

-
unabsorbed orally ingested drugs or drugs that are
secreted directly into the intestines or in bile.
– The lungs are primarily involved in the elimination of
anaesthetic gases (e.g. halothane and isoflurane).
– Elimination of drugs in breast milk is clinically relevant
as a potential source of undesirable side effects for the
infant. Toxicology
&
– Excretion of most drugs via sweat, saliva, tears, hair
-
and skin occurs only to a small extent.
-

PHRB – 301 LECTURES 3-5- Pharmacokinetics I, II and III
Dr. Tariq Alqahtani/Dr. Rawan Alnafisah