NSAIDS Notes Full PDF

Summary

This document is lecture notes from the University of Nairobi for a course on Pharmaceutical Chemistry II. It covers the classification, mechanisms of action, and examples of non-steroidal anti-inflammatory drugs (NSAIDs). It begins with a general introduction to pain and analgesics, then focuses exclusively on NSAIDs.

Full Transcript

UNIVERSITY OF NAIROBI
COLLEGE OF HEALTH SCIENCES

SCHOOL OF PHARMACY

In collaboration with

CENTRE FOR OPEN AND DISTANCE LEARNING

DEPARTMENT OF PHARMACEUTICAL CHEMISTRY

UPC 213: PHARMACEUTICAL CHEMISTRY II:

NON-STEROIDAL ANTI-INFLAMMATORY DRUGS

AUTHOR

GRACE N. THOITHI
 LECTURE ONE
GENERAL CLASSIFICATION OF DRUGS USED TO RELIEVE PAIN

Lecture Outline
1.1 Introduction
1.2 Objectives
1.3 Definition of Pain
1.4 Classification of Pain
1.5 Definition of Analgesics
1.6 Classification of Analgesics
1.6.1 Mild Analgesics
1.6.1.1 Analgesic – Antipyretic Drugs
1.6.1.2 Anti-inflammatory Drugs
1.6.2 Strong Analgesics
1.6.2.1 Mu Receptor Agonists
1.6.2.2 Mixed Agonist/Antagonist Analgesics
1.6.2.3 Mu Receptor Antagonist
1.6.2.4 Other Analgesics
1.7 Summary
1.8 References

1.1 Introduction
This is our first lecture in a series of lectures during which you will learn about some of
the drugs that are used to relieve pain. I will tell you about the classification of pain. In
order for you to understand the classification of pain, you need to remember the
physiology of the nervous system. Thereafter in this lecture you will learn that analgesics
can be classified into ‘mild’ and ‘strong’ analgesics. In this lecture I will give you an
overview of classification of analgesics, with a few examples, but we will not look at the
details of these drugs. Once you have an overview of the classification of all drugs used
for relieving pain, we will start the lectures on non-steroidal anti-inflammatory drugs

1
(NSAIDs). Our aim in this module is to learn about drugs that are used for treatment of
mild pain (mild analgesics), of which the biggest category is the non-steroidal anti-
inflammatory drugs (NSAIDs). In lectures 2-10, we will see that the NSAIDs have
analgesic, antipyretic and anti-inflammatory activities. After that we will discuss
analgesic-antipyretic drugs in lecture 11. Lastly, we will discuss drugs that are used for
treatment of arthritis and gout in lectures 12 and 13, respectively. Steroids are also useful
anti-inflammatory drugs and you will learn about them in another module. Let us now
look at the objectives of this lecture.

1.2 Objectives

At the end of this lecture you should be able to:
1. Explain what pain is.
2. Discuss the classification of pain.
3. Explain what analgesics are.
4. Describe the various classes of drugs that are in clinical use for
relieving pain.

1.3 Definition of Pain

Intext Question

Have you ever experienced pain? What was it like?

What are some of the thoughts that have come to your mind after considering the above
question? It is hard to define pain. Pain can be considered to be a syndrome of highly
unpleasant sensations, usually with two components: the initial sensation or actual
perception; and the psychological effect or reaction component. This later component
involves mental modifications and therefore accounts for the variation in the reaction of
different people or even variation in the reaction by the same individual to identical pain

2
stimuli. Pain may be described as throbbing, gnawing, splitting, stabbing, pinching,
crushing or burning. I believe you now understand pain better.

1.4 Classification of Pain
Having understood what pain is, how do we classify pain? There are different ways of
classifying pain.
One of the common ways is by considering the origin of the pain, and hence the
classification into visceral and somatic pain.
1. Visceral pain is of non-skeletal origin and examples are gastric pain, intestinal
cramps and colic.
2. Somatic pain emanates from muscle and bone and includes headaches, sprains
and arthritic pain.
Another way of classifying pain is by considering whether the pain is acute or
chronic.
1. Acute pain may be produced by disease, injury, noxious chemicals or physical
stimulation.
2. Chronic pain is persistent and pathological in form.
The etiology, pathophysiology, functions and diagnosis of acute pain differs from that
of chronic pain and so do the means of treatment. Let us now consider the drugs used
to relieve pain.
1.5 Definition of Analgesics
Drugs that relieve pain are commonly called analgesics or analgetics, but most people
prefer to use the term analgesics. These two words are derived from the Greek word
meaning ‘painlessness’. Analgesics are also referred to as ‘antinociceptives’.
Traditionally, they have been classified into two main categories, ‘mild’ or ‘strong’
analgesics. However, it is worth noting that advancement in drug development has
defied this strict separation of the two categories. Today, drugs exist that chemically
belong to the ‘mild’ category but whose potency exceeds that of some that are
chemically in the ‘strong’ analgesics category. In addition, most traditional ‘strong’
analgesics were addicting, but today there are drugs derived from narcotic (strong)
analgesics which are not addicting. Having said this, we shall still use this traditional
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 classification of ‘Strong analgesics’ and ‘Mild analgesics’ for ease of reference. A
third main class of drugs that relieve pain is the ‘local anaesthetics’, the prototype of
which is codeine. Note that the term ‘anaesthesia’ means loss of all sensation. Local
anaesthetics interrupt impulse transmission in all nerve fibres when applied locally
near the nerve trunk. In this lecture, we will discuss the classification of weak and
strong analgesics. Later in this module, we will discuss in detail the mild analgesics.
You will learn details about the strong analgesics and the local anaesthetics in later
years of your pharmacy training.

1.6 Classification of Analgesics
1.6.1 Mild Analgesics

Intext Question

Try and think about a time that you had a headache. What medicine did
you take, if any? Where did you obtain it from?

Concerning your answer to the above question, I believe that if you used a medicine for
your headache, it was an analgesic of the ‘mild’ type. Mild analgesics generally fall into
either the analgesic-antipyretic class or to the non-steroidal anti-inflammatory class. Let
us look at an overview of these two classes.

1.6.1.1 Analgesic -Antipyretic Drugs
Drugs in this class have the ability to alleviate mild, and sometimes, severe pain. They
are also effective in relieving fever in febrile subjects. The prototype in this class is
paracetamol or acetaminophen (Panadol®, Tylenol®). We will learn more about these
medicines in lecture 11.

1.6.1.2 Anti-inflammatory Drugs
This class of compounds is made up of drugs with variable and interesting chemical
features. However, they all have the ability to alleviate pain (analgesic) and relieve fever
4
(antipyretic) in febrile subjects. In addition, they all have anti-inflammatory activity.
Some examples are the salicylates, aryl acetic acids, indole acetic acids, fenamates,
pyrazolidines and oxicams which we will discuss in lectures 4-9. An emerging sub-class
of NSAIDs are the selective cyclo-oxygenase inhibitors, which we will learn about in
lecture 10.

1.6.2 Strong analgesics

Intext Question

Which drugs are considered to be strong analgesics?

Strong analgesics are the most effective drugs for alleviation of severe acute or chronic
pain. They are often called ‘opioid analgesics’. The term ‘opioid’ refers to opium- or
morphine-like in terms of pharmacological actions. They are sometimes referred to as
narcotic analgesics. The prototype is morphine. You will learn more about opioid
analgesics in other modules in the coming years of study.

Take Note
The word ‘narcotic’ literally means that they cause sleep or loss of
consciousness (narcosis) and it is also associated with addictive
properties. The term ‘narcotic analgesics’ is thus misleading because
some of these drugs induce analgesia without narcosis and not all
opioids are addicting.

1.6.2.1 Mu Receptor Agonists

Drugs in this class act on the mu (µ) opioid receptor and they have the ability to alleviate
severe pain. They include morphine, codeine, dihydroxymorphine, dihydrocodeine,
oxymorphone, oxycodone, levopharnol, meperidine, methadone, fentanyl, sufentanil,
among others.

5
1.6.2.2 Mixed Agonist/Antagonist Analgesics
In this class we have important drugs like buprenorphine, butorphanol, nalbuphine,
pentazocine and dezocine. Their activity at the µ,  and  opioid receptors may vary.
1.6.2.3 Mu Receptor Antagonist
Some mu (µ) opioid receptor antagonists have analgesic activity. Naloxone and
naltrexone belong to this class.

1.6.2.4 Other Analgesics
Tramadol and propoxyphene are examples of strong analgesics in common use.

Activity
1 Make a list of all the classes of drugs we have discussed in this lecture.
2 For each class, name one example (prototype).
3 List the pharmacological activities of each class.
4 Give the mechanism of action of each class.
5 Give the major side effect(s) of each class of drugs.

1.7 Summary

In this lecture you have learnt that:
1 Pain is a syndrome of highly unpleasant sensations and it is often
treated depending on whether it is acute or chronic, and whether it is
mild or severe.
2 Analgesics are broadly classified into ‘mild’ or ‘strong’ analgesics.
3 The two main categories of mild analgesics are antipyretic analgesics
and anti-inflammatory analgesics, of which examples are
paracetamol and aspirin, respectively.
4 The strong analgesics are also called opioid analgesics and are related
to morphine in activity.
5 Local anaesthetics also have analgesic activity

6
1.8 References

1. Introduction to Medicinal Chemistry. Alex Gringauz. Wiley-VCH.
New York. 1997
2. Foye’s Principles of Medicinal Chemistry, 6th ed. Thomas L.
Lemke, David A. Williams, Victoria F. Roche and S. William
Zito. Wolters Kluwer Health/Lippincott Williams and Wilkins.
Philadelphia. 2008.
3. Textbook of Pharmacology. 2nd ed. 1980. W. C. Bowman and M.
J. Rand. Blackwell Scientific Publications. Oxford.
4. Goodman & Gilmans. 2006. The pharmacological basis of
therapeutics. 12th Ed. Laurence L. Brunton, Bruce A. Chabner,
Bjorn C. Knollmann. McGraw-Hill Comp. Inc.

7
 LECTURE TWO

CLASSIFICATION AND MECHANISM OF ACTION OF NSAIDS
Lecture Outline
2.1 Introduction
2.2 Objectives
2.3 Definition of NSAIDs
2.4 Mechanism of NSAIDs
2.4.1 Anti inflammatory mechanisms
2.4.1.1 Inflammation
2.4.1.2 Anti-inflammatory action
2.4.2 Anti-pyretic mechanism
2.4.2.1 Fever
2.4.2.2 Antipyretic action
2.4.3 Analgesic mechanism
2.4.3.1 Pain
2.4.3.2 Analgesic action
2.4.4 Mechanism for GIT damage
2.4.4.1 Mucoprotection
2.4.4.2 Mucosa damage
2.5 Approaches to reduce gastric damage
2.5.1 Molecular approach
2.5.2 Pharmaceutical approach
2.6 Classification of NSAIDs
2.6.1 Non-selective cyclo-oxygenase inhibitors
2.6.1.1 Carboxylic acid derivatives
2.6.1.2 Enolic acids
2.6.2 Selective cyclooxygenase II inhibitors
2.7 Uses of NSAIDs
2.8 Summary
2.9 References

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2.1 Introduction
In our first lecture, you learnt what pain is and how it is classified. I also explained that
drugs that relieve pain are called analgesics and gave the general classification of
analgesics. Mild analgesics can either belong to the antipyretic/analgesics class or to the
anti-inflammatory analgesics class, of which examples are paracetamol and aspirin,
respectively. The strong analgesics are also called opioid analgesics and are related to
morphine in activity. Local anaesthetics also have analgesic properties.
In this lecture you will learn about the non-steroidal anti-inflammatory drugs (NSAIDs).
In addition to being analgesics, the NSAIDS have anti-pyretic and anti-inflammatory
activity. We will learn that their activity is due to inhibition of cyclo-oxygenase, an
enzyme involved in mediation of pain and inflammation. You have already covered the
module on prostaglandins and you will need to remember the synthesis of prostaglandins
and the role of cyclo-oxygenase. The activity of NSAIDs is related to the chemical nature
of the drugs and therefore we will learn that they are classified depending on their
structural features. Lastly, you will learn about the uses of NSAIDs.

2.2 Objectives
At the end of this lecture you should be able to:
1 Explain what the non-steroidal anti-inflammatory drugs are.
2 Discuss the mechanism of action of the non-steroidal anti-
inflammatory drugs as analgesic, antipyretic and anti-inflammatory
agents.
3 Discuss the mechanism of NSAIDs in causing gastrointestinal damage.
4 Discuss molecular and pharmaceutical approaches to drug design that
are used to reduce gastric damage.
5 Describe the various classes of non-steroidal anti-inflammatory drugs.
6 Discuss the general uses of NSAIDs.

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2.3 Definition of NSAIDs
The non-steroidal anti-inflammatory drugs are a group of agents that generally in addition
to having analgesic activity, also have antipyretic and anti-inflammatory activity. The
NSAIDs are largely used for management of inflammation especially in rheumatic
disorders. Inflammation, just like allergies, is considered a defence mechanism to noxious
stimuli that threaten the host. For this reason, NSAIDs, antiallergic agents and antiulcer
agents are considered to be drugs that affect the immune system.
Take note
1 NSAIDs are useful in the treatment of rheumatic disorders.
2 A few of the NSAIDs have uricosuric properties and are useful for
the treatment of gout.

2.4 Mechanisms of Action of NSAIDs

Intext Question

What are the mechanisms by which NSAIDs elicit pharmacological actions?

The NSAIDs treat rheumatic conditions by alleviating inflammation (anti-inflammatory),
alleviating pain (analgesic) and relieving fever (anti-pyretic). Let us now look at the
details involved in each of these mechanisms. You can now assess your answer to the
intext question with the discussion I have given below.

2.4.1 Anti-inflammatory mechanisms

2.4.1.1 Inflammation
Inflammation is a normal and essential response when there is injury to tissue, when
microorganisms invade the host or when there are other diseases or injuries.
Inflammation has several components which often follow each other:
Release of inflammatory mediators e.g. histamine, bradykinins, 5HT (serotonin),
prostaglandins and leukotrienes.

10
 Vasodilation.
Increased vascular permeability and exudation.
Leucocyte migration, and chemotaxis and phagocytosis.
Proliferation of connective tissue cells.
These maintain the inflammation, which manifests itself as redness, swelling, leaky
capillaries and fluid moves out of blood to tissues. Figure 2.1 shows inflammation of the
skin.

Figure 2.1. Inflammation of the skin ( Source: www.howtogetridofstuff.com).

Now that you have understood the outward manifestations of inflammation, let us
consider what happens at the molecular level when inflammation occurs. The NSAIDS
act as anti-inflammatory agents by inhibition of the enzyme cyclooxygenase and so they
inhibit prostaglandin synthesis. Other agents, such as antihistamines, a common example
being chlorpheniramine, relieve allergic inflammation. Still others, like lipooxygenase
inhibitors, inhibit leukotrienes synthesis.

Activity
Before you proceed, try and refresh your memory with the following
activities:
1 Draw a diagrammatic representation of the synthesis of prostaglandins
D, E and F from arachidonic acid.
2 Show all the enzymes involved.
11
2.4.1.2 Anti-inflammatory action
In order to understand how the NSAIDs work, let us have a look at the biosynthesis of
prostaglandins, as shown in Figure 2.2. Most eicosanoids are derived from arachidonic
acid. Arachidonic acid can be acted upon by lipooxygenase to produce leukotrienes or by
cyclo-oxygenase to produce prostaglandins PGG2 and PGH2, which give PGD2, PGE2
and PGF2. Prostaglandins A, B and C are unsaturated ketones that arise non-
enzymatically from PGE. Prostacyclin (PGI2) has an additional tetrahydrofuran ring
which is very unstable and very easily opened up and deactivated. Thromboxane A2 is
non-enzymaticaly converted to thromboxane B2.
Cyclooxygenase: Three isoforms of cyclooxygenase have been identified:
cyclooxygenase-1, cyclooxygenase-2 and cyclooxygenase-3 (COX-1, COX-2 and COX-
3). Both COX-1 and COX-2 are very similar in structure and almost identical in length.
Therapeutically, the major difference between them is in their physiological function
rather than structure.

Cyclooxygenase-1 (COX-1): Cyclooxygenase-1 is continually expressed and it seems to
be more specific than COX-2 for fatty acid substrates, and it primarily metabolizes
arachidonic acid. COX-1 is useful for maintaining normal physiological functions in the
GIT and kidneys by producing cytoprotective prostaglandins (PGE2) which:

stimulate bicarbonate and mucus secretion

reduce acid production

maintenance of kidney function

Therefore, inhibition of COX-1 by non-selective NSAIDs leads to side effects such as
gastric and renal damage.

Cyclooxygenase-2 (COX-2): The expression of COX-2 is induced by cytokines (in
vascular smooth muscle, fibroblasts and epithelial cells) and growth factors.
Cyclooxygenase-2 accepts a wider range of fatty acid substrates than COX-1 and it
metabolizes C-18 and C-20 fatty acid substrates. Selective inhibitors of COX-2 do not
bind Arginine-120, which is used by the carboxylic acid group of arachidonic acid and
12
the NSAIDs with a carboxylic acid group (both selective and non-selective). COX-2
functions to produce prostaglandins at inflammatory sites. The treatment of inflammatory
disorders by selective COX-2 inhibitors is through inhibition of inducible COX-2 but not
the continually expressed COX-1.

Cyclooxygenase-3 (COX-3):. Cyclooxygenase-3 is the third and most recently
discovered cyclooxygenase isoenzyme, but it is not functional in humans. It is selectively
inhibited by analgesic-antipyretic drugs and is potently inhibited by some drugs. We will
discuss the analgesic-antipyretics in lecture 11.

2.4.2 Anti-pyretic Mechanisms
2.4.2.1 Fever
Body temperature is regulated in the hypothalamus. If there is an infection, body injury,
inflammation or other disease states, there is enhanced formation of cytokines (such as
interleukin-1) by cells. This induces formation of PGE2 in vascular organs in the pre-
optic hypothalamic area and this leads to elevated body temperature via cyclic adenosine
monophosphate (cAMP).
2.4.2.2 Antipyretic action

Intext Question
We have seen that the hypothalamus controls body temperature. How do drugs that
reduce fever act?

Drugs that act as antipyretics do so by inhibition of PGE2 synthesis at cyclooxygenase
level. They may act peripherally or centrally. At the periphery they inhibit the release of
endogenous leukocytic pyrogens from cells that are activated by exogenous pyrogens
and/or inhibit activation of cells by exogenous pyrogens. At the central level they act by
direct competitive inhibition of endogenous pyrogens on hypothalamus and/or inhibition
of prostaglandins in the central nervous system.

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2.4.3 Analgesic mechanism
2.4.3.1 Pain
Intext Question

How did we describe pain in lecture 1?

In lecture one, we said that pain is a manifestation of highly unpleasant sensations, which
may be described as throbbing, gnawing, splitting, stabbing, pinching, crushing or
burning. In fact, there are different levels of pain as follows:

Mechanical or thermal stimuli activate high threshold nociceptors and this sends an
impulse to the brain through C nerve fibres and the host withdraws from the source of
pain.
However, if the stimulus is severe or prolonged there is release of pro-inflammatory
agents (prostaglandins, cytokines e.g. interleukin 1 and humoral factors). This release
is mediated by substance P, histamine and serotonin and it results in sensitization of
nociceptors (pain receptors), thus giving primary hyperalgesia or physiological pain.

Secondary hyperalgesia: Large quantities of chemical mediators lower pain threshold
and increase excitability of neighbouring nerve endings and pain spreads to areas
originally not affected by stimulus. So small stimulus now becomes very painful and
gives secondary hyperalgesia or pathological pain.

Peripherally, prostaglandins sensitize peripheral pain receptors and so NSAIDs may help
to restore normal activity to sensitized nociceptors by inhibiting prostaglandins.
Centrally, prostaglandins help pain signal to pass through the central nervous system.
Pain passes from the periphery into the spinal cord through pain fibres and requires
neurotransmitters such as substance P, glutamate aspartate and neurokinins.
Prostaglandins increase conductivity of peripheral pain and central pain fibres.
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2.4.3.2 Analgesic Action
Non-steroidal anti-inflammatory drugs inhibit spinal hyperalgesia through inhibition of
prostaglandin synthesis. Generally, NSAIDs have peripheral action although some have
central action as well. Endogenous opiates, such as endorphins, inhibit transmission of
pain in brain.
Below are some examples of NSAIDs activity:

It has been demonstrated that aspirin reduces conductivity of pain by
prostaglandins

Diclofenac has been shown to decrease pain if injected in the thalamus.

Ketoprofen inhibits prostaglandins both peripherally and centrally.

It is thought that cyclooxygenase 1 may be involved in chronic inflammation so some
degree of COX-1 inhibition may be desirable.

2.4.4 Mechanism for GIT Damage

Activity
Before you proceed, stop and refresh your memory:
o Using the knowledge you have on prostaglandins, outline the
mechanisms by which COX-1 protects the gastrointestinal
mucosa.

2.4.4.1 Mucoprotection
Prostaglandin synthetase is present in the gastro-intestinal wall and therefore there are
PGEs and PGFs in the GIT. The gastric mucosa secretes PGE into gastric juice and these
prostaglandins are responsible for maintaining gastric integrity and protection, a property
referred to as cyto-protection. This protection possibly extends to the duodenum, colon,
bladder and even other organs. Prostaglandins protect gastric mucosa by inhibiting

15
histamine stimulated hydrochloric acid secretion and increasing bicarbonate and mucus
secretion/viscosity, increasing secretion of water into mucosa and increasing blood flow.
2.4.4.2 Mucosa Damage
Have you ever heard a person who has taken drugs like aspirin (Ascard®) or ibuprofen
(Brufen®) complaining of hyperacidity in the stomach? This is a common complaint in
patients who take these medicines. Non-steroidal anti-inflammatory agents damage the
mucosa by the so called “dual insult” mechanism. Let us see what this means and how it
happens.
1. The first ‘insult’ is because many NSAIDS are organic acids with direct acid damage
on mucosa. They also inhibit Cox-1 and this results in increased hydrochloric acid
secretion. The weak organic acids such as aspirin cause ‘ion trapping’. Ion trapping
means that at the pH of stomach they are non-ionised and easily penetrate mucosal
cells. In the cell, the pH rises so they are ionized and cannot escape, so protons enter
the cells and cause damage.

2. The second way of ‘insult’ is by inhibition of cyclooxygenase, which leads to
prostaglandin inhibition. In addition, inhibition of cyclooxygenase may lead to
activation of 5-lipoxygenase which results in production of leukotrienes which
generate super oxides which damage mucosa. Figure 2.2 illustrates damage to the
stomach mucosa.

16
 Figure 2.2. Picture of a peptic ulcer (Source: www.emedicinehealth.com)

2.5 Approaches to Reduce Gastric Damage
The pharmacist, as the professional who is responsible for management of the effects of
drugs in the patient, is concerned that if a patient has to benefit from a drug, the side
effects should be controlled. For this reason, during drug development two broad
approaches have been used to reduce gastric damage. These approaches are at the
molecular and/or the pharmaceutical level.

2.5.1 Molecular Approach
The molecular approach involves designing a drug with a chemical structure which will
not lead to gastric damage. At the molecular level several approaches have been used as
follows:
Prodrugs: The drug may be synthesized as a pro-drug which is not acidic, but

which releases the active drug in the body. An example is nabumetone which we
shall discuss in lecture five.

Non-acidic drugs: Drug design may also focus on getting drugs which have no
acidic group. Sulindac, which we shall discuss in lecture 6, is an example.

Cyclooxygenase 2 selective drugs: This class of compounds, which we shall
discuss in lecture 10, is designed in such a way as to inhibit only cyclooxygenase
2, but not cyclooxygenase 1. It therefore does not inhibit the mucoprotective
effects of prostaglandins.

2.5.2 Pharmaceutical Approach
The pharmaceutical approach involves using pharmaceutical technology to eliminate or
minimize mucosal damage. At the technology level the following approaches have been
used:
Enteric coated drugs: An enteric coating is a barrier applied to oral medication
that controls the location in the digestive system where it is absorbed. Enteric refers
17
 to the small intestine, therefore enteric coatings prevent release of medication before
it reaches the small intestines. Drugs like ibuprofen are ‘enteric coated’ to minimize
damage to stomach mucosa.

Combination of a NSAID and a synthetic prostaglandin: The synthetic
prostaglandin such as misoprostol supplies the muco-protective actions. One may
therefore give a drug like ibuprofen together with misoprostol.

Combination of NSAID ( insoluble) and a soluble molecule: An example is the
combination of piroxicam with β-cyclodextrin to form a complex which thus reduces
damage to the gastric mucosa.

Combination of a NSAID and an antacid: The antacid neutralizes the acidity in
the stomach. An example is compound magnesium trisilicate.

Combination of a NSAID and an inhibitor of gastric secretion: The inhibitor of
gastric acid secretion minimizes production of acid in the stomach. Such drugs
include cimetidine and ranitidine.

Community Activity
Visit any community pharmacy and request the pharmacist for the following:
1. To show you samples of ibuprofen, misoprostol, compound
magnesium trisilicate and cimetidine.
2. To give you literature inserts of these drugs for you to take away and
read.

2.6 Classification of NSAIDs
Non-steroidal anti-inflammatory agents can broadly be classified depending on how
selective or non-selective they are in their interaction with the different isoforms of the
enzyme cyclo-oxygenase.

2.6.1 Non-selective Cyclo-oxygenase Inhibitors

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Non-selective cyclo-oxygenase inhibitors inhibit both cyclo-oxygenase-1 and
cyclooxygenase-2. These can further be classified depending on how they were
developed on the basis of structural similarities. They are all acidic in nature, either due
to the presence of a carboxylic acid group or due to being enolic acids.
2.6.1.1 Carboxylic Acid Derivatives
Salicylates
Fenamates
Aryl aliphatic acids
Indole acetic acids
2.6.1.2 Enolic acids
Pyrazolidinediones
Oxicams
2.2.2 Selective Cyclooxygenase-2 Inhibitors
Selective cyclo-oxygenase-2 inhibitors largely inhibit cyclo-oxygenase-2 but not cyclo-
oxygenase-1. Structurally, they either belong to the ‘sulide’ or ‘coxib’ group.

Sulides

Coxibs

2.7 Uses of NSAIDs
From our discussion, the NSAIDs are generally used as:
Antiinflammatory agents for relief of inflammation

Analgesics for alleviation of pain

Antipyretic agents for alleviation of fever

Antirheumatic agents which are used in rheumatic conditions

Antigout agents for relief of gouty conditions

2.8 Summary

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 In this lecture you have learnt that the non-steroidal anti-inflammatory
agents:
1. Have anti-inflammatory, antipyretic and analgesic activity.
2. Produce these activities largely due to the inhibition of
cyclooxygenase.
3. Can be classified into non-selective cyclooxygenase inhibitors and
selective cyclooxygenase-2 inhibitors.
4. May be used for treatment of gout and/or rheumatic conditions.

2.9 References

1. Introduction to Medicinal Chemistry. 1997. Alex Gringauz. Wiley-
VCH. New York.
2. Foye’s Principles of Medicinal Chemistry, 6th ed. 2008. Thomas
L. Lemke, David A. Williams, Victoria F. Roche and S. William
Zito. Wolters Kluwer Health/Lippincott Williams and Wilkins.
Philadelphia.
3. Textbook of Pharmacology. 2nd ed. 1980. W. C. Bowman and M.
J. Rand. Blackwell Scientific Publications. Oxford.
4. Goodman & Gilmans. 2006. The pharmacological basis of
therapeutics. 12th Ed. Laurence L. Brunton, Bruce A. Chabner,
Bjorn C. Knollmann. McGraw-Hill Comp. Inc.

20
 LECTURE THREE

PHYSICO-CHEMICAL PROPERTIES OF NSAIDS

Lecture outline
3.1 Introduction
3.2 Objectives
3.3 Physico-chemical properties of NSAIDs
3.3.1 Partition coefficient
3.3.2 Dissociation of drug
3.4 Absorption and distribution of NSAIDs
3.5 Summary
3.6 References

3.1 Introduction
In lecture two, you learnt that in addition to being analgesics, the NSAIDS have anti-
pyretic and anti-inflammatory activity. You learnt their mechanisms of action and that
their activity is due to inhibition of cyclo-oxygenase, an enzyme involved in mediation of
pain and inflammation. The activity of NSAIDs is related to the chemical nature of the
drugs and therefore classified into non-selective cyclooxygenase inhibitors and selective
cyclooxygenase 2 inhibitors. Lastly, you learnt that some NSAIDs can be used for
treatment of gout and/or arthritis.

Unlike many other drugs, the NSAIDS have to transverse a series of alternating lipophilic
and hydrophilic compartments in order to reach their site of action. For this reason, their
physical and chemical properties play a critical role in their transportation to these sites,
and hence, their activity. In this lecture, we will look at these physicochemical properties
and how they affect the distribution of NSAIDs.

3.2 Objectives

21
 At the end of this lecture you should be able to:
1. Explain the physico-chemical properties of NSAIDs.
2. Discuss how the physico-chemical properties of NSAIDs affect
their distribution in the body.

3.3 Physico-chemical Properties of NSAIDs
Physico-chemical properties of NSAIDs play an important role in the ionization of drugs
and hence their absorption and transportation to their sites of action. Before we proceed,
let us think of the properties which are important.

Activity
Before you proceed, stop and refresh your memory:

1. Give the definition of the following terminologies:

o pH

o pKa

o partition coefficient

2. How is partition coefficient determined?

3. Write an equation for the ionization of a weak acid and derive the
Henderson-Hasselbach equation.

3.3.1 Partition Coefficient
Intext Question

What is partition coefficient??

22
I believe that doing the activity given above has helped you to understand what partition
coefficient is. Whenever you have a molecule X, which has access into two
compartments, it will tend to distribute itself between the organic (lipophilic) and
aqueous (hydrophilic) phases with a partition coefficient P, which is defined as the
relative solubility of the molecule between the two phases. Partition coefficient is
determined by dissolving the molecule in an aqueous solution and equilibrating it, with
some shaking , with an organic solvent. P is defined as the partition between 1-octanol
and a buffer at pH 7.4 (physiological pH).
This is illustrated below:

X X

Aq org

This partition coefficient can be defined as:
P= Cxorg ÷Cxaq
Where;
Cxorg is the concentration of molecule x in the organic phase,
Cxaq is the concentration of molecule x in the aqueous phase.
Most drugs are not structurally similar to normal cellular molecules and so they will not
be transported across membranes by active transport mechanisms. Their transport is a
passive process determined by the partition coefficient. A ratio between lipid and
aqueous phase of greater than 0.01 indicates good lipid solubility.

3.3.2 Dissociation of Drug
At the same time, remember that in the aqueous phase, any molecule that is capable of
ionizing will ionize. Substances that ionize completely are considered to be strong
electrolytes, while those that do not are non-electrolytes. Most drugs are in between,
being weak electrolytes and are only partially ionized. The ionized part has low lipid
23
solubility, while the non-ionized has higher lipid solubility. The fraction of the total drug
concentration that is in the molecular and ionic forms can be indicated by the dissociation
constant, Ka. Since the NSAIDs are mostly acids, we can represent their ionization as
follows:

HA H+ + A-
Where,
HA is a weak acid and represents the NSAID
H+ is the cation (proton) from the ionization,

If we take the logarithms of the above we get:

log10Ka = log10[H+] + log10[A- ] - log10[HA]

Therefore, -log10[H+] = -log10Ka + log10[A-] - log10[HA]

This is the well known Henderson-Hasselbalch equation:

By using pKa values, we are able to express the strength of an acid (its tendency to
dissociate) with reference to the pH scale. If Ka, the dissociation constant, is large, then
pKa will have a low numerical value. A strong acid is one which is largely, perhaps
completely, dissociated, and which therefore has a high Ka value. Lower values of
pKa (e.g. 0.7) correspond to stronger acids. A weak acid is one that is only slightly
dissociated in solution, and has a low Ka value. Higher values (e.g. 4.7) correspond to
weaker acids. Weak acids have higher pKa than strong ones, thus an acid with a pKa of 5
is 100 times weaker than that with a pKa of 3. The converse is true for bases. Therefore,

24
the distribution of the molecule (log P) is determined by the pKa of the compound and the
pH of the medium through which it transverses.

Take Note

The distribution of the NSAIDs is a function of two parameters:
The pKa of the drug
The pH of the medium through which it transverses

3.4 Absorption and distribution of NSAIDs
Let us look at the example of aspirin which is a drug that is orally taken. It is a weak acid
with a pKa of 3.5 as shown on table 3.1. The stomach is highly acidic, with a pH of about
1, while the small intestine has a pH of about 6. The question is, is aspirin more likely to
be absorbed in the stomach or in the small intestines? In the stomach, it would be almost
completely un-ionized and very ionized in the small intestines. Since we know that the
molecular form of the drug is more lipid soluble, the unionized form would be readily
absorbed and this would happen in the stomach, which has lipoprotein membranes in its
lining. The converse is true: weakly basic drugs have poor absorption in the stomach.
However, all physicochemical parameters need to be considered when looking at the
absorption of a drug. The other factors that affect absorption and bioavailabitlity are
dosage formulation, food contents in the stomach, gastric emptying time, particle size and
the presence of drugs like antacids. Indeed, for aspirin, the larger surface area of the small
intestines allows absorption to take place primarily in the small intestines and not in
the stomach as we would expect from our discussion above.

For a NSAID, it has to go through a biological system from the GIT, to the GIT wall, the
blood, the capillary wall, synovial fluid and finally the site of action. There are alternate
aqueous and organic layers through which it has to transverse to get to the site of action.
If a compound is too water soluble, it has a low P, and thus it will remain in the first
aqueous layer it finds. If it is too lipid soluble, it has a high P, and it is retained in the first
lipid layer. In both cases it will not get to the site of action. For this reason, a drug must

25
have an optimum P value to allow it to partition successively and to get to the site of
action. P determines the pharmacokinetics and excretion. Most NSAIDs have similar log
P value between 0 and 2 and pKa between 3 and 5.
Table 3.1. pKa values of some non-steroidal anti-inflammatory drugs

Drug pKa Drug pKa
Aspirin 3.5 Indomethacin 4.5
Diflunisal 3.0 Mefenamic acid 4.2
Diclofenac 4.5 Phenyl butazone 4.5
Ibuprofen 5.2 Piroxicam 4.6

Take Note
1. Generally, only lipid soluble, undissociated forms of a drug pass
through membranes easily.
2. Ionised species usually cannot pass unless a mediated transport
system is present in the membrane.

It has been found that the pH of inflamed tissues is less than that of blood and so there is
a pH gradient between blood and the site of inflammation which favours movement of
acidic compounds into inflamed tissues.

3.5 Summary
In this lecture you have learnt that:
1. the distribution of the molecule is determined by the pKa of the
compound and the pH of the medium through which it transverses.
2. the non-steroidal anti-inflammatory agents (NSAIDs) are weak acids
with pKa 3-5.
3. NSAIDs are largely undissociated in gastric juice and they are
dissociated in the small intestines.
4. NSAIDs have a good partition coefficient (P) of 0-2, which allows
them to transverse membranes.
26
3.7 References

1. Introduction to Medicinal Chemistry. 1997. Alex Gringauz. Wiley-
VCH. New York.
2. Foye’s Principles of Medicinal Chemistry, 6th ed. 2008. Thomas L.
Lemke, David A. Williams, Victoria F. Roche and S. William Zito.
Wolters Kluwer Health/Lippincott Williams and Wilkins.
Philadelphia.

27
 LECTURE FOUR
SALICYLATES

Lecture Outline
4.1 Introduction
4.2 Objectives
4.3 Definition of salicylates
4.3.1 History of aspirin
4.3.2 Absorption and bioavailability of aspirin
4.3.3 Side effects of aspirin
4.4 Mechanism of action of salicylates
4.5 Structure-activity relationships of salicylates
4.6 Structural modifications on aspirin
4.7 Commonly used salicylates
4.8 Synthesis of salicylates
4.9 Metabolism of salicylates
4.10 Analysis of salicylates
4.11 Summary
4.12 References

4.1 Introduction
In our last lecture, we learnt that the NSAIDs have to transverse a series of alternating
lipophilic and hydrophilic compartments in order to reach their site of action. Therefore,
their physical and chemical properties play a critical role in their transportation to these
sites, and hence these properties affect their activity. The non-steroidal anti-inflammatory
agents (NSAIDs) are weak acids with pKa 3-5 and a partition coefficient (P) of 0-2. They
are largely undissociated in gastric juice and they are dissociated in the small intestines.
In this lecture, we will discuss the salicylates, the first and oldest class of the NSAIDs.
We will see how their structure is related to their activity and their mechanisms of action.
We will then discuss their synthesis, metabolism in man and how they are analyzed.
28
 4.2 Objectives
At the end of this lecture you should be able to:
1. Explain what the salicylates are.
2. Describe the relationship between the structure and the activity of
salicylates.
3. Discuss the mechanism of action and uses of the salicylates.
4. Describe the synthesis of salicylates.
5. Discuss the metabolism of salicylates.
6. Demonstrate the analysis of salicylates.

4.3 Definition of Salicylates

Intext Question

What are salicylate non-steroidal anti-inflammatory drugs?

The salicylate NSAIDs are derivatives of salicylic acid.

O
6
1
5
OH
2
4

3
OH

Figure 4.1. Chemical structure of salicylic acid

4.3.1 History of Aspirin
The use of salicylates dates back to 19th century when salicylic acid was first obtained in
1838 from salicin, a glycoside found in willow (Salix alba) and poplar bark. By 1875,
sodium salicylate was used as antipyretic-antirheumatic drug. In 1886 several phenyl
esters were in use. Aspirin (acetyl salicylic acid) was prepared in 1853 and used as a
medicine in 1899. Aspirin (acetyl salicylic acid) is the prototype salicylate and it is also

29
the most widely used analgesic, antipyretic and anti-inflammatory agent. It promotes uric
acid secretion and is therefore used in treatment of gouty arthritis. Because it inhibits
platelet aggregation, it is used in low doses to protect against stroke and heart attacks
(Ascard-75®, Cardispirin®).

COOH

OCOCH3

Figure 4.2. Chemical structure of aspirin

Activity
Aspirin has been said to be the most widely used drug in the world. Using
reference 2, list all the uses of aspirin that we have mentioned so far and
give one use of aspirin that we have not yet mentioned.

4.3.2 Absorption and Bioavailability of Aspirin
Aspirin is well absorbed, mainly from the small intestines. The rate of absorption
depends on the dosage formulation, gastric pH and particle size of the formulation.
Salicylates are protein-bound and this is important in drug interactions.

4.3.3 Side-effects of Aspirin
The commonest side effect of aspirin is gastro-intestinal disturbances, including
dyspepsia, duodenal bleeding, ulcerations and gastritis. This happens by inhibiting the
formation of PGE1, which is cytoprotective. Another side effect associated with aspirin is
Reye’s syndrome. This is a potentially fatal disease that affects multiple organs
particularly the brain and the liver. Though it may affect adults, children of age 4-14
years are more susceptible, especially if they have had a viral illness like chicken pox or
influenza.

30
 Take Note

Aspirin has also been found to be protective against colon cancer.

4.4 Mechanism of Action of Salicylates
The major mechanism of action is inhibition of biosynthesis of prostaglandins by non-
selective inhibition of the enzyme cyclo-oxygenase. They may also act by:
Inhibition of biosynthesis of histamine
Antagonizing functions of various kinins involved in inflammatory reactions
Inhibiting release of lysosomal enzymes
Inhibiting leukocyte migration

4.5 Structure-activity Relationships of Salicylates
1. The salicylate anion is the active moiety of all salicylate NSAIDs.
O

O

OH

Figure 4.3. Chemical structure of salicylate anion

2. The carboxylic acid (-COOH) group is essential for anti-inflammatory activity.
Reducing acidity of -COOH maintains the analgesic properties but eliminates the anti-
inflammatory properties. An example is salicylamide, which has analgesic but no anti-
inflammatory activity..
O

NH2

OH

31
Figure 4.4. Chemical Structure of Salicylamide
3. An ortho relationship between the -OH and the -COOH groups is essential for activity.
Moving them from ortho to either meta or para position abolishes activity.
4. Halogen substituents on the salicylic acid ring enhance both potency and toxicity. An
example is 5-chlorosalicylic acid.
5. Aryl groups (aromatic rings) at position 5 increase anti-inflammatory activity e.g.
diflunisal.
F

COOH

F
OH

Figure 4.5. Chemical structure of diflunisal (Dolobid®)

4.6 Structural Modifications on Aspirin
Salicylates have severe gastrointestinal side effects and have short half-life, hence are
administered frequently. Modifications have been made aimed at:
Decreasing gastro-intestinal side effects
Increasing duration of action
The following drugs have been developed:

1. A prodrug of salicylic acid
O
O
CH3
N
O
O

Figure 4.6. Chemical structure of a prodrug of aspirin

In this drug the -COOH and -OH groups are masked leading to a drug free of
gastrointestinal toxicity.

32
2. A halogenated salicylic acid
Cl COOH

OH

Figure 4.7. Chemical structure of 5-chlorosalicylic acid
This drug is less polar than aspirin and therefore it has a longer duration of action.
However it is more toxic; it causes greater gastrointestinal ulcerations
3. Introduction of a methyl group at position 3 protects against microsomal
hydroxylation and thus increases duration of action.

COOH COOH

OH OCOCH3
CH3 CH3
3-methyl salicylic acid 3-methyl acetyl salicylic acid

Figure 4.8. Chemical structures of 3-methylsalicylic acid and 3-methylacetylsalicylic acid

4. Introduction of halogenated aryl group increases anti-inflammatory activity as is the
case for diflunisal (Figure 4.5).

Take Note

The highly non-polar aryl group of diflunisal retards
metabolism and hence increases half-life.
Diflunisal has greater anti-inflammatory activity than aspirin,
but little antipyretic activity.
It has no appreciable effect on platelet aggregation and
therefore has no significant gastric bleeding side effects.
It is used mainly in osteoarthritis, rheumatoid arthritis and
other musculoskeletal pains.

33
5. Condensed aspirin molecules
OCOCH 3 OCOCH 3

C O C

O O

Figure 4.9. Chemical structure of aspirin anhydride

Aspirin anhydride was synthesized by condensing two aspirin molecules in the hope of:

Achieving higher blood levels
Having less gastrointestinal disturbances because the -COOH group is masked.
However, it was found to be less active than aspirin and to have the same GI irritation
since it is unstable and produces aspirin in aqueous media.

6. Aluminium-aspirin preparations
Aloxiprin was developed by polymeric condensation of aluminium oxide and aspirin.

Al2O3 [C6H4(OOCMe)COO-]5

Figure 4.10. Chemical formula of aloxiprin

It was found to be more active than aspirin and it has less GI irritations because
aluminium oxide neutralizes gastric acid.

7. Salicylamide
In salicylamide (Figure 4.4) the carboxylate group responsible for anti-inflammatory
activity is masked. It therefore has analgesic and antipyretic activities, but negligible anti-
inflammatory activity.

8. Dimer of salicylic acid
O COOH
OH
C O

34
Figure 4.11. Chemical structure of salsalate

This is a dimer of salicylic acid and it is claimed to have fewer gastrointestinal side
effects.
9. Prodrug of aspirin and paracetamol
O

O C Me
O

O N C Me
H
O

Acetaminophen-aspirin prodrug

Figure 4.12. Chemical structure of acetaminophen-aspirin prodrug (Benorylate®)

Benorylate is an ester of aspirin and paracetamol (acetaminophen) and upon hydrolysis in
the body gives the two drugs. It has the following properties:
It has a longer duration of action than aspirin and only needs to be taken twice
daily.
It has fewer side effects than aspirin, including gastric irritation and bleeding.
Mainly used to relieve joint pain and inflammation in osteoarthritis.
It is sometimes used for juvenile rheumatoid arthritis.

4.7 Commonly used Salicylates
The most common salicylates you will find in the market are aspirin, salicylamide,
salsalate, diflunisal, sodium salicylate, sodium thiosalicylate, magnesium salicylate and
choline salicylate.

Activity
Using reference 2, draw the structures of sodium salicylate, sodium
thiosalicylate, Magnesium salicylate and choline salicylate.

35
4.8 Synthesis of Aspirin
Aspirin can be synthesized by the Kolbe synthesis.

Activity
Using reference 3, discuss the Kolbe synthesis for synthesis of aspirin with the
aid of a schematic diagram.

4.9 Metabolism of Salicylates
The first step in the metabolism of aspirin and its derivatives is conversion to salicylic
acid, which may be excreted in urine as the free acid (about 10%); or which can be
conjugated with glycine to give salicyluric acid (about 75%) or with glucuronic acid to
give the glucuronide ester or glucuronide ether (up to 15%). In addition, small amounts of
salicylic acid undergo microsomal aromatic hydroxylation, of which the major product
(of hydroxylation) is gentisic acid. Figure 4.13 illustrates the metabolism of salicylates.
O
O O Glu COOH
COOH
O M+ +
OH O Glu
OCOCH3 OH 15 %
Aspirin Salicylate esters/salts
Glucuronyl transferase
UDP Glucuronic acid

COOH O
Acetic acid
N-acyltransferase N CH2COOH
OH H
Salicylic acid Glycine
OH
Salicyluric acid
(major metabolite, 75 %)
HO COOH COOH
HO COOH

OH OH
OH
Gentisic acid, major
OH OH
Microsomal aromatic hydroxylation

May then be conjugated with sulphate or glucuronic acid

36
Figure 4.13. Metabolism of aspirin and salicylate esters and salts

4.10 Analysis of Salicylates
Salicylates are carboxylic acid derivatives and therefore they can be analyzed by titration
as demonstrated below with the assay of aspirin.
Assay of Aspirin: Samples of aspirin may, in addition to aspirin (acetylsalicylic acid,
ASA), have the degradation products acetic acid (AA) and salicylic acid (SA). The assay
of aspirin is therefore done in two steps to allow quantification of ASA and give the
limits for the degradation products.

In the first step aspirin is dissolved in dry ethanol and titrated immediately with 0.1 N
NaOH. In this step all acids, ASA (i) , SA (ii) and acetic acid (iii), that can possibly be in
an aspirin sample are neutralized to their respective sodium salts, acetylsalicylate sodium,
sodium salicylate and sodium acetate.
COOH
COONa
i) + NaOH
+ H2O
O C CH3
O C CH3
O
O
COOH COONa
Hydrolysate
products present ii) + NaOH + H2O
before dissolution OH OH

iii) CH3COOH + NaOH CH3COONa + H2O

Figure 4.14. Equations for reactions of the first step of analysis of aspirin

In the second step of analysis of aspirin sodium hydroxide is added in excess (e.g. 50 ml)
and the mixture is refluxed for 15 minutes. In this step, acetylsalicylate sodium is
hydrolysed by NaOH to sodium salicylate and sodium acetate. Sodium salicylate and
sodium acetate do not participate in this reaction. The excess NaOH is then back-titrated
with 0.1 N HCl.

37
 COOH COONa COONa
1 2
NaOH Excess NaOH
O C CH3 O C CH3 OH
Reflux
O O +
CH3COONa

Figure 4.15 Equations for reactions of the second step of analysis of aspirin

The first titration gives the total acids (ASA, SA and acetic acid) present. The second step
gives the actual ASA present. The pharmacopoeia set the limit of the difference between
NaOH used in the 1st and 2 nd steps as 0.4 ml based on titration of 500 mg of aspirin. This
also serves as a limit test. It means that the degradation products (AA and SA) should not
exceed the limit given in the pharmacopoeia.

4.10 Summary
In this lecture you have learnt that:
The salicylates group of non-steroidal anti-inflammatory
agents have analgesic, antipyretic and anti-inflammatory
activity.
In addition, aspirin, which is the prototype promotes uric
acid excretion, inhibits platelet aggregation and also protects
against colon cancer.
Salicylates are non-selective inhibitors of the enzyme cyclo-
oxygenase.
Salicylates are excreted largely unchanged, but can also be
oxidized before excretion.
They are often analyzed by titration using 0.1 N NaOH, by
virtue of being acids.

38
4.11 References

1. Introduction to Medicinal Chemistry. 1997. Alex Gringauz.
Wiley-VCH. New York.
2. Foye’s Principles of Medicinal Chemistry, 6th ed. 2008. Thomas
L. Lemke, David A. Williams, Victoria F. Roche and S. William
Zito. Wolters Kluwer Health/Lippincott Williams and Wilkins.
Philadelphia.
3. Goodman & Gilmans. 2006. The pharmacological basis of
therapeutics. 12th Ed. Laurence L. Brunton, Bruce A. Chabner,
Bjorn C. Knollmann. McGraw-Hill Comp. Inc.
4. Medicinal Chemistry. 5th ed. 2010. Ashutosh Kar. New Age
International Publishers. New Delhi.
5. The British Pharmacopoeia. 2010. www.pharmacopoeia.co.uk

39
 LECTURE FIVE

ARYL ALIPHATIC ACIDS

Lecture outline
5.1 Introduction
5.2 Objectives
5.3 Definition of the aryl aliphatic acids
5.4 Classification of aryl aliphatic acids
5.4.1 Phenyl propionic acids
5.4.2 Phenyl acetic acids/aryl acetic acids
5.4.3 Heteroaryl acetic acids
5.5 Structure-activity relationships of aryl aliphatic acids
5.5.1 SAR of aryl aliphatic acids and indole acetic acids
5.5.2 SAR specific to aryl aliphatic acids
5.6 Mechanism of action of aryl aliphatic acids
5.7 Metabolism of aryl aliphatic acids
5.7.1 Metabolism of ibuprofen
5.7.2 Metabolism of diclofenac
5.8 Analysis of aryl aliphatic acids
5.9 Summary

5.10 References

5.1 Introduction

In lecture four, I introduced you to the salicylate class of non-steroidal anti-
inflammatory drugs. I explained that they have analgesic, antipyretic and anti-
inflammatory activity. In addition, aspirin, which is the prototype, promotes uric acid
excretion, inhibits platelet aggregation and also protects against colon cancer. Salicylates
are non-selective inhibitors of the enzyme cyclo-oxygenase and they are excreted largely
unchanged, but can also be oxidized before excretion. They are often analyzed by
titration using 0.1 N NaOH, by virtue of being acids.
40
In this lecture, I will introduce you to the aryl aliphatic acids class of NSAIDs.
Sometimes they are referred to as aryl alkanoic acids. We will see how their structure is
related to their activity and their mechanisms of action. We will then discuss their
synthesis, metabolism in man and the methods of analysis.

5.2 Objectives

At the end of this lecture you should be able to:
1. Explain what the aryl aliphatic acids NSAIDS are.
2. Discuss the classification of aryl aliphatic acids
3. Describe the relationship between the structure and the activity of aryl
aliphatic acids.
4. Discuss the mechanism of action of the aryl aliphatic acids.
5. Discuss the metabolism of aryl aliphatic acids.
6. Demonstrate the analysis of aryl aliphatic acids.

5.3 Definition of the Aryl Aliphatic Acids

Intext Question

What are aryl aliphatic acids?

The aryl aliphatic acids are NSAIDs which are derivatives of aryl aliphatic acids and they
have the general structure:

R O

Ar C C OH

H

41
Figure 5.1. General structure of aryl aliphatic acids

Where,

R can be H, CH3 or alkyl

Ar is an aryl group such as a phenyl or heteroaryl ring

This is probably the largest group of NSAIDs and they all have anti-inflammatory,
antipyretic and analgesic effects. Their activity is related to both the aliphatic acid
moiety, as well as the aryl moiety of the drugs. They are non-selective inhibitors of the
enzyme cyclo-oxygenase. They are excreted largely unchanged, but can also be oxidized
before excretion. By virtue of being acids, they are often analyzed by titration.

5.4 Classification of aryl aliphatic acids

Take Note

There are many ways of classifying this group of NSAIDS. We shall
categorize them into three broad classes, namely:
o Phenyl propionic acids e.g. ibuprofen
o Phenyl acetic acids e.g. diclofenac
o Heteroaryl acetic acids e.g. indomethacin

5.4.1 Phenyl Propionic Acids
This class is also referred to as ‘profens’. The prototype drug in this class of NSAIDs is
ibuprofen, which is commonly marketed as Brufen® (Boots Company). In ibuprofen, R is
a methyl group, while Ar is a substituted phenyl ring. From the structure of ibuprofen,
you can see that it is actually a derivative of propionic acid. Other examples of drugs in
this class include flurbiprofen, ketoprofen, naproxen, fenprofen and carprofen.

42
 Me Me

CH COOH CH COOH
Me

CH CH2
Me F
Ibuprofen Flurbiprofen

Me
O Me
CH COOH
CH COOH

OMe

Ketoprofen Naproxen

Me
H Me
O CH COOH N
CH COOH

Cl Carprofen
Fenprofen

Figure 5.2. Chemical structures of some phenyl propionic acids

5.4.2 Phenyl Acetic Acids/Aryl Acetic Acids
An example of a phenyl acetic acid is diclofenac (Voltaren ®). Diclofenac is unique
because it has the structural features of both the aryl aliphatic acids (specifically phenyl
acetic acid) and the fenamates. Fenamates are derived from anthranilic acid. We shall
discuss the fenamates in lecture seven. Until the development of the selective NSAIDs,
diclofenac was the most potent and widely used NSAID. It is marketed as diclofenac
sodium and diclofenac potassium. It is an inhibitor of both cyclo-oxygenase (I and II) and
lipo-oxygenase enzymes.

43
 CH2COOH

NH

Cl Cl

Figure 5.3. Chemical structure of diclofenac

5.4.3 Heteroaryl Acetic Acids
This class of drugs has a heteroaryl moiety and acetic acid moiety. Indomethacin can be
considered to be both a heteroaryl acetic acid and an indole acetic acid (Figure 5.4). We
shall discuss it in detail in lecture six when we discuss the indole acetic acids.

Figure 5.4. Chemical structure of indomethacin

44
Me Cl
Me

CH2COOH CH2COOH
N N
O O
Me Me
Tolmetin Zomepirac

COOH O
N CH2CO2H
O N CH2CH3
H
C2H3
Ketorolac Etodolac
Etodolac

O
CH2CH2CO2H
N

Oxaprozin

Figure 5.5. Chemical structures of some heteroaryl acetic acids

Other heteroaryl acetic acids include tolmetin, zomepirac, ketorolac, etodolac and
oxaprozin. Zomepirac is an analogue of tolmetin which is four times more active than
tolmetin, but has been withdrawn due to severe anaphylaxis. These drugs are sometimes
classified as indole acetic acids because they have a heteroaryl nucleus.

5.5 Structure-activity relationships of Aryl Acetic Acids
5.5.1 SAR of Aryl Aliphatic Acids and Indole Acetic Acids
The following structure–activity relationships apply to both the aryl aliphatic acids and
the indole acetic acid classes of NSAIDs. We will discuss the indole acetic acids in
lecture six.
1. These drugs must have an acidic center of activity to enable interaction with the
receptors.

45
 This center is often represented by carboxylic function, as in the structure
of ibuprofen above.

In some rare cases, the center can be enolic, hydroxamic acid, sulfonamide
or a tetrazole ring.

This center corresponds to the -COOH group of arachidonic acid.

Figure 5.6. Chemical structure of arachidonic acid

2. Derivatives such as esters and amides may be active due to the metabolic
hydrolysis products. An example is nabumetone, which has no acidic group but
its activity is due to bioactivation to an active acidic metabolite.

CH2CH2COCH3
O CH2CH2 COOH

N CH3 O

Oxaprozin Nabumetone

Figure 5.7. Chemical structures of oxaprozin and nabumetone

3. The center of acidity must be located one carbon away from a flat surface which
is represented by an aromatic or heteroaromatic ring. The aromatic ring system
correlates with the double bonds at C5 and C8 of arachidonic acid.

This is the case in ibuprofen, fenoprofen and ketoprofen.

46
 Increasing this distance to two or three carbon atoms reduces activity, as
in the case of oxaprozin and nabumetone.

4. Substitution of a methyl group on the carbon separating the acid centers from the
aromatic ring increases activity.

This gives α-methyl acetic acids commonly referred to as “profens”.
Examples are ibuprofen, fenoprofen, ketoprofen, flurbiprofen and
suprofen.

F O
CH3
CH3 S
CHCOOH
CH COOH

Flurbiprofen Suprofen

Figure 5.8. Chemical structure of flurbiprofen and suprofen

Substitution with groups which are larger than a methyl group decreases
activity.

5. This methyl group introduces a chiral center and the S(+) enantiomer is the active
isomer. The R(-) enantiomer is inactive in vitro.

Many manufacturers formulate racemates.

In the case of ibuprofen, it has been found that the R enantiomer is
biologically converted to S(+) isomer.

6. A second group which is lipophilic may be added as an aromatic ring or alkyl
group either attached to or fused to the aromatic center. It is non-coplanar with
the aromatic ring and it enhances activity. It seems to correspond to double bonds
at C11 and C14 of arachidonic acid.

5.5.2 SAR specific to aryl aliphatic acids

47
 The following structure–activity relationships apply only to the aryl aliphatic acids
class of NSAIDs and not the indole acetic acids.
1. Substitution of α- methyl group on the alkanoic acid enhances anti-inflammatory
actions and reduces many side effects. This is the case with all profens. For
example, ibuprofen is more active and less toxic than ibufenac.

CH2COOH

CH2CH2CH3

Figure 5.9. Chemical structure of ibufenac
2. The aryl propionic acids are optically active. Although many are marketed as
racemic mixtures, the S (+) isomer has been found to be responsible for most
activity.
3. Derivatives of 2-naphthylpropionic acids are more potent than corresponding
acetic acid analogs.
4. For the naphthyl derivatives such as naproxen, small lipophilic groups such as
-Cl, -CH3 , -OCH F2 and -OCH3 increase anti-inflammatory activity with –OCH3
being most potent. Larger groups reduce activity.
5. Replacing –COOH group with groups that can be metabolized to –COOH leads to
retention of activity.

5.6 Mechanism of action of Aryl acetic Acids
Aryl aliphatic acids are non-selective inhibitors of the enzyme cyclooxygenase

5.7 Metabolism of Aryl acetic Acids

Activity
Before you proceed any further,

o Find out what is the major difference between the metabolism of
ibuprofen and that of diclofenac in man and make brief notes in the

48
 form of schematic diagrams.

5.7.1 Metabolism of Ibuprofen
Ibuprofen is nearly completely excreted unchanged in the urine.
It may also undergo ώ-1 and ώ-2 oxidation of the p-isobutyl side chain.
OH

H3C C CH2

major
CH3

-1 oxidation
OH
-2 oxidation
H3C CH CH2 CH CH
H3C

CH3 CH3

-1 oxidation

H3C CH CH2 H3C CH CH2
Hydrolytic Hydrolytic
oxidation oxidation
CH2 OH COOH HOOC
major

Figure 5.10. Metabolism of ibuprofen

49
5.7.2 Metabolism of Diclofenac
Diclofenac is extensively metabolized in the liver mainly by aromatic hydroxylation.

6
1 CH2COOH HO CH2COOH
5
2
4 NH
NH
3
Cl 6' 1' Cl Cl Cl
2'
5' 3' 5-hydroxy
4' derivative

CH2COOH HO CH2COOH
CH2COOH

NH NH
NH
Cl Cl Cl Cl
Cl Cl

OH OH
OH
4'-hydroxy 3'-hydroxy 4',5 - dihydroxy
derivative, derivative derivative
major

Figure 5.11. Metabolism of diclofenac

5.8 Analysis of Aryl acetic Acids

Activity
Before you proceed any further,
o Look at the structure of ibuprofen and give possible methods of analysis
o Check the recommended method of ibuprofen in the British
Pharmacopoeia or the United States Pharmacopoeia.

I hope that you got several possible methods for analysis of ibuprofen. The official
method of analysis of ibuprofen is titration 0.1N NaOH, with potentiometric detection.

50
5.9 Summary

In this lecture you have learnt that:
The aryl aliphatic acids have analgesic, antipyretic and anti-
inflammatory activity.
They are non-selective inhibitors of the enzyme cyclo-
oxygenase.
They are further classified into:
o Phenyl propionic acids e.g. ibuprofen
o Phenyl acetic acids e.g. diclofenac
o Heteroaryl acetic acids e.g. indomethacin
Ibuprofen is nearly completely excreted unchanged in the urine,
while diclofenac is extensively metabolized in the liver mainly
by aromatic hydroxylation.
They are often analyzed by titration, by virtue of being acids.

5.10 References
1. Introduction to Medicinal Chemistry. 1997. Alex Gringauz.
Wiley-VCH. New York.
2. Foye’s Principles of Medicinal Chemistry, 6th ed. 2008. Thomas
L. Lemke, David A. Williams, Victoria F. Roche and S. William
Zito. Wolters Kluwer Health/Lippincott Williams and Wilkins.
Philadelphia.
3. Goodman & Gilmans. 2006. The pharmacological basis of
therapeutics. 12th Ed. Laurence L. Brunton, Bruce A. Chabner,
Bjorn C. Knollmann. McGraw-Hill Comp. Inc.
4. Medicinal Chemistry. 5th ed. 2010. Ashutosh Kar. New Age
International Publishers. New Delhi.
5. The British Pharmacopoeia. 2010. www.pharmacopoeia.co.uk

51
 LECTURE SIX

INDOLE ACETIC ACIDS

Lecture outline
6.1 Introduction
6.2 Objectives
6.3 Definition of the indole acetic acids
6.4 Structure-activity relationships
6.4.1 Structure-activity relationships of indoles and indenes
6.4.2 Notable structural features of sulindac
6.5 Mechanism of action of indole acetic acids
6.6 Metabolism of aryl indole acetic acids
6.6.1 Metabolism of indomethacin
6.6.2 Metabolism of sulindac
6.7 Analysis of indole acetic acids
6.8 Summary
6.9 References

6.1 Introduction
In the last lecture, we discussed the aryl aliphatic acid class of non-steroidal anti-
inflammatory drugs and found that they are non-selective inhibitors of the enzyme cyclo-
oxygenase. We discussed that they are further classified into phenyl propionic acids,
phenyl acetic acids and heteroaryl acetic acids. Ibuprofen is nearly completely excreted
unchanged in the urine, while diclofenac is extensively metabolized in the liver mainly by
aromatic hydroxylation. They are often analyzed by titration, by virtue of being acids.
In this lecture, I will introduce you to the indole acetic acid class of NSAIDs. I will show
you how their structure, which is based on an indole nucleus, is related to their activity.
We will discuss indenes, which are molecules that are isosteric to indoles and they
exhibit similar properties to indole. Lastly, we will discuss their metabolism in man and
how they can be analyzed.

52
6.2 Objectives

Objectives
At the end of this lecture you should be able to:
1. Explain what the indole acetic acid NSAIDS are.
2. Describe the relationship between the structure and the activity
of indole acetic acids.
3. Discuss the mechanism of action of the indole acetic acids.
4. Discuss the metabolism of indole acetic acids.
5. Explain how the analysis of indole acetic acids and indenes
can be carried out.

6.3 Definition of the indole acetic acids

Intext Question

What are indole acetic acids?

The indole acetic acids have an indole nucleus (Figure 6.1) and the prototype in this class
is indomethacin (Indocid®), whose IUPAC name is 1-(p-chlorobenzoyl)-5-methoxy-2-
methylindole-3-acetic acid.

4
5
3

6 2
7 N
1

Figure 6.1. Chemical structure of indole nucleus

The development of the indole acetic acids was based on an earlier assumption that
serotonin (5-hydroxytryptomine, 5-HT) was responsible for inflammation.

53
 4
HO 3
5 CH2CH2NH2
6 2
N
7 1

Figure 6.2. Chemical structure of 5-hydroxytryptomine

Indomethacin (Indocid®) was developed after screening of hundreds of indole compounds
for anti-inflammatory activity. The other important drug in this class is sulindac
(Clinoril®). As shown in Figure 6.3, indomethacin has an indole nucleus and it is the only
true indole drug in clinical use, while sulindac has an indene nucleus.

CH3 O CH2COOH F CH2COOH

N CH3
CH3
O
CH

Cl
S O
CH3

Indomethacin Sulindac

Figure 6.3. Chemical structure of indomethacin and sulindac

The other drugs that are considered to be indole acetic acids are tolmetin, tenidap,
etodolac, ketorolac, zomepirac and carprofen. You will remember that tolmetin, etodolac,
ketorolac, and carprofen are also classified as aryl aliphatic acid derivatives as we saw in
the last chapter.

54
 Activity
o Draw the chemical structure of tenidap.

o List structural similarities with indomethacin

o List structural differences from indomethacin

Take Note

o Zomepirac is very potent but it has been withdrawn due to causing
anaphylactic reactions in patients
o Etodolac has significant selective cyclooxygenase 2 inhibition
activity

6.4 Structure-activity relationships

Activity
Before you proceed any further, stop and refresh your memory by
drawing the indole nucleus. Show the numbering in this moiety.

I hope that the structure you have drawn is the same as that we drew in Figure 6.1. We
will refer to that figure as we discuss the relationship between structure and activity.

6.4.1 Structure-activity relationships of indoles and indenes
1. N1 position:
Indole N is not essential for activity since indenes are active, e.g. sulindac.
2. C2 position:
Alkyl-substituents produce more active compounds than aryl-substituents. A
methyl group is the most active of these alkyl substituents. Presence of CH3 at C2
and H at C7 causes the indole ring to swing out of plane and this swing is thought

55
 to be essential for activity. Removal of the methyl group gives a compound that is
almost coplanar and therefore inactive.
Increasing the alkyl chain to one bigger than a methyl group decreases activity.
This is due to the steric hindrance of a long chain that affects the fitting of the
drug into the receptor.
3. C3 position:
The -COOH group is essential for anti-inflammatory activity.
Increasing acidity of the carboxyl group generally increases anti-inflammatory
action.
Replacing it or reducing its acidity decreases activity.
Amide analogues are inactive.
4. Methyl group at α position of the acetic group side chain:
Produces equipotent compounds.
Introduces a chiral centre.
Only the S (+) isomer displays anti-inflammatory action.
5. C5 position:
Substitution with methoxy, fluoro, and dimethylamino, methyl, alkoxy and
acetyl groups yields more active compounds than non-substituted ones.

O-Demethylation leads to inactivation of the compounds ( OCH3→OH).
6. The benzoyl moiety:
Is essential for activity. This is demonstrated by the fact that metabolism of
indomethacin involves hydrolysis of amide group to give an inactive
compound and this suggests the benzoyl group is essential.
Met OMe CH2COOH inactive

CH3

O
Cl is essential.
N

Figure 6.4. Inactive and essential moieties of indomethacin

56
 Replacement of benzoyl group with aliphatic carboxylic or aryl carboxylic groups
results in compounds much less active.

Substitution at para position with F, Cl, trifluoromethyl (-CF3), thiomethyl (-
SCH3) groups gives the most active compounds.

Metabolism of indomethacin involves amide hydrolysis to give inactive
metabolites.
7. The para chlorobenzoyl moiety is free to rotate around the amide bond. The preferred
conformation is a chlorobenzoyl group that is cis to the methoxy group. This cis
conformation puts the benzoyl group away from the C2 methyl and the compound is
non-coplanar due to steric hindrance of C2 methyl and C7 hydrogen.
CH3O
CH2COOH OMe
CH2COOH
N CH3 CH3
N

O
O

Cl Cl

cis indomethacin trans indomethacin

Figure 6.5. Chemical structures of cis and trans indomethacin

8. The presence of the indole moiety is not essential for activity. This is shown by the
fact that indenes are active. Indoles, such as indomethacin, have the benzoylindole
moiety. On the other hand, indenes, such as sulindac, have the benzylidenylindene
moiety. The two groups are isosteric, meaning that they have the same size.

57
 N
O
CH

Benzoyl indole 1- Benzylidenyl indene

Figure 6.6. Chemical structures of benzoyl indole and 1-benzylidenyl indene

The structure-activity relationships of the indenes is similar to that of indoles.

6.4.2 Notable structural features of sulindac
We have discussed structural features of the indole acetic acids and how they relate to the
indene-based molecules. Let us now see features which are notable in sulindac.
1. Isosteric replacement of indole with indene nucleus.
2. Replacement of benzoyl with benzylidene moiety
3. Also exhibits geometric isomerism due to rotation about C=C double bond. As we
discussed for the indoles, the cis isomer is more active than the trans isomer. This
shows that both indomethacin and sulindac assume similar conformations at the
active site of cyclooxygenase.
4. Replacement of 5-methoxy group with 5-fluoro group results in enhsnced
analgesic activity.
5. The para-chloro substituent of indomethacin is replaced with a methylsulfoxide
group. This causes decreased water solubility of indenes, which may lead to
crystalluria.
6. In sulindac, this poor solubility is alleviated by replacing Cl of phenyl group with
a sulfinyl group.

58
 Take Note
Sulindac has the following advantages over indomethacin
1. Sulindac is a prodrug metabolized to the active sulfide metabolite.
The sulfide metabolite is responsible for COX inhibition.
2. It has fewer gastrointestinal side effects than indomethacin since it
does not affect prostaglandin synthesis in the gastrointestinal tract.

6.5 Mechanism of action of indole acetic acids
Indole acetic acids are non-selective inhibitors of the enzyme cyclooxygenase.
6.6 Metabolism of indole acetic acids
We will now look at the metabolism of indomethacin and then at that of sulindac.
Before we do so, let us refresh our minds with the activity below.

Activity
o What are phase I and phase II reactions in relation to drug metabolism?

o What are the products of these reactions and what is the pharmacological
activity relative to that of the original drug?

6.6.1 Metabolism of Indomethacin

Indomethacin is metabolized largely by O-demethylation (50%) followed by conjugation
with glucuronic acid (10%) as shown in Figure 6.7.

59
 CH3O CH2COOH

N CH3
MeO O
CH2COO Glu
CH3O CH2COOH
N CH3
O N CH3
H
Cl

HO
CH2COOH
Cl
N CH3
O

Cl

HO CH2COOH

N CH3
H

HO
CH2COOGlu

N CH3
H
Glu: Glucuronide

Figure 6.7. Metabolism of indomethacin

6.6.2 Metabolism of Sulindac.

Sulindac is a prodrug in which the sulfoxide is reduced to sulfide (active) which is highly
protein bound and is not found in urine. In urine you get the sulfone and glucuronide as
shown in figure 6.8.

60
 F
CH2COOH
F
CH2COOH
CH3
CH3
H
H
O H3C S
H3C S active

F
CH2COOH F
CH2COOH
CH3
CH2OH
H
O OH
O
S
H3C S
H3C
O
F F CH2 COO Glu
CH2COOGlu
CH2OH

OH
H
O O
S
H3C O H3C S

Glu: Glucuronide

Figure 6.8. Metabolism of sulindac

6.7 Analysis
As with salicylates and aryl aliphatic acids, indomethacin may be analyzed by titration of
the –COOH group with NaOH. However, the British Pharmacopoiea recommends
ultraviolet spectrophotometry (UV) for both indomethacin and sulindac. The United
States Pharmacopoiea recommends liquid chromatographic analysis with UV detection
for both.

6.8 Summary

61
 In this lecture, you learnt that indole acetic acids and indenes:
Have similar activity and structure-activity relationships.
Are non-selective inhibitors of the enzyme cyclo-oxygenase.
Are excreted largely unchanged, but can also be oxidized before
excretion.
Can be analyzed by titration, ultraviolet spectroscopy or by
liquid chromatography.

6.9 References

1. Introduction to Medicinal Chemistry. 1997. Alex Gringauz.
Wiley-VCH. New York.
2. Foye’s Principles of Medicinal Chemistry, 6th ed. 2008. Thomas
L. Lemke, David A. Williams, Victoria F. Roche and S. William
Zito. Wolters Kluwer Health/Lippincott Williams and Wilkins.
Philadelphia.
3. Medicinal Chemistry. 5th ed. 2010. Ashutosh Kar. New Age
International Publishers. New Delhi.
4. The British Pharmacopoeia. 2010. www.pharmacopoeia.co.uk

5. The United States Pharmacopeia. www.uspnf.com/

62
 LECTURE SEVEN
FENAMATES
Lecture outline
7.1 Introduction
7.2 Objectives
7.3 Definition and examples of fenamates
7.4 Structure-activity relationships of fenamates
7.5 Mechanism of action of fenamates
7.6 Metabolism of fenamates
7.6.1 Metabolism of mefenamic acid
7.6.2 Metabolism of meclofenamic acid
7.7 Analysis of fenamates
7.7.1 Assay of mefenamic acid
7.7.2 Assay of etofenamate
7.8 Summary
7.9 References

7.1 Introduction
In lecture six, you were introduced to the indole acetic acids, a class of non-steroidal anti-
inflammatory drugs. I explained how their activity is related to their structure and how
the indenes, which are molecules that are isosteric to indoles, exhibit similar properties to
indoles. We also discussed their metabolism in man and observed that they are excreted
largely unchanged, but can also be oxidized before excretion. They can be analyzed by
titration, ultraviolet spectroscopy or by liquid chromatography
In this lecture, you will learn about fenamates, the last class of NSAIDs that have a
carboxylic acid group. We will see how their structure, which is based on anthranilic
acid, is related to their activity. We will then discuss their metabolism in man and how
they can be analyzed.

63
 7.2 Objectives
At the end of this lecture you should be able to:
1. Descibe the fenamates class of NSAIDS.
2. Explain the mechanism of action of fenamates.
3. Describe the relationship betwe