Pharmacology of Inflammation Lecture 1 PDF

Summary

This lecture details the pharmacology of inflammation, focusing on the role of histamine and other mediators. It covers various aspects of histamine, including its release, regulation, and effects on the body, along with methods for regulating its release.

Full Transcript

PHARMACOLOGY OF

INFLAMMATION
Newman Osafo, BPharm, PhD
Department of Pharmacology, FPPS, CoHS, KNUST
[email protected]
 INFLAMMATION

 Inflammation is a local reaction to injury or
invasion associated with swelling and pain.

 The inflammatory response although primarily
defensive often results in tissue damage
serious enough to warrant pharmacological
intervention

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TISSUE RESPONSE TO INJURY

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Divided into three (3) phases
 Acute Phase
 Initial response to tissue injury
 Release of autocoids
 Immune Response
 Immunologically competent cells are
activated in response to antigenic substances
 Chronic Inflammation
 Release of numerous cellular mediators

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INTRODUCTION

 Autacoid: Greek autos (self) akos (medical agent,
remedy).

 Autacoids have a brief duration, act near site of synthesis,
and are not blood borne. They are "Local hormones".

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INTRODUCTION
 Autacoids are a heterogeneous group of
pharmacologically active compounds which are
formed by the tissues they act on
 thus they function as local hormones.

 Autacoids include histamine, serotonin, AA
Metabolites, PAF

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INTRODUCTION
 Autocoids are substances that are called into
play in the defense of the body.

 Theirimportance lies mainly in their roles in
inflammation and allergic responses.

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HISTAMINE

 Chemical mediator of a wide variety of
cellular responses including allergic and
inflammatory reactions, and gastric acid
secretion.

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 Biosynthesis

L-histidine
decarboxylase
L-histidine Histamine

 Histamine is synthesized in mammalian tissues by decarboxylation
of the amino acid L-histidine.
 The reaction is catalyzed by histidine decarboxylase

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TISSUE LOCALIZATION (STORAGE):

 The chief site of histamine storage in most
tissues is the mast cell.

 In the blood, the major site of storage is in the
basophil.

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 Histamine is stored in bound form in granules along
with
 heparin,
 eosinophil chemotactic factor of anaphylaxis (ECF-A),
 neutrophil chemotactic factor
 and various enzymes such as (-glucuronidase, neutral
proteases, superoxide dismutase and peroxidase.

 The bound form of histamine is biologically inactive

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 1. RELEASE WITHOUT MAST CELL INJURY OR DEGRANULATION

 Certainchemicals such as morphine, succinylcholine, d-
tubocurarine have the capacity to release histamine.

 These substances displace histamine from the heparin-protein
complex within mast cells.
 Because of this property, the narcotic analgesics may cause
intense itching when used in the treatment of pain.
 Some addicts also complain of itching.
 Intravenous injection of organic bases, i.e., quaternary amines,
antibiotic bases, alkaloids, etc. can also release pharmacological
amounts of histamine.

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2. RELEASE WITH MAST CELL INJURY

 Loss of storage granules from the mast cell into the
extracellular fluid results in rapid release of histamine.
 Sodium ions in the extracellular fluid rapidly displace histamine from its
binding complex with polysaccharide, heparin and protein.

 The redness and urticaria that follow scratching of the skin
exemplifies histamine release due to nonspecific cell
damage.

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3. IMMUNOLOGIC RELEASE (DEGRANULATION).

i) Interaction of antigen with macrophage
to produce an antibody (e.g., IgE).

ii) Interaction of IgE antibody and antigen
(allergen) with mast cell to release
histamine.

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MAST CELL

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RELEASE (SUMMARY)
1. Pharmacologic (direct release)
 Morphine
 Tubocurarine
 Succinylcholine
 Radiocontrast media
 Carbohydrate plasma expanders
 Vancomycin (red-man syndrome)

2. Physical stimuli – scratching the skin
3. Immunologic - usually a component of an
immediate hypersensitivity reaction (IgE)

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 REGULATION OF RELEASE
 Mast cells and basophils contain receptors linked to
signaling systems that can enhance or block the IgE-
induced release of mediators.

 Inhibition of release is produced by adrenaline and other
drugs that activate (β-receptors).
 Stimulation of these receptors results in the accumulation of cAMP
which is responsible for reducing histamine release.

 Histamine reduces its own release by interacting with H2
receptors on mast cells and basophils.
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RELEASE INHIBITORS
 Adrenaline
 Theophylline Inhibits PDE thereby causing increase in cAMP
 Isoproterenol

 Mechanism:
β-adrenoceptor activation and cAMP accumulation

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 RELEASE OF OTHER AUTACOIDS WITH
HISTAMINE.

 A multiplicity of released chemicals accounts for the
allergic response.
 Alone, the histamine hypothesis of immediate
hypersensitivity reactions is INCOMPLETE.
 The release of histamine provides only a partial
explanation for the spectrum of effects which
characterizes immediate hypersensitivity reactions.
 The mast cell secretes many inflammatory compounds in
addition to histamine.
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 Each contributes to the major symptoms of the allergic
response:
 constriction of bronchi,
 decrease in blood pressure,
 increased capillary permeability and edema.

 Also, the many mediators released during the allergic
response accounts for the ineffectiveness of drug therapy
focused on a single mediator.

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 Other mediators released in the allergic response
include:
 PAF
 leukotriene D4. induce the contraction of smooth muscle, resulting in bronchoconstriction
and vasoconstriction. It also increases vascular permeability.

 This latter compound, LD4, causes contraction of
bronchial smooth muscle and may be a dominant
influence in allergic conditions such as asthma

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 HISTAMINE RECEPTORS:

 Acts by binding to four types of receptors,
H1, H2, H3, and H4
 Histamine stimulates all four
 Certain drugs selectively stimulate and
block these receptors

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 H1 elicits ↑ in IP3 and DAG
classical antagonist is pyrilamine, cyclizine

 H2 mediated through ↑ in cAMP
classical antagonist is cimetidine, ranitidine

 H3 – ↓ cAMP. Autoreceptor that also decreases ACh, NE, Serotonin
release
classical antagonist is thioperamide

 H4 – ↓ cAMP. Mediates mast cell chemotaxis
classical antagonist (nonspecific) is thioperamide, pimozide
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 ANATOMICAL LOCATION OF RECEPTORS
 H1 receptors are located on the smooth muscles of the intestine, bronchi,
trachea, capillaries and CNS

 H2 receptors are located on uterine smooth muscle, cardiac muscle,
gastric glands and CNS

 H3 receptors are predominantly located within the brain particularly the
cerebral cortex.

 H4 receptors are part of the immune system.

 On vascular smooth muscle that is responsible for vasodilator responses,
both H1 and H2 receptors are present.
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METABOLISM - BIOLOGICAL INACTIVATION,
DEGRADATION AND EXCRETION.
 Histamine is inactivated by enzymatic metabolism and by
transport processes that reduce the concentrations of this
substance in the vicinity of its receptors.

 The metabolites of histamine have little or no histamine-like
effects in mammalian tissues.

 They are excreted in the urine.

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 Metabolism
 The two major pathways of
degradation are catalyzed by the
enzymes:
 Histamine-N-methyltransferase. This
enzyme converts histamine to 1-
methylhistamine-methylation
Brain & periphery Periphery

 Diamine oxidase “DAO”
(histaminase). This enzyme converts
histamine to imidazole acetic acid
– oxidative deamination

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PHYSIOLOGICAL ROLES OF HISTAMINE

 Hypersensitivity and allergic responses
 Histamine release is partially responsible for allergic responses.

 Regulation of gastric acid secretion.
 Histamine evokes a copious secretion of acid from parietal cells by
activating H2 receptors. Other physiological factors also play some role in
gastric acid secretion.
 Blockade of H2 receptors blocks acid secretion in response to histamine
and causes essentially complete inhibition of responses to other releasing
agents such as gastrin or vagal stimulation.

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 Neurotransmitters in the CNS.

 Histamine appears to function as a transmitter in the CNS.

 High concentrations of H1 receptors occur in the thalamus,
hypothalamus, and regions of the cerebellum.

 Histaminergic neurons may play a role in the regulation of
drinking, body temperature regulation and secretion of
antidiuretic hormone, the control of blood pressure and the
perception of pain.

 Both H1 and H2 receptors appear to play a role in these
responses.

 H3 receptors are apparently located on histaminergic nerve
terminals, where they exert feedback regulation of histamine
synthesis and release.
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C.V.S.
 Vascular smooth vessels
 Vasodilation: H1& H2
 Flushing
 ↓ peripheral resistance
 ↓ blood pressure

 ↑ capillary permeability: H1

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INCREASED VASCULAR PERMEABILITY
 H1 receptor activation produces inhibitory effect of histamine on
the post capillary venules.
 This causes endothelial cells to contract and become separate at
their boundaries thus exposing the basement membrane which is
freely permeable to plasma proteins and fluid.
 The overall increased permeability results
 in outward movement of plasma protein and fluid into the extracellular
spaces,
 an increase in the flow of lymph and in its protein content, the formation
of oedema.

 The involvement of H2 receptors in this effect is not certain. 30
 THE HEART
 +Ionotropic effect both atria and ventricular resulting from
the promotion of calcium flux. This effect is predominantly H2
activity.

 +Chronotropic effect by increasing diastolic depolarization
in the S.A. Node (predominantly H2 activity).

 Slowing down of A.V. conduction (-dromotropy) to increase
sinus rate and ventricular automaticity of the heart
(predominantly H1 activity).

 In high doses histamine causes diverse arrhythmia (H2
activity).
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VASODILATION
 Histamine- induced vasodilation is mediated via both H1
and H2 receptors present in most vascular smooth
vessels.
 H1 receptors are the most sensitive because of their
higher affinity for histamine.

 H1 receptor induced dilation is rapid in onset and of
short duration,
 The vasodilation results primarily through H1 receptor
mediated release of EDRF (nitric oxide).

– H2 receptor induced dilation is slow in onset and more
sustained. 32
SYSTEMIC BLOOD PRESSURE
 Moderate doses of histamine cause a fall in systemic blood
pressure.
 This fall is due to a reduction in peripheral resistance and
dilatation of the peripheral blood vessels.
 There are 2 components of this response;
 H1 receptor mediated; this is rapid in onset but transient
 H2 receptor mediated; this is slower in onset but sustained

 The fall in systemic BP triggers baroreceptor reflexes which
call into play increased sympathetic discharge leading to a
reversal of the fall of the BP – a biphasic BP effect
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 High doses of histamine will produce histamine shock. There is a profound
and sustained fall in the BP. The body itself cannot compensate for it
Leading to no reversal.

 This fall in BP is due to;
 dilation of minute blood vessels
 pooling of blood in the peripheral vascular bed
 increased vascular permeability therefore loss of plasma fluid and proteins from the
circulation
 drastic fall in blood volume
 reduction in venous return and a fall in the cardiac output
 collapse of large arteries

 Histamine shock is mainly due to the injection of exogenous histamine.
 Endogenous histamine can be mobilized in the body by taking drugs which
release histamine and the state of such a person may resemble that of one
due to exogenous histamine.
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 EXTRAVASCULAR SMOOTH MUSCLES:
 Histamine causes contraction of the smooth muscle (H1
receptor activation).
 There is also relaxation (H2 receptor activation).

 The tissue responses relating to smooth muscles are species
dependent. For example,
 Human bronchial smooth muscle is normally not very
sensitive but in subjects predisposed to bronchial asthma
and some other pulmonary diseases, there can be
intense bronchospasms to minute doses of histamine.

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 SENSORY NERVE ENDINGS

 Introduction of histamine into the superficial layers of the
skin produces itching.
 When administration is made more deeply into the skin
then pain is produced.

"Triple Response (of Lewis)": (red, intense flare, wheal)

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PHYSIOLOGICAL FUNCTIONS OF
ENDOGENOUS HISTAMINE

 Hypersensitivity & allergic responses (one of the
mediators in local and systemic allergic reactions)
SRS-A, ECF-A ???
 Mediator of gastric acid secretion
 Neurotransmitter in the CNS

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ADVERSE EFFECTS & CONTRAINDICATION

 Flushing
 Hypotension,
 Tachycardia,
 Headache,
 Wheals,
 Bronchoconstriction,
 Gastrointestinal Upset.
 Histamine is contraindicated in asthmatics and
patients with active ulcer disease or GI bleeding.

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ANTIHISTAMINES
 H1 blockers

 H2 blockers

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H1 BLOCKERS
 1st generation antihistamines are more likely to
 cause sedation in therapeutic doses
 affect autonomic receptors (cholinergic and
adrenergic)

 2nd generation antihistamines are sometimes called
“non-sedating” antihistamines

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1ST GENERATION

 Developed in France pre-WWII
 More sedating
 Penetrate the CNS and generally have CNS
effects
 Significant anticholinergic effects

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2ND GENERATION

 Less sedating - less CNS penetration
 Almost no anticholinergic effects
 Some can produce cardiac toxicity e.g.,
terfenadine, astemizole and ebastine.

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2ND GENERATION ANTIHISTAMINES
 Ionized molecules that cross BBB poorly.
 Loratidine (Claritin™) – No apparent cardiac toxicity

 Fexofenadine (Allegra™) - active metabolite of terfenadine, safer
than parent compound

 Rupatadine – anatgonist of PAF

 Cetirizine (Zyrtec™) - metabolite of hydroxyzine
 Removed from the market for serious cardiac arrhythmias
 Terfenadine (Seldane™)
 Astemizole (Hismanal™)
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MECHANISM OF ANTIHISTAMINIC H1 ACTION

 Competitive or surmountable antagonism contributes to
most of the effects of H1 antagonists

 But most of these drugs produce some of their effects
through OTHER mechanisms.
 Many of the H1 antagonists are also inhibitors of muscarinic
receptors.
 These atropine-like properties are sufficiently prominent with
some of these drugs to be clinically significant.

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HISTAMINE H1 RECEPTOR ANTAGONISTS
Classification Generic name Trade Name(™)
Ethanolamines Dimenhydrinate Dramamine
Diphenhydramine Benadryl
Carbinoxamine Clistin

Ethylenediamine Pyrilamine
Tripelennamine
Alkylamines Chlorpheniramine Piriton
Brompheniramine Dimetane

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Piperazines Meclizine Antivert
Cyclizine Marezine

Phenothiazines Promethazine Phenergan/Avomine

Miscellaneous Cyproheptadine Periactin

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Bilastine and Acrivastine
 Cause less sedation and psychomotor impairment

 Limited information on its safety in pregnancy but no
data on its teratogenicity

 Bilastine has similar efficacy as cetirizine but
significantly reduced somnolence (PMID: 22185046).

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EFFECTS ON AUTONOMIC RECEPTORS
ANTICHOLINERGIC ACTIONS
 Anti-motion sickness effects/anti-emetics

 Mechanism: Blocking of muscarinic receptors
 Promethazine strongest muscarinic receptor blocking
activity of clinically useful H1 antagonists

 Others: Cinnarizine

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LOCAL ANAESTHETIC EFFECTS
 Promethazine & mepyramine particularly active
 Less potent than dibucaine
 Comparable to procaine
 Tripelennamine & chlorpheniramine - cocaine-like
action

 Large doses higher than antihistamine doses
required

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CNS
1st generation antihistamines cross BBB and
produce CNS depressant effect
 Sedation
 Cough suppression

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 PHARMACOKINETICS
 Most well absorbed and remain effective for 3-6 h

 Loratadine is converted to a long acting metabolite

 Metabolism by the liver and excretion in the urine.

 Most have peripheral antimuscarinic activity

 Terfenadine is a prodrug requiring oxidation by CYP3A4 to to its
safer metabolite (fexofenadine). The parent drug’s
cardiotoxicity resulted in its withdrawal from the market.
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SIDE EFFECTS

 CNS
– sedation, headache, visual disturbances dizziness, euphoria, tinnitus,
insomnia, tremors

 GIT
 anorexia, epigastric distress, constipation,

 ANTIMUSCARINIC EFFECTS
-dryness of mouth & respiratory passages, urinary retention, etc

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 SIDE EFFECTS

 DRUG ALLERGY Dermatitis, Urticaria, Rash

 HAEMATOLOGICAL COMPLICATIONS Hemolytic anaemia,
leukopenia

 TERATOGENIC EFFECTS in experimental animals with piperazine
derivatives like cetirizine

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ACUTE POISONING

 Central depression
 Central excitation
 Hallucinations
 Convulsions
 Coma
 Cardio-respiratory collapse
 Death

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THERAPEUTIC USES

 Allergy (hives, rhinitis, hay fever, conjunctivitis).
 Bronchial Asthma
 Common cold
 Vertigo Vertigo is a feeling of spinning or tilting that can be caused by inner ear problems, brain problems,
or medications
 Nausea & vomiting
 Parkinson’s disease (orphenadrine, diphenhydramine)
 Insomnia
 Prevention of Motion sickness & Emesis.

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