Respiratory System Pharmacology PDF

Summary

This document describes the respiratory system and common conditions like asthma and COPD. It details the causes, symptoms, and various treatment options, including drugs like beta-2 adrenergic agonists and corticosteroids. A useful resource for learning about the respiratory system and related disorders.

Full Transcript

Pharmacology
College of Dentistry
Dr Maha Mohsin Khalaf University of Baghdad

Respiratory System
Asthma, chronic obstructive pulmonary disease (COPD), and allergic rhinitis are commonly encountered
respiratory disorders. Each of these conditions may be associated with a troublesome cough, which may be
the only presenting complaint. Asthma is a chronic disease characterized by hyperresponsive airways and
episodes of acute bronchoconstriction causing shortness of breath, Allergic rhinitis characterized by itchy,
watery eyes, runny nose, and a nonproductive cough that can significantly decrease quality of life. Whereas
asthma is characterised by reversible airways obstruction and bronchial hyperreactivity, COPD is
characterised by incompletely reversible airways obstruction and mucus hypersecretion; it is predominantly
a disease of the smaller airways. Nevertheless, distinguishing the two can be difficult in some patients.
Drugs used to treat respiratory conditions can be delivered topically to the nasal mucosa, inhaled into the
lungs, or given orally or parenterally for systemic absorption. Local delivery methods, such as nasal sprays
or inhalers, are preferred to target affected tissues while minimizing systemic side effects.

ASTHMA
The bronchi become hyperreactive (Figure 1) as a result of a persistent
inflammatory process in response to a number of stimuli that include biological
agents, e.g. allergens, viruses, and environmental chemicals such as ozone and
glutaraldehyde. Inflammatory mediators are liberated from mast cells,
eosinophils, neutrophils, monocytes and macrophages. Some mediators such as
histamine are pre-formed and their release causes an immediate bronchial
reaction. Others are formed after activation of cells and produce more sustained
bronchoconstriction;
Preferred drugs used to treat asthma:

β2 -Adrenergic agonists
Inhaled β2 -adrenergic agonists directly relax airway smooth muscle. They are
used for the quick relief of asthma symptoms, as well as adjunctive therapy for
long-term control of the disease.
1. Quick relief: Short-acting β2 agonists (SABAs) have a rapid onset of action
(5 to 30 minutes) and provide relief for 4 to 6 hours. They are used for
symptomatic treatment of bronchospasm, providing quick relief of acute
bronchoconstriction. All patients with asthma should be prescribed a SABA
inhaler. β2 agonists have no anti-inflammatory effects, and they should never be
used as the sole therapeutic agents for patients with persistent asthma. However,
monotherapy with SABAs may be appropriate for patients with intermittent
asthma or exercise-induced bronchospasm. Direct acting β2 -selective agonists

1 Figure 1: difference between
normal and asthmatic airways
include albuterol and levalbuterol. These agents provide significant bronchodilation with little of the
undesired effect of α or β1 stimulation. Adverse effects, such as tachycardia, hyperglycemia, hypokalemia,
and hypomagnesemia, are minimized with inhaled delivery versus systemic administration. These agents
can cause β2 -mediated skeletal muscle tremors.
2. Long-term control: Salmeterol and formoterol are long-acting β2 agonists (LABAs) and chemical
analogs of albuterol. Salmeterol and formoterol have a long duration of action, providing bronchodilation
for at least 12 hours. Neither salmeterol nor formoterol should be used for quick relief of an acute asthma
attack. Use of LABA monotherapy is contraindicated, and LABAs should be used only in combination with
an asthma controller medication. Inhaled corticosteroids remain the long-term controllers of choice in
asthma, and LABAs are considered to be useful adjunctive therapy for attaining asthma control. Some
LABAs are available as a combination product with an ICS. Adverse effects of LABAs are similar to
quick-relief β2 agonists.

Corticosteroids
ICS are the drugs of choice for long-term control in patients
with any degree of persistent asthma. Corticosteroids inhibit the
release of arachidonic acid through phospholipase A2
inhibition, thereby producing direct anti-inflammatory
properties in the airways. No other medications are as effective
as ICS in the long-term control of asthma in children and adults.
To be effective in controlling inflammation, glucocorticoids
must be used regularly. Severe persistent asthma may require
the addition of a short course of oral glucocorticoid treatment.

1. Actions on lung: ICS do not directly affect the airway
smooth muscle. Instead, ICS therapy directly targets underlying
airway inflammation by decreasing the inflammatory cascade
(eosinophils, macrophages, and T lymphocytes), reversing
mucosal edema, decreasing the permeability of capillaries, and
inhibiting the release of leukotrienes (Figure 2). After several
months of regular use, ICS reduce the hyperresponsiveness of
the airway smooth muscle to a variety of bronchoconstrictor
stimuli, such as allergens, irritants, cold air, and exercise.

2. Routes of administration a. Inhalation: The development
of ICS has markedly reduced the need for systemic
corticosteroid treatment to achieve asthma control. However, as
with all inhaled medications, appropriate inhalation technique
is critical to the success of therapy. b. Oral/systemic: Patients
with a severe exacerbation of asthma (status asthmaticus) may
require intravenous methylprednisolone or oral prednisone to
reduce airway inflammation. In most cases, suppression of the
hypothalamic–pituitary–adrenal cortex axis will not occur
Figure 2: Mechanism of action of Corticosteroids

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during the short course of oral prednisone “burst” typically prescribed for an asthma exacerbation.
Therefore, prednisone dose taper is unnecessary prior to discontinuation. Due to the increased incidence of
adverse effects with oral therapy, chronic maintenance with systemic administration of corticosteroids
should be reserved for patients who are not controlled on an ICS.
3. Adverse effects: Oral or parenteral glucocorticoids have a variety of potentially serious side effects
(Figure 3), whereas ICS, particularly if used with a spacer, have few systemic effects. ICS deposition on
the oral and laryngeal mucosa can cause adverse effects, such as oropharyngeal candidiasis (due to local
immune suppression) and hoarseness. Patients should be instructed to rinse the mouth in a “swish-and-spit”
method with water following use of the inhaler to decrease the chance of these adverse events.

Figure 3: ICS side effects

Alternative drugs used to treat asthma
These drugs are useful for treatment of asthma in patients who are poorly controlled by conventional therapy
or experience adverse effects secondary to corticosteroid treatment. These drugs should be used in
conjunction with ICS therapy for most patients, not as monotherapy.
A. Leukotriene modifiers Leukotrienes (LT) B4 and the cysteinyl leukotrienes, LTC4, LTD4, and LTE4,
are products of the 5-lipoxygenase pathway of arachidonic acid metabolism and part of the inflammatory
cascade. 5-Lipoxygenase is found in cells of myeloid origin, such as mast cells, basophils, eosinophils, and

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neutrophils. LTB4 is a potent chemoattractant for neutrophils and eosinophils, whereas the cysteinyl
leukotrienes constrict bronchiolar smooth muscle, increase endothelial permeability, and promote mucus
secretion. Zileuton is a selective and specific inhibitor of 5-lipoxygenase, preventing the formation of both
LTB4 and the cysteinyl leukotrienes. Because zafirlukast and montelukast are selective antagonists of the
cysteinyl leukotriene-1 receptor, they block the effects of cysteinyl leukotrienes (Figure 2). All three drugs
are approved for the prevention of asthma symptoms. They should not be used in situations where
immediate bronchodilation is required. Leukotriene receptor antagonists have also shown efficacy for the
prevention of exercise induced bronchospasm.
Pharmacokinetics: All three drugs are orally active and highly protein bound. Food impairs the absorption
of zafirlukast. The drugs are metabolized extensively by the liver. Zileuton and its metabolites are excreted
in urine, whereas zafirlukast, montelukast, and their metabolites undergo biliary excretion.
Adverse effects: Elevations in serum hepatic enzymes have occurred with all three agents, requiring
periodic monitoring and discontinuation when enzymes exceed three to five times the upper limit of normal.
Other effects include headache and dyspepsia.
B. Cromolyn is a prophylactic anti-inflammatory agent that inhibits mast cell degranulation and release of
histamine. It is an alternative therapy for mild persistent asthma. However, it is not useful in managing an
acute asthma attack, because it is not a bronchodilator. Cromolyn is available as a nebulized solution for
use in asthma. Due to its short duration of action, this agent requires dosing three or four times daily, which
affects adherence and limits its use. Adverse effects are minor and include cough, irritation, and unpleasant
taste.
C. Cholinergic antagonists The anticholinergic agents block vagally mediated contraction of airway
smooth muscle and mucus secretion. Inhaled ipratropium, a quaternary derivative of atropine, is not
recommended for the routine treatment of acute bronchospasm in asthma, as its onset is much slower than
inhaled SABAs. However, it may be useful in patients who are unable to tolerate a SABA or patients with
concomitant COPD. Ipratropium also offers additional benefit when used with a SABA for the treatment
of acute asthma exacerbations in the emergency department. Adverse effects such as xerostomia and bitter
taste are related to local anticholinergic effects.
D. Theophylline is a bronchodilator that relieves airflow obstruction in chronic asthma and decreases its
symptoms. It may also possess anti-inflammatory activity, Theophylline competitively inhibits type III and
type IV phosphodiesterase (PDE), the enzyme responsible for breaking down cyclic AMP in smooth muscle
cells, possibly resulting in bronchodilation. Theophylline also binds to the adenosine A2B receptor and
blocks adenosine mediated bronchoconstriction. Previously, the mainstay of asthma therapy, theophylline
has been largely replaced with β2 agonists and corticosteroids due to its narrow therapeutic window,
adverse effect profile, and potential for drug interactions. Overdose may cause seizures or potentially fatal
arrhythmias. Theophylline is metabolized in the liver. It is subject to numerous drug interactions. Serum
concentration monitoring should be performed when theophylline is used chronically.
E. Omalizumab is a recombinant DNA-derived monoclonal antibody that selectively binds to human
immunoglobulin E (IgE). This leads to decreased binding of IgE to its receptor on the surface of mast cells
and basophils. Reduction in surface-bound IgE limits the release of mediators of the allergic response.
Omalizumab is indicated for the treatment of moderate to severe persistent asthma in patients who are
poorly controlled with conventional therapy. Its use is limited by the high cost, route of administration
(subcutaneous), and adverse effect profile. Adverse effects include serious anaphylactic reaction (rare),
arthralgias, fever, and rash. Secondary malignancies have been reported.

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CHRONIC OBSTRUCTIVE PULMONARY DISEASE
COPD is a chronic, irreversible obstruction of airflow that is usually progressive. Symptoms include cough,
excess mucus production, chest tightness, breathlessness, difficulty sleeping, and fatigue. Although
symptoms are similar to asthma, the characteristic irreversible airflow obstruction of COPD is one of the
most significant differences between the diseases. Smoking is the greatest risk factor for COPD and is
directly linked to the progressive decline of lung function as demonstrated by forced expiratory volume in
one second (FEV1). Smoking cessation and/or continued avoidance should be recommended regardless of
stage/ severity of COPD and age of patient. Drug therapy for COPD is aimed at relief of symptoms and
prevention of disease progression.
A. Bronchodilators Inhaled bronchodilators, including the β2 -adrenergic agonists and anticholinergic
agents (ipratropium and tiotropium), are the foundation of therapy for COPD. These drugs increase
airflow, alleviate symptoms, and decrease exacerbation rates. The long-acting agents, LABAs and
tiotropium, are preferred as first-line treatment of COPD for all patients except those who are at low risk
with less symptoms. Combination of both an anticholinergic and a β2 agonist may be helpful in patients
who have inadequate response to a single inhaled bronchodilators.
B. Corticosteroids The addition of an ICS to a long-acting bronchodilator may improve symptoms, lung
function and quality of life in COPD patients. However, the use of an ICS is associated with an increased
risk of pneumonia, and therefore, use should be restricted to these patients. Although often used for acute
exacerbations, oral corticosteroids are not recommended for long-term treatment.
C. Other agents: Roflumilast is an oral phosphodiesterase-4 inhibitor used to reduce exacerbations in
patients with severe chronic bronchitis. Although its activity is not well defined in COPD, it is theorized to
reduce inflammation by increasing levels of intracellular cAMP in lung cells. Roflumilast is not a
bronchodilator and is not indicated for the relief of acute bronchospasm. Its use is limited by common side
effects including nausea, vomiting, diarrhea, and headache.
As in asthma, the use of theophylline has largely been replaced by the more effective and tolerable long-
acting bronchodilators.

DRUGS USED TO TREAT ALLERGIC RHINITIS
Rhinitis is an inflammation of the mucous membranes of the nose and is characterized by sneezing, itchy
nose/eyes, watery rhinorrhea, nasal congestion, and sometimes, a nonproductive cough. An attack may be
precipitated by inhalation of an allergen (such as dust, pollen, or animal dander). The foreign material
interacts with mast cells coated with IgE generated in response to a previous allergen exposure. The mast
cells release mediators, such as histamine, leukotrienes, and chemotactic factors that promote bronchiolar
spasm and mucosal thickening from edema and cellular infiltration. Antihistamines and/or intranasal
corticosteroids are preferred therapies for allergic rhinitis.
A. Antihistamines (H1 -receptor blockers) Antihistamines are useful for the management of symptoms of
allergic rhinitis caused by histamine release (sneezing, watery rhinorrhea, itchy eyes/nose). However, they
are more effective for prevention of symptoms, rather than treatment once symptoms have begun.
Ophthalmic and nasal antihistamine delivery devices are available for more targeted tissue delivery. First-
generation antihistamines, such as diphenhydramine and chlorpheniramine, are usually not preferred due
to adverse effects, such as sedation, performance impairment, and other anticholinergic effects. The second
generation antihistamines (for example, fexofenadine, loratadine, desloratadine, cetirizine, and

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intranasal azelastine) are generally better tolerated. Combinations of antihistamines with decongestants are
effective when congestion is a feature of rhinitis.
B. Corticosteroids Intranasal corticosteroids, such as beclomethasone, budesonide, fluticasone,
ciclesonide, mometasone, and triamcinolone, are the most effective medications for treatment of allergic
rhinitis. They improve sneezing, itching, rhinorrhea, and nasal congestion. Systemic absorption is minimal,
and side effects of intranasal corticosteroid treatment are localized. These include nasal irritation,
nosebleed, sore throat, and, rarely, candidiasis. To avoid systemic absorption, patients should be instructed
not to inhale deeply while administering these drugs because the target tissue is the nose, not the lungs or
the throat. For patients with chronic rhinitis, improvement may not be seen until 1 to 2 weeks after starting
therapy.
C. α-Adrenergic agonists Short-acting α-adrenergic agonists (“nasal decongestants”), such as
phenylephrine, constrict dilated arterioles in the nasal mucosa and reduce airway resistance. Longer-acting
oxymetazoline is also available. When administered as an aerosol, these drugs have a rapid onset of action
and show few systemic effects. Unfortunately, the α-adrenergic agonist intranasal formulations should be
used no longer than 3 days due to the risk of rebound nasal congestion (rhinitis medicamentosa). For this
reason, the α-adrenergic agents have no place in the long-term treatment of allergic rhinitis. Administration
of oral α-adrenergic agonist formulations results in a longer duration of action but also increased systemic
effects.
As with intranasal formulations, regular use of oral α-adrenergic agonists (phenylephrine and
pseudoephedrine) alone or in combination with antihistamines is not recommended.
D. Other agents Intranasal cromolyn may be useful in allergic rhinitis, particularly when administered
before contact with an allergen. To optimize the therapeutic effect, dosing should begin at least 1 to 2 weeks
prior to allergen exposure. A nonprescription (over-the-counter) nasal formulation of cromolyn is available.

DRUGS USED TO TREAT COUGH
Coughing is an important defense mechanism of the respiratory system to irritants and is a common reason
for patients to seek medical care. A troublesome cough may represent several etiologies, such as the
common cold, sinusitis, and/or an underlying chronic respiratory disease. In some cases, cough may be an
effective defense reflex against an underlying bacterial infection and should not be suppressed. Before
treating cough, identification of its cause is important to ensure that antitussive treatment is appropriate.
The priority should always be to treat the underlying cause of cough when possible.
A. Opioids: Codeine, an opioid, decreases the sensitivity of cough centers in the central nervous system to
peripheral stimuli and decreases mucosal secretion. These therapeutic effects occur at doses lower than
those required for analgesia. However, common side effects, such as constipation, dysphoria, and fatigue,
still occur. In addition, it has addictive potential. Dextromethorphan is a synthetic derivative of morphine
that has no analgesic effects in antitussive doses. In low doses, it has a low addictive profile. However, it is
a potential drug of abuse, since it may cause dysphoria at high doses. Dextromethorphan has a significantly
safer side effect profile than codeine and is equally effective for cough suppression. Guaifenesin, an
expectorant, is available as a single-ingredient formulation and is also a common ingredient in combination
products with codeine or dextromethorphan.

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B. Benzonatate Unlike the opioids, benzonatate suppresses the cough reflex through peripheral action. It
anesthetizes the stretch receptors located in the respiratory passages, lungs, and pleura. Side effects include
dizziness, numbness of the tongue, mouth, and throat. These localized side effects may be particularly
problematic if the capsules are broken or chewed and the medication comes in direct contact with the oral
mucosa.
Table 1 summarize all the drugs used in respiratory system diseases treatment

Table 1 drugs for respiratory system
diseases

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 Lecture 8
HISTAMINE AND ANTIHISTAMINE
Histamine is a naturally occurring amine that is found in most tissues in an inactive bound form, and
pharmacologically active free histamine, released in response to stimuli such as physical trauma or
immunoglobulin (Ig) E-mediated activation, is an important component of the acute inflammatory response.
The physiological functions of histamine are suggested by its distribution in the body, in:
 Body epithelia (the gut, the respiratory tract and in the skin), where it is released in response to
invasion by foreign substances
 Glands (gastric, intestinal, lachrymal, salivary), where it mediates part of the normal secretory
process
 Mast cells near blood vessels, where it plays a role in regulating the microcirculation. \
 Histamine functions as a neurotransmitter in the brain.
 It also occurs as a component of venoms and in secretions from insect stings.
Release of histamine: Most often, histamine is just one of several chemical mediators released in response
to stimuli. The stimuli for release of histamine from tissues may include destruction of cells as a result of
cold, toxins from organisms, venoms from insects and spiders, and trauma. Allergies and anaphylaxis can
also trigger significant release of histamine.
Actions Histamine acts as a local hormone (autacoid) similarly to serotonin or prostaglandins, i.e. it
functions within the immediate vicinity of its site of release. With gastric secretion, for example, stimulation
of receptors on the histamine containing cell causes release of histamine, which in turn acts on receptors on
parietal cells which then secrete hydrogen ion.
Histamine receptors Histamine binds to H1, H2 and H3 receptors, all of which are G-protein coupled. The
H1 receptor is largely responsible for mediating its pro-inflammatory effects, including the vasomotor
changes, increased vascular permeability and upregulation of adhesion molecules on vascular endothelium,
i.e. it mediates the oedema and vascular effects of histamine.
H2 receptors mediate release of gastric acid. Blockade of histamine H1 and H2 receptors has substantial
therapeutic utility. H3 receptors are expressed in a wide range of tissues including brain and nerve endings,
and function as feedback inhibitors for histamine and other neurotransmitters. More recently identified is
the H4 receptor, which is involved in leucocyte chemotaxis.

HISTAMINE ANTAGONISM AND H1- AND H2-RECEPTOR
ANTAGONISTS
The effects of histamine can be opposed in three ways:

 By using a drug with opposing effects. Histamine constricts bronchi, causes vasodilatation and increases
capillary permeability; adrenaline (epinephrine), by activating α and β2 adrenoceptors, produces opposite
effects - referred to as physiological antagonism.

 By blocking histamine binding to its site of action (receptors), i.e. using competitive H1- and H2-receptor
antagonists.

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 By preventing the release of histamine from storage cells. Glucocorticoids and sodium cromoglicate
can suppress IgE-induced release from mast cells; β2 agonists have a similar effect.
Drugs that competitively block H1-histamine receptors were the first to be introduced and are
conventionally called the 'antihistamines'. They effectively inhibit the components of the triple response
and partially prevent the hypotensive effect of histamine, but they have no effect on histamine-induced
gastric secretion which is suppressed by blockade of histamine H2 receptors.
Thus, histamine antagonists are classified as:

 histamine H1-receptor antagonists

 histamine H2-receptor antagonists: cimetidine, famotidine, nizatidine, ranitidine
Histamine H1-receptor antagonists. The selectivity implied by the term 'antihistamine'is unsatisfactory
because the older first-generation antagonists show considerable blocking activity against muscarinic
receptors, and often serotonin and α-adrenergic receptors as well. These features are a disadvantage when
H1 antihistamines are used specifically to antagonise the effects of histamine, e.g. for allergies. Hence the
appearance of second-generation H1 antagonists that are more selective for H1 receptors and largely free
of anti-muscarinic and sedative effects has been an important advance. Actions H1-receptor antihistamines
oppose, to varying degrees, the effects of liberated histamine. They are generally competitive, surmountable
inhibitors and strongly block all components of the triple response (a pure H1-receptor effect), but only
partially counteract the hypotensive effect of high-dose histamine (a mixed H1- and H2-receptor effect).
H1 antihistamines are of negligible use in asthma, in which non-histamine mediators, such as the cysteinyl
leukotrienes, are the predominant constrictors. They are more effective if used before histamine has been
liberated, and reversal of effects of free histamine is more readily achieved by physiological antagonism
with adrenaline (epinephrine), which is used first in life-threatening allergic reactions. The older first-
generation H1 antihistamines cause drowsiness and patients should be warned of this, e.g. about driving or
operating machinery, and about additive effects with alcohol. Paradoxically, they can increase seizure
activity in epileptics, especially children, and can cause seizures in non-epileptic subjects if taken in
overdose. The newer second-generation H1 antihistamines penetrate the blood-brain barrier less readily and
are largely devoid of such central effects. Antimuscarinic effects of first-generation H1 antihistamines are
sometimes put to therapeutic advantage in parkinsonism and motion sickness.
Uses The H1 antihistamines are used for symptomatic relief of allergies such as hay fever and urticaria.
They are of broadly similar therapeutic efficacy.
INDIVIDUAL H1-RECEPTOR ANTIHISTAMINES
Non-sedative second-generation drugs These newer drugs are relatively selective for H1 receptors, enter
the brain less readily than do the earlier antihistamines, and lack the unwanted antimuscarinic effects.
Differences lie principally in their duration of action. Cetirizine (t½ 7 h), loratadine (t½ 15 h) and
terfenadine (t½ 20 h) are effective taken once daily and are suitable for general use. Acrivastine (t½ 2 h)
is so short acting that it is best reserved for intermittent therapy, e.g. when breakthrough symptoms occur
in a patient using topical therapy for hay fever. Other non-sedating antihistamines are desloratadine,
fexofenadine, levocetirizine and mizolastine.
Adverse effects The second-generation antihistamines are well tolerated but a noteworthy effect occurs
with terfenadine. This drug can cause ventricular tachycardia and probably explains the sudden deaths
reported during early use of terfenadine. The event is prone to occur with high dose or when metabolism of

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terfenadine is inhibited, and inhibiting drugs include erythromycin, ketoconazole and even grapefruit juice.
Fexofenadine, the active metabolite of terfenadine, appears to be safer regarding the effect on the heart.
Sedative first-generation agents
Chlorphenamine (t½ 20 h) is effective when urticaria is prominent, and its sedative effect is then useful.
Diphenhydramine (t½ 32 h) is strongly sedative and has antimuscarinic effects; it is also used in
parkinsonism and motion sickness. Promethazine (t½ 12 h) is so strongly sedative that it is used as an
hypnotic in adults and children. Alimemazine, azatadine, brompheniramine, clemastine,
cyproheptadine, diphenylpyraline, doxylamine, hydroxyzine and triprolidine are similar.
Adverse effects Apart from sedation, these include: dizziness, fatigue, insomnia, nervousness, tremors and
antimuscarinic effects, e.g. dry mouth, blurred vision and gastrointestinal disturbance. Dermatitis and
agranulocytosis can occur. Severe poisoning due to overdose results in coma and sometimes in convulsions.

Corticosteroids
The adrenal gland consists of the cortex and the medulla. The medulla secretes catecholamines, whereas
the cortex, secretes two types of corticosteroids (glucocorticoids and mineralocorticoids) and the adrenal
androgens. The adrenal cortex has three zones, and each zone synthesizes a different type of steroid
hormone from cholesterol. The outer zona glomerulosa produces mineralocorticoids (for example,
aldosterone) that are responsible for regulating salt and water metabolism. Production of aldosterone is
regulated primarily by the renin–angiotensin system. The middle zona fasciculata synthesizes
glucocorticoids (for example, cortisol) that are involved with metabolism and response to stress. The inner
zona reticularis secretes adrenal androgens.
A. Glucocorticoids
Cortisol is the principal human glucocorticoid. Normally, its production is diurnal, with a peak early in the
morning followed by a decline and then a secondary, smaller peak in the late afternoon. Factors such as
stress and levels of the circulating steroid influence secretion. The effects of cortisol are many and diverse.
In general, all glucocorticoids:
1. Promote normal intermediary metabolism: Glucocorticoids favor gluconeogenesis. They stimulate
protein catabolism (except in the liver) and lipolysis, thereby providing the building blocks and energy that
are needed for glucose synthesis.
2. Increase resistance to stress: By raising plasma glucose levels, glucocorticoids provide the body with
energy to combat stress caused by trauma, fright, infection, bleeding, or debilitating disease.
3. Alter blood cell levels in plasma: Glucocorticoids cause a decrease in eosinophils, basophils, monocytes,
and lymphocytes by redistributing them from the circulation to lymphoid tissue. Glucocorticoids also
increase hemoglobin, erythrocytes, platelets, and polymorphonuclear leukocytes.
4. Anti-inflammatory effect They have powerful anti-inflammatory and immunosuppressant effects. They
prevent or suppress the clinical features of inflammation such as redness, heat, pain and swelling. At tissue
level, they suppress the early phenomena (capillary permeability, oedema, cellular infiltration and
phagocytosis) and late responses like capillary proliferation, collagen deposition, fibroblast activity and
scar formation (Figure 4).

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 Figure 4: anti-inflammatory effect of glucocorticoids

a. Glucocorticoids induce a protein called lipocortin, which inhibits phospholipase A2, so
prostaglandins (PGs), leukotrienes (LTs) and PAF are not formed.
b. Tumour necrosis factor-alpha (TNF-α- is inhibited by glucocorticoids, which is necessary for
initiating infl ammatory process.

Figure 5: another mechanism of action of steroid
hormones
c. Glucocorticoids stabilize the lysosomal membrane and prevent the release of inflammatory
mediators.
B. Mineralocorticoids
Mineralocorticoids help to control fluid status and concentration of electrolytes, especially sodium and
potassium. Aldosterone acts on distal tubules and collecting ducts in the kidney, causing reabsorption of
sodium, bicarbonate, and water. Conversely, aldosterone decreases reabsorption of potassium, which, with
H+, is then lost in the urine. Enhancement of sodium reabsorption by aldosterone also occurs in
gastrointestinal mucosa and in sweat and salivary glands.

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Therapeutic uses of the corticosteroids (disturbance of corticosteroids production from adrenal cortex
can cause two diseases. Reduction in corticosteroids is called Addison disease, while increase is called
Cushing syndrome)
Endocrinal uses:
1. Acute adrenal insufficiency: It is a medical emergency. It is treated with i.v. hydrocortisone and i.v.
normal saline with 5% glucose to correct fluid and electrolyte imbalance. Precipitating causes such as
trauma, infection or haemorrhage should be treated.
2. Chronic adrenal insufficiency: Treated with oral hydrocortisone
(two-third of the daily dose is given in the morning and one-third in
the evening) along with adequate salt and water.
Non-endocrinal uses
Corticosteroids are one of the most important groups of drugs used
clinically in a variety of diseases. Because of their dramatic
symptomatic relief, they are often misused. Non-endocrinal diseases
require supra-physiological doses of steroid, which inevitably carries
risk. The beneficial effects of glucocorticoids are mainly due to their
anti-inflammatory and immunosuppressant effects.
1. In dentistry: Topical or systemic glucocorticoids are used in: a.
Recurrent aphthous stomatitis b. Chronic ulcerative stomatitis c. Oral
pemphigoid d. Erythema multiforme e. Temporomandibular joint
pain: Intra-articular triamcinolone is used.
2- Relief of inflammatory symptoms: Corticosteroids significantly
reduce the manifestations of inflammation associated with rheumatoid
arthritis and inflammatory skin conditions, including redness,
swelling, heat, and tenderness that may be present at the site of
inflammation. These agents are also important for maintenance of
symptom control in persistent asthma, as well as management of
asthma exacerbations and active inflammatory bowel disease. In
noninflammatory disorders such as osteoarthritis, intra-articular
corticosteroids may be used for treatment of a disease flare.
Corticosteroids are not curative in these disorders.
3- Treatment of allergies: Corticosteroids are beneficial in the
treatment of allergic rhinitis, as well as drug, serum, and transfusion
allergic reactions. [Note: In the treatment of allergic rhinitis and
asthma, fluticasone and others are applied topically to the respiratory
tract through inhalation from a metered dose dispenser. This minimizes systemic effects and allows the
patient to reduce or eliminate the use of oral corticosteroids.]
4- Acceleration of lung maturation: Respiratory distress syndrome is a problem in premature infants.
Fetal cortisol is a regulator of lung maturation. Consequently, a regimen of betamethasone or
dexamethasone administered intramuscularly to the mother within the 48 hours proceeding premature
delivery can accelerate lung maturation in the fetus.

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