Pharmacology Lec12 (Adrenergic Agonists) PDF

Summary

This document covers the topic of adrenergic agonists in pharmacology. It details the characteristics of various categories of adrenergic drugs, including catecholamines and non-catecholamines. The document also explains their mechanisms of action and therapeutic uses.

Full Transcript

Pharmacology I Lecture: 11

Dr. Wrood Salim

Adrenergic Agonists
Characteristics of Adrenergic Agonist:

Most of the adrenergic drugs are derivatives of β-phenylethylamine (Figure 1).
Substitutions on the benzene ring or on the ethylamine side chains produce a variety of
compounds with varying abilities to differentiate between α and β receptors and to
penetrate the CNS. Two important structural features of these drugs are 1) the number and
location of OH substitutions on the benzene ring and 2) the nature of the substituent on the
amino nitrogen.
A. Catecholamines
Sympathomimetic amines that contain the 3,4-dihydroxybenzene group (such as
epinephrine, norepinephrine, isoproterenol, and dopamine) are called catecholamines.
These compounds share the following properties:

1. High potency: Catecholamines (with –OH groups in the 3 and 4 positions on the
benzene ring) show the highest potency in directly activating α or β receptors.

2. Rapid inactivation: Catecholamines are metabolized by COMT postsynaptically and
by MAO intraneuronally, as well as by COMT and MAO in the gut wall, and by MAO in
the liver. Thus, catecholamines have only a brief period of action when given parenterally,
and they are inactivated (ineffective) when administered orally.

3. Poor penetration into the CNS: Catecholamines are polar and, therefore, do not readily
penetrate into the CNS. Nevertheless, most catecholamines have some clinical effects
(anxiety, tremor, and headaches) that are attributable to action on the CNS.

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B. Non-catecholamines
Compounds lacking the catechol hydroxyl groups have longer half-lives, because
they are not inactivated by COMT. These include phenylephrine, ephedrine, and
amphetamine (Figure 1). These agents are poor substrates for MAO (an important route of
metabolism) and, thus, show a prolonged duration of action. Increased lipid solubility of
many of the non-catecholamines (due to lack of polar hydroxyl groups) permits greater
access to the CNS.

Mechanism of action of adrenergic agonists:

1. Direct-acting agonists: These drugs act directly on
α or β receptors, producing effects similar to those that
occur following stimulation of sympathetic nerves or
release of epinephrine from the adrenal medulla
(Figure 2). Examples of direct-acting agonists include
epinephrine, norepinephrine, isoproterenol, and
phenylephrine.

2. Indirect-acting agonists: These agents may block
the reuptake of norepinephrine or cause the release of
norepinephrine from the cytoplasmic pools or vesicles
of the adrenergic neuron (Figure 2).
The norepinephrine then traverses the synapse and
binds to α or β receptors. Examples of reuptake
inhibitors and agents that cause norepinephrine release
include cocaine and amphetamines, respectively.

3. Mixed-action agonists: Ephedrine and its
stereoisomer, pseudoephedrine, both stimulate
adrenoceptors directly and release norepinephrine from
the adrenergic neuron (Figure 2).

Figure 1: Structures of several important
adrenergic agonists. Drugs containing the
catechol ring are shown in yellow.
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Direct-acting agonists:
Direct-acting agonists bind to adrenergic
receptors on effector organs without interacting
with the presynaptic neuron. As a group, these
agents are widely used clinically.
A. Epinephrine
Epinephrine is one of the four catecholamines
(epinephrine, norepinephrine, dopamine, and
dobutamine) commonly used in therapy. The
first three are naturally occurring
neurotransmitters, and the latter is a synthetic
compound. In the adrenal medulla,
norepinephrine is methylated to yield
epinephrine, which is stored in chromaffin cells
along with norepinephrine. On stimulation, the
adrenal medulla releases about 80% epinephrine
and 20% norepinephrine directly into the
circulation. Figure 2: Sites of action of direct-, indirect-,
and mixed-acting adrenergic agonists.

Epinephrine interacts with both α and β receptors. At low doses, β effects
(vasodilation) on the vascular system predominate, whereas at high doses, α effects
(vasoconstriction) are the strongest.
1. Actions:
a. Cardiovascular: The major actions of epinephrine are on the cardiovascular system.
Epinephrine strengthens the contractility of the myocardium (positive inotrope: β1 action)
and increases its rate of contraction (positive chronotrope: β1 action). Therefore, cardiac
output increases. These effects increase oxygen demands on the myocardium. Epinephrine
activates β1 receptors on the kidney to cause renin release. Renin is an enzyme involved in
the production of angiotensin II, a potent vasoconstrictor.

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 Epinephrine constricts arterioles in the skin, mucous membranes, and viscera (α effects),
and it dilates vessels going to the liver and skeletal muscle (β2 effects). Renal blood flow
is decreased. Therefore, the cumulative effect is an increase in systolic blood pressure,
coupled with a slight decrease in diastolic pressure due to β2 receptor–mediated
vasodilation in the skeletal muscle vascular bed (Figure 3).
b. Respiratory: Epinephrine causes powerful bronchodilation by acting directly on
bronchial smooth muscle (β2 action). It also inhibits the release of allergy mediators such
as histamines from mast cells.
c. Hyperglycemia: Epinephrine has a significant
hyperglycemic effect because of increased
glycogenolysis in the liver (β2 effect), increased
release of glucagon (β2 effect), and a decreased
release of insulin (α2 effect).
d. Lipolysis: Epinephrine initiates lipolysis
through agonist activity on the β receptors of
adipose tissue. Increased levels of cAMP stimulate
a hormone-sensitive lipase, which hydrolyzes
triglycerides to free fatty acids and glycerol.
2. Therapeutic uses:
a. Bronchospasm: Epinephrine is the primary
drug used in the emergency treatment of
respiratory conditions when bronchoconstriction
has resulted in diminished respiratory function.
Thus, in treatment of acute asthma and
anaphylactic shock, epinephrine is the drug of
choice and can be life saving in this setting. Within
a few minutes after subcutaneous administration,
respiratory function greatly improves. However,
selective β2 agonists, such as albuterol, are Figure 3: Cardiovascular effects of intravenous
infusion of low doses of epinephrine.
favored in the chronic treatment of asthma because
of a longer duration of action and minimal cardiac
stimulatory effects.
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b. Anaphylactic shock: Epinephrine is the drug of choice for the treatment of type I
hypersensitivity reactions (including anaphylaxis) in response to allergens.

c. Cardiac arrest: Epinephrine may be used to restore cardiac rhythm in patients with
cardiac arrest.

d. Anesthetics: Local anesthetic solutions may contain low concentrations (for example,
1:100,000 parts) of epinephrine. Epinephrine greatly increases the duration of local
anesthesia by producing vasoconstriction at the site of injection. This allows the local
anesthetic to persist at the injection site before being absorbed into the systemic circulation.

Adverse effects: Epinephrine can produce adverse CNS effects that include anxiety, fear,
tension, headache, and tremor. It can trigger cardiac arrhythmias, particularly if the patient
is receiving digoxin. Epinephrine can also induce pulmonary edema.
Epinephrine may have enhanced cardiovascular actions in patients with hyperthyroidism,
and the dose must be reduced in these individuals.
Patients with hyperthyroidism may have an increased production of adrenergic receptors
in the vasculature, leading to a hypersensitive response.
Epinephrine increases the release of endogenous stores of glucose. In diabetic patients,
dosages of insulin may have to be increased. Nonselective β-blockers prevent vasodilatory
effects of epinephrine on β2 receptors, leaving α receptor stimulation unopposed. This may
lead to increased peripheral resistance and increased blood pressure.

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B. Norepinephrine
Because norepinephrine is the neurotransmitter of
adrenergic nerves, it should, theoretically, stimulate
all types of adrenergic receptors. However, when
administered in therapeutic doses, the α-adrenergic
receptor is most affected.

1. Cardiovascular actions:
a. Vasoconstriction: Norepinephrine causes a rise
in peripheral resistance due to intense
vasoconstriction of most vascular beds, including the
kidney (α1 effect). Both systolic and diastolic blood
pressures increase (Figure 4). [Note: Norepinephrine
causes greater vasoconstriction than epinephrine,
because it does not induce compensatory
vasodilation via β2 receptors on blood vessels
supplying skeletal muscles. The weak β2 activity of
norepinephrine also explains why it is not useful in
the treatment of asthma or anaphylaxis.]

b. Baroreceptor reflex: Norepinephrine increases
blood pressure, and this stimulates the baroreceptors,
inducing a rise in vagal activity. The increased vagal Figure 4: Cardiovascular effects of
activity produces a reflex bradycardia, which is intravenous infusion of norepinephrine.

sufficient to counteract the local actions of norepinephrine on the heart, although the reflex
compensation does not affect the positive inotropic effects of the drug (Figure 4). When
atropine, which blocks the transmission of vagal effects, is given before norepinephrine,
stimulation of the heart by norepinephrine is evident as tachycardia.
2. Therapeutic uses: Norepinephrine is used to treat shock, because it increases vascular
resistance and, therefore, increases blood pressure. It has no other clinically significant
uses.

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Figure 4: Schematic representation of the cardiovascular effects of intravenous infusions of adrenaline,
noradrenaline and isoprenaline in humans. Noradrenaline (predominantly α agonist) causes
vasoconstriction and increased systolic and diastolic pressure, with a reflex bradycardia. Isoprenaline (β
agonist) is a vasodilator, but strongly increases cardiac force and rate. Mean arterial pressure falls.
Adrenaline combines both actions.

C. Isoproterenol
Isoproterenol is a direct-acting synthetic catecholamine that stimulates both β1- and β2-
adrenergic receptors. Its non-selectivity is one of its drawbacks and the reason why it is
rarely used therapeutically. Its action on α receptors is insignificant.
Isoproterenol produces intense stimulation of the heart, increasing heart rate, contractility,
and cardiac output (Figure 4). It is as active as epinephrine in this action. Isoproterenol
also dilates the arterioles of skeletal muscle (β2 effect), resulting in decreased peripheral
resistance. Because of its cardiac stimulatory action, it may increase systolic blood pressure
slightly, but it greatly reduces mean arterial and diastolic blood pressures (Figure 4).
Isoproterenol is a potent bronchodilator (β2 effect). The use of isoproterenol has largely
been replaced with other drugs, but it may be useful in atrioventricular (AV) block. The
adverse effects of isoproterenol are similar to those of epinephrine.

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D. Dopamine
Dopamine [DOE-pa-meen], the immediate metabolic
precursor of norepinephrine, occurs naturally in the
CNS in the basal ganglia, where it functions as a
neurotransmitter, as well as in the adrenal medulla.
Dopamine can activate α- and β-adrenergic receptors.
For example, at higher doses, it causes
vasoconstriction by activating α1 receptors, whereas at
lower doses, it stimulates β1 cardiac receptors.
In addition, D1 and D2 dopaminergic receptors,
distinct from the α- and β-adrenergic receptors, occur
in the peripheral mesenteric and renal vascular beds,
where binding of dopamine produces vasodilation. D2
receptors are also found on presynaptic adrenergic
neurons, where their activation interferes with
norepinephrine release.

1. Actions:
a. Cardiovascular: Dopamine exerts a stimulatory
effect on the β1 receptors of the heart, having both
positive inotropic and chronotropic effects (Figure
6.13). At very high doses, dopamine activates α1
receptors on the vasculature, resulting in
vasoconstriction. Figure 5: Clinically important actions
of isoproterenol and dopamine.

b. Renal and visceral: Dopamine dilates renal and splanchnic arterioles by activating
dopaminergic receptors, thereby increasing blood flow to the kidneys and other viscera
(Figure 6.13). These receptors are not affected by α- or β-blocking drugs. Therefore,
dopamine is clinically useful in the treatment of shock, in which significant increases in
sympathetic activity might compromise renal function.

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2. Therapeutic uses: Dopamine is the drug of choice for cardiogenic and septic shock and
is given by continuous infusion. It raises blood pressure by stimulating the β1 receptors on
the heart to increase cardiac output and α1 receptors on blood vessels to increase total
peripheral resistance. In addition, it enhances perfusion to the kidney and splanchnic areas,
as described above.

E. Fenoldopam
Fenoldopam is an agonist of peripheral dopamine D1 receptors. It is used as rapid-
acting vasodilators to treat sever hypertension in hospitalized patients, acting on coronary
arteries, kidney arterioles, and mesenteric arteries. Fenoldopam is a racemic mixture, and
the R-isomer is the active component. It undergoes extensive first-pass metabolism and has
a 10-minute elimination half-life after IV infusion. Headache, flushing, dizziness, nausea,
vomiting, and tachycardia (due to vasodilation) may be observed with this agent.

F. Dobutamine
Dobutamine is a synthetic, direct-acting catecholamine that is a β1 receptor agonist.
It increases cardiac rate and output with few vascular effects. Dobutamine is used to
increase cardiac output in acute heart failure, as well as for inotropic support after cardiac
surgery. The drug increases cardiac output and does not significantly elevate oxygen
demands of the myocardium, a major advantage over other sympathomimetic drugs.

G. Oxymetazoline
Oxymetazoline is a direct-acting synthetic adrenergic agonist that stimulates both
α1- and α2-adrenergic receptors. Oxymetazoline is found in many over-the-counter short-
term nasal spray decongestants, as well as in ophthalmic drops for the relief of redness of
the eyes associated with swimming, colds, and contact lenses. Oxymetazoline directly
stimulates α receptors on blood vessels supplying the nasal mucosa and conjunctiva,
thereby producing vasoconstriction and decreasing congestion. It is absorbed in the
systemic circulation regardless of the route of administration and may produce
nervousness, headaches, and trouble sleeping.

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Local irritation and sneezing may occur with intranasal administration. Rebound
congestion and dependence are observed with long-term use.

H. Phenylephrine
Phenylephrine is a direct-acting, synthetic adrenergic drug that binds primarily to
α1 receptors. Phenylephrine is a vasoconstrictor that raises both systolic and diastolic blood
pressures. It has no effect on the heart itself but, rather, induces reflex bradycardia when
given parenterally. The drug is used to treat hypotension in hospitalized or surgical patients
(especially those with a rapid heart rate).
Large doses can cause hypertensive headache and cardiac irregularities. Phenylephrine acts
as a nasal decongestant when applied topically or taken orally. Phenylephrine is also used
in ophthalmic solutions for mydriasis.

I. Clonidine
Clonidine is an α2 agonist that is used for the treatment of hypertension. It can also
be used to minimize the symptoms that accompany withdrawal from opiates, tobacco
smoking, and benzodiazepines. Clonidine acts centrally on presynaptic α2 receptors to
produce inhibition of sympathetic vasomotor centers, decreasing sympathetic outflow to
the periphery. The most common side effects of clonidine are lethargy, sedation,
constipation, and xerostomia.
Abrupt discontinuance must be avoided to prevent rebound hypertension.

J. Albuterol and terbutaline
Albuterol and terbutaline are short-acting β2 agonists used primarily as bronchodilators and
administered by a metered-dose inhaler. Albuterol is the short-acting β2 agonist of choice
for the management of acute asthma symptoms.
Terbutaline is also used off-label as a uterine relaxant to suppress premature labor. One of
the most common side effects of these agents is tremor, but patients tend to develop
tolerance to this effect. Other side effects include restlessness, apprehension, and anxiety.
When these drugs are administered orally, they may cause tachycardia or arrhythmia (due
to β1 receptor activation), especially in patients with underlying cardiac disease.

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Monoamine oxidase inhibitors (MAOIs) also increase the risk of adverse cardiovascular
effects, and concomitant use should be avoided.

K. Salmeterol and formoterol
Salmeterol and formoterol are long acting β agonists (LABAs) that are β2 selective. A
single dose by a metered-dose inhalation device, such as a dry powder inhaler, provides
sustained bronchodilation over 12 hours, compared with less than 3 hours for albuterol.
Unlike formoterol, however, salmeterol has a somewhat delayed onset of action. These
agents are not recommended as monotherapy, but are highly efficacious when combined
with a corticosteroid. Salmeterol and formoterol are the agents of choice for treating
nocturnal asthma in symptomatic patients taking other asthma medications.

L. Mirabegron
Mirabegron is a β3 agonist that relaxes the detrusor smooth muscle and increases bladder
capacity. It is used for patients with overactive bladder. Mirabegron may increase blood
pressure and should not be used in patients with uncontrolled hypertension.

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 INDIRECT-ACTING ADRENERGIC AGONISTS

Indirect-acting adrenergic agonists cause the release, inhibit the reuptake, or inhibit the
degradation of epinephrine or norepinephrine. They potentiate the effects of epinephrine
or norepinephrine produced endogenously, but do not directly affect postsynaptic
receptors.

A. Amphetamine
The marked central stimulatory action of amphetamine is often mistaken by drug abusers
as its only action. However, the drug can also increase blood pressure significantly by α1
agonist action on the vasculature, as well as β1-stimulatory effects on the heart.
Its actions are mediated primarily through an increase in nonvesicular release of
catecholamines such as dopamine and norepinephrine from nerve terminals. Thus,
amphetamine is an indirect-acting adrenergic drug. The actions and therapeutic uses of
amphetamine and its derivatives are discussed under stimulants of the CNS.

B. Tyramine
Tyramine is not a clinically useful drug, but it is important because it is found in fermented
foods, such as aged cheese and Chianti wine. It is a normal by-product of tyrosine
metabolism.
Normally, it is oxidized by MAO in the gastrointestinal tract, but, if the patient is taking
MAOIs, it can precipitate serious vasopressor episodes. Like amphetamines, tyramine can
enter the nerve terminal and displace stored norepinephrine. The released catecholamine
then acts on adrenoceptors.

C. Cocaine
Cocaine is unique among local anesthetics in having the ability to block the sodium-
chloride (Na+/Cl-)-dependent norepinephrine transporter required for cellular uptake of
norepinephrine into the adrenergic neuron. Consequently, norepinephrine accumulates in
the synaptic space, resulting in enhanced sympathetic activity and potentiation of the
actions of epinephrine and norepinephrine. Therefore, small doses of the catecholamines
produce greatly magnified effects in an individual taking cocaine. In addition, the duration

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of action of epinephrine and norepinephrine is increased. Like amphetamines, it can
increase blood pressure by α1 agonist actions and β stimulatory effects.

MIXED-ACTION ADRENERGIC AGONISTS
Ephedrine and pseudoephedrine are mixed-action adrenergic agents. They not only
release stored norepinephrine from nerve endings but also directly stimulate both α and β
receptors. Thus, a wide variety of adrenergic actions ensue that are similar to those of
epinephrine, although less potent.
Ephedrine and pseudoephedrine are not catechols and are poor substrates for
COMT and MAO. Therefore, these drugs have a long duration of action. Ephedrine and
pseudoephedrine have excellent absorption orally and penetrate into the CNS, but
pseudoephedrine has fewer CNS effects. Ephedrine is eliminated largely unchanged in
urine, and pseudoephedrine undergoes incomplete hepatic metabolism before elimination
in urine. Ephedrine raises systolic and diastolic blood pressures by vasoconstriction and
cardiac stimulation and can be used to treat hypotension. Ephedrine produces
bronchodilation, but it is less potent and slower acting than epinephrine or isoproterenol.
It was previously used to prevent asthma attacks but has been replaced by more effective
medications. Ephedrine produces a mild stimulation of the CNS. This increases alertness,
decreases fatigue, and prevents sleep. It also improves athletic performance. [Note: The
clinical use of ephedrine is declining because of the availability of better, more potent
agents that cause fewer adverse effects. Ephedrine-containing herbal supplements (mainly
ephedra-containing products) have been banned by the U.S. Food and Drug Administration
because of life-threatening cardiovascular reactions.] Pseudoephedrine is primarily used
orally to treat nasal and sinus congestion. Pseudoephedrine has been illegally used to
produce methamphetamine.

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