Basic principles of pharmacology PDF

Summary

This document is a lecture on basic principles of pharmacology, focusing on direct-acting adrenergic agonists. It covers topics like adrenergic receptors, catecholamines, and their effects on various organ systems.

Full Transcript

Welcome To

Basic principles of
pharmacology

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 Welcome to this topic
DRUGS AFFECTING THE
ADRENERGIC NERVOUS SYSTEM

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 Welcome to this session
Attendance password:

Dobutamine

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 Lecture Overview

In this lecture you can expect to learn about direct acting adrenergic agonists.

You have previously learned about indirect-acting adrenergic drugs that may mimic or inhibit the sympathetic nervous system.

In this lecture you will build upon that knowledge and further explore the effects of drugs that bind to and stimulate alpha and beta
receptors.

Throughout this lecture it will become clear that alpha 2 agonists inhibits the effects of the sympathetic nervous system though its
negative feedback mechanism on adrenergic neurons.

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 Learning Outcomes

At the end of this lecture, you should be able to:
 Describe the adrenergic receptors in the body, their location and actions
 Describe the actions, adverse effects and clinical uses of the mixed-acting sympathomimetic agonists
 Describe the actions of the catecholamines on organ systems (including selectivity for specific adrenoceptors), their clinical
uses and adverse effects
 Describe the mechanisms of action of non-catecholamine adrenoceptor agonist drug classes with drug examples, their
clinical uses and adverse effects

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 Adrenergic transmission

Rang & Dale’s Pharmacology - Page 165
Goodman & Gilman's: The Pharmacological Basis of Therapeutics – Chapter 10 – Figure
10.2
ACh is also the neurotransmitter at cells of the adrenal medulla, where it acts on NN
receptors to cause release of adrenaline and NA into the circulation, which stimulates
the sympathetic nervous system

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 Adrenoceptors

Adrenergic receptors include alpha and beta receptors, which NA binds to:
Alpha receptors: α1, α2
Beta receptors: β1, β2, β3

Rang and Dale’s pharmacology. 2024. Chapter 15. Page 205.

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 α 1(A,B,D) α 2(A,B,C) β1 β2 β3
G protein Gq Gi/Go GS GS GS
Characteristics of adrenoceptors

coupling
Second Phospholipase C ↓ cAMP ↑ cAMP ↑ cAMP ↑ cAMP
messengers activation ↓ Calcium
and effectors ↑ Inositol channels
trisphosphate ↑ Potassium
↑ Diacylglycerol channels
2+
↑ Ca
Agonist NA > A ≫ ISO A > NA ≫ ISO ISO > NA > A ISO > A > NA ISO > NA = A
potency order
Selective Phenylephrine Clonidine Dobutamine Salbutamol Mirabegron
agonists Oxymetazoline Terbutaline
Salmeterol
Formoterol
Selective Prazosin Yohimbine Atenolol (Butoxamine) —
antagonists Doxazosin Metoprolol

Table 15.2 Characteristics of adrenoceptors

Rang and Dale’s pharmacology. 2024. Chapter 15. Page 207.

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Table 15.1
Distribution and actions of adrenoceptors

Rang and Dale’s pharmacology. 2024. Chapter 15. Page 207.

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 Tissues and effects β1 β2 β3
Smooth muscle
Blood vessels — Dilate —
Bronchi — Dilate —
Gastrointestinal tract — Relax —
Uterus — Relax —
Bladder detrusor — Relax Relax
Seminal tract — Relax —
Iris (radial muscle) — — —
Ciliary muscle — Relax —
Heart
a
Rate Increase Increase —
a
Force of contraction Increase Increase —
Other tissues/cells
Skeletal muscle — Tremor Thermogenesis
Increased muscle mass and
speed of contraction
Glycogenolysis
Liver (hepatocytes) — Glycogenolysis —
Fat (adipocytes) — — Lipolysis
Thermogenesis
Nerve terminals
Adrenergic — Increase release —

Table 15.1
Distribution and actions of adrenoceptors

Rang and Dale’s pharmacology. 2024. Chapter 15. Page 207.

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Direct-acting sympathomimetic
drugs

Catecholamines and non-
catecholamines
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 Direct-acting sympathomimetic drugs

Drugs that act as
agonists at adrenergic
receptors – α and β

DIRECT-ACTING NON-
CATECHOLAMINES
SYMPATHOMIMETICS CATECHOLAMINES

Brenner & Stevens’ Pharmacology. 2023. Chapter 8. Table 8.2 Pharmacologic effects and
clinical uses of adrenoceptor agonists. Page 88.

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 Catecholamines (non-selective adrenergic receptor agonists)
Each catecholamine consists of the catechol moiety and an ethylamine
side chain
Naturally occurring catecholamines include:
Noradrenaline (norepinephrine)
Endogenous sympathetic neurotransmitter
Adrenaline (Epinephrine)
Principal hormone of the adrenal medulla
Synthetic catecholamines include:
Isoprenaline (US- Isoproterenol)
Dobutamine

Brenner & Stevens’ Pharmacology. 2023. Chapter 8. Figure 8.5. Page 87.

Figure 8.5. Structures of selected adrenoceptor agonists. Catecholamines contain the
catechol moiety and an ethylamine side chain. The amine nitrogen substitution (R2)
determines the relative affinity for α- and β-adrenoceptors, with larger substitutions
(e.g., in isoproterenol and dobutamine) decreasing the affinity for α-adrenoceptors and
increasing the affinity for β-adrenoceptors. Note that dopamine has an even higher
affinity for dopamine D1 receptors than for the adrenoceptors.

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 Catecholamines (non-selective adrenergic receptor agonists)
Each of the catecholamines differs in terms of their
affinity for the adrenergic receptors
This affects the effects that they have on various
organ systems
The catecholamines differ slightly from each other in
their clinical effects
These drugs are rapidly metabolised by MAO and
COMT
They must thus be administered parenterally,
They are used primarily to treat cardiac disorders and
various types of shock

Brenner & Stevens’ Pharmacology. 2023. Chapter 8. Figure 8.5. Page 87.
Structures of selected adrenoceptor agonists. Catecholamines contain the catechol
moiety and an ethylamine side chain. The amine nitrogen substitution (R2) determines
the relative affinity for α- and β-adrenoceptors, with larger substitutions (e.g., in
isoproterenol and dobutamine) decreasing the affinity for α-adrenoceptors and
increasing the affinity for β-adrenoceptors. Note that dopamine has an even higher
affinity for dopamine D1 receptors than for adrenoceptors.

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 Catecholamines
RECEPTOR PHARMACOLOGICAL
DRUG CLINICAL USE
SELECTIVITY EFFECT
β1 Cardiac stimulation Cardiogenic shock
Dobutamine Acute heart failure
(β1>β2>α) Cardiac stimulation during
β2 Vasodilation
heart surgery

β1 Cardiac stimulation Cardiogenic shock
Septic shock
Dopamine β1 Heart failure
↑BP Hypotension
(D>β1>α) α1
Adjunct to fluid
Dopamine-1 administration in
Renal vasodilation
(D1) hypovolemic shock
Isoprenaline β1 Cardiac stimulation Atrioventricular block
(β1=β2>α)
β2 Bronchodilation Bradycardia

Brenner & Stevens’ Pharmacology. 2023. Table 8.2 Pharmacologic effects and clinical
uses of adrenoceptor agonists. Page 88.

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 Catecholamines

RECEPTOR PHARMACOLOGICAL
DRUG CLINICAL USE
SELECTIVITY EFFECT

Noradrenaline Vasoconstriction Shock
α1
(α1=α2; β1>β2) and ↑BP Hypotension

Anaphylaxis
β1 Cardiac stimulation
Cardiac arrest
Adrenaline β1 Ventricular fibrillation
↑BP Reduction in bleeding
(epinephrine) α1
(α1=α2; β1=β2)
β2 Bronchodilation during surgery
Prolongation of the action
α1 Vasoconstriction of local anesthetics

Brenner & Stevens’ Pharmacology. 2023. Table 8.2 Pharmacologic effects and clinical
uses of adrenoceptor agonists. Page 88.

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 Cardiac effects of catecholamines

Due to their
differences in
affinity for the
adrenergic
receptors, the
catecholamines
differ in their
cardiac effects

Brenner & Stevens’ Pharmacology. 2023. Page 89 – Figure 8.6
Comparison of the cardiovascular effects of four catecholamines when a low dose of
each drug is given by intravenous infusion. Arrows indicate when the infusion was
started and stopped. The blood pressure recordings show systolic, diastolic, and mean
arterial pressure. Peripheral resistance is expressed on an arbitrary scale, ranging from 0
to 4 units. The reflex mechanism, adrenoceptors (α1, β1, and β2), or dopamine (D1)
receptors responsible for changes in the heart rate and peripheral resistance are
illustrated. Norepinephrine increases peripheral resistance and blood pressure, and this
leads to reflex bradycardia. Epinephrine increases heart rate while reducing peripheral
resistance, and the mean arterial blood pressure increases slightly. Isoproterenol
increases heart rate but significantly lowers peripheral resistance, and the mean arterial
pressure declines. Dopamine increases heart rate (and increases cardiac output) while
lowering vascular resistance, and the mean arterial pressure increases

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 Respiratory effects of catecholamines
Stimulation of β2 receptors:
↑ Bronchial muscle relaxa on
(bronchodilation)

Isoprenaline (Isoproterenol) and adrenaline
have potent bronchodilator effects, and have
been used in the treatment of acute asthma
attacks (Adrenaline nebulisers)
More selective β2 agonists are now used in
practice e.g. salbutamol ( Ventolin / Venteze)

Image source: https://www.sciencebuzz.com/the-cellular-and-molecular-basis-of-bitter-
tastant-induced-bronchodilation/
Brenner & Stevens’ Pharmacology. 2023. Page 91.
Rang & Dale’s Pharmacology. 2024. Chapter 15. Table 15.4 Adrenoceptor agonists. Page
212.

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 Metabolic effects of catecholamines
Catecholamines encourage the
conversion of energy stores to freely
available fuels
Conversion of glycogen and fat to increase
the plasma concentration of glucose and
free fatty acids
The effects on carbohydrate metabolism of
liver and muscle are mediated through β2
receptors
The stimulation of lipolysis and
thermogenesis is produced by β3
receptors
Activation of α2 receptors inhibits insulin
secretion, which further contributes to
hyperglycaemia

Rang & Dale’s Pharmacology. 2024. Chapter 15. Page 216-217.
Fig. 15.5 Regulation of energy metabolism by catecholamines.
The main enzymic steps that are affected by β-adrenoceptor activation are indicated by
+ and − signs, deno ng s mula on and inhibi on, respec vely. The overall effect is to
mobilise glycogen and fat stores to meet energy demands. TCA, Tricarboxylic acid.

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 Local anaesthetics and catecholamines
Most local anaesthetics (LA) have a direct vasodilator action, which
increases the rate at which they are absorbed into the systemic
circulation
This increases their potential toxicity and reduces their LA action
Adrenaline may be added to LA solutions injected locally to cause
vasoconstriction through α1 agonist effects
Prevents LA diffusing away from the site of injection
Action of the LA remains localised where it’s needed
Prolongs LA action at the injection site
Prevents side effects which would occur if the LA diffused to other sites

Brenner and Steven’s pharmacology. 2023. Page 233-234.

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 Adverse effects of catecholamines
Due to β2 agonism:
Skeletal muscle tremor (Fine tremor after using Beta 2 agonist inhaler)
Hyperglycaemia (undesirable in diabetics)
Excessive cardiac stimulation that leads tachycardia and other cardiac
dysrhythmias
Due to α1 agonism:
Excessive vasoconstriction leading to leading to tissue ischemia and necrosis

Brenner & Stevens’ Pharmacology. 2024. Chapter 8. page 89

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Non-catecholamines

No catechol moity YFRM202

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 Non-catecholamine adrenergic receptor agonists
The non-catecholamines differ in
chemical structure to the
catecholamines
They don’t contain a catechol moiety
Not substrates for COMT
Some of the non-catecholamines are
also resistant to degradation by MAO
Thus, non-catecholamines are effective
after oral administration and have a
longer duration of action than
catecholamines

Brenner & Stevens’ Pharmacology. 2023. Page 90.

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Non-catecholamine adrenergic receptor agonists
Drug classes (based on selectivity for receptor)
Non-selective agonists (α and β agonist –including indirect
mechanisms)
Selective α1 - agonists
Selective α2 - agonists
Selective β2 – agonists
Selective β3 – agonist

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Mixed-acting sympathomimetic
drugs

Indirect and direct effects YFRM202

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 Mixed-acting sympathomimetic drugs

Mixed-acting

Indirect effects Direct effects

Increase release of
NA Non-selective α and
Inhibit reuptake via β receptor agonist
NET

Brenner and Steven’s pharmacology. 2023. Chapter 8. Page 93.

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 Mixed-acting sympathomimetic - ephedrine

Ephedrine – is chemically related to amphetamine
i.e its indirect sympathomimetic effects
AND it is an agonist of alpha-1 beta-1 and beta-2 receptors

DRUG PHARMACOLOGICAL EFFECT CLINICAL USE

Nasal decongestion due to
vasoconstriction (α1- Treatment of nasal
Ephedrine agonist) congestion caused by colds
Bronchodilation (β2- and flu
agonist)

Drugbank online. 2024. Ephedrine. Available at:
https://go.drugbank.com/drugs/DB01364 (Date accessed: 2 October 2024)

Brenner and Steven’s pharmacology. 2023. Chapter 8. Page 93.

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 Indirect-acting mechanism of ephedrine

Displacers of NA:
These drugs are structurally similar enough to NA that
they are taken up into the presynaptic neuron by the
NA transporter (norepinephrine transporter - NET)
Drug enters synaptic vesicles via the vesicular
monoamine transporter (VMAT), in exchange for NA,
which accumulates in the cytosol
NA escapes, in exchange for drug via the NET, to act
on postsynaptic receptors
These drugs also reduce NA reuptake via NET, so
enhancing the action of the released NA

Fig. 15.7 The mode of action of amphetamine, an indirectly acting sympathomimetic
amine.
Amphetamine enters the nerve terminal via the noradrenaline transporter (NET) and
enters synaptic vesicles via the vesicular monoamine transporter (VMAT), in exchange
for noradrenaline (NA), which accumulates in the cytosol. Some of the NA is degraded
by monoamine oxidase (MAO) within the nerve terminal and some escapes, in exchange
for amphetamine via the noradrenaline transporter, to act on postsynaptic receptors.
Amphetamine also reduces NA reuptake via the transporter, so enhancing the action of
the released NA. The effect is a result of adrenergic hyperstimulation centrally and
peripherally hence its street name “Speed”.

Rang and Dale’s pharmacology. 2024. Page 214, 222-223.
Table 15.6 Drugs that affect noradrenaline synthesis, release or uptake. Page 214

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 Mixed-acting sympathomimetic - Pseudoephedrine
Pseudoephedrine is structurally related to ephedrine, but have a weaker
effect on the sympathetic nervous system.
Alpha-receptor agonist, less strong agonist of beta-receptors, block
NET (i.e. NE reuptake)
Relatively resistant to metabolism by MAO and COMT, contributing to
a longer duration of action
Used in illicit manufacture of methamphetamine (co-formulated S2, single ingredient S6)

DRUG PHARMACOLOGICAL EFFECT CLINICAL USE

Nasal decongestion due to
vasoconstriction(primary Treatment of nasal
Pseudoephedrine α1-agonist) congestion caused by colds
Bronchodilation (lesser and flu
β2-agonist)

Drugbank online. 2024. Pseudoephedrine. Available at:
https://go.drugbank.com/drugs/DB00852 (Date accessed: 2 October 2024)

SAMF. 2022. Page 573.

Brenner and Steven’s pharmacology. 2023. Chapter 8. Page 93.

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 Decongestant action
Pseudoephedrine
Limited to short-term symptomatic relief of acute nasal congestion
Topical therapy preferred
Systemic formulations often co-formulated:
With analgesic: Pseudoephedrine + paracetamol: Sudafed Sinus Pain
With antihistamine: Pseudoephedrine + loratadine: Demazin NS
S2 – one pack per customer
Dose of pseudoephedrine max 60mg/dose,
Pack size limit 720mg / pack

SAMF. 2022. R02 Nasal preparations. Decongestants for systemic use Page 573-574.

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 Pseudoephedrine
Adverse effects:
Tachycardia (β1)
↑ Blood pressure (β1 and α1)
CNS stimulation and insomnia
Urinary retention due to contraction of the sphincter muscle of the
bladder, especially in men with prostatic hypertrophy (α1)

SAMF. 2022. R02 Nasal preparations. Decongestants for systemic use Page 573-574.

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 RECEPTOR PHARMACOLOGICAL
DRUG CLINICAL USE
SELECTIVITY EFFECT
Nasal and ocular
Phenylephrine Vasoconstriction decongestion
- (Sudafed tabs ; Also α1 Mydriasis Mydriasis
IVI preparations)
↑BP Maintenance of BP
Shock
Oxymetazoline Vasoconstriction Nasal and ocular
(Dristan, Vicks Sinex nasal α1
sprays) decongestion
Xylometazoline Nasal and ocular
α1 Vasoconstriction
(Otrivin nasal spray) decongestion
Midodrine α1 Vasoconstriction Orthostatic hypotension

Brenner & Stevens’ Pharmacology. 2023. Chapter 8. Table 8.2. Page 88.
Rang & Dale’s Pharmacology. 2024. Chapter 15. Table 15.4. Page 211.

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 The α1-agonists have a vasoconstrictive effect on the nasal mucosa
This reduces vascular congestion and mucus secretion, which opens the nasal
passages and facilitates breathing
Both topical and oral preparations are available for this purpose
Treatment with topical α1-agonists must not exceed 3-5 days’
duration
Prolonged vasoconstriction leads to tissue ischaemia
Triggers a compensatory mechanism by the body resulting in vasodilation and
↑ mucosal gland secre on
Rebound nasal congestion, also known as ‘rhinitis medicamentosa’

Brenner & Stevens’ Pharmacology. 2023. Chapter 8. Page 90

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 The α1-agonists have a vasoconstrictive effect in the arterioles of the
conjunctiva, thereby reducing redness
Decongestant eye drops:
Phenylephrine
Naphazoline(Safyr Blur®)
Oxymetazoline
Tetryzoline/antazoline (Spersallerg®, Gemini®)

SAMF. 2022. Page 612-613.

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 Drug Main action Indications Adverse effects
Clonidine α 2 partial agonist Hypertension, Drowsiness,
migraine hypotension,
prophylaxis, oedema and
vasomotor weight gain,
instability (‘hot rebound
flushes’) hypertension

Rang & Dale’s Pharmacology. 2024. Table 15.4 Adrenoceptor agonists. Page 212.

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 Adrenergic transmission and presynaptic feedback control

The inhibitory feedback mechanism operates through
α2 receptors
↓
Activation of presynaptic α2 receptors
↓
Activation of Gi protein
↓
Inhibits adenylyl cyclase
↓
Prevents the opening of calcium channels
↓
Inhibits exocytosis and release of NA

Rang & Dale’s Pharmacology. 2024. Chapter 15. page 209 –
Figure 15.2 Feedback control of noradrenaline (NA) release. The presynaptic α2 receptor
inhibits Ca2+ influx in response to membrane depolarisation via an action of the βγ
subunits of the associated G protein on the voltage-dependent Ca2+ channels

G protein-coupled inwardly-rectifying K+ channels – promotes hyperpolarization of the
neuronal membrane thus delaying action potentials

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 RECEPTOR PHARMACOLOGICAL
DRUG CLINICAL USE
SELECTIVITY EFFECT
Salbutamol Bronchodilation
β2 (short-acting - Asthma and COPD
(albuterol) Preterm labour
(Ventolin / Venteze) SABA)
Bronchodilation
Salmeterol β2 (long-acting - Asthma and COPD
LABA)
Bronchodilation
Formoterol β2 (long-acting - Asthma and COPD
LABA)
Bronchodilation
(SABA)
Terbutaline β2 Asthma and COPD
Relaxation of the
uterus (tocolysis)

Brenner & Stevens’ Pharmacology. 2023. Chapter 8. Table 8.2. Page 88.
Rang & Dale’s Pharmacology. 2024. Chapter 15. Table 15.4. Page 211.

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 Skeletal muscle tremor
Tachycardia
Nervousness
Increased susceptibility to cardiac dysrhythmias
Thought to be partly due to hypokalaemia, caused by an increase in K+
uptake by skeletal muscle

SAMF. 2022. Page 612-613.

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 Drug Main action Indications Adverse effects
Mirabegron β 3 agonist Symptoms of Tachycardia
overactive bladder

Picture source:
http://ars.els-cdn.com/content/image/3-s2.0-B9780124077102000291-f29-01-
9780124077102.jpg?httpAccept=%2A%2F%2A (Date accessed: 2Apr17)

Rang & Dale’s Pharmacology. 2024. Chapter 15. Table 15.4. Page 211.

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 Checklist

Can you...
 Describe the adrenergic receptors in the body, their location and actions?
 Describe the actions, adverse effects and clinical uses of the mixed-acting sympathomimetic agonists?
 Describe the actions of the catecholamines on organ systems (including selectivity for specific adrenoceptors),
their clinical uses and adverse effects?
 Describe the mechanisms of action of non-catecholamine adrenoceptor agonist drug classes with drug examples,
their clinical uses and adverse effects?

Did you...
 Complete The Attendance Register?

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 Resources

Osmosis videos:
Sympathomimetics: direct agonists
Sympatholytics: alpha-2 agonists

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 References

Brenner & Stevens’ Pharmacology. 2023. Chapter 8 Sympathetic neuropharmacology and adrenergic agonists.
Page 83-94.
Rang and Dale’s Pharmacology. 2024. Chapter 15 Noradrenergic transmission. Page 205-224.

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