Antiadrenergics Lecture Notes PDF

Summary

This document provides detailed information on antiadrenergics. It covers various aspects of adrenergic antagonists, including their mechanisms of action, pharmacologic effects, and therapeutic uses. The document also discusses drug interactions and adverse effects.

Full Transcript

Antiadrenergics

Pranaya Mishra PhD
[email protected]

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Learning Objectives
• Describe the receptor affinities for various adrenergic
antagonists.
• Explain the mechanism of action of nonselective and selective αadrenergic antagonists.
• Explain the mechanism of action of nonselective and selective βadrenergic antagonists.
• Explain the mechanism of action of indirect-acting
antiadrenergic drugs.
• Describe the pharmacologic effects of nonselective and selective
α-adrenergic antagonists.
• Describe the pharmacologic effects of nonselective and selective
β-adrenergic antagonists.
• Relate the effects of adrenergic antagonists to the blockade of
specific receptors.

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Learning Objectives
• Describe the significant pharmacokinetic features of αadrenergic and β-adrenergic antagonists.
• Describe the main adverse effects of α-adrenergic and βadrenergic antagonists.
• Describe the main drug interactions between adrenergic
antagonists and other autonomic drugs.
• Outline the main contraindications of α-adrenergic and βadrenergic antagonists.
• Describe the main therapeutic uses of α-adrenergic antagonists.
• Describe the main therapeutic uses of β-adrenergic antagonists.

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Diseases Treated with Autonomic
Drugs
• Hypertension
• Ophthalmic hyperemia
• Hypotension
• Shock
• Heart failure
• Angina
• Arrhythmias
• Pheochromocytoma
• Benign prostatic
hyperplasia
• Nasal congestion

(red eyes)
• Myasthenia Gravis
• Urinary retention
• Urinary incontinence
• Glaucoma
• Asthma
• COPD
• Dry mouth
• Sialorrhea
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This list is not comprehensive; however, many of the most common uses are listed.

Adrenergic blockers

α blockers

Irreversible
e.g., Phenoxybenzamine

ß blockers

Reversible

Non-selective
e.g., Phentolamine

Selective

α1 blockers
e.g., Prazosin,
Terazosin,
Doxazosin,
Tamsulosin

α2 blockers
e.g., Yohimbine

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ß-blockers

Non-selective
(ß1 +ß2 blockers)
1. without intrinsic
sympathomimetic activity
e.g., Propranolol, Timolol,
Sotalol, Nadolol
2. with intrinsic
sympathomimetic activity
e.g., Acebutolol, Pindolol

Selective

ß1-selective
(cardioselective)
e.g., Atenolol,
Acebutolol, Esmolol,
Metoprolol

ß2-selective
e.g., Butoxamine

3. with additional α-blocking
property
e.g, Labetalol, Carvedilol

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α blockers

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α blockers
GENERAL EFFECTS OF α BLOCKADE on CVS:
•
•
•
•

blockade of vasoconstriction – TPR - hypotension
cause reflex tachycardia (due to fall of BP)
postural reflex is interfered – postural hypotension
Dale’s vasomotor reversal (Epinephrine reversal)

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Other Actions of α blockade
• relaxation of trigone & spinchter muscles in the base
of urinary bladder and prostate
-------> decrease resistance to urinary outflow
• nasal stuffiness and miosis
• increase intestinal motility
--------> diarrhea
• failure of ejaculation (impotence)
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Nonselective α blocker (antagonists)
Phenoxybenzamine :
• non-selective, irreversible α1 and α2 blocker
• Actions - prevents vasoconstriction
- causes reflex tachycardia
• Selectively used in Pheochromocytoma (prior to
surgical removal, to preclude hypertensive crisis)
• Dale’s vasomotor reversal (Epinephrine reversal)

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Epinephrine reversal:
• Epinephrine, when given in high doses, increases
blood pressure (vasopressor effect) by acting on the
α1 receptors. Epinephrine has an effect on ß2
receptors also (at low doses, epinephrine stimulates
only ß2 predominantly). So, when α1 blockers are
given before epinephrine (high dose), it will not be
able to act on α1 receptor and won’t exhibit
a vasopressor effect, instead epinephrine will cause
a drop in BP (vasodepressor effect).

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α1 effect
Blood
pressure

Epinephrine in high dose

ß2 effect
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Epinephrine reversal:
"vasomotor reversal of Dale”

Blood
pressure
Epinephrine

Phenoxybenzamine

DROP in BP: Predominant
ß2 effect
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Nonselective α blocker (antagonists)
Phentolamine
• a competitive (reversible), non-selective α blocker
(both α1 and α 2 blocker)
• like phenoxybenzamine, produces postural
hypotension and causes epinephrine reversal
• also used in Pheochromocytoma (prior to surgical
removal, to preclude hypertensive crisis)
• causes reflex tachycardia, which is mediated by
baroreceptor reflex and by blocking of α2
receptors of the cardiac sympathetic nerves

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Nonselective α blocker (antagonists)
Phentolamine
Adv effects:
• can trigger arrhythmias and anginal pain
C/I:
• patients with decreased coronary perfusion

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Therapeutic uses: α blockers
– only used for the acute hypertension (in hospital;
given IV)
– opposing catecholamines actions in
Pheochromocytoma
– Raynaud’s disease
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Raynaud’s disease

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Adverse effects
• Postural hypotension
• Nasal stuffiness

• Sexual dysfunction (inhibit ejaculation)
• Tachycardia

• Contraindicated in ↓ coronary perfusion
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α1 selective blockers
• Prazosin
• Terazosin
• Doxazosin – long acting
• Tamsulosin (α1A antagonist)
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α1-selective blockers
α1 blocker
Prazosin

Duration of action
High first pass
metabolism

6 hrs

Terazosin

20 hrs

Doxazosin

30 hrs

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α1-selective blockers
Uses :
• as antihypertensive agent (Prazosin, Terazosin,
Doxazosin; Tamsulosin has least effect on BP)
• in Raynaud disease
• in benign prostatic hypertrophy (BPH): Tamsulosin is
a more potent inhibitor of α receptors found on the
smooth muscle of the prostate (α1A) --------> decrease
tone in the smooth muscle of the bladder neck and
prostate---------> improves urine flow
Silodosin - α1A selective blocker (uroselectivity),
approved by FDA in 2008 for BPH.
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Adverse effects of α1 blockers
• “First dose” effect: syncope (fainting)
(greater hypotensive effect when administered first
time)
o may be minimized by adjusting the first dose to
1/3rd or 1/4th of normal dose, and by giving the
drug at bedtime
• Orthostatic (postural) hypotension
• Headache, dizziness
• Reflex tachycardia (less compared to non-selective
blockers)
• Nasal stuffiness/congestion
• Sexual dysfunction (less with selective agents)
• Miosis
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Selective α2 blockade
• Yohimbine
o selective, competitive α2 blocker
o sexual stimulant (aphrodisiac)
o can be used in postural hypotension and sexual
impotence (but no clinical utility)
• Mirtazapine (used as antidepressant)

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α blockers
Uses :
• Pheochromocytoma
• Hypertension
• BPH

• Raynaud’s disease

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Distribution of Adrenoceptor Subtypes
Receptor
Type

α1

α2

Tissue

Action

Most vascular smooth muscle

Contraction

Pupillary dilator muscle

Contraction (mydriasis)

Prostate; urinary sphincter

Contraction

Adrenergic and cholinergic
nerve
terminals
Ciliary epithelium

Inhibits transmitter release

Pancreatic β-cells

↓ insulin secretion

Platelets

Aggregation

Fat cells

Lipolysis

Action in the
presence of
α-antagonists:
Fill in the blank
spaces.

↓aqueous humor production

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ß blockers

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ß-blockers

Non-selective
(ß1 +ß2 blockers)
1. without intrinsic
sympathomimmetic activity,
e.g., Propranolol, Timolol,
Sotalol, Nadolol
2. with intrinsic
sympathomimmetic
activity
e.g., Acebutolol, Pindolol
3. with additional α-blocking
property
e.g, Labetalol, Carvedilol

Selective

ß1-selective
(cardioselective)
e.g., Acebutolol,

ß2-selective
e.g., Butoxamine

Atenolol,
Esmolol
Metoprolol

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Propranolol
• well absorbed after oral administration
• undergo extensive first-pass metabolism
• lipophilic and enters the brain

• excreted in urine as glucuronide metabolites

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Propranolol: Pharmacological actions
1. On CVS
Heart:
• decrease force of contraction (negative inotropic)
• decrease rate of contraction (negative chronotropic)
• directly suppresses SA and AV nodal activities-------->
bradycardia
• HR, SV, CO

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Propranolol
• cardiac work
in angina)

decreased O2 consumption (useful

Blood vessels:
• blocks ß2 mediated vasodilatation

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Blood pressure
• does not decrease BP in normal individual, but
decrease BP in hypertensive patients
• decrease both, systolic and diastolic BP
• no postural hypotension occurs (as no effect on α1adrenergic receptors)

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Propranolol
2. Kidney:
• decrease renin release from kidney (ß1-action)
(very useful property in reducing compensatory
BP elevation)
• ß-blockers are often combined with a diuretic in
treatment of HTN***

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Propranolol
3. Respiratory tract: bronchoconstriction and can
precipitate bronchial asthma (ß2 action). (ß-blockers
are thus contraindicated in patients with bronchial
asthma)
• Bronchoconstriction is minimal in normal individual but can
be life threatening in patients with asthma or COPD

4. Eyes: decrease the IOT due to decreased aqueous
humor production
5. CNS: sedation, lethargy, depression, forgetfulness,
sleep disturbances (dreams and nightmares)
6. Skeletal muscle: antagonizes the epinephrineinduced tremors
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Propranolol
7. Metabolic effects:
• blocks epinephrine induced glycogenolysis (fasting
hypoglycemia)
• by decreasing insulin release (ß2-blockade), causes
hyperglycemia after meal
• Propranolol should be used with great caution in diabetics:
because propranolol blocks the sympathetic signs and
symptoms such as sweating, palpitations (tachycardia)
induced by hypoglycemia
• all ß-blockers mask tachycardia - a warning signal of
hypoglycemia
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Therapeutic Uses: Propranolol
• HTN
• Angina (except Prinzmetal’s angina)

• MI
o Prophylactic use post-MI
• Cardiac arrhythmias (Class II: Propranolol, Acebutolol,
Esmolol)
• Migraine - Prophylactically
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Therapeutic Uses: Propranolol
• Hyperthyroidism:
o may be live saving in protecting against severe cardiac
arrhythmias in acute hyperthyroidism (thyroid storm)
▪ Chance of thyroid storm increases during surgical removal of thyroid
(Prior admin of ß-blockers is desirable)

• Pheochromocytoma (along with α blockers)
• Performance anxiety
o blocks peripheral manifestations of anxiety (palpitations,
tremors)

• Essential tremors
• Glaucoma (Timolol)
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Adverse Effects
CVS
• Bradycardia
• AV block
• Abrupt discontinuation of propranolol can
precipitate angina, arrhythmia and HTN
PROPRANOLOL SHOULD BE WITHDRAWN
GRADUALLY AFTER LONG TERM USE

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Adverse Effects
Respiratory
• causes bronchoconstriction
• should not be used in asthmatic and COPD patients

Metabolic
• fasting hypoglycemia (diabetics being treated with insulin &
persons prone to hypoglycemia must use propranolol with
caution)
• increases blood lipid levels (LDLs, TGs)

Other adverse effects:
• sexual dysfunction
• fatigue and exercise intolerance

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C/I
- Asthmatics and COPD
- Diabetics

- Raynaud’s disease
- Prinzmetal angina

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Drug Interactions
1. Digitalis and Verapamil
additive depression of SA and AV node-----cardiac arrest
2. Insulin and oral hypoglycemics
aggravate hypoglycemic effects mask warning sign
(tremor and tachycardia)***
3. Indomethacin and other NSAIDs
annul antihypertensive actions of ß-blockers

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Drug Interactions
4. Cimetidine
inhibits metabolism of Propranolol
5. TIMOLOL
potent non-selective ß-blocker
reduces the production of aqueous humor in the eye
and hence used topically for the treatment of chronic
open-angle glaucoma

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6. NADOLOL: very long duration of action
Same effects and adverse effects as propranolol.

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ß1–selective Antagonists
•
•
•
•

Acebutolol
Atenolol
Esmolol
Metoprolol
They can be used in hypertensive patients with
asthma & COPD and do not cause
bronchoconstriction at therapeutic doses.
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ß1–selective Antagonists
Pharmacological actions
•
•
•
•
•
•

preferentially block ß1-receptors
decrease BP in hypertensive patients
increase exercise tolerance in angina
no bronchoconstriction effect
no effect on PR
no effect on CHO metabolism (this effect would be through ß2, so
no impact)

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ß1–selective Antagonists
Therapeutic Uses:
• HTN patients (with impaired pulmonary functions and diabetic
patients receiving insulin and other oral hypoglycemic agents)

• ANGINA
• MI

Adverse effects:
• bradycardia
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Atenolol
• Lower lipid solubility
• Less CNS entry
• Excreted unchanged in the urine
Therapeutic Uses:
• HTN***
• Angina
• MI
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Metoprolol
Orally / IV

Therapeutic Uses:
• HTN***
• Angina
• Acute MI

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Esmolol

• Shortest acting

• I.V. administration to treat acute supraventricular
tachycardia

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Antagonists with Partial Agonist
Activity (ISA)
• PINDOLOL
• ACEBUTOLOL
o
o
o
o

act as partial agonists
less bradycardia (ß1)
slight vasodilation or bronchodilation (ß2)
minimal change in plasma lipids (ß2)

Therapeutic Uses:
HTN with moderate bradycardia in DM cases

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Antagonists with Partial Agonist
Activity (ISA)
Therapeutic Uses:
• effective in hypertensive patients with moderate bradycardia
• CHO metabolism less affected than Propranolol, hence valuable
in the treatment of HTN in diabetics

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ß-blocker with K+-channel blockade
Sotalol
• Used as antiarrhythmic (Class III)

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a & b blockers
LABETALOL & CARVEDILOL
•
•
•
•

Peripheral vasodilation -- ↓ B.P
Do not alter serum lipid and glucose levels
Can be used in HTN emergency
Good point
– Does not cause reflex tachycardia

• Bad point
– Same contraindications of non-selective beta blockers

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Indirect Acting Antiadrenergic Drug
Metyrosine
Mechanism of action
• Inhibition of tyrosine hydroxylase, the rate-limiting
enzyme in catecholamine biosynthesis.

Clinical uses
• Pheochromocytoma – before surgery, or long-term
management for malignant pheochromocytoma.

Adverse effects
• orthostatic hypotension
• sedation
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Distribution of Adrenoceptor Subtypes
Rec
ept
or
Typ
e
β1

Tissue

Action

Heart

Increases force and rate
of contraction

Kidney; juxtaglomerular cells

Increases renin release

Respiratory and
uterine smooth
muscle
Eye; ciliary epithelium

Promotes smooth
muscle relaxation

Skeletal muscle

Vasodilation;
promotes potassium
uptake
Activates glycogenolysis

β2

Liver

Action in the presence of
β-antagonists
Fill in the blank spaces:

↑ aqueous humor
production

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Questions?

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THANKS!

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