CV Pharmacology Lecture Notes PDF

Summary

These lecture notes cover the pathophysiology of hypertension, mechanisms of action, and classification of antihypertensive drugs, including beta-blockers. They also discuss the role of various drugs in treating hypertension and related cardiovascular conditions.

Full Transcript

Learning Objectives

An appreciation of the pathophysiology of hypertension
An understanding of the mechanism of action
Classification
Drug drug interactions
For the class of beta blocking agents
 Physiological Compensatory Mechanisms
that Counteract Decreased Blood Pressure

Brody’s Human Pharmacology 2025
Hypertension and its Complications

Laffan & Bakris in Opie’s Cardiovascular Drugs 9th Edition Elsevier 2021
 Hypertension
The level of blood pressure above which the
benefits of treatment (either with lifestyle
interventions or drugs) unequivocally outweigh
the risks of treatment, as documented by
clinical trials
Present in 60% of patients over 60 years of age

ESC Guidelines for Hypertension Williams et al, EHJ 2018; 39: 3021-204
Hypertension

Netter’s Illustrated Pharmacology
 Hypertension
Understand the mechanism of action of drugs used to treat
hypertension
Know the side effects of those medications
Know which patients should be treated, and when treatment should
be initiated
Know which drugs are most effective in treating individual patients
with specific comorbidities
Know which drugs can be used in combination
Know how to set, and measure, treatment goals in hypertension

Rollins and Blumenthal. Workbook and casebook for Goodman and Gilman 2016
 TREATMENT OF ESSENTIAL HYPERTENSION:
1930 Drug or Method Used
Animasa Mistletoe
Benzyl Benzoate “Natheim” Bath
Benzyl Succinate Nitroscleran
Calcium Diuretin Potassium Sulphocyanate
Calcium Salts and low Protein Diet Radiation to the Skull
Corpus Luteum Radium Water
Desecin Subtonin
Diathermy Sodium Sulphocyanate
Irradiation of the Suprarenal Region Theominal
Liver Extract Thyroid and Potassium
Lumbar Sympathectomy Permanganate
Luminal Ayman, JAMA 1930; 95:246. Watermelon Extract
 Development of
Antihypertensive Therapies
Effective but poorly As effective and As effective and even better
tolerated better tolerated tolerated
1940’s 1950 1957 1960’s 1970’s 1980’s 1990’s 2001 2007 2024

Direct ACE ARBs DRIs ?
vasodilators inhibitors
Others
Ganglion Thiazides a-blockers
blockers diuretics
Central a2 agonists
Peripheral Calcium antagonists
sympatholytics Calcium antagonists (DHPs)
Veratrum (Verapamil)
alkaloids
b-blockers
 Classes of Antihypertensive Agents
Volume reduction (various diuretics)
Renin-angiotensin-aldosterone system inhibition
(angiotensin-converting enzyme [ACE] inhibitors,
angiotensin-receptor blockers [ARBs] mineralocorticoid
receptor antagonists [MRA])
Sympathetic nervous system (SNS) inhibition (α-blockers,
β-blockers, sympatholytics)
Vasodilation (calcium channel blockers [CCBs], direct
arterial vasodilators)
Sites and Mechanisms of action of
antihypertensive drugs

Brody’s Human Pharmacology 2025
 Drugs to be preferred in specific conditions
Condition Drug Condition Drug

Asymptomatic organ damage Clinical CV event (continued)

LVH ACE-I, CCB, ARB Aortic aneurysm BB

Asymptomatic CCB, ACE-I Atrial fib, prevention Consider ARB, ACE-I, BB, MRA
CAD
Atrial fib, rate control BB, non-dihydro CCB
Microalbuminuria ACE-I, ARB
ESRD/proteinuria ACE-I, ARB
Renal ACE-I, ARB
dysfunction Peripheral art disease ACE-I, CCB
Clinical CV event
Other
Previous stroke Any agent effectively lowering BP
ISH (elderly) Diuretic, CCB
Previous MI BB, ACE-I, ARB
Metabolic syndrome ACE-I, ARB, CCB
Angina pectoris BB, CCB
Diabetes ACE-I, ARB
Heart failure Diuretic, BB, ACE-I, MRA
Pregnancy Methyldopa, BB, CCB
Eur Heart J. 2013;34(28):2159-2219.
Compelling and possible contra-indications
to the use of antihypertensive drugs
Drug Contraindications
Compelling Possible
Diuretics Gout Metabolic syndrome, Glucose
intolerance, Pregnancy, ↑ Ca++ ↓ K+
Beta blockers Asthma, High degree SA or AV block, Metabolic synd, Glucose intol,
Bradycardia athletes & physically active pts
CCB Dihydroperidines Tachyarrhythmia, HFrEF, oedema
CCB Non- High degree SA or AV block, Bradycardia, Constipation
dihydroperidines Severe LV dysfunction
ACE-inhibitors Pregnancy, Previous Angioneurotic Oedema, Women of childbearing potential
Hyperkalaemia, bilat Renal Artery stenosis without reliable contraception
ARBs Pregnancy, Hyperkalaemia, bilat Renal Artery Women of childbearing potential
stenosis without reliable contraception

ESC Guidelines for Hypertension Williams et al, EHJ 2018; 39: 3021-204
Evolution from Hypertension to Heart Failure

Gallo and Savoia Int J Molecular Sciences 2024; 25:6661
BIHS ACD Approach to hypertension
β-Blockers
 Sympathetic and
Parasympathetic Innervation

Noradrenaline

Adrenergic
Receptor

Sympathetic
Activation

Rang et al. Pharmacology 2003
 β1 Adrenoreceptor
Increases heart rate
Increases cardiac contractility
Renin release
 β2 Adrenoreceptor
B 2 agonist

Arteriole: dilatation
Bronchial muscle: dilatation
Gastrointestinal tract: relaxation
Uterus: relaxation
Pancreas: insulin release
Liver: hyperglycemia
 History of β-blocker Development

Dr. James Black joined ICI
Pharmaceuticals in 1958 to
develop a drug for the
treatment of angina.
Foundations:
Angina could be precipitated by psychic stress or injection of adrenaline.
Partial thyroidectomy may improve severe angina.
Myocardial oxygen demand is determined by myocardial work and is
dependent on the product of heart rate and blood pressure.

James Black, Drugs from emasculated hormones. Science 1989; 245:486
 History of β-blocker Development
The effects of adrenaline were thought to be mediated by
at least two receptor types, α and β (Langley, Daley and
Ahlquist).
Vasoconstrictive effects could be blocked by some drugs
(antagonist defined α receptor effects).
Tachycardia and contractility could be stimulated by isoprenaline
(agonist defined β receptor effects).
Led to the search for a β receptor antagonist.
Pronethanol was first compound (caused cancer in rats)
Propranolol was first clinically viable drug (1965)

James Black, Drugs from emasculated hormones. Science 1989; 245:486
History of β-blocker Development
CONTROL
PRONETHALOL

extend out to 8 minutes

James Black, Drugs from emasculated hormones. Science 1989; 245:486
 β Blockers: resting vs activated
The effects of beta blockade are mild when
someone is at rest, because adrenergic tone is
low.
When the sympathetic nervous system is
activated, e.g. with exercise, the effects of beta-
blockade are much more obvious and significant.
 β-Adrenergic Antagonists

Maximal exercise capacity is reduced
Chronotropic incompetence
Reduced β-mediated skeletal muscle
vasodilatation
Mild reduction in coronary flow
Greater reduction in myocardial oxygen utilization
 Effect of β-Blockers during Exercise
Heart Rate Cardiac Output Arterial Pressure

No Propranolol Propranolol
 β1 vs β2 Selectivity
Beta 1 receptors predominate
in the heart, and stimulation
of these receptors leads to an
increase in HR,
} β1

atrioventricular (AV)
conduction, and contractility;
release of renin from
juxtaglomerular cells in the
kidneys; and lipolysis in
} β2

adipocytes.
Beta 2 stimulation causes
bronchodilation, vasodilation,
and glycogenolysis } β1 + β2

oden in Opie’s Cardiovascular Drugs 9th Edition Elsevier 2021
Morrow and De Lemos Braunwald’s Textbook of CV Disease 2019
Occupation of β1 vs β2 Receptors
by Bisoprolol in the Rat

Brodde Rev Contemp Pharmacotherap 1997; 8:21-33
β1:β2 Selectivity Ratios in Ligand Binding
Studies

Wellstein et al. J Cardiovasc Pharmacol 1986; 8(Suppl) S36-40
 Nebivolol x 3.5 times
more β1 selective than
bisoprolol
Nebivolol increases
NO (probably via β3)
Carvedilol is an
antagonist for β1 β2
and a1 receptors

Page & Clive, Integrated Pharmacology, 2006 Chapter 13, 371-434
Veira & Mehra: Opie’s Cardiovascular Drugs 9th Edition Elsevier 2021
Advantages of Cardio-selective β Blockers
In airways disease
In diabetes mellitus
In peripheral vascular disease
 Benefits of non-selective β blockers
Treatment of portal hypertensive bleeding (oesophageal
varices)
Only non-selective β -blockers have been shown to have benefit
Inhibition of β 2-induced splanchnic arterial vasodilation
decreases portal venous flow and portal hypertension
Treatment of tremor
β -blockers commonly prescribed for treatment of bothersome
benign essential tremor
Only non-selective β -blockers have been effective for this
Vascular headache prophylaxis (migraines and cluster
headaches)
Conventional wisdom is that propranolol more effective than more
selective and less lipophilic β -blockers
 β-blocker Characteristics
Intrinsic Sympathomimetic Activity (ISA)
Partial beta-agonists that also produce blockade by
shielding beta receptors from more potent beta-agonists.
Resting heart rate is not as affected (reduced).
Blood pressure lowering effects are relatively preserved
Drugs with ISA may not be as beneficial in treating
myocardial ischaemia or in improving post-MI survival.
Opie and Gersh 7th Edition, 2009
Morrow and De Lemos Braunwald’s Textbook of CV Disease 2019
Intrinsic Sympathomimetic Activity
 Reduced Benefit of β-
blockers with ISA post MI

Yusuf et al. Prog Cardiovasc Dis 1985; 27:335-71
 Route of Elimination

Lipid Water
Soluble Soluble

Boden: Opie’s Cardiovascular Drugs 9th Edition Elsevier 2021
 Lipid-soluble β-blockers
Lipophilic drugs (metoprolol, propranolol, timolol) are rapidly
and completely absorbed from the gastrointestinal tract but
are extensively metabolised in the gut wall and in the liver
(first pass effect), so that their oral bioavailability is low (10–
30%).
May accumulate in patients with reduced hepatic blood flow
(e.g., elderly, CHF, liver cirrhosis)
Lipophilic drugs have short elimination half-lives (1-5 hours)
Easily enter the central nervous system (CNS) and may
lead to lethargy, depression and hallucinations across barrier
blood brain

Task Force on Beta-Blockers of the European Society of Cardiology Eur Heart J 2004; 25:1341–62
 Water-soluble β-blockers
Hydrophilic drugs (atenolol) are excreted unchanged or as
active metabolites by the kidney.
They have longer half-lives (6–24 h)
Do not interact with liver-metabolised drugs.
They barely cross the blood–brain barrier.
Elimination half-life is increased when glomerular filtration rate is
reduced (e.g, elderly, renal insufficiency).
In patients with renal or liver disease, the simpler
pharmacokinetic patterns of lipid-insoluble agents make dosage
easier
Task Force on Beta-Blockers of the European Society of Cardiology Eur Heart J 2004; 25:1341–62
Opie and Gersh 8th Edition, 2012
 β-blocker Characteristics
Half Life -> useful for titration

Esmolol shortest at 9 minutes (© brevibloc)
Combined
Labetalol combined blockade of β1 and β2 with a1 with a
ratio of 1:3 = a1: β when administered orally
Anti-arrhythmic activities
All β-blockers
Sotalol
Racemic mixture of β blocker and a class III antiarrhythmic
Boden: Opie’s Cardiovascular Drugs 9th Edition Elsevier 2021
 Clinical Uses of β-Blockers
Cardiovascular Other
Angina Hyperthyroidism
Myocardial Infarction Phaeochromocytoma
Arrhythmias Portal Hypertensive Bleeding
Hypertrophic-Cardiomyopathy Glaucoma
Hypertension Tremor
Alcohol withdrawal syndrome
Prophylaxis of migraine
 β-Blockers in Ischaemic Heart Disease
Decrease myocardial oxygen demand
by reducing the double product of heart
rate and blood pressure (afterload) and
by limiting exercise induced increases
in contractility
Proven to improve survival and reduce
reinfarction rate after MI (both by reducing
oxygen demand, and perhaps by
antiarrhythmic effects) – indicated in acute
ischaemia
Opie & Gersh Drugs for the Heart 8th Edition Elsevier 2013
β-Blockers in Ischaemic Heart Disease
↓ myocardial O2 consumption
↑ coronary blood flow
↑ diastolic perfusion time
Improve supply/demand ratio
Reduce mortality in first year
post MI
Improve O2 dissociation from
haemoglobin

Opie & Gersh Drugs for the Heart 8th Edition Elsevier 2013
in Morrow and De Lemos Braunwald’s Textbook of CV Disease 2019
 Candidates for use of Beta Blocking
Agents for Angina
Ideal Candidates Poor Candidates

Prominent relationship of physical activity to attacks Asthma or reversible airway component in patients
of angina with chronic lung disease
Co-existant hypertension Severe LV dysfunction with severe heart failure
symptoms
History of supraventricular tachycardia History of severe depression

Previous MI Raynaud phenomenon

LV Systolic dysfunction Symptomatic peripheral arterial disease

Mild to moderate heart failure symptoms Severe bradycardia or heart block

Prominent anxiety state Diabetes with frequent hypo-glycaemic episodes

Morrow and De Lemos Braunwald’s Textbook of CV Disease 2019
 Proposed MOA of β Blockers in the
treatment of Hypertension
1. Reduction in cardiac output
2. Central nervous system effect
3. Inhibition of renin secretion (and possibly other steps in the renin-
angiotensin-aldosterone cascade)
4. Reduction in plasma volume
5. Reduction in vasomotor tone
6. Reduction in peripheral vascular resistance
7. Improvement in vascular compliance
8. Resetting of baroreceptor levels
9. Effects on prejunctional β-receptors: reduction in norepinephrine release
10. Attenuation of pressor response to catecholamines with exercise and stress

Carlberg et al Hypertension a Companion to Braunwald Elsevier 2013
 Effects of reduction in systolic BP
stratified by class of antihypertensive

Ettehad et al. Lancet 2016; 387:957-67
 β Blockers in the treatment of
Hypertension
No longer considered first line therapy for hypertension
Other agents have better outcome data
Increased development of diabetes

β Blocker

β Blocker
 β-blockade in CHF
dont give a beta blocker if they are in uncompensated Heart failure! stabilise it using it diuretics first
Counterintuitive BUT they work!
Mechanisms unkown but perhaps
Improved β-adrenergic signaling
Protection from catecholamine myocyte toxicity
Avoids hyperphosphorylation of the ryanodine receptor
Antiarrhythmic effects
Bradycardia
Anti-apoptosis
Renin-angiotensin antagonism

Opie Drugs for the Heart 8th Edition Elsevier 2012
 β-blockade in CHF

Hoste, AM, Glaucoma Volume 1: Medical Diagnosis & Therapy, 2009 525-537
 its better to survive than to not

Effect of beta blockade on mortality in heart failure
Metoprolol Bisoprolol Carvedilol

Braunwald’s Heart Disease
 Adverse Reactions to β Blockers
Fatigue (potentially aggravated by β2 blockade)
Bradycardia
Cold peripheries (vasoconstriction via β2 blockade may worsen the
situation)
Aggravation of heart failure
Rare cases of symptomatic hypotension
Bronchospasm in patients with reversible, labile, reactive airways
disease
Depression and sleep disturbance

Cruikshank, The Modern Role of Beta-blockers in Cardiovascular Medicine 2011
 Withdrawal of β Blockers
Sudden withdrawal of beta-adrenoceptor
antagonists may result in severe exacerbation of
angina pectoris, acute myocardial infarction,
sudden death, malignant tachycardia, sweating,
palpitation, and tremor
These are consistent with transient adrenergic
hypersensitivity.
Meylers Side Effects of Drugs 2016
 Withdrawal of β Blockers
More apparent after drug withdrawal in patients
with ischaemic heart disease than hypertension
Hypersensitivity from 2-6 days post withdrawal
The density of beta-adrenoceptors on human
lymphocyte membranes increased by 40%
during treatment with propranolol for 8 days
Withdrawal should be accomplished by gradual
dosage reduction over 10–14 days
Meylers Side Effects of Drugs 2016
Royster et al Kaplans Cardiovascular Anaesthesia 2024
 Adverse Effects of β-adrenergic
Antagonists
Hypoglycaemia
Mask response to hypoglycaemia in diabetes mellitus

Adverse Lipid Profile

Rang et al. Pharmacology 2003
 Compensatory Mechanisms limiting the
response to antihypertensive agents
Class BP Compensatory mechanism
Alpha1 antagonists Salt/water retention; tachycardia
Alpha 2 agonists Salt/water retention
CCBs (especially short acting) Tachycardia
Direct vasodilators Salt/water retention; tachycardia
(hydralazine, minoxidil)
Diuretics Salt/water retention

American Heart Association
European Core Drug Treatment for
Uncomplicated Hypertension

ESC Guidelines for Hypertension Williams et al, EHJ 2018; 39: 3021-204
 Possible combinations of classes of
antihypertensive drugs
Useful combinations Preferred

Possible combinations Not Recommended
Modified from Eur Heart J. 2013;34(28):2159-2219. doi:10.1093/eurheartj/eht151