Heart Failure 2024 Zarqa University PDF

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This document details pharmacology I, focusing on drugs used in heart failure. It covers definitions, types of heart failure, treatment, and the pathophysiology of heart failure. The document was created by Zarqa University.

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Zarqa University
Pharmacy school
Clinical Pharmacy Department

Pharmacology I

Drugs Used in Heart
Failure

Dr. Haneen Basheer
Dr. Shorouk Ibraheem

1ST semester 2023/2024
The normal blood cycle
 Definitions
Heart failure (HF) is a progressive clinical syndrome
that can result from any changes in cardiac structure or
function that impair the ability of the ventricle to fill
with or eject blood.
Heart failure (HF) is a complex, progressive disorder in
which the heart is unable to pump sufficient blood to
meet the needs of the body.(Unable to provide the
oxygen level needed to the body)
HF may be caused by an abnormality in systolic
function, diastolic function, or both.
The leading causes of HF are coronary artery disease
and hypertension.
The primary manifestations of the syndrome are
dyspnea, fatigue, and fluid retention.
 Heart Failure can be classified into:
High-output heart (physiological): is an
increase in the body’s metabolic demands that
rises an increase in cardiac output (CO) of a
generally normally functioning heart.

low-output heart (pathological): low CO
secondary to impaired cardiac function.

The term heart failure refers to low-output HF.

4
 Types of HF
1. Heart failure with reduced ejection fraction. (HFrEF)
2. Heart Failure with preserved ejection fraction. (HFpEF)
Cases are due to a reduction of cardiac contractile force and
ejection fraction (systolic failure) (ie, reduced left ventricular
ejection fraction [LVEF]), now referred to as heart failure with
reduced ejection fraction (HFrEF), was previously thought to be the
sole disturbance in cardiac function responsible for HF.
Other cases: changes of the ventricles that prevent adequate filling
during diastole; ejection fraction may be normal (diastolic failure)
- Many patients with HF syndrome have relatively normal systolic
function (ie, normal LVEF). This is now referred to as HF with
preserved LVEF (HFpEF).
The remainder of cases can be attributed to a combination of
systolic and diastolic dysfunction.
 Cont
Historically, this disorder was commonly
referred to as congestive HF; the preferred
nomenclature is now HF since a patient may
have the clinical syndrome of HF without
having symptoms of congestion.
 Acute heart failure
The term acute heart failure (AHF) is used to
signify either an acute decompensation of a
patient with a history of chronic HF or to refer
to a patient presenting with new-onset HF
symptoms.
Complications of heart failure, particularly
acute heart failure, include respiratory and/or
renal failure.
 Pathophysiology of HF
The primary signs & symptoms of all types of HF include:

- Tachycardia. Why?
- Decreased exercise tolerance.
- Shortness of breath.
- Cardiomegaly.
- Peripheral & pulmonary edema (the congestion of congestive heart
failure) are often but not always present.

 Decreased exercise tolerance with rapid muscular fatigue is the
major direct consequence of diminished cardiac output.

 The other manifestations result from the attempts by the body to
compensate for the intrinsic cardiac defect.
The homeostatic responses to depressed cardiac output are
extremely important and are mediated mainly by the sympathetic
nervous system and the renin-angiotensin-aldosterone system.
 The result is a vicious cycle that is characteristic of heart failure.

Apoptosis is a later response,and results in a reduction in the number of functioning
myocytes
 Goals of Treatment:
1) Reducing symptoms & slowing progression as much as possible
during relatively stable periods

2) Managing acute episodes of decompensated failure.
 HF drugs

ARB, ARNI

hydralazine and isosorbide dinitrate Chronic

NA glucose cotransporter
inhibitors / What are the
approved drugs/
 Treatment
Considerable evidence indicates that renin-
angiotensin system (RAS), certain β-
adrenoceptor blockers, and the aldosterone
antagonists spironolactone and eplerenone, a
sodium-glucose cotransporter 2 (SGLT2)
inhibitor have long-term beneficial effects.
 Chronic failure

Pharmacologic therapies for heart failure include:
1. the removal of retained salt and water with diuretics (loop is most required)
2. reduction of afterload and salt and water retention by means Renin-angiotensin
System Inhibitors (ACEI,ARB, ARNI angiotensin receptor-neprilysin inhibitor)
3. reduction of excessive sympathetic stimulation by means of β blockers
4. reduction of preload or afterload with vasodilators (hydralazine and isosorbide
dinitrate )
5. a sodium-glucose cotransporter 2 (SGLT2) inhibitor: give SGLT2 inhibitors to
patients with symptomatic chronic HFrEF to decrease cardiovascular mortality
and hospitalization for heart failure irrespective of the presence of type 2
diabetes
6. Mineralocorticoid receptor antagonist (MRA) if estimated glomerular filtration
rate (eGFR) is > 30 mL/min/1.73 m2 and serum potassium is < 5 mEq/L
7. In systolic failure, direct augmentation of depressed cardiac contractility with
positive inotropic drugs such as digitalis glycosides.
 Acute Failure
Current clinical evidence suggests that acute
heart failure should be treated with a loop
diuretic; if severe, a prompt-acting positive
inotropic agent such as a
β agonist or phosphodiesterase
inhibitor, and vasodilators should be used as
required to optimize filling pressures and blood
pressure.
Nesiritide, a recombinant form of brain
natriuretic peptide (BNP), has vasodilating and
diuretic properties and has been heavily
promoted for use in acute failure.
 Drugs without positive inotropic
effect
First-line therapies for chronic heart failure

Are directed at non-cardiac targets is more
valuable in the long-term treatment of HF than
traditional positive inotropic agents
 Inhibitor of the renin-angiotensin
system (RAS)
These agents have been shown to reduce morbidity and
mortality in chronic heart failure.
Although they have no direct positive inotropic action,
angiotensin antagonists reduce aldosterone secretion, salt
and water retention, and vascular resistance
1ST line IF show NO signs or symptoms of volume overload
(edema)
ACE inhibitors may be used in combination with diuretics, β-
blockers, digoxin, and aldosterone antagonists.
Patients with recent myocardial infarction also benefit from
ACEI.
It is recommended that ACE inhibitors be initiated
immediately after myocardial infarction
 ARNI
modulation of the natriuretic peptide system is inhibition of the
neutral endopeptidase enzyme, neprilysin, which is
responsible for the degradation of BNP and atrial natriuretic
peptide (ANP), as well as angiotensin II, bradykinin, and other
peptides.
Sacubitril is a prodrug that is metabolized to an active
neprilysin inhibitor plus an ARB. A combination of valsartan plus
sacubitril has recently been approved for use in HFrEF.
 Diuretics
Are the first-line therapy for both systolic and diastolic failure and are used
in heart failure before digitalis and other drugs are considered*. (if
symptoms of fluid retention present)
Reduce the symptoms of volume overload, including orthopnea and paroxysmal
nocturnal dyspnea.
Decrease preload and afterload**.
Furosemide is a very useful agent for immediate reduction of the
pulmonary congestion and severe edema associated with acute heart
failure and for moderate or severe chronic failure.
Thiazides such as hydrochlorothiazide are sometimes sufficient for mild
chronic failure.
Clinical studies suggest that, unlike other diuretics, spironolactone and
eplerenone (aldosterone antagonist diuretics) have significant long-term
benefits and can reduce mortality in chronic failure.
 Beta-Adrenoceptor Antagonists
Beta blockers (carvedilol, bisoprolol, ER metoprolol
succinate, (Chapter 10) have been shown in long-term
studies to slow progression of chronic heart failure.
The benefit is recognized in patients with hypertrophic
cardiomyopathy but has also been shown to occur in patients
without cardiomyopathy.
Beta blockers are of no value in acute failure and may be
detrimental if systolic dysfunction is marked
β-Blockade is recommended for all patients with heart disease
except those who are at high risk but have no symptoms and those
who are in acute HF.
 Vasodilator
Chronic heart failure sometimes responds
favorably to oral vasodilators such as
hydralazine or isosorbide dinitrate (or both)
this combination has been shown to reduce
mortality due to heart failure in African
Americans.
If the patient is intolerant of ACE inhibitors or β-
blockers, or if additional vasodilator response is
required
Calcium channel blockers (eg, verapamil) are
of no value in heart failure.
 Digitalis
Is the genus name for the family of plants that provide most of the
medically useful cardiac glycosides , e.g, digoxin (prototype).

All of the cardiac glycosides combine a steroid nucleus linked to a
lactone ring at the 17 position and a series of sugars at carbon 3 of the
nucleus.

Because they lack an easily ionisable group, their solubility is not pH-
dependent.

Common Foxglove
 Pharmacokinetics
- Digoxin, the only cardiac glycoside used in the USA.

- is 65–80% absorbed after oral administration.

- Absorption of other glycosides varies from zero to nearly 100%.

- Once present in the blood, all cardiac glycosides are widely distributed to tissues,
including the CNS.

- Digoxin is not extensively metabolized in humans.

- Almost 2/3 is excreted unchanged by the kidneys.

- Its renal clearance is proportional to creatinine clearance.

- Half-life is 36–40 h in patients with normal renal function.

- Need to adjust digoxin dosage in patients with renal impairment.
 Pharmacodynamics – MECHANISM OF ACTION
At the molecular level, all therapeutically useful cardiac glycosides inhibit
Na+/K+ - ATPase, the membrane-bound transporter often called the
sodium pump.

This inhibitory action is largely responsible for the therapeutic effect
(Positive Inotropy) as well as a major portion of the toxicity of digitalis.
harmacodynamics – SYSTEM ORGAN EFFECT
A. Cardiac Effects
1. Mechanical effects:
Cardiac glycosides increase contraction of the cardiac sarcomere by
increasing the free [Ca+2] in the vicinity of the contractile proteins during
systole.
The increase in [Ca+2] is the result of a two-step process:
1) an increase of intracellular [Na+] because of Na+/K+-ATPase inhibition
2) a relative reduction of calcium expulsion from the cell by the Na+/
Ca+2Exchanger caused by the increase in intracellular Na+.

The increased cytoplasmic Ca+2 is sequestered by SERCA in the SR for
later release.

The net result of the action of therapeutic concentrations of a
cardiac glycoside is a distinctive increase in cardiac
contractility. +ve inotropic effect.
 The increase in contractility evoked by digitalis results in
increased ventricular ejection, decreased end-systolic
and end-diastolic size, increased cardiac output, and
increased renal perfusion
Decrease in the compensatory sympathetic and renal
responses previously described.
Reduced heart rate, preload, and afterload permit the
heart to function more efficiently
2. Electrical effects:
The effects of digitalis on the electrical properties of the heart are a mixture of
direct & autonomic actions:

Direct actions on the membranes of cardiac cells follow a well-
defined progression: an early, brief prolongation of the action potential,
followed by shortening (especially the plateau phase).

 The decrease in action potential duration is probably the result of increased
K+ conductance that is caused by increased intracellular Ca+2. All these effects
can be observed at therapeutic concentrations in the absence of overt toxicity.
- At higher concentrations, resting membrane potential is reduced (made
less negative) as a result of inhibition of the sodium pump and reduced
intracellular potassium. As toxicity progresses, oscillatory depolarizing
afterpotentials appear following normally evoked action potentials.
-The afterpotentials (also known as delayed after-depolarizations, DADs)
are associated with overloading of the intracellular Ca+2 stores and
oscillations in the free intracellular [Ca+2].
-When afterpotentials reach threshold, they elicit action potentials (premature
depolarizations, ectopic “beats”) that are coupled to the preceding normal
action potentials.
- If afterpotentials in the Purkinje conducting system regularly reach
threshold in this way, bigeminy will be recorded on the ECG.
With further intoxication, each after potential-evoked action
potential will itself elicit a suprathreshold after-potential, and a
self-sustaining tachycardia will be established.
If allowed to progress, such a tachycardia may deteriorate
into fibrillation; in the case of ventricular fibrillation, the
arrhythmia will be rapidly fatal unless corrected.
Autonomic actions of cardiac glycosides on the heart
involve both the parasympathetic & the sympathetic
systems:
In the lower portion of the dose range, cardioselective
parasympathomimetic effects predominate. In fact, these
atropine-blockable effects account for a significant portion of
the early electrical effects of digitalis
 This action involves sensitization of the baroreceptors,
central vagal stimulation, and facilitation of muscarinic
transmission at the cardiac muscle cell.
Because cholinergic innervation is much richer in the atria,
these actions affect atrial and atrioventricular nodal function
more than Purkinje or ventricular function.
Some of the cholinomimetic effects are useful in the
treatment of certain arrhythmias.
 At toxic levels, sympathetic outflow is
increased by digitalis.
This effect is not essential for typical digitalis
toxicity but sensitizes the myocardium &
exaggerates all the toxic effects of the drug.
The most common cardiac manifestations of
digitalis toxicity include AV junctional rhythm,
premature ventricular depolarizations,
bigeminal rhythm, & second-degree AV
blockade. However, it is claimed that digitalis
can cause virtually any arrhythmia.
B. Effects on Other Organs
Cardiac glycosides affect all excitable tissues, including
smooth muscle & the CNS.

The GIT is the most common site of digitalis toxicity outside the
heart.
effects include anorexia, nausea, vomiting, & diarrhea. 

This toxicity is caused in part by direct effects on the GIT & in
part by CNS actions.

CNS effects include vagal & chemoreceptor trigger zone
stimulation. Less often, disorientation and hallucinations—
especially in the elderly—and visual disturbances are noted.

- Gynecomastia is a rare effect reported in men taking digitalis.
C. Interactions with K+, Ca+2, and Mg+2
K+ & digitalis interact in two ways:

1. They inhibit each other’s binding to Na+/K+ -ATPase; therefore,
hyperkalemia reduces the actions of cardiac glycosides, whereas
hypokalemia facilitates these actions.

2. Abnormal cardiac automaticity is inhibited by hyperkalemia 
Moderately increased extracellular K+ therefore reduces the effects of
digitalis, especially the toxic effects.

Ca+2 facilitates the toxic actions of cardiac glycosides by accelerating the
overloading of intracellular Ca+2 stores that appears to be responsible for
digitalis-induced abnormal automaticity. Hypercalcemia therefore
increases the risk of a digitalis-induced arrhythmia.

The effects of Mg+2 ion are opposite to those of Ca+2. These interactions
mandate careful evaluation of serum electrolytes in patients with digitalis-
induced arrhythmias.
Digitalis toxicity, especially arrhythmogenesis, is increased by hypokalemia,
 Clinical indication of digoxin
Digoxin is indicated in patients with heart failure and atrial
fibrillation.
It is usually given only when diuretics and ACE inhibitors
have failed to control symptoms.
Only about 50% of patients with when symptoms are mild,
slow loading (digitalization) with 0.125–0.25 mg/d is safer and
just as effective as the rapid method (0.5–0.75 mg every 8
hours for three doses, followed by 0.125–0.25 mg/d).
Contraindication: Ventricular fibrillation
 Case
Digoxin has a narrow therapeutic window, and its dosing must be
carefully managed.
The drug’s minimum effective concentration is about 1 ng/mL.
About 60% is excreted in the urine; the rest is metabolized in the
liver.
The normal clearance of digoxin is 7 L/h/70 kg; volume of
distribution is 500 L/70 kg; and bioavailability is 70%.

If your 70-kg patient’s renal function is only 30% of normal, what
daily oral maintenance dosage should be used to achieve a safe
plasma concentration of 1 ng/mL?
 Ivabradine
MOA: selective If sodium channel
blockers (eg, ivabradine), reduce cardiac rate by inhibiting the
hyperpolarization-activated sodium channel in the sinoatrial node.

Consider using ivabradine in symptomatic patients with :
HFrEF, in sinus rhythm, ejection fraction ≤ 35% and heart rate ≥ 70
beats/minute who are either intolerant of, or on maximally tolerated beta
blockers (presistant tachycardia)

Contraindications:
Clinically significant hypotension
Clinically significant bradycardia
Statin