Agents for Treating Heart Failure PDF

Summary

This document discusses agents for treating heart failure, a condition involving cardiac muscle dysfunction. It covers various causes, including coronary artery disease, cardiomyopathy, and hypertension. The document also covers cardiotonic agents and their actions, pharmacokinetics, contraindications, and potential adverse effects.

Full Transcript

Agents for Treating Heart Failure
Heart Failure – a condition that was once called “dropsy” or
decompensation, is a syndrome that usually involves dysfunction
of the cardiac muscle, of which the sarcomere is the basic unit.
The sarcomere* contains two contractile proteins, actin and
myosin, which are highly reactive with each other but at rest are
kept apart by the chemical troponin.
Heart Failure can result from conditions that damage or
overwork the heart muscle, this may include:
Coronary Artery Disease – reduces blood flow to the heart
muscle, causing it to become oxygen-deficient and function
poorly. If it progresses to MI or heart attack, heart muscles die,
further impairing the heart’s ability to pump blood.
Cardiomyopathy – this heart ,muscle disease can lead to an
enlarged heart and eventually complete heart failure. It can be
caused by viral infections, alcoholism, steroid abuse or collagen
disorders. This condition alters the heart muscle, making
contraction and pumping ineffective.
Hypertension – high blood pressure forces the heart to work
harder, eventually leading to enlarged heart muscle. This
increased workload can eventually cause heart failure.
Valvular Heart Disease – leads to an overload of the ventricles
because the valves do not close tightly, which allows blood to
leak backward into the ventricles.
CARDIOTONIC AGENTS
Cardiotonic drugs increase calcium levels in heart muscle,
boosting contraction strength and cardiac output. This increased
output leads to higher renal blood flow, reduced renin release,
increased urine production, and decreased blood volume. The
overall effect is reduced heart workload and felief from heart
failure.
Cardiac Glycosides
These were originally derived from the foxglove or digitalis plant.
These plants were once ground up to make digitalis leaf, today
digoxin(Lanoxin) is the drug most often used to treat heart
failure.
Actions and Indications:
Digoxin increases calcium in heart muscles, leading to stronger
contractions (positive inotropic effect) and a slower heart rate
(negative chronotropic effect). This reduces the heart’s workload.
It also increases urine output, lowering blood volume. Digoxin is
used to treat heart failure, atrial flutter, atrial fibrillation, and
paroxysmal atrial tachycardia. However, it has a narrow safety
margin, meaning the therapeutic dose is close to the toxic dose,
requiring careful monitoring.
Pharmacokinetics:
Digoxin is available in oral and parenteral administration. It has a
rapid onset of action and rapid absorption (30-120 mins when
taken orally, 5 to 30 mins in IV). Widely distributed throughout
the body, excreted unchanged in the urine. Caution for those
with renal impairment because the drug may not be excreted
and could accumulate, causing toxicity.
Contraindications and Cautions:
Contraindicated in patients with: allergy to any component of the
drug, patients with ventricular tachycardia or fibrillation
(potentially fatal heart rhythm problems), heart block or sick
sinus syndrome, idiopathic hypertrophic subaortic stenosis
(IHHS), acute MI, renal insufficiency and electrolyte
abnormalities, ex: high calcium, low potassium, low magnesium.
Digoxin should be used cautiously in pregnant or lactating
women due to potential adverse effect on fetus or neonate,
though the effect on the neonate are not fully known.
Pediatric and geriatric patients are at higher risk for adverse
effects and require close monitoring.
Adverse Effects: Adverse effects with cardiac glycosides include,
headache, weakness, drowsiness, and vision changes (yellow
halo around objects)
GI upset and anorexia commonly occurs. Arrythmias may
develop because the glycosides affect the action potential and
conduction system of the heart. The patient may also present
nausea, vomiting, malaise, depression, irregular heart rhythms
including heart block, atrial arrythmias and ventricular
tachycardia.

ANTIARRYTHMIC AGENTS
Arrhythmias are abnormal rhythms of the heart that occur when
the electrical impulses that coordinate heartbeats don't work
properly, causing the heart to beat too fast, too slow, or
irregularly.
Types of Arrhythmias
1.Tachycardia: A fast heart rate, typically over 100 beats per
minute.
1. Examples: Atrial fibrillation (AFib), ventricular tachycardia.
2.Bradycardia: A slow heart rate, typically under 60 beats per
minute.
1. Examples: Sinus bradycardia, heart block.
3.Irregular Rhythms: Variations in heart rhythm that are not
necessarily fast or slow.
1. Examples: Atrial fibrillation, premature ventricular contractions
(PVCs).
Class I Antiarrhythmics
Class 1 Antiarrhythmics are sodium-channel blockers that inhibit
the fast sodium channels in non-nodal myocardial tissues. They
are subdivided into three categories based on their speed of
dissociation from the sodium channels and electrophysiologic
effects:
These drugs are generally used to treat atrial and ventricular
arrhythmias
Pharmacokinetics:
Class IA: Quinidine and Procainamide are well absorbed orally
and have a relatively long half-life.
Class IB: Lidocaine is often administered intravenously and has
a rapid onset and short duration of action.
Class IC: Flecainide and Propafenone are also well absorbed
orally and have a longer duration of action.
Contraindications and Cautions:
Class IA: Contraindicated in patients with a history of heart block
or severe myocardial dysfunction.
Class IB: Caution in patients with severe liver disease
Class IC: Contraindicated in patients with structural heart
disease, such as a history of myocardial infarction
Adverse Effects:
Class I antiarrhythmic adverse effects: These drugs can cause a
range of side effects affecting the central nervous system (CNS),
gastrointestinal (GI) system, cardiovascular system, and
respiratory system.
CNS: Dizziness, drowsiness, fatigue, twitching, numbness,
slurred speech, vision changes, and potentially convulsions.
GI: Changes in taste, nausea, and vomiting.
Cardiovascular: Proarrhythmic effects (leading to
arrhythmias and heart blocks), hypotension (low blood
pressure), vasodilation, and potentially cardiac arrest.
Respiratory: Respiratory depression, potentially leading to
respiratory arrest.
Other: Rash, hypersensitivity reactions, hair loss, and bone
marrow depression.
Specific drug examples: Moricizine (Class Ia) and Flecainide
(Class Ic) have been linked to increased cardiac death risk
due to their proarrhythmic effects.
Class II Antiarrhythmics
Class 2 antiarrhythmics work by blocking beta-adrenergic
receptors, which inhibits the effects of norepinephrine and
epinephrine on the heart.
This results in decreased heart rate, reduced cardiac
contractility, and prolonged atrioventricular (AV) node
conduction time.
Actions and Indications:
They are commonly used to treat:
Atrial fibrillation and flutter, Supraventricular tachycardia,
Ventricular arrhythmias, Sinus tachycardia.
Pharmacokinetics:
Beta-blockers are typically well-absorbed orally, with variable
bioavailability depending on the specific drug. They undergo
hepatic metabolism and are excreted in the urine. The onset of
action varies, with some drugs like esmolol having a rapid onset
and short duration, while others like propranolol have a longer
duration of action.
Contraindications and Cautions:
Class 2 antiarrhythmics should be used with caution in patients
with: Severe bradycardia, Heart block, Severe heart failure
(unless specifically indicated), Bronchospastic diseases (e.g.,
asthma), Hypotension.
Adverse Effects:
Common adverse effects include: Bradycardia, Hypotension,
Fatigue, Dizziness, Bronchospasm, Fluid retention

Class III Antiarrhythmics
Actions and Indications:
These drugs block potassium channels and slow the outward
movement of potassium during phase 3 of the action potential,
prolonging it.
All of these drugs are proarrhythmic and have the potential of
inducing arrythmias.
Pharmacokinetics:
These drugs are well absorbed after oral administration and are
immediately available after IV administration and widely
distributed. They are metabolized in the liver and excreted in the
urine.
Contraindications and Cautions:
When these drugs are used to treat life-threatening arrythmias
for which no other drug has been effective, there are no
contraindications.
Adverse Effects:
The adverse effects associated with these drugs re related to the
changes they cause in action potentials. Nausea, vomiting, and
GI distress, weakness and dizziness; and hypotension, heart
failure and arrythmias are common. Amiodarone has been
associated with a potentially fatal liver toxicity, ocular
abnormalities and the development of very serious cardiac
arrythmias.
Class IV Antiarrhythmics
Actions and Indications:
These drugs block the movement of calcium ions across the cell
membrane, depressing the generation of action potentials and
delaying phases 1 and 2 of repolarization, which slows
automaticity and conduction.
Other Antiarrhythmics
ANTIANGINAL AGENTS
Antianginal agents are medications used to relieve and
prevent angina, which is chest pain or discomfort caused by
reduced blood flow to the heart. These agents work by either
increasing the oxygen supply to the heart or decreasing the
heart's oxygen demand.
Antianginal agents are primarily used to manage angina
pectoris and improve the quality of life for patients with
coronary artery disease. They help balance the oxygen supply
and demand of the heart, reducing the frequency and severity
of angina attacks.
Types of Antianginal Agents
1.Nitrates:
Examples: Nitroglycerin, Isosorbide Mononitrate, Isosorbide
Dinitrate
Mechanism: Dilate blood vessels, increasing blood flow to the
heart
Uses: Immediate relief of angina attacks
2. Beta-Adrenergic Blockers:
Examples: Propranolol, Metoprolol, Atenolol
Mechanism: Reduce heart rate and contractility, decreasing
oxygen demand
Uses: Prevent angina attacks, manage hypertension
3. Calcium Channel Blockers:
Examples: Amlodipine, Diltiazem, Verapamil
Mechanism: Inhibit calcium entry into cells, relaxing blood vessels
and reducing heart workload
4. Ranolazine:
Mechanism: Inhibits ion channels during cardiac repolarization,
reducing oxygen demand
Uses: Chronic angina management
Side Effects
Nitrates: Headache, hypotension, dizziness
Beta-Adrenergic Blockers: Bradycardia, fatigue, bronchospasm
Calcium Channel Blockers: Peripheral edema, constipation,
dizziness
Ranolazine: Dizziness, nausea, constipation
LIPID LOWERING AGENTS
Lipid-lowering agents, also known as antihyperlipidemic agents, are
medications used to lower levels of lipids (fats) in the blood, particularly
cholesterol and triglycerides. These agents are crucial in managing and
preventing cardiovascular diseases.
Lipid-lowering agents are used to manage dyslipidemia (abnormal lipid
levels) and reduce the risk of cardiovascular events such as heart attacks
and strokes.
They are often prescribed based on individual lipid profiles and
cardiovascular risk factors.
Types of Lipid-Lowering Agents
1.Statins (HMG-CoA Reductase Inhibitors)
Mechanism: Inhibit the enzyme HMG-CoA reductase, which is
involved in cholesterol synthesis
Indications: High LDL cholesterol, prevention of
cardiovascular events
Side Effects: Muscle pain, increased liver enzymes, potential
for diabetes in rare cases
2. Fibrates
Mechanism: Activate peroxisome proliferator-activated
receptors (PPARs), which increase the oxidation of fatty acids
and reduce triglyceride levels
Indications: High triglycerides, low HDL cholesterol
Side Effects: Gastrointestinal issues, myopathy, liver
dysfunction
3. Bile Acid Sequestrants
Mechanism: Bind bile acids in the intestine, preventing their
reabsorption and promoting their excretion
Indications: High LDL cholesterol
Side Effects: Gastrointestinal discomfort, constipation, possible
nutrient malabsorption
4. Cholesterol Absorption Inhibitors
Mechanism: Inhibit the absorption of cholesterol from the
small intestine
Indications: High LDL cholesterol, often used in combination
with statins
Side Effects: Diarrhea, abdominal pain
5. PCSK9 Inhibitors
Examples: Evolocumab, Alirocumab
Mechanism: Monoclonal antibodies that inhibit PCSK9,
increasing the number of LDL receptors on liver cells
Indications: Severe hypercholesterolemia, familial
hypercholesterolemia
Side Effects: Injection site reactions, potential for
neurocognitive effects
6. Niacin (Nicotinic Acid)
Mechanism: Inhibits lipolysis in adipose tissue, reducing free
fatty acids and VLDL production
Indications: High triglycerides, low HDL cholesterol
Side Effects: Flushing, hyperglycemia, liver toxicity
Monitoring and Considerations
Regular Monitoring: Lipid levels, liver function tests, and
muscle symptoms should be monitored regularly.
Lifestyle Modifications: Diet, exercise, and weight
management are essential components of lipid management.
DRUGS AFFECTING COAGULATION
Drugs affecting coagulation are used to prevent or treat blood
clots and are categorized into three main groups:
anticoagulants, antiplatelets, and thrombolytics. These drugs
play a vital role in managing and preventing thromboembolic
disorders, but they must be used carefully to balance the
benefits of preventing clots with the risks of bleeding.
Anticoagulants
Purpose: Prevent the formation of new clots and the growth of
existing clots. Indications: Atrial fibrillation, deep vein
thrombosis (DVT), pulmonary embolism (PE), and after certain
surgeries to prevent clot formation. Side Effects: Bleeding,
bruising, and in rare cases, heparin-induced thrombocytopenia
(HIT).
Antiplatelets
Purpose: Prevent platelets from clumping together to form clots.
Indications: Coronary artery disease, after a heart attack, and in
patients with stents to prevent clotting. Side Effects: Increased
risk of bleeding, gastrointestinal issues, and in rare cases,
thrombotic thrombocytopenic purpura (TTP).
Thrombolytics
Purpose: Dissolve existing clots. Indications: Acute myocardial
infarction (heart attack), acute ischemic stroke, and massive
pulmonary embolism. Side Effects: Bleeding, including
intracranial hemorrhage, and allergic reactions.
Monitoring and Considerations
Regular Monitoring: Patients on anticoagulants often require
regular blood tests to monitor their coagulation status (e.g.,
INR for warfarin).
Patient Education: Educating patients on the signs of bleeding
and when to seek medical attention is crucial.
Drug Interactions: Be aware of potential interactions with
other medications, foods, and supplements that can affect
coagulation.
OTHER DRUGS AFFECTING CLOT FORMATION
DRUGS USED TO TREAT ANEMIAS
Anemia is a medical condition characterized by a deficiency in
the number or quality of red blood cells (RBCs) or hemoglobin in
the blood. Hemoglobin is the protein in red blood cells that
carries oxygen from the lungs to the rest of the body. When you
have anemia, your body does not get enough oxygen-rich blood,
which can lead to a variety of symptoms and complications.
Drugs used to treat anemias are tailored to the specific type and
cause of anemia.
Iron Supplements
Purpose: Treat iron deficiency anemia by replenishing iron
stores. Examples: Ferrous sulfate, ferrous gluconate, ferrous
fumarate. Indications: Iron deficiency anemia due to blood loss,
poor dietary intake, or increased need (e.g., pregnancy). Side
Effects: Constipation, nausea, dark stools.
Vitamin B12 and Folate Supplements
Purpose: Treat anemias caused by vitamin B12 or folate
deficiencies. Examples: Cyanocobalamin (Vitamin B12), Folic acid.
Indications: Pernicious anemia, dietary deficiencies, malabsorption
syndromes. Side Effects: Rare, but may include allergic reactions or
gastrointestinal issues.
Erythropoiesis-Stimulating Agents (ESAs)
Purpose: Stimulate the production of red blood cells. Examples:
Epoetin alfa, Darbepoetin alfa. Indications: Anemia due to chronic
kidney disease, chemotherapy-induced anemia. Side Effects:
Hypertension, thrombosis, bone pain.
Blood Transfusions
Purpose: Provide immediate increase in red blood cell count.
Indications: Severe anemia requiring rapid correction, such as in
acute blood loss or severe hemolysis. Side Effects: Risk of
transfusion reactions, infections.
Medications for Hemolytic Anemias
Purpose: Treat anemias caused by the destruction of red blood cells.
Examples: Corticosteroids, Rituximab. Indications: Autoimmune
hemolytic anemia, hereditary spherocytosis. Side Effects:
Immunosuppression, increased infection risk.
Medications for Thalassemia and Sickle Cell Anemia
Purpose: Manage symptoms and complications. Examples:
Hydroxyurea, Luspatercept. Indications: Thalassemia, sickle cell
anemia. Side Effects: Bone marrow suppression, increased infection
risk.
Medications for Anemia of Chronic Disease
Purpose: Address underlying inflammation or infection. Examples:
Erythropoiesis-stimulating agents, iron supplements. Indications:
Anemia associated with chronic infections, inflammatory diseases.
Side Effects: Similar to those of ESAs and iron supplements.
Each type of anemia requires a specific approach to treatment,
and the choice of medication depends on the underlying cause
and severity of the condition. It's important to consult a
healthcare provider for a proper diagnosis and treatment plan.