Class IV antiarrhythmics: Calcium channel blockers and others

Last updated: June 05, 2025

Class IV antiarrhythmics: Calcium channel blockers and others

CCRN Prep Total

CCRN Prep Total

Anatomic and physiologic dead space
Ventilation
Ventilation-perfusion ratios and V/Q mismatch
Gas exchange in the lungs, blood and tissues
Approach to a cough (pediatrics): Clinical sciences
Reading a chest X-ray
Approach to respiratory distress (newborn): Clinical sciences
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Acute respiratory distress syndrome
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Upper respiratory tract infection
Apnea of prematurity
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Apnea, hypoventilation and pulmonary hypertension: Pathology review
Hospital-acquired and ventilator-associated pneumonia: Clinical sciences
Acid-base map and compensatory mechanisms
Respiratory acidosis
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Bronchodilators: Beta 2-agonists and muscarinic antagonists
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Pneumothorax: Clinical sciences
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Pulmonary hypertension: Clinical sciences
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Hypertensive emergency
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Esophageal atresia and tracheoesophageal fistula: Year of the Zebra
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Blood transfusion reactions and transplant rejection: Pathology review
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Anatomy of the descending spinal cord pathways
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Necrotizing enterocolitis: Year of the Zebra 2024
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Acute coronary syndrome: Clinical sciences
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Syndrome of inappropriate antidiuretic hormone secretion (SIADH)
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Diffusion-limited and perfusion-limited gas exchange
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Cardiac tamponade: Clinical sciences
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Ventricular tachycardia: Clinical sciences
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ECG cardiac infarction and ischemia
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Stroke volume, ejection fraction, and cardiac output
Dilated cardiomyopathy
Supraventricular tachycardia: Clinical sciences
Class IV antiarrhythmics: Calcium channel blockers and others
Atrial fibrillation and atrial flutter: Clinical sciences
Positive inotropic medications
Class I antiarrhythmics: Sodium channel blockers
Cardiomyopathies: Pathology review
Class III antiarrhythmics: Potassium channel blockers
Hypertrophic cardiomyopathy
Ventricular fibrillation
Aortic stenosis: Clinical sciences
Myocarditis
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Mitral stenosis: Clinical sciences
Congestive heart failure: Clinical sciences
Atrial flutter
Pressures in the cardiovascular system
Cardiovascular system anatomy and physiology
Restrictive cardiomyopathy
Airflow, pressure, and resistance
Total anomalous pulmonary venous return
Atrial fibrillation
Hypertrophic cardiomyopathy: Clinical sciences
Hypothermia: Clinical sciences
Hemothorax: Clinical sciences
Anaphylaxis: Clinical sciences
Abdominal aortic aneurysm: Clinical sciences
Muscarinic antagonists
Selective serotonin reuptake inhibitors
General anesthetics
Neuromuscular blockers
Right heart failure: Clinical sciences
Heart failure: Pathology review
Mitral valve disease
Approach to a murmur (pediatrics): Clinical sciences
Tricuspid valve disease
ACE inhibitors, ARBs and direct renin inhibitors
Patent ductus arteriosus
Adrenergic antagonists: Beta blockers
Pheochromocytoma
cGMP mediated smooth muscle vasodilators
Cardiac conduction system
Hypoplastic left heart syndrome
Hypoplastic left heart syndrome: Year of the Zebra 2024
Heart blocks: Pathology review
Rheumatic heart disease
Abnormal heart sounds
Valvular heart disease: Pathology review
Coronary artery disease: Pathology review
Pericarditis: Clinical sciences
Approach to hypertension: Clinical sciences
Deep vein thrombosis
Deep vein thrombosis: Clinical sciences
Approach to a fever: Clinical sciences
Anticoagulants: Heparin
Approach to hypercoagulable disorders: Clinical sciences
Heparin-induced thrombocytopenia
Thrombolytics
Atrial septal defect
Superior vena cava syndrome
Introduction to the somatic and autonomic nervous systems
Anticonvulsants and anxiolytics: Benzodiazepines
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Approach to congenital heart diseases (acyanotic): Clinical sciences
Tetralogy of Fallot
Cyanotic congenital heart defects: Pathology review
Approach to congenital heart diseases (cyanotic): Clinical sciences
Ventricular septal defect
Aortic valve disease
Pyloric stenosis
Aortic dissection
Pneumonia
Aortic dissection: Clinical sciences
Aortic dissections and aneurysms: Pathology review
Coarctation of the aorta
Acyanotic congenital heart defects: Pathology review
Pulmonary valve disease
Pulmonary chemoreceptors and mechanoreceptors
Zones of pulmonary blood flow
Carotid artery stenosis screening: Clinical sciences
Endocarditis
Endocarditis: Pathology review
Valvular insufficiency (regurgitation): Clinical sciences
Infectious endocarditis: Clinical sciences
Choanal atresia
Tetralogy of Fallot: Year of the Zebra
Mycoplasma pneumoniae
Measles virus
Respiratory alkalosis
Metabolic alkalosis
Approach to metabolic alkalosis: Clinical sciences
Approach to respiratory acidosis: Clinical sciences
Metabolic acidosis
Approach to metabolic acidosis: Clinical sciences
Pericardial disease: Pathology review
Atherosclerosis and arteriosclerosis: Pathology review
Cardiac and vascular tumors: Pathology review
Peripheral artery disease: Pathology review

Transcript

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Antiarrhythmic medications help control arrhythmias, or abnormal heartbeats. There are four main groups of antiarrhythmic medications: class I, sodium-channel blockers; class II, beta-blockers; class III, potassium-channel blockers; class IV, calcium-channel blockers; and miscellaneous antiarrhythmics, or unclassified antiarrhythmics. Now, we’ll focus on class IV and miscellaneous antiarrhythmics in this video.

First, let’s start with two main types of cells within the heart; pacemaker cells and non-pacemaker cells. Pacemaker cells build the electrical conduction system of the heart, which consists of the sinoatrial node, or SA node; the atrioventricular node, or AV node; the bundle of His; and the Purkinje fibers.

Pacemaker cells have a special property called automaticity, which is the ability to spontaneously depolarize and fire action potentials.

On the other hand, non-pacemaker cells, also known as cardiomyocytes, make up the atria and ventricles; and they give the heart its ability to contract and pump blood throughout the body.

Now, in contrast to non-pacemaker cells, whose action potential has 5 phases (0, 1, 2, 3, and 4 ), an action potential in pacemaker cells has only 3 phases (4, 0, and 3). Here’s a graph of the membrane potential vs. time for a pacemaker cell. Phase 4, also known as the pacemaker potential, starts with the opening of the pacemaker channels. The current through these channels is called pacemaker current or funny current (If), and it mainly consists of sodium ions. These sodium ions cause the membrane potential to begin to spontaneously depolarize and as the membrane potential depolarizes, voltage-dependent T-type calcium channels open up, thereby further depolarizing the pacemaker cell. As calcium enters the cell, voltage-dependent L-type calcium channels open up, causing more calcium to rush into the cell, ultimately depolarizing the membrane to its threshold potential. This marks the start of phase 0, which is also known as the depolarization phase. Now phase 0 in a pacemaker cell is caused by an influx of calcium ions through the voltage-dependent L-type calcium channels that started opening at the end of phase 4. But, compared to phase 0 of a non-pacemaker cell, which consists of a rapid influx of sodium ions, this influx of calcium ions isn’t that rapid, so the slope of phase 0 in a pacemaker cell is more gradual. Also during phase 0, the pacemaker channels and voltage-dependent T-type calcium channels close. Finally, during phase 3, which is the repolarization phase, L-type calcium channels close and potassium channels open up, resulting in a net outward positive current. At the end of repolarization, pacemaker channels open up and we start over with phase 4 again. During phase 4 there’s also an outward movement of potassium ions as the potassium channels responsible for the repolarization phase continue to close.

Finally, it’s important to note that besides pacemaker cells, L-type calcium channels are also found in non-pacemaker cells and they’re responsible for phase 2 or the "plateau" phase of their action potential. Furthermore, calcium that passes through these channels, along with calcium that’s released from the sarcoplasmic reticulum, are essential for the contraction of the cardiac myocytes that make up the rest of the heart.

Now, the automaticity of the heartbeat is led by the pacemaker cells that have the fastest phase 4, which are normally the pacemaker cells found in the SA node. The SA node fires an electrical signal that propagates throughout both atria, making them contract. The signal gets delayed a bit as it goes through the AV node, then goes through the Bundle of His to the Purkinje fibers of both ventricles, making them contract as well. When the electrical signal of the heart doesn’t follow this path, it’s called an irregular heartbeat or arrhythmia.

For example, let’s say a part of the ventricle begins to fire off action potentials at a rate that’s even faster than the SA node. This area of the heart essentially flips roles with the SA node, firing so fast that the pacemaker cells in the SA node don’t get a chance to fire. At that point, the heartbeat is being driven by the ventricles.

Alright, switching gears and moving on to pharmacology. Calcium channel blockers bind and inhibit voltage-dependent L-type calcium channels and they’re subdivided into two main groups: dihydropyridines and non-dihydropyridines. Dihydropyridines, like amlodipine, nicardipine, and nifedipine, are highly selective for calcium channels on the vascular smooth muscle tissue; so they’re primarily used to treat hypertension. On the other hand, non-dihydropyridines are the class IV antiarrhythmics and they include verapamil and diltiazem. These medications work by targeting the pacemaker cells and non-pacemaker cells in the heart.

In pacemaker cells, they decrease the amount of calcium entering the cell during phase 4 and 0, causing a slower pacemaker potential and slower depolarization. Moreover, by prolonging phase 4 and 0, class IV antiarrhythmics also prolong effective refractory period or ERP, which is the period of time that the cell is unexcitable to new stimulus. This way, they reduce firing of the SA node, eventually decreasing the heart rate. But besides decreasing the activity of the SA node, they also decrease conduction velocity through the AV node. On the ECG, this shows up as a longer PR interval, which is the time between the onset of atrial depolarization and the onset of ventricular depolarization.

On the other hand, in non-pacemaker cells, like cardiac myocytes, class IV antiarrhythmics decrease the amount of calcium entering the cell. This way, they decrease the amount of calcium available inside the cell, weakening the force generated during heart contraction.

Sources

  1. "Katzung & Trevor's Pharmacology Examination and Board Review,12th Edition" McGraw-Hill Education / Medical (2018)
  2. "Rang and Dale's Pharmacology" Elsevier (2019)
  3. "Hurst's the Heart, 14th Edition: Two Volume Set" McGraw-Hill Education / Medical (2017)
  4. "Effects of L-type calcium channel and human ether-a-go-go related gene blockers on the electrical activity of the human heart: a simulation study" Europace (2014)
  5. "Therapeutic drug monitoring: antiarrhythmic drugs" British Journal of Clinical Pharmacology (1998)
  6. "Goodman and Gilman's The Pharmacological Basis of Therapeutics, 13th Edition" McGraw-Hill Education / Medical (2017)