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Related Concept Videos

Antiarrhythmic Drugs: Class I Agents as Sodium Channel Blockers01:22

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Class I antiarrhythmic drugs are used to treat various types of arrhythmias or irregular heart rhythms. These drugs block the sodium (Na+) channels in the cardiac cells, thereby affecting the movement of electrical impulses across the heart. Class I antiarrhythmic drugs are divided into three subgroups: Class IA, Class IB, and Class IC, each with distinct mechanisms of action and effects on the heart.
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Cardiovascular diseases, encompassing a range of conditions, can significantly affect the heart's operations and the overall circulatory system. These conditions impair the heart's ability to pump blood, leading to a deficit in oxygen supply to crucial organs. Anomalies in the heart's electrical system, known as arrhythmias, can cause heartbeats to accelerate or slow down. Usually, heart rates increase during physical activity and decrease while resting or sleeping. However,...
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Antiarrhythmic Drugs: Class III Agents as Potassium Channel Blockers01:12

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Class III antiarrhythmic drugs are a group of medications that can prolong action potentials in the heart. They achieve this by blocking potassium channels or enhancing inward currents from sodium channels. However, these drugs have a unique property of "reverse use-dependence," which is most pronounced at slower heart rates and can lead to torsades de pointes—a specific type of arrhythmia. However, it is essential to note that excessive QT interval prolongation—a measure of...
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Positive inotropic agents are commonly used as the first line of treatment for heart failure. One such agent is digoxin, derived from the genus Digitalis, which has been known for centuries but effectively utilized since 1785. However, these cardiac glycosides can have potentially toxic effects due to their mechanism of action, which involves inhibiting Na+/K+-ATPase and increasing contractility. Digoxin is absorbed orally and distributed in various tissues, including the CNS. It has a long...
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Neurotransmitters play a crucial role in the communication between neurons in the autonomic nervous system. Neurons in the autonomic nervous system can be cholinergic or adrenergic depending on the neurotransmitters synthesized. Cholinergic neurons use acetylcholine as their primary neurotransmitter. This includes all the preganglionic fibers of the sympathetic and pre- and postganglionic fibers of the parasympathetic nervous systems. In addition, neurons of the somatic nervous system also use...
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Antiarrhythmic Drugs: Class IV Agents as Calcium Channel Blockers01:20

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Class IV antiarrhythmic drugs, such as verapamil and diltiazem, block calcium channels. They primarily affect the heart, slowing the conduction in calcium-dependent tissues like the SA and AV nodes. These drugs manage reentrant supraventricular tachycardia (SVT) and reduce ventricular rate in atrial flutter/fibrillation.
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Updated: Mar 27, 2026

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Graph-Based Classification with GNN-Explainer for Predicting Cardiac Toxicity Associated with Multi-Ion Channel

Dhairiya Agarwal1, Anju Sharma1, Prabha Garg1

  • 1Department of Pharmacoinformatics, National Institute of Pharmaceutical Education and Research, S. A. S. Nagar 160062, Punjab, India.

Chemical Research in Toxicology
|March 24, 2026
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Summary
This summary is machine-generated.

A new deep learning model predicts drug cardiotoxicity by analyzing inhibition of three key cardiac ion channels: Kv11.1, Cav1.2, and Nav1.5. This approach enhances early safety profiling in drug discovery.

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Area of Science:

  • Computational chemistry and toxicology
  • Drug discovery and development
  • Machine learning in pharmacology

Background:

  • Cardiotoxicity is a major cause of drug attrition, traditionally assessed via Kv11.1 channel inhibition.
  • The Comprehensive in Vitro Proarrhythmic Assay (CiPA) highlights the need to evaluate Cav1.2 and Nav1.5 channels.
  • Existing machine learning models often lack comprehensive ion channel data.

Purpose of the Study:

  • To develop a deep learning framework integrating inhibition data for Kv11.1, Cav1.2, and Nav1.5 channels.
  • To improve early-stage cardiotoxicity risk assessment in drug discovery.
  • To provide interpretable insights into molecular contributions to cardiotoxicity.

Main Methods:

  • Curated a large dataset (Cardio-Tox) from multiple repositories (PubChem, CUPID, CToxPred2).
  • Developed and trained Graph Neural Network (GNN) models for individual channel inhibition prediction.
  • Utilized GNNExplainer for interpretable visualization of atom- and bond-level contributions.

Main Results:

  • The integrated CardiotoxPred method achieved 86.7% average prediction accuracy on a test dataset.
  • GNN models demonstrated capability for individual channel prediction.
  • Interpretable visualizations provided insights into molecular drivers of cardiotoxicity.

Conclusions:

  • The developed deep learning framework offers robust and interpretable cardiotoxicity prediction.
  • Freely accessible models in Docker containers facilitate early safety profiling.
  • This tool aids in optimizing drug candidates and reducing late-stage failures.