Table of Contents
Toxicology
Toxicology is the branch of pharmacology that studies the harmful effects of chemicals, drugs, and poisons on the human body. It explains how toxic substances produce cellular injury, organ damage, and systemic complications. Understanding toxicology is essential for medical students and healthcare professionals to manage poisoning cases effectively and reduce morbidity and mortality.
Basic Concepts in Toxicology
1. Dose–Response Relationship
Toxic effects depend on the dose, route of exposure, and duration.
Low dose → Therapeutic effect
High dose → Toxic effect
Extremely high dose → Lethal effect
2. Types of Toxicity
Acute toxicity – Single large exposure
Chronic toxicity – Repeated small exposure
Local toxicity – At site of contact
Systemic toxicity – After absorption into bloodstream
General Mechanism of Toxicity
Toxic substances typically follow this pathway:
Exposure (ingestion, inhalation, skin contact)
Absorption into bloodstream
Distribution to organs
Cellular interaction
Organ damage and clinical symptoms
Common cellular mechanisms include:
Enzyme inhibition
Oxidative stress
Mitochondrial dysfunction
Membrane disruption
DNA damage
Toxicokinetics (ADME in Toxicology)
Toxicokinetics describes how the body handles toxic substances.
Absorption: GI tract, lungs, skin
Distribution: Via blood to target organs (brain, liver, kidneys)
Metabolism: Mainly in liver (may convert to more toxic metabolites)
Excretion: Kidneys (urine), bile, lungs
Some toxins become more dangerous after metabolism (e.g., formation of reactive metabolites).
Common Types of Poisoning in Clinical Practice
1. Organophosphate Poisoning
Organophosphates inhibit acetylcholinesterase, causing excess acetylcholine accumulation.
Clinical Features:
Salivation
Sweating
Bronchospasm
Bradycardia
Muscle twitching
Management:
Atropine
Pralidoxime
Airway support
2. Paracetamol (Acetaminophen) Toxicity
High doses cause liver injury due to toxic metabolite accumulation.
Stages:
Early: Nausea, vomiting
Later: Liver failure
Antidote:
N-acetylcysteine (NAC)
3. Opioid Toxicity
Overdose leads to respiratory depression.
Classic Triad:
Pinpoint pupils
Respiratory depression
Unconsciousness
Antidote:
Naloxone
4. Heavy Metal Poisoning
Examples include lead, mercury, and arsenic.
Features:
Neurological symptoms
Abdominal pain
Anemia
Treatment:
Chelating agents (EDTA, dimercaprol)
Antidote Mechanism Overview
Chemical Antidotes – Neutralize poison (e.g., chelators)
Pharmacological Antidotes – Oppose effect (e.g., naloxone)
Physical Antidotes – Prevent absorption (e.g., activated charcoal)
General Principles of Poison Management
Ensure airway, breathing, circulation (ABC approach)
Identify toxin if possible
Prevent further absorption
Enhance elimination
Administer specific antidote if available
Provide supportive care
Factors Affecting Toxicity
Age
Body weight
Genetic factors
Liver and kidney function
Drug interactions
Route of exposure
Children and elderly individuals are more vulnerable to toxic effects.
Importance of Toxicology in Pharmacology
Prevents drug overdose complications
Guides safe prescribing
Helps in emergency management
Reduces medication errors
Essential for forensic medicine
Key Takeaways for Medical Students
Toxicity is dose-dependent
Early recognition saves lives
Some drugs form toxic metabolites
Antidotes must be administered promptly
Supportive care is the cornerstone of treatment