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Inhalational Anesthetics: Overview01:20

Inhalational Anesthetics: Overview

294
Inhalation anesthetics are drugs that induce general anesthesia upon inhalation. They work by increasing the sensitivity of GABAA receptors or inhibiting NMDA receptors, leading to a decrease in central nervous system activity. The depth of anesthesia can be rapidly adjusted by changing the concentration of the inhaled gas. Some common examples of inhalational anesthetics include volatile liquids like isoflurane, desflurane, sevoflurane and gases like xenon and nitrous oxide. Isoflurane, a...
294
Parenteral Anesthetics: Overview01:24

Parenteral Anesthetics: Overview

128
Intravenous anesthetics are drugs administered parenterally to induce anesthesia or sedation. Propofol is a widely used agent formulated as a 1% emulsion in soybean oil, glycerol, and egg phosphatide. It induces rapid anesthesia primarily due to its rapid distribution from the bloodstream to target tissues and is metabolized in the liver. However, it can cause significant pain on injection and hypertriglyceridemia. Fospropofol, a water-based prodrug of propofol, lacks these adverse effects.
128
Stages of General Anesthesia01:22

Stages of General Anesthesia

449
Various sedation levels offer significant advantages in facilitating procedural interventions for patients undergoing medical or invasive surgical procedures. These levels span from anxiolysis to general anesthesia, providing a spectrum of sedative effects to cater to specific patient needs. Anxiolysis reduces anxiety and is achieved through minimal sedation, enabling patients to remain awake and responsive while feeling more at ease during the procedure. This level can benefit minor...
449
General Anesthesia: Overview01:24

General Anesthesia: Overview

219
Anesthesia is a medical procedure that uses drugs for CNS suppression to enable painless surgeries and procedures. The selection of anesthetics is influenced by their pharmacokinetic properties, side effects, and patient characteristics. Various types of anesthesia include general, local, regional, spinal, and inhalational.
General anesthesia induces unconsciousness in the whole body, while the others target specific areas or sensations. It is administered to minimize adverse effects, maintain...
219
Additional Routes of Drug Administration01:18

Additional Routes of Drug Administration

2.8K
Choosing the appropriate route of drug administration is significantly influenced by two key factors: the therapeutic objectives and the inherent properties of the drug being used.
Administering drugs via inhalation allows for the direct delivery of gaseous, volatile substances or droplets to different parts of the respiratory tract. One of the advantages of the inhalation route is the rapid absorption of drugs into the circulatory system, which is possible because of the large surface area of...
2.8K
Local Anesthetics: Common Agents and Their Applications01:23

Local Anesthetics: Common Agents and Their Applications

448
Local anesthetics (LAs) are commonly used for various applications in medical and dental procedures. Some of the common agents used are cocaine, lidocaine, and bupivacaine.
Cocaine is an ester of benzoic acid and methylecgogine. It is used to anesthetize and vasoconstrict locally. Currently, it is used primarily for topical applications. It is beneficial for surgeries on the upper respiratory tract, providing anesthesia and shrinking the mucosa. Cocaine in the form of cocaine hydrochloride is...
448

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Assessing 2‑Fluorobutane (CH<sub>3</sub>CHFCH<sub>2</sub>CH<sub>3</sub>) as a Climate-Friendly Alternative: Atmospheric Chemistry and Global Warming Potentials.

ACS earth & space chemistry·2026
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Photolysis of 1,1-Difluoroacetone (CF<sub>2</sub>HC(O)CH<sub>3</sub>) and 1,1,1-Trifluoroacetone (CF<sub>3</sub>C(O)CH<sub>3</sub>): Quantum Yields and Products of UV-B and UV-C Photolysis.

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Atmospheric chemistry of (<i>E</i>)-1,2-difluoroethene: kinetics and mechanisms of the reactions with Cl atoms, OH radicals and O<sub>3</sub>.

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Updated global warming potentials of inhaled halogenated anesthetics, isoflurane and sevoflurane from new temperature dependent OH-kinetics.

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Related Experiment Video

Updated: Jul 5, 2025

In Vitro Method to Control Concentrations of Halogenated Gases in Cultured Alveolar Epithelial Cells
04:56

In Vitro Method to Control Concentrations of Halogenated Gases in Cultured Alveolar Epithelial Cells

Published on: October 23, 2018

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Inhalational volatile anaesthetic agents: the atmospheric scientists' viewpoint.

O J Nielsen1, M P Sulbaek Andersen1,2

  • 1Copenhagen Center for Atmospheric Research, Department of Chemistry, University of Copenhagen, Copenhagen, Denmark.

Anaesthesia
|January 11, 2024
PubMed
Summary
This summary is machine-generated.

Healthcare must cut greenhouse gas emissions from volatile anesthetic agents to combat climate change. Understanding global warming potential guides strategies to reduce these potent gases and their climate impact.

Keywords:
atmospheric chemistryglobal warming potentialsvolatile anaesthetics

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Optogenetic Activation of Afferent Pathways in Brain Slices and Modulation of Responses by Volatile Anesthetics
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Area of Science:

  • Environmental Science
  • Anesthesiology
  • Climate Science

Background:

  • Climate change necessitates carbon footprint reduction across all societal sectors.
  • The healthcare sector contributes to greenhouse gas emissions, particularly through anesthetic agents.
  • Volatile anesthetic agents are potent greenhouse gases with significant environmental implications.

Purpose of the Study:

  • To review the environmental impact of volatile anesthetic agents.
  • To explain climate metrics like global warming potential, atmospheric lifetime, and radiative efficiency.
  • To discuss mitigation strategies for reducing anesthetic-induced climate forcing.

Main Methods:

  • Narrative review of existing literature.
  • Analysis of environmental data related to anesthetic agents.
  • Evaluation of climate metrics and their application to mitigation.

Main Results:

  • Volatile anesthetic agents are significant contributors to greenhouse gas emissions in healthcare.
  • Global warming potential, atmospheric lifetime, and radiative efficiency are key metrics for assessing environmental impact.
  • Various strategies exist for mitigating the climate impact of anesthetic agents.

Conclusions:

  • Reducing volatile anesthetic agent emissions is crucial for healthcare's climate mitigation efforts.
  • Climate metrics provide a framework for developing effective emission reduction strategies.
  • Implementing present and future mitigation options can significantly lessen the environmental burden of anesthesia.