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Local Anesthetics: Clinical Application as Spinal Anesthesia01:11

Local Anesthetics: Clinical Application as Spinal Anesthesia

2.0K
Spinal anesthetics are given during lower abdomen and limb surgeries to block sensory and motor neurons. They are administered in the mid to low lumbar regions, primarily acting on the cauda equina's nerve roots. The blockade level depends on the local anesthetic (LA) concentration. Usually, low LA concentrations are sufficient to block sensory fibers, while only high LA concentrations block motor fibers. Other factors like injection volume and speed, the patient's posture, and the drug...
2.0K
Local Anesthetics: Chemistry and Structure-Activity Relationship01:30

Local Anesthetics: Chemistry and Structure-Activity Relationship

5.0K
Local anesthetics (LAs) are drugs that induce a temporary loss of sensation in a limited body area, preventing pain. Cocaine was the first local anesthetic discovered in the late 19th century. Cocaine is a benzoic acid ester obtained from the leaves of coca shrubs and was often used for its psychotropic effects. Cocaine was first isolated in 1860 by Albert Niemann. Sigmund Freud studied the physiological actions of cocaine. Carl Koller later introduced it into clinical practice in 1884 as a...
5.0K
General Anesthesia: Overview01:24

General Anesthesia: Overview

1.1K
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...
1.1K
Local Anesthetics: Pharmacokinetics01:13

Local Anesthetics: Pharmacokinetics

1.6K
The potency and duration of action of local anesthetics (LAs) are determined by their pharmacokinetics. Pharmacokinetics describes how LAs are absorbed, distributed, metabolized, and eliminated from the body. When administered to the vascular tissues, LAs are quickly absorbed and enter the systemic circulation, reducing their localized effects. Adding vasoconstrictors such as epinephrine to LAs reduces their absorption into the systemic circulation, making them clinically effective. The...
1.6K
Local Anesthetics: Common Agents and Their Applications01:23

Local Anesthetics: Common Agents and Their Applications

1.3K
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...
1.3K
Local Anesthetics: Clinical Application as Surface, Infiltration, and Conduction Block Anesthesia01:30

Local Anesthetics: Clinical Application as Surface, Infiltration, and Conduction Block Anesthesia

2.9K
Depending on the target organ, local anesthetics (LAs) can be administered via various routes. In surface anesthesia, LAs are applied directly to the surface of the skin or mucous membranes. It is widely used for topical skin numbing before venipuncture or minor surgical procedures. Commonly used surface local anesthetics are lidocaine or benzocaine sprays or creams. Surface anesthesia occurs within 5 minutes and lasts for about 60 minutes. One of the main disadvantages of topical anesthesia is...
2.9K

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Related Experiment Video

Updated: May 6, 2026

Use of a Low-flow Digital Anesthesia System for Mice and Rats
08:06

Use of a Low-flow Digital Anesthesia System for Mice and Rats

Published on: September 7, 2016

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Anesthesia and the Lone Star State.

Casey B Wiley1

  • 1Department of Anesthesiology, University of Texas Health Science Center San Antonio, San Antonio, Texas, USA.

Bulletin of Anesthesia History
|November 8, 2013
PubMed
Summary
This summary is machine-generated.

Anesthesiology has evolved from basic ether administration to advanced monitoring like pulse oximetry. Continuous adaptation is key for advancing patient care in this dynamic medical field.

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Area of Science:

  • Anesthesiology
  • Medical Technology Advancement

Background:

  • Historical context of anesthesiology practices.
  • Evolution from rudimentary methods to sophisticated techniques.

Observation:

  • Shift from subjective monitoring (blood color) to objective, continuous measurements.
  • Introduction of precise inhaled anesthetic concentrations and pulse oximetry.

Findings:

  • Modern anesthesiology relies on advanced technology for improved patient safety and care.
  • Technological integration has transformed anesthetic delivery and monitoring.

Implications:

  • The field of anesthesiology must embrace continuous evolution to meet future medical challenges.
  • Ongoing adaptation ensures the advancement of patient care standards in anesthesiology.