general anesthesia
DESCRIPTION
General anesthesia. General anesthesia was not known until the mid-1800’s Diethylether was the first general anesthetic used for surgery General Anesthetics are divided into two classes: Inhaled anesthetics (usually halogenated compounds) Intravenous anesthetics or induction agents. - PowerPoint PPT PresentationTRANSCRIPT
General anesthesia
• General anesthesia was not known until the mid-1800’s
• Diethylether was the first general anesthetic used for surgery
• General Anesthetics are divided into two classes:– Inhaled anesthetics (usually halogenated
compounds)– Intravenous anesthetics or induction agents
Modern Anesthesia• It combines the following:1. Analgesia2. Sleep (loss of consciousness)3. Skeletal Muscle relaxation4. amnesia5. Abolition sensory & autonomic
reflexes• No single drug can produce all these
effects
Ideal anesthesia is
• Induce loss of consciousness smoothly and rapidly
• Allow for prompt recovery of cognitive function after its administration is discontinued
• Possess wide margin of safety • Have no side effects• No single drug can produce all these
effects
Stages of anesthesia• Stage 1:analgesia Decreased pain awareness, sometimes with amnesia ,conscious
may be impaired but not lost • Stage 2:disinhibitionDelirium, excitation, amnesia, enhanced reflexes, irregular
respiration and incontinence • Stage 3:surgical anesthesiaUnconsciousness ,no pain reflex, regular respiration and
maintained blood pressure• Stage 4:medullary depressionSevere CVS and respiratory depression and the patient require
pharmacological and ventilatory support
Anesthesia protocols • For minor procedure, conscious sedation conscious
sedation techniques that combine IV agent with local anesthetics are often used ;these can provide profound analgesia, with retention of the patient ability to maintain a patent airway and response to verbal commands
• For extensive surgical procedure protocol commonly includes IV drug for induction, inhaled agent(with or without IV)for maintenance and neuromuscular junction blockers to cause muscle relaxation
General Anesthetics• Absence of sensation associated with a reversible loss of
consciousness, skeletal muscle relaxation, and loss of reflexes.
• Drugs used for anesthesia are CNS depressants with action that can be induced and terminated more rabidly than conventional sedative and hypnotics
• Most sensitive site of action for general anesthetics is the reticular activating system of the brainstem (RAS)
• Anesthetic dose: does not cause depression of cardiac, vasomotor or respiratory centers
• Has a small margin of safety
Inhaled Anesthetics
• Include: Nitrous oxide
HalothaneEnfluraneIsoflurane Desflurane
Intravenous Anesthetics
• Include:– Barbiturates• Thiopental & Methohexital
– Opioids• Alfentanil, Meperidine, Fentanyl, Sufentanil
(agonists)• Naloxone (antagonist)
– Benzodiazepines• Diazepam, Midazolam• Flumazenil (antagonist)
Intravenous Anesthetics
• Miscellaneous Agents– Etomidate – non-barbiturate hypnotic agent without
analgesic properties– Droperidol - Neuroleptic (similar to Haloperidol) -
combined with Fentanyl and is used for neuroleptanalgesia (state of analgesia and amnesia)
– Ketamine - dissociative anesthetic– Propofol
General Uses of IV Anesthetics
• Primary Use = induction of general anesthesia– Supplement general anesthesia– maintain general anesthesia– provide sedation– control Blood Pressure
Intravenous agents
• Mechanism of action– Act at cell surface receptors• Barbiturates and benzodiazepine act at GABA-A
receptors to increase Cl- influx• Opioids act on m and other subtypes• Ketamine antagonizes PCP site on NMDA receptors
(prevent excitation)• Pharmacokinetics– Rapid induction = shorter acting– Duration of effect proportional to redistribution from
brain to other tissue
Barbiturates: Thiopentone
• Ultra-short acting hypnotic with no analgesic action• High lipid solubility promotes rapid entry to the brain• Eliminated by the liver• Has rapid onset of action and recovery• M.O.A.= potentiates GABA, decrease glutamate activity,
increase chloride ion conductance Adverse reactions: decreased myocardial and
respiratory activity
Etomidate • Imidazole derivative that provide induction with minimal
change in cardiac function and respiratory rate and has short duration of action
• It is not analgesic , and its primary advantage is in anesthesia for patient with limited respiratory and cardiac reserve
• Activates GABA receptors• Uses– Induction of anesthesia
• Side effects – Myoclonus– Post-operative nausea and vomiting
Ketamine
• This drug produce dissociative state in which the patient is patient remains conscious but has marked catatonia, analgesia, and amnesia
• It is a chemical congener of the psychotomimetic agent, phencyclidine (PCP)
• It is a cardiovascular stimulant drug and this action may cause increase ICP
• Emergency reactions include disorientation ,excitation and hallucination which can be reduced by preoperative administration of benzodiazepines
• Uses- Induction of anesthesia – in children – in severely hypovolemic patients
• Contraindications– Increased intracranial pressure– Ischemic heart disease– Psychological disorders
• Effects– Analgesic with dissociative anesth. properties– Dreaming in children
Propofol • Uses– Induction and maintenance of anesthesia– As anesthetic agent at outpatient surgery – Also effective in producing prolog sedation in patient in
critical care setting • Contraindications – Cardiovascular instability due to marked reduction in
the peripheral resistance • Effects– Hypnosis ,Antiemetic– Fast acting, short duration. Fewer peripheral side
effects compared to barbiturates
Opiates• Potent analgesics – Fentanyl -Potency 50-100X >Morph– Alfentanil -Potency 25-30X > Morph– Sufentanil -Potency 5-10X >Fentanyl– Meperidine
• Uses– Supplementation of general anesthesia or analgesia
• Effects– respiratory depression– nausea and vomiting– muscle rigidity
INHALATION ANESTHETICS
MAC(minimal alveolar concentration)
• MAC of anaesthetic measures potency of anaesthetic vapour. High MAC means low potency
• Defined as the concentration of anesthetic that prevents movement induced by a painful stimulus in 50 % of subjects.
Mechanism of Action
• Potency is correlated with lipid solubility–Olive oil:gas partition coefficient• The greater the number, the more potent
the anesthetic Methoxyflurane>halothane>isoflurane etc.
Theories for Mechanism of Action• Theory #1– Gas movement into lipid membrane disrupting ion
channels and action potential propagation• Increased Atmospheric pressure will reverse effects
• Theory #2– Binding theory = anesthetics bind to hydrophobic
portion of the ion channel• Theory #3– Neuromodulator theory = anesthetics bind to cell-
surface receptors.• increased Cl- flux (possible GABA mediation)
Pharmacokinetics of Inhaled Anesthetics
• Factors influencing the effects of inhaled anesthetics– Amount that reaches the brain• Indicated by oil:gas ratio (lipid solubility)
– Partial pressure of anesthetic• 5% anesthetic = 38 mmHg (10% =76 mmHg)
– Solubility of gas into blood• The lower the blood:gas ratio, the more
anesthetic will arrive at the brain– Cardiac Output• Increased CO = greater Induction time
Rate of Entry into the Brain: Influence of Blood and Lipid Solubility
General Actions of Inhaled Anesthetics
• Respiration– Depressed respiration
• Kidney– Depression of renal blood flow and urine output
• Muscle– High enough concentrations will relax skeletal muscle
General Actions of Inhaled Anesthetics
• Cardiovascular System–Generalized reduction in arterial pressure and
peripheral vascular resistance. Isoflurane maintains CO and coronary function better than other agents
• Central Nervous System– Increased cerebral blood flow and decreased
cerebral metabolism
Toxicity and Side Effects• Depression of respiratory drive• Depressed cardiovascular drive• Fluoride-ion toxicity from methoxyflurane– Metabolized in liver = release of Fluoride ions• Decreased renal function allows fluoride to
accumulate = nephrotoxicity• Malignant hyperthermia– To treat this, rapidly cool the individual and
administer Dantrolene to block release of Calcium from muscle sarcoplasmic reticulum
Advantages and Disadvantages of Selected Inhaled Anesthetics
• Isoflurane– Cardiac output is maintained– Arrhythmias are uncommon– Potentiates the actions of muscle relaxants– Minimally metabolized and no reports of heptato- or
nephrotoxicity– most widely used agent– MAY CAUSE MALIGNANT HYPERTHERMIA
Advantages and Disadvantages of Selected Inhaled Anesthetics
• Desflurane–More irritating to airways than other agents–Rapid recovery–No reports of malignant hyperthermia
Preanaesthetic Medication
Focus Points
1 Induction of anesthesia is through use of any of the IV agents (Barbiturates: Thiopental, Opiate: Fentanyl, Benzodiazepines: Midazolam, Dissociative: Ketamine, Others: Propofol, Etomidate and Droperidol)
2 Majntenance of anesthesia is through use of any of the ihalation agents
-N2O (70% in oxygen) is not suitable alone - N2O is usually combined with another inhalation agent
or with opioids e.g. fentanyl
A comparison
halothane N2OSpeed of induction intermediate fastPotency v.potent weak MAC=2% MAC 80%Muscle relaxation some noneCardiac arrhythmia yes noLiver damage yes noRecovery slow rapid
• NOTES:• Enflurane releases flouride ions which may cause
renal failure• All inhalation anesthetics can cause resp. depression,
myocardial depression, cardiac arrhythmias, hypotension and PONV
• A mixture of N2O(50-70%) and haothane 1% is usually used in anesthesia.
Nitrous Oxide
• Characterized by inert nature with minimal metabolism
• Colorless, odorless, tasteless, and does not burn
• Simple linear compound• Only anesthetic agent that is inorganic• Major difference is low potency• MAC value is 80 - 105%• Weak anesthetic, powerful analgesic• Needs other agents for surgical anesthesia• Low blood solubility (quick recovery)
GOOD LUCK