Barbiturates

Thiopentone: Thiopentone is a barbiturate, and its introduction in 1934 by Water and Lundy has changed the face of modern anesthesia practice.

Physicochemical Properties

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  A rapid-acting barbiturate derived from barbituric acid. The substitution with a particular chemical group in barbituric acid imparts characteristic property to the parent compound:

  
  
  
  
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    Sulfur at second position—increases lipid solubility.

    
    
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    Aryl/alkyl group at fifth position—has hypnotic and sedative effects.

    
    
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    Increase in length of alkyl chain at fifth position—increases potency.

    
    
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    Phenyl group at fifth position—increases anticonvulsant activity (but no effect on hypnotic activity).

    
    
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    Methyl group on nitrogen—increases hypnotic potency but lowers the seizure threshold.

  
  
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  Preparation: Yellow amorphous powder (500- and 1,000-mg vial) prepared in the atmosphere of nitrogen and 6% anhydrous sodium carbonate is added to prevent precipitation of free acid by carbon dioxide from the atmosphere.

  
  
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  The powder is diluted to prepare a 2.5% solution (acidic pH of Ringer lactate can precipitate thiopentone; so it should not be used for dilution).

  
  
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  The 2.5% solution is highly alkaline with a pH of 10.4 and pKa of 7.6.

  
  
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  The freshly prepared solution should be used within 48 hours; however, it can be used for 1 week if refrigerated.

Mechanism of Action

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  It acts on GABA_A receptors in the central nervous system (CNS) and causes the opening of chloride channels, leading to CNS depression through hyperpolarization of neurons.

  
  
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  At low-dose, it is GABA-facilitatory, while at higher doses, it acts as GABA-mimetic.

  
  
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  It also acts on glutamate, adenosine, and neuronal nicotinic acetylcholine receptors.

Pharmacokinetics

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  It has rapid uptake and rapid distribution out of the brain into inactive tissues, leading to unconsciousness in one brain-arm circulation time (i.e., 15 s) after an IV dose.

  
  
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  80 to 90% is bound to plasma proteins (mainly albumin).

  
  
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  99% of thiopentone is metabolized by the liver (low-hepatic extraction ratio and capacity-dependent elimination) and excreted through the kidney.

  
  
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  The prolonged infusion or repeated doses of thiopentone leads to its accumulation in muscle and fat. The thiopentone is released into circulation after stopping the infusion and causes delayed awakening.

  
  
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  With usual induction doses (4–5 mg/kg), it follows first-order kinetics (i.e., a constant fraction is cleared per unit time), while at higher doses (200–300 mg/kg), it follows zero-order kinetics (a constant amount is cleared per unit time).

  
  
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  The children and adults are similar in terms of protein binding and volume of distribution.

  
  
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  Increased protein binding in pregnant patients leads to longer elimination half-life.

Pharmacodynamics and Clinical Applications

CNS

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  It produces unconsciousness in 15 seconds after an IV dose.

  
  
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  It causes a dose-dependent decrement in cerebral metabolic rate, cerebral oxygen consumption, and intracranial pressure (ICP) and thus provides neuroprotection against partial cerebral ischemia (however, there is no neuroprotection in global ischemia).

  
  
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  At lower doses, barbiturates decrease pain threshold.

  
  
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  There is dose-related suppression of EEG.

  
  
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  There is a lower degree of amnesia compared to benzodiazepines.

Respiratory system

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  Dose-related central respiratory depression with increased susceptibility in patients with chronic lung diseases.

  
  
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  Respiratory depression correlates with EEG suppression and minute ventilation.

  
  
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  The peak respiratory depression occurs at
  1 to 1.5 minutes of drug administration and returns to baseline within 15 minutes.

  
  
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  Thiopental causes “double apnea” in 20% of cases, which can be described as apnea of few seconds succeeded by few breaths of normal tidal volume, with subsequent prolonged apnea (25 s).

Cardiovascular system

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  It causes hypotension by the following mechanisms:

  
  
  
  
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    Negative inotropic effect.

    
    
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    Decreased ventricular filling (venous pooling).

    
    
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    Reduced sympathetic outflow from CNS.

  
  
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  There is baroreceptor reflex-mediated tachycardia (avoid in patients with coronary artery disease [CAD]).

  
  
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  Prolongation of QT interval and flattening of T wave (so, it is not good for patients at risk of QT prolongation and ventricular arrhythmias).

  
  
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  Significant reduction in cardiac output (not good for hypovolemic patients).

Complications

The IV use of thiopentone can sometime result in local complications such as thrombophlebitis, tissue necrosis due to intramuscular (IM)/subcutaneous (SC) injection, but the most dreadful is an intra-arterial injection which needs special attention here.

Intra-arterial injection: The inadvertent intra-arterial injection (commonly happen when thiopentone is injected in antecubital fossa) can cause gangrene and loss of limb if timely diagnosis and intervention are not instituted. The high alkalinity and pH of blood lead to precipitation and crystal formation which, in turn, leads to vasospasm and thrombus formation with consequent ischemia. Utmost precautions should be taken to prevent such incidents, and these are as follows:

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  Always use a 2.5% solution.

  
  
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  Slow injection in incremental doses.

  
  
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  Avoid injection in the antecubital fossa.

Once the intra-arterial injection has happened, the definitive measures include:

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  Leave the needle at its site and use it for all therapeutic injections.

  
  
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  Dilution with normal saline.

  
  
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  Inject heparin to prevent thrombus formation.

  
  
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  Papaverine or 1% lignocaine to cause local vasodilation.

  
  
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  Relieve vasospasm with stellate ganglion block if the above measures do not work.

  
  
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  Defer the elective surgery.

  
  
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  Prescribe oral anticoagulants and follow-up in consultation with the vascular surgeon.

Dosing

Induction dose is 3 to 4 mg/kg.

Uses

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  Induction and maintenance of anesthesia.

  
  
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  Electroconvulsive therapy (ECT).

  
  
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  Cerebral protection.

Side Effects

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  Hypotension.

  
  
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  Coughing and laryngospasm.

  
  
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  Apnoea at induction.

  
  
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  Allergic reactions.

Contraindications

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  Absolute:

  
  
  
  
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    Porphyria (except porphyria cutanea tarda).

    
    
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    History of allergy.

  
  
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  Relative:

  
  
  
  
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    Hypovolemia, fixed cardiac output lesions, CAD.

    
    
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    Asthmatics (risk of asthma precipitation).

    
    
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    Severe hepatic dysfunction (decreased metabolism).

    
    
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    Renal dysfunction (dose reduction required).

Methohexitone

It is an ultrashort-acting barbiturate with an anesthetic effect lasting for 2 to 5 minutes. It is twice as potent as thiopentone. The epileptogenic potential of methohexitone makes it an attractive choice for ECT.

The solution is stable for 6 weeks at 25℃.

Nonbarbiturates

Propofol: Propofol is popularly known as “milk of anesthesia” among anesthesia providers. It was discovered in 1970 by John B. Glenn and approved by the Food and Drug Administration (FDA) in 1989 for clinical use.

Physicochemical Properties

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  It is an alkylphenol, and its chemical name is 2,6-diisopropyl phenol.

  
  
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  It is milky white in appearance due to scattering of light by the lipid droplets.

  
  
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  pH = 6 to 8.5.

  
  
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  Protein-binding: 97 to 99%.

  
  
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  Constituents of 1% propofol preparation are as follows:

  
  
  
  
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    1% propofol.

    
    
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    10% soyabean oil (emulsifier).

    
    
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    1.2% purified egg phospholipid (emulsifier).

    
    
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    2.25% glycerol (to maintain tonicity).

    
    
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    NaOH (to maintain the pH of the solution).

  
  
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  Caloric value = 1 kcal/mL.

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  The propofol causes pain at the injection site due to soyabean oil. The fospropofol, a water-soluble preparation of propofol, introduced in 2008 by FDA does not cause pain on injection; however, perineal paresthesias and pruritus have been reported after bolus injection.

Mechanism of Action

The main site of action is the beta-subunit of GABA_A receptors. It is GABA-facilitatory in a lower dose and GABA-mimetic with higher doses. The other receptors are:

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  Potentiation of glycine receptors in the spinal cord.

  
  
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  Serotonergic receptors in area postrema (antiemetic action).

  
  
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  Inhibition of NMDA/glutamate receptors.

  
  
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  Increase in dopamine in nucleus accumbens (possible role in pleasure-seeking behavior and abuse potential).

Pharmacokinetics

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  It is oxidized to 1,4-diisopropylquinol in the liver, followed by conjugation with glucuronic acid and consequent excretion through kidneys.

  
  
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  The major site of metabolism is the liver (high-hepatic extraction ratio, so the metabolism is hepatic blood flow-dependent). The other sites are kidneys and lungs.

  
  
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  The context-sensitive half-life is 40 minutes after 8 hours of infusion.

  
  
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  The dose requirement decreases with age.

  
  
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  The children require a higher dose than adults because of the larger volume of distribution and rapid clearance of the drug.

  
  
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  Elimination half-life: 4 to 7 hours.

Pharmacodynamics

CNS

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  The hypnosis onset occurs in one brain-arm circulation time (30 s), with peak effect at 90 to 100 seconds.

  
  
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  Effect on EEG shows an initial rise in alpha rhythm, followed by a shift to gamma and theta rhythm.

  
  
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  It causes a dose-dependent decrease in cerebral metabolic oxygen consumption, cerebral blood flow, and ICP; however, its role in neuroprotection is controversial.

  
  
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  It is a dose-dependent anticonvulsant; grand mal seizures have been described in the literature.

  
  
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  It has abuse potential; however, the evidence for it among the general public is scarce.

  
  
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  It causes a remarkable decrease in intraocular pressure (30–40%).

Respiratory system

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  An induction dose of propofol cause apnea in 25 to 30% of the subjects.

  
  
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  Infusion of propofol decreases hypoxic drive through its action on carotid body chemoreceptors.

  
  
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  A good bronchodilator in chronic obstructive pulmonary disorder (COPD) patients.

  
  
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  It potentiates hypoxic pulmonary vasoconstriction.

  
  
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  It blunts airway reflexes better than thiopentone.

Cardiovascular system

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  It causes significant hypotension by decreasing systolic, diastolic, and mean arterial pressure. It occurs through the following mechanisms:

  
  
  
  
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    Direct myocardial depression (controversial).

    
    
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    Venous pooling because of vasodilation.

    
    
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    Decreased sympathetic drive to the heart.

  
  
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  It blunts baroreceptor reflex (so no significant tachycardia in response to hypotension).

  
  
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  The hemodynamic response to propofol lags behind the hypnotic effect.

Gastrointestinal tract

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  It is a potent antiemetic.

Other effects

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  It does not enhance neuromuscular blockade produced by muscle relaxants.

  
  
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  No effect on evoked responses.

  
  
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  Does not trigger malignant hyperthermia.

  
  
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  No effect on corticosteroid synthesis or adrenocorticotropic hormone (ACTH) stimulation.

  
  
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  It decreases chemotaxis of neutrophils but has no effect on phagocytosis and killing.

Uses

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  Induction of anesthesia: 1 to 2.5 mg/kg
  (adults), 2 to 3 mg/kg (children), 1 to 1.75 mg/kg (>60 years).

  
  
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  Maintenance of anesthesia: Dose (50–150 µg/kg/min with opiates or nitrous oxide).

  
  
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  For sedation in intensive care units: Dose (25–75 µg/kg/min).

  
  
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  In combination with remifentanil for total intravenous anesthesia (TIVA).

  
  
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  As an antiemetic: 10 to 20 mg IV can be repeated every 5 to 10 minutes or infusion of 10 µg/kg/min.

Side Effects

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  Pain at injection site is quite common, and the following measures can decrease it:

  
  
  
  
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    Use a large vein.

    
    
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    Use of water-soluble preparation (e.g., fospropofol).

    
    
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    Addition of lidocaine to the syringe of propofol.

    
    
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    Use of opiates/nonsteroidal anti-inflammatory drugs (NSAIDs)/ketamine/esmolol/clonidine/dexamethasone.

    
    
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    Use of Valsalva maneuver.

  
  
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  Apnea.

  
  
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  Hypotension.

  
  
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  Thrombophlebitis.

  
  
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  Risk of bacterial contamination and sepsis.

  
  
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  Propofol-infusion syndrome:

  
  
  
  
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    A rare lethal syndrome which occurs mostly in critically ill patients who receive it for sedation at doses 4 mg/kg/hr for more than 48 hours.

    
    
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    Clinical manifestations:

    
    
    
    
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      Acute refractory bradycardia.

      
      
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      Metabolic acidosis.

      
      
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      Rhabdomyolysis.

      
      
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      Cardiac arrhythmias.

      
      
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      Hyperlipidemia.

      
      
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      Fatty liver.

      
      
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      Cardiomyopathy/skeletal myopathy.

      
      
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      Increased hepatic transaminases.

      
      
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      A rise in serum creatinine.

  
  

  The risk factors for propofol infusion syndrome are:

  
  
  
  
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    Sepsis.

    
    
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    Significant brain injury.

    
    
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    Larger propofol dose.

    
    
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    Genetic disorders involving the metabolism of fatty acids.

Treatment of propofol infusion syndrome includes:

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  Discontinue propofol infusion immediately.

  
  
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  Supportive care with:

  
  
  
  
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    Hemodialysis.

    
    
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    Hemodynamic support (with fluids and vasopressors/inotropes).

    
    
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    Extracorporeal membrane oxygenation (ECMO) in refractory cases.

Contraindications

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  Known hypersensitivity or allergy to propofol.

  
  
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  Fat metabolism disorder.

Etomidate

It was first manufactured by Janssen Chemicals in 1965 as an antifungal agent.

Physicochemical Properties

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  It is an imidazole derivative.

  
  
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  It is a R-enantiomer, which is five times more potent than S-enantiomer.

  
  
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  Preparation: 0.2% solution (either in lipid emulsion or 35% propylene glycol).

  
  
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  pKa = 4.2.

Mechanism of Action

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  It acts on GABA_A receptor and produces hypnosis.

Pharmacokinetics

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  It can be given through IV/per oral/ rectal route.

  
  
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  Context-sensitive half-life is less than propofol.

  
  
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  Protein binding: 75%.

  
  
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  It is metabolized into carboxylic acid and ethanol in the liver through ester hydrolysis and excreted in urine and bile.

  
  
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  Use of continuous infusion is limited by adrenal suppression caused by etomidate.