| In vivo: |
| European Journal of Anaesthesiology, 01 Jul 2002, 19(7):466-473. | | Laudanosine, an atracurium and cisatracurium metabolite.[Reference: WebLink] | Laudanosine is a metabolite of the neuromuscular-blocking drugs atracurium and cisatracurium with potentially toxic systemic effects.
It crosses the blood-brain barrier and may cause excitement and seizure activity. Its interest in recent years has increased because of the recognized interaction with gamma-aminobutyric acid, opioid and nicotinic acetylcholine receptors.
METHODS AND RESULTS:
It has been shown to produce analgesia in animals. In the cardiovascular system, high plasma concentrations produce hypotension and bradycardia. In hepatic failure, its elimination half-life is prolonged but only moderate accumulation occurs in adults, whereas in infants and children plasma concentration are greater. In patients undergoing liver transplantation, Laudanosine concentrations are increased during preanhepatic, anhepatic and postanhepatic stages. Patients with renal failure have higher plasma concentrations and a longer mean elimination half-life. In pregnancy, Laudanosine crosses the placental barrier. The mean transplacental transfer is 14% of maternal blood concentrations. Except for prolonged administration of atracurium in intensive care units, Laudanosine accumulation and related toxicity seem unlikely to be achieved in clinical practice.
CONCLUSIONS:
When cisatracurium is used, plasma concentrations of Laudanosine are lower. Further studies are needed, especially around the interactions with gamma-aminobutyric acid, opioid and nicotinic acetylcholine receptors. | | Anesthesiology, 1985, 63(6):584-588. | | Laudanosine (A Metabolite of Atracurium) Increases the Minimum Alveolar Concentration of Halothane in Rabbits.[Reference: WebLink] | The authors hypothesized that Laudanosine, a metabolite of atracurium and a central nervous system stimulant, might increase the minimum alveolar concentration (MAC) of halothane.
METHODS AND RESULTS:
An initial study in five rabbits anesthetized with halothane used a two-compartment model to produce estimates of pharmacokinetic variables for Laudanosine. These estimates were used to determine the rates of infusion that would produce steady state plasma concentrations of Laudanosine of approximately 200, 400, and 800 ng . ml-1. Subsequent infusion of Laudanosine in eight rabbits produced mean (+/- SD) steady state plasma concentrations of Laudanosine of 234 +/- 56, 457 +/- 66, and 873 +/- 105 ng . ml-1. The control value for MAC of halothane was 1.08 +/- 0.28%. At the lowest steady state plasma Laudanosine concentration, MAC did not significantly differ from control (MAC = 1.15 +/- 0.23%, P less than 0.1). However, at 457 and 873 ng . ml-1, Laudanosine significantly increased the MAC of halothane by 23% and 30%, respectively. Infusion with saline in two additional rabbits did not affect MAC.
CONCLUSIONS:
Therefore, at the plasma concentrations of Laudanosine found in humans after administration of atracurium, Laudanosine increased the MAC of halothane in rabbits. |
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