Recirculatory model of fentanyl disposition with the brain as the target organ

doi:10.1093/bja/aeh261

BJA Advance Access published online on September 17, 2004
British Journal of Anaesthesia, doi:10.1093/bja/aeh261
© 2004 by The Board of Management and Trustees of the British Journal of Anaesthesia

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Accepted July 23, 2004

Laboratory Investigation

Recirculatory model of fentanyl disposition with the brain as the target organ

R. N. Upton ¹^*, C. Grant ¹, A. M. Martinez ¹, and G. L. Ludbrook ¹

¹ Department of Anaesthesia and Intensive Care, Royal Adelaide Hospital and University of Adelaide, Adelaide SA 5005, Australia

^* To whom correspondence should be addressed. E-mail: richard.upton{at}adelaide.edu.au.

Abstract

Background. The factors affecting the concentrations of fentanylin the brain after intravenous administration have not beencompletely quantified.

Methods. A model integrating the roleof brain, lung and systemic kinetics was developed based ondata from conscious instrumented sheep. Brain kinetics wereinferred from arterio-sagittal sinus concentration gradientsand cerebral blood flow, and lung kinetics from the pulmonaryartery-aortic gradient and cardiac output. The best models ofthe lung and brain were incorporated into a recirculatory modelof the whole-body disposition of fentanyl. The validity of themodel structure was tested by its ability to describe publisheddata on the effect of hypo-, normo- and hypercarbia on the bloodand brain concentrations of fentanyl in anaesthetized dogs.

Results.The cerebral kinetics of fentanyl were consistent with partialmembrane limitation: the time to 50% equilibration with arterialblood was 10.0 min. Lung kinetics had two distinct components:a shallow compartment that was 50% equilibrated with blood in0.72 min, and a loss term probably representing sequestration.Despite its simplicity, the recirculatory model was an adequatedescription of the sheep data. The dog data could be describedif cerebral blood flow and cardiac output in the model wereallowed to differ between hypo-, normo- and hypercarbic states.The required flow changes were in good agreement with the knowneffect of these states in the dog.

Conclusions. A recirculatorymodel with the brain as a target organ defined the quantitativerelationship between the brain concentrations of fentanyl andthe circulatory state.

Keywords: brain, cerebral blood flow; heart, cardiac output; pharmacokinetics, brain; pharmacokinetics, fentanyl; pharmacokinetics, lung; pharmacokinetics, models.

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