Cerebral and lung kinetics of morphine in conscious sheep after short intravenous infusions

doi:10.1093/bja/aeg131

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British Journal of Anaesthesia, 2003, Vol. 90, No. 6 750-758
© 2003 The Board of Management and Trustees of the British Journal of Anaesthesia

Laboratory Investigations

Cerebral and lung kinetics of morphine in conscious sheep after short intravenous infusions

R. N. Upton¹, G. L. Ludbrook¹, A. M. Martinez¹, C. Grant¹ and R. W. Milne²

¹ Department of Anaesthesia and Intensive Care, Royal Adelaide Hospital, University of Adelaide, SA 5005 Adelaide, Australia. ² Centre for Pharmaceutical Research, School of Pharmacy and Medical Sciences, University of South Australia, Adelaide, Australia

Corresponding author. E-mail: richard.upton@adelaide.edu.au

Background. The analgesic effects of morphine are delayed relativeto its concentration in blood. The rate of equilibration ofmorphine between blood and brain may contribute to this delay,but the kinetics of this process have not been modelled. Thiswas determined in conscious instrumented sheep. The lung kineticsof morphine were also determined given their importance in definingsystemic kinetics after i.v. bolus administration.

Methods. Sheep were given short i.v. infusions of morphine (30mg over 4 min). Cerebral kinetics were inferred from arterio–sagittalsinus concentration gradients and cerebral blood flow, and lungkinetics from the pulmonary artery–aortic gradient andcardiac output. These data were fitted to flow- and membrane-limitedmodels of the kinetics in each organ.

Results. Morphine had minimal cardiovascular effects, did notalter cerebral blood flow and caused insignificant respiratorydepression. Lung kinetics were best described by a single distributionvolume (2036 ml) with a first-order loss (1370 ml min^–1),which was attributed to deep distribution. The cerebral kineticsof morphine were characterized by a significant permeabilitybarrier. Permeability across the barrier (7.44 ml min^–1)was estimated with good precision, and was approximately one-fifthof the nominal cerebral blood flow. The distribution volumeof morphine in the brain was estimated with less precision,but was described by a brain:blood partition coefficient ofapproximately 1.4. The time required for 50% equilibration betweenbrain and blood concentrations was approximately 10.3 min.

Conclusion. The cerebral equilibration of morphine was relativelyslow, and was characterized by significant membrane limitation.

Br J Anaesth 2003; 90: 750–8

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