Strong ions, weak acids and base excess: a simplified Fencl-Stewart approach to clinical acid-base disorders{dagger}

doi:10.1093/bja/aeh018

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British Journal of Anaesthesia, 2004, Vol. 92, No. 1 54-60
© 2004 The Board of Management and Trustees of the British Journal of Anaesthesia

Clinical Investigations

Strong ions, weak acids and base excess: a simplified Fencl–Stewart approach to clinical acid–base disorders

D. A. Story^*^,1, H. Morimatsu² and R. Bellomo²

¹ Department of Anaesthesia, and ² Department of Intensive Care, Austin and Repatriation Medical Centre, Heidelberg, Victoria 3084, Australia

*Corresponding author. E-mail: David.Story@austin.org.au
Presented in part at the Australian and New Zealand College of Anaesthetists Annual Scientific Meeting, May 12, 2002, Brisbane, Australia.

Background. The Fencl–Stewart approach to acid–basedisorders uses five equations of varying complexity to estimatethe base excess effects of the important components: the strongion difference (sodium and chloride), the total weak acid concentration(albumin) and unmeasured ions. Although this approach is straightforward,most people would need a calculator to use the equations. Weproposed four simpler equations that require only mental arithmeticand tested the hypothesis that these simpler equations wouldhave good agreement with more complex Fencl–Stewart equations.

Methods. We reduced two complex equations for the sodium–chlorideeffect on base excess to one simple equation: sodium–chlorideeffect (meq litre^–1)=[Na⁺]–[Cl^–]–38.We simplified the equation of the albumin effect on base excessto an equation with two constants: albumin effect (meq litre^–1)=0.25x(42–[albumin]g litre^–1).Using 300 blood samples from critically ill patients, we examinedthe agreement between the more complex Fencl–Stewart equationsand our simplified versions with Bland–Altman analyses.

Results. The estimates of the sodium–chloride effect onbase excess agreed well, with no bias and limits of agreementof –0.5 to 0.5 meq litre^–1. The albumin effectestimates required log transformation. The simplified estimatewas, on average, 90% of the Fencl–Stewart estimate. Thelimits of agreement for this percentage were 82–98%.

Conclusions. The simplified equations agree well with the previous,more complex equations. Our findings suggest a useful, simpleway to use the Fencl–Stewart approach to analyse acid–basedisorders in clinical practice.

Br J Anaesth 2004; 92: 54–60

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