Base excess can be misleading in acute respiratory acidosis

Base excess (BE) is the measure of nonrespiratory change of acid-base status in the body. It is calculated after correcting the blood sample's pH to 7.4, temperature to 37°C and pCO₂ to 40 mmHg. Actual HCO₃ level is a metabolic parameter derived directly from the Henderson-Hasselbalch equation. There is some evidence that temporary changes in pCO₂ affect BE [1, 2], but little is known about the response of HCO₃. Therefore, the aim of this study was to investigate the relationship between BE and HCO₃ in critically ill patients immediately after admission to the ICU.

The first arterial blood gas samples (within 1 hour of admission) of patients admitted to our ICU were retrospectively evaluated and pH, HCO₃, pCO₂ and BE were registered and analysed. After testing the data distribution, correlation was determined with Pearson's correlation.

Arterial blood gas samples from 88 patients were analysed. There was a strong, significant correlation between BE and HCO₃ (r² = 0.93, P < 0.001) in the whole sample. In blood samples with pCO₂ > 45 mmHg, in 26 cases the pH was >7.3, and in 15 cases pH was <7.3 (that is, acute respiratory acidosis). In these cases with a cut-off BE <0 mmol/l, the BE had sensitivity = 73% and specificity = 85% for predicting acidosis. With a cut-off for HCO₃ < 24 mmol/l, the HCO₃ had sensitivity = 27% and specificity = 100% for acidosis. Choosing a cut-off for BE <-2 mmol/l, sensitivity = 47%, specificity = 100%; for HCO₃ < 22 mmol/l, sensitivity = 13%, specificity = 100%.

Although BE and HCO₃ had very good correlation in the whole sample, in acute respiratory acidosis BE indicated metabolic acidosis with high sensitivity, while the high specificity and low sensitivity of HCO₃ showed that there was no metabolic component of the acid-base imbalance. Therefore, in accord with previous studies, our preliminary results give further evidence that HCO₃ is a more reliable parameter to analyse acid-base balance in acute circumstances, especially in acute respiratory acidosis, than BE.

Authors and Affiliations

1. University of Szeged, College Station, Hungary

   S Kocsi, K Kiss, B Szerdahelyi, M Demeter & Z Molnar

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