Quantitative Analysis of Acid-Base Disorders in Patients With Chronic Respiratory Failure in Stable or Unstable Respiratory Condition

Abstract

BACKGROUND:

The Stewart approach theorizes that plasma pH depends on P_aCO₂, the strong ion difference, and the plasma total concentration of non-volatile weak acids (A_tot). The conventional approach measures standardized base excess, bicarbonate (HCO₃ ^–), and the anion gap.

OBJECTIVE:

To describe acid-base disorders with the Stewart approach and the conventional approach in patients with chronic respiratory failure.

METHODS:

This was an observational prospective study in a medical intensive care unit and a pneumology ward of a university hospital. There were 128 patients included in the study, of which 14 had more than one admission, resulting in 145 admissions. These were allocated to 4 groups: stable respiratory condition and elevated HCO₃ ^– (Group 1, n = 23), stable respiratory condition and non-elevated HCO₃ ^– (Group 2, n = 41), unstable respiratory condition and elevated HCO₃ ^– (Group 3, n = 44), and unstable respiratory condition and non-elevated HCO₃ ^– (Group 4, n = 37). Elevated HCO₃ ^– was defined as ≥ 3 standard deviations higher than the mean value we found in 8 healthy volunteers. Measurements were taken on admission.

RESULTS:

In groups 1, 2, 3, and 4, the respective mean ± SD values were: HCO₃ ^– 33 ± 3 mM, 26 ± 3 mM, 37 ± 4 mM, and 27 ± 3 mM (P < .001); strong ion difference 45 ± 3 mM, 38 ± 4 mM, 46 ± 4 mM, and 36 ± 4 mM (P < .001); and A_tot 12 ± 1 mM, 12 ± 1 mM, 10 ± 1 mM, 10 ± 2 mM (P < .001). Non-respiratory disorders related to high strong ion difference were observed in 12% of patients with elevated HCO₃ ^–, and in none of those with non-elevated HCO₃ ^– (P = .003). Non-respiratory disorders related to low strong ion difference were observed in 9% of patients with non-elevated HCO₃ ^–, and in none of those with elevated HCO₃ ^– (P = .02). Hypoalbuminemia was common, especially in unstable patients (group 3, 66%; group 4, 65%). Normal standardized base excess (16%), HCO₃ ^– (28%), and anion gap (30%) values were common. The Stewart approach detected high effective strong ion difference in 13% of normal standardized base excess, and in 20% of normal anion gap corrected for albuminemia, and low effective strong ion difference in 22% of non-elevated HCO₃ ^–.

CONCLUSIONS:

In patients with chronic respiratory failure the acid-base pattern is complex, metabolic alkalosis is present in some patients with elevated HCO₃ ^–, and metabolic acidosis is present in some with non-elevated HCO₃ ^–. The diagnostic performance of the Stewart approach was better than that of the conventional approach, even when corrected anion gap was taken into account.

Keywords

chronic respiratory failure acute respiratory failure acid-base balance metabolic alkalosis respiratory acidosis

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