The acute impact of NaHCO3 in treatment of metabolic acidosis on back-titration of non-bicarbonate buffers: a quantitative analysis.
Objective: The major non-bicarbonate buffers are intracellular proteins, a detrimental effect of severe acidosis could be their titration with H+. This in turn would lead to their net charge becoming more positive, and possibly, to changes in their shape and function. Since NaHCO3 is a treatment option in patients with severe metabolic acidosis, the purpose of this study was to examine the acute effect of the administration of NaHCO3 on back-titration of non-bicarbonate buffers in metabolic acidosis.
Methods: Prospective, controlled, non-randomized laboratory study. Methods: Research laboratory. Methods: 21 male Wistar rats. Methods: Rats were anesthetized, intubated and ventilated. Ventilation was adjusted at the beginning of the experiment to a PCO2 of approximately 30 mmHg, no further adjustments were made thereafter. Acute metabolic acidosis was induced by the infusion of 3.5 mmol of hydrochloric acid over 1 hour. After an equilibration period, 3 groups of seven rats were studied; group I received 0.75 mmol NaHCO3, group II received equimolar NaCl, and group III served as time control.
Results: Measurements were made to enable quantitation of how much HCO3 was retained in the ECF and how much was titrated with H+ and was excreted as "acid-base" CO2. Since there are so few H+ present in the ECF in a free or a bound form, and in the absence of an increase in endogenous acid-production, the source of this H+ is from proteins in the ICF. As compared to the NaCl and the time control groups, the administration of NaHCO3 led to significant alkalinization of the ECF, pH rose from 7.22 +/- 0.03 to 7.34 +/- 0.02. Of the 0.75 mmol of NaHCO3 that was administered, 67% or 0.52 +/- 0.08 mmol was retained in ECF. Only a small amount (0.07 +/- 0.09 mmol) of acid-base CO2 was excreted.
Conclusions: The administration of NaHCO3 does not acutely lead to a significant back-titration of non-bicarbonate buffers, especially under conditions of fixed ventilation.