A change from HCO3(‐)‐CO2‐ to hepes‐buffered medium modifies membrane properties of rat CA1 pyramidal neurones in vitro.

1. Intracellular recordings were obtained from CA1 pyramidal neurones in rat hippocampal slices. Perfusion with a HCO3(‐)‐CO2‐free, HEPES‐buffered medium at pH 7.4 produced a wide variety of reversible effects on neuronal excitability, compared to responses obtained under standard (21 mM‐HCO3‐, 5% CO2, pH 7.4) conditions. 2. Introduction of HCO3(‐)‐CO2‐free medium most commonly elicited, within 5‐20 min, a fall in resting membrane potential (Vm), a rise in threshold for Na(+)‐dependent action potential generation, and a reduction in input resistance. Anomalous inward rectification in the hyperpolarizing direction and subthreshold inward rectification were commonly reduced in HEPES‐buffered medium. More prolonged exposure (> or = 25 min) to HCO3(‐)‐CO2‐free medium produced, on occasion, Na+ spike inactivation. 3. The amplitudes of the fast and medium after‐hyperpolarizations (AHPs) following a single depolarizing current‐evoked action potential were attenuated during perfusion with HEPES‐buffered medium at pH 7.4, as was the composite AHP following a train of action potentials. 4. Perfusion with HEPES‐buffered medium at pH 7.4 reduced the degree of spike frequency adaptation and abolished depolarizing current‐evoked burst‐firing behaviour when this was present under standard conditions. 5. In tetrodotoxin (TTX)‐ and tetraethylammonium (TEA)‐poisoned neurones, perfusion with HCO3(‐)‐CO2‐free medium at pH 7.4 slightly raised the threshold for activation of Ca(2+)‐dependent potentials and slightly reduced their duration, compared to responses obtained in HCO3(‐)‐CO2‐buffered medium at the same pH. The AHP following the Ca2+ spike was, however, markedly attenuated. 6. Perfusion with a low‐pH HCO3(‐)‐CO2‐buffered medium (7 mM‐HCO3‐, 5% CO2, pH 6.9) produced changes qualitatively similar to those observed during perfusion with HEPES‐buffered medium at pH 7.4. Raising the pH of the HEPES‐buffered medium to 7.8 or 7.9 reversed inconsistently and then only in part the changes noted on the transition from a HCO3(‐)‐CO2‐ to a HEPES‐buffered medium at the same pH (7.4). 7. The effects noted are unlikely to be due to a direct action of HEPES itself on neuronal membrane conductances. Rather, I suggest that they are likely to be caused by intracellular acidosis consequent upon the omission of HCO3‐ and CO2 from the extracellular medium.