Cultured CO2-sensitive neurons from the ventrolateral medulla of newborn rats enhanced their bioelectric activity upon intracellular acidification induced by inhibition of the Na+/H+ exchanger type 3 (NHE3). Now we detected NHE3 also in the medulla oblongata of adult rabbits. Therefore, this animal model was employed to determine whether NHE3 inhibition also affects central respiratory chemosensitivity in vivo. Seven anesthetized (pentobarbital), vagotomized, paralyzed rabbits were artificially ventilated with O2-enriched air. From the phrenic nerve compound discharge, integrated burst amplitude (IPNA), respiratory rate (fR), and phrenic minute activity (IPNA. fR) were taken as measures of central respiratory rhythm and drive. Effects of potent NHE3 inhibition with the novel brain permeant substance S8218 were studied by comparing respiratory characteristics before and after up to 9.2 +/- 1.1 mg/kg cumulative drug application, yielding average plasma concentrations of 0.9 +/- 0.2 microg/ml. In response to S8218, the baseline level of IPNA. fR was significantly enhanced by an average of 51.0 +/- 6.4% (n = 27, p < 0.0001). The influence of NHE3 inhibition on the respiratory CO2 response was studied at plasma concentrations of S8218 maintained in the range of 0.3 microg/ml (10(-6) M). Although the metabolic acid-base status thereby remained widely unchanged, the group mean apneic threshold PaCO2 was significantly lowered by 0.45 +/- 0.11 kPa (n = 7, p < 0.01), whereby in four of seven animals even strong hyperventilation failed to suppress phrenic nerve rhythmicity completely. Likewise, S8218 significantly augmented IPNA. fR, in the range of PaCO2 between 1 and 6 kPa above threshold, by an average of 38.0 +/- 8.5% (n = 35, p < 0.0001). These in vivo results are compatible with the effects of NHE3 inhibition on chemosensitive brainstem neurons in vitro. Moreover, rhythmogenesis is supported through NHE3 inhibition by lowering the threshold PCO2 for central apnea.
In human medicine, the carbonic anhydrase (CA) inhibitor acetazolamide is used to treat irregular breathing disorders. Previously, we demonstrated in the rabbit that this substance stabilized closed-loop gain properties of the respiratory control system, but concomitantly weakened respiratory muscles. Among others, the highly diffusible CA-inhibitor methazolamide differs from acetazolamide in that it fails to activate Ca 2+ -dependent potassium channels in skeletal muscles. Therefore, we aimed to find out, whether or not methazolamide may exert attenuating adverse effects on respiratory muscle performance as acetazolamide. In anesthetized spontaneously breathing rabbits ( n = 7), we measured simultaneously the CO 2 responses of tidal phrenic nerve activity, tidal transpulmonary pressure changes, and tidal volume before and after intravenous application of methazolamide at two mean (± SE) cumulative doses of 3.5 ± 0.1 and 20.8 ± 0.4 mg/kg. Similar to acetazolamide, low- and high-dose methazolamide enhanced baseline ventilation by 52 ± 10% and 166 ± 30%, respectively ( P < 0.01) and lowered the base excess in a dose-dependent manner by up to 8.3 ± 0.9 mmol/l ( P < 0.001). The transmission of a CO 2 -induced rise in phrenic nerve activity into volume and/or pressure and, hence, respiratory work performance was 0.27 ± 0.05 ml·kg −1 ·kPa·unit −1 under control conditions, but remained unchanged upon low- or high-dose methazolamide, at 0.30 ± 0.06 and 0.28 ± 0.07 ml·kg −1 ·kPa·unit −1 , respectively. We conclude that methazolamide does not cause respiratory muscle weakening at elevated levels of ventilatory drive. This substance (so far not used for medication of respiratory diseases) may thus exert stabilizing influences on breathing control without adverse effects on respiratory muscle function.
We studied the acute effect of a single, oral dose of 200 mg almitrine and of placebo on arterial blood gas tensions, ventilation, gas exchange and pulmonary mechanics in 28 patients with chronic obstructive bronchitis and emphysema (COPD), 20 patients with bronchial asthma and 10 patients with interstitial lung disease. Almitrine significantly increased PaO2 in COPD, had a borderline effect in bronchial asthma and no effect in lung fibrosis. In all groups of patients almitrine significantly increased minute ventilation and decreased arterial carbon dioxide tension (PaCO2). Placebo had no effect on arterial oxygen tension (PaO2) and PaCO2 in any of the groups. Therefore, despite similar effects on ventilation, the improvement of arterial PO2 by almitrine depends on the underlying disease.
Abstract The carbonic anhydrase (CA) inhibitor acetazolamide is a classic drug to treat patients with breathing disorders. Recent studies in rabbits showed that low-dose acetazolamide (not causing appreciable inhibition of red cell CA) significantly weakened respiratory muscle performance, accompanied by diminished ventilatory CO2-sensitivity, which implies stabilizing loop-gain properties. Now is aimed to explore the interaction of these factors under conditions of complete CA-inhibition by acetazolamide in a higher dose-range. In anesthetized rabbits (N=7), acetazolamide (up to 75 mg·kg−1) distinctly lowered the base excess (to-7.6 ± 0.9mM, mean ± SEM) without respiratory compensation of arterial pH. Ventilatory CO2-sensitivity was nearly abolished to 15.1 ± 5.2% of control, but the transmission of a CO2-mediated rise in tidal phrenic activity into respiratory work was only reduced by 51.6 ± 6.4%, P < 0.001, not very much more than (~38%) already observed at low-doses. Thus, the large reduction of ventilatory CO2-sensitivity in the high-dose range cannot be ascribed to respiratory muscle weakening, but rather may relate to complete inhibition of red cell CA. Conversely, CA-inhibition may not be the only cause for the weakening effect of acetazolamide on (respiratory) muscles. Adverse effects on respiratory muscles, impaired CO2-transport and acid-base imbalance may limit to make use of stabilizing effects on breathing control functions by high-dose acetazolamide.
