Tachyphylaxis to furosemide in isolated airways of guinea pigs.

This in vitro study was conducted to determine whether tachyphylaxis of guinea pig airway to furosemide occurs under conditions that produce tachyphylaxis to the beta 2-adrenoceptor agonist, salbutamol. Isometric tension was measured in tracheal rings bathed in HEPES buffer from 4-6 d newborn guinea pigs of either sex, and 6 wk old males. Paired rings were first incubated with furosemide, 30 or 300 microM, or control for 60 min, washed, then constricted with 3 microM acetylcholine. At stable contraction, relaxation to furosemide (30 microM-1 mM) was measured. For comparison, similar experiments were performed with 10 microM salbutamol incubation for 30 min. 86Rb uptake, a marker for K+ transport and Na-K-Cl cotransport activity, was also measured in these airway segments. Pre-exposure to these airway relaxants did not affect contractile force generation by acetylcholine. Tracheal desensitization to both salbutamol and furosemide was observed. Partial recovery of furosemide induced relaxation was seen one hour after desensitization. Pre-exposure to 300 microM furosemide did not inhibit the decrease in 86Rb uptake normally observed with furosemide. In summary, we found that: 1) tachyphylaxis of guinea pig airway relaxation occurred with both salbutamol and furosemide under similar experimental conditions; however 2) inhibition of 86Rb uptake by furosemide was not affected by prior exposure. Taken together, these results suggest that furosemide induced airway relaxation could be affected by repeated or prolonged exposure, but this response may not be associated with changes in furosemide-sensitive Na-K-Cl cotransporter activity.

Furosemide-induced airway relaxation in guinea pigs: relation to Na-K-2Cl cotransporter function.

This study tested the hypothesis that airway relaxation to furosemide is mediated via the Na-K-2Cl cotransporter. If this mechanism exists in airway smooth muscle like in vascular smooth muscle, changes in airway relaxation should be associated with changes in Na-K-2Cl cotransporter function, and both should be substrate dependent. Tracheal rings from newborn guinea pigs were bathed in standard (STD) or varying low Cl- concentration ([Cl-]) N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid (HEPES). Isometric relaxation to 300 microM furosemide or 10(-8) to 10(-5) M salbutamol was measured. Airway segments were incubated with rubidium-86 (86Rb) in STD or varying low [Cl-] HEPES, with and without 300 microM furosemide or 25 microM salbutamol. Furosemide was unable to reduce 86Rb uptake at 10 mM [Cl-], although relaxation was still observed in 10 mM [Cl-]. Salbutamol did not affect 86Rb uptake. This study demonstrated that there is a furosemide-sensitive Na-K-2Cl cotransporter in newborn guinea pig trachea. However, the effect of furosemide on cotransporter function did not always directly correspond to differences in relaxation, suggesting that the Na-K-2Cl cotransporter may play a major, but not exclusive, role in furosemide-induced airway relaxation.

Amiloride-induced contraction of isolated guinea pig, mouse, and human fetal airways.

Nebulized amiloride has been proposed as therapy in cystic fibrosis to block Na+ hyperabsorption in airway epithelium and prevent dehydration of secretions. Patients with cystic fibrosis often have reaction airways. Bovine and canine trachea relax to amiloride in vitro, suggesting another benefit as a bronchodilator, whereas guinea pig trachea, a useful model of human airways, does not. We hypothesized that human airways would respond like guinea pig airways. Airway ring segments from guinea pigs, mice, and human fetuses were constricted with the concentration of acetylcholine producing 50-75% maximum contraction. Subsequent changes in isometric tension to cumulative additions of amiloride (10(-8)-10(-4) M) were measured. Guinea pig airways contracted 29 +/- 5%, mouse airways contracted 23 +/- 6%, and human fetal airways contracted 30 +/- 8%. Contraction to amiloride was mimicked by dimethylamiloride, a more selective inhibitor of the Na+/H+ antiporter, and was attenuated by protein kinase C (PKC) inhibition with GF109203X and staurosporine. The present study indicates that amiloride-induced airway contraction in guinea pigs and mice closely parallels the response in isolated human airways and that the mechanism may involve the Na+/H+ antiporter and PKC.