Lung tissue behavior in the mouse during constriction induced by methacholine and endothelin-1

Nagase, Takahide, Hirotoshi Matsui, Tomoko Aoki, YasuyoshiOuchi, and Yoshinosuke Fukuchi. Lung tissue behavior in the mouseduring constriction induced by methacholine and endothelin-1. J. Appl. Physiol. 81(6):2373-2378, 1996.Recently, mice have been extensively used toinvestigate the pathogenesis of pulmonary disease because appropriatemurine models, including transgenic mice, are being increasinglydeveloped. However, little information about the lung mechanics of miceis currently available. We questioned whether lung tissue behavior andthe coupling between dissipative and elastic processes, hysteresivity(), in mice would be different from those in the other species. Toaddress this question, we investigated whether tissue resistance (Rti)and  in mice would be affected by varying lung volume, constrictioninduced by methacholine (MCh) and endothelin-1 (ET-1), andhigh-lung-volume challenge during induced constriction. From measuredtracheal flow and tracheal and alveolar pressures in open-chest ICRmice during mechanical ventilation [tidal volume = 8 ml/kg,frequency (f) = 2.5 Hz], we calculated lung resistance(RL), Rti, airway resistance(Raw), lung elastance (EL),and  (=2fRti/EL). Underbaseline conditions, increasing levels of end-expiratory transpulmonarypressure decreased Raw and increased Rti. The administration ofaerosolized MCh and intravenous ET-1 increasedRL, Rti, Raw, andEL in a dose-dependent manner.Rti increased from 0.207 ± 0.010 to 0.570 ± 0.058 cmH₂O ^· ml^{1 ·} safter 10⁷ mol/kg ET-1(P < 0.01). After inducedconstriction, increasing end-expiratory transpulmonary pressuredecreased Raw. However,  was not affected by changing lung volume,constriction induced by MCh and ET-1, or high-lung-volume challengeduring induced constriction. These observations suggest that1)  is stable in mice regardlessof various conditions, 2) Rti is animportant fraction of RL andincreases after induced constriction, and3) mechanical interdependence mayaffect airway smooth muscle shortening in this species. In mammalianspecies, including mice, analysis of  may indicate that both Rti andEL essentially respond to asimilar degree.