Evaluation of Peripheral Airways

An alveolar capsule oscillation technique was used to determine 1) the lobe pressure and volume at which airways close and reopen, 2) the effect of expiration rate on closing volume and pressure, 3) the phase in the breathing cycle at which airway closure occurs, and 4) the site of airway closure. Experiments were conducted in excised dog lobes; closure was detected by an abrupt increase in the input impedance of surfacemounted alveolar capsules. Mean transpulmonary pressure (Ptp) at closure was slightly less than zero (Ptp = -2.3 cmH2O); the corresponding mean reopening pressure was Ptp = 14 cmH2O. The expiration rate varied between 1 and 20% of total lobe capacity per second and had no consistent effect on the closing volume and pressure. When lung volume was cycled up to frequencies of 0.2 Hz, closure generally occurred on expiration rather than inspiration. These observations support the conclusion that mechanical collapse, rather than meniscus formation, is the most likely mechanism producing airway closure in normal excised dog lungs. Analysis of measured acoustic impedances and reopening pressures suggests that closure occurs in the most peripheral airways. Reopening during inspiration was often observed to consist of a series of stepwise decreases in capsule impedance, indicating a sequence of opening events.

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Respiratory input impedance in anesthetized paralyzed patients

Journal of Applied Physiology ◽

10.1152/jappl.1990.69.4.1372 ◽

1990 ◽

Vol 69 (4) ◽

pp. 1372-1379 ◽

Cited By ~ 43

Author(s):

D. Navajas ◽

R. Farre ◽

J. Canet ◽

M. Rotger ◽

J. Sanchis

Keyword(s):

Mechanical Model ◽

Forced Oscillation ◽

Respiratory Resistance ◽

Frequency Range ◽

Entire Frequency Range ◽

Peripheral Airways ◽

Distal Branch ◽

Low Amplitude ◽

Gas Compressibility ◽

Central Airway

Respiratory impedance (Zrs) was measured between 0.25 and 32 Hz in seven anesthetized and paralyzed patients by applying forced oscillation of low amplitude at the inlet of the endotracheal tube. Effective respiratory resistance (Rrs; in cmH2O.l-1.s) fell sharply from 6.2 +/- 2.1 (SD) at 0.25 Hz to 2.3 +/- 0.6 at 2 Hz. From then on, Rrs decreased slightly with frequency down to 1.5 +/- 0.5 at 32 Hz. Respiratory reactance (Xrs; in cmH2O.l-1.s) was -22.2 +/- 5.9 at 0.25 Hz and reached zero at approximately 14 Hz and 2.3 +/- 0.8 at 32 Hz. Effective respiratory elastance (Ers = -2pi x frequency x Xrs; in cmH2O/1) was 34.8 +/- 9.2 at 0.25 Hz and increased markedly with frequency up to 44.2 +/- 8.6 at 2 Hz. We interpreted Zrs data in terms of a T network mechanical model. We represented the proximal branch by central airway resistance and inertance. The shunt pathway accounted for bronchial distensibility and alveolar gas compressibility. The distal branch included a Newtonian resistance component for tissues and peripheral airways and a viscoelastic component for tissues. When the viscoelastic component was represented by a Kelvin body as in the model of Bates et al. (J. Appl. Physiol. 61: 873-880, 1986), a good fit was obtained over the entire frequency range, and reasonable values of parameters were estimated. The strong frequency dependence of Rrs and Ers observed below 2 Hz in our anesthetized paralyzed patients could be mainly interpreted in terms of tissue viscoelasticity. Nevertheless, the high Ers we found with low volume excursions suggests that tissues also exhibit plasticlike properties.

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Hypocapnia-induced constriction of the canine peripheral airways exhibits tachyphylaxis

Journal of Applied Physiology ◽

10.1152/jappl.1987.63.2.497 ◽

1987 ◽

Vol 63 (2) ◽

pp. 497-504 ◽

Cited By ~ 11

Author(s):

J. Kolbe ◽

S. R. Kleeberger ◽

H. A. Menkes ◽

E. W. Spannhake

Keyword(s):

Prolonged Exposure ◽

Atropine Sulfate ◽

Chlorpheniramine Maleate ◽

Mechanically Ventilated ◽

Peripheral Airways ◽

Airway Constriction ◽

Peripheral Lung ◽

Histamine H1 Receptors ◽

Constrictor Response ◽

Compensatory Effect

Hypocapnia-induced constriction of peripheral airways may be important in regulating the distribution of ventilation in pathological conditions. We studied the response of the peripheral lung to hypocapnia in anesthetized, paralyzed, mechanically ventilated dogs using the wedged bronchoscope technique to measure resistance of the collateral system (Rcs). A 5-min hypocapnic challenge produced a 161 +/- 19% (mean +/- SE) increase in Rcs. The magnitude of this response was not diminished with repeated challenge or by atropine sulfate (1 mg base/kg iv), chlorpheniramine maleate (5 mg base/kg iv), or indomethacin (5 mg/kg iv). The response was reduced by 75% by isoproterenol (5 micrograms/kg iv) (P less than 0.01) and reduced by 80% by nifedipine (20 micrograms/kg iv) (P less than 0.05). During 30-min exposure to hypocapnia the maximum constrictor response occurred at 4–5 min, after which the response attenuated to approximately 50% of the maximum response (mean = 53%, range 34–69%). Further 30-min challenges with hypocapnia resulted in significantly decreased peak responses, the third response being 50% of the first (P less than 0.001). The inability of indomethacin or propranolol to affect the tachyphylaxis or attenuation of the response suggests that neither cyclooxygenase products nor beta-adrenergic activity was involved. Hence, hypocapnia caused a prompt and marked constrictor response in the peripheral lung not associated with cholinergic mechanisms or those involving histamine H1-receptors or prostaglandins. With prolonged exposure to hypocapnia there was gradual attentuation of the constrictor response with continued exposure and tachyphylaxis to repeated exposure both of which would tend to diminish any compensatory effect of hypocapnic airway constriction on the distribution of ventilation.

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Simulation of the effects of mechanical nonhomogeneities on expiratory flow from human lungs

Journal of Applied Physiology ◽

10.1152/jappl.1990.68.6.2550 ◽

1990 ◽

Vol 68 (6) ◽

pp. 2550-2563 ◽

Cited By ~ 3

Author(s):

R. K. Lambert

Keyword(s):

Fluid Mechanics ◽

Left Lung ◽

Flow Volume ◽

Alveolar Pressure ◽

Peripheral Airways ◽

Volume Curve ◽

Human Lungs ◽

Flow Volume Curve ◽

Expired Gas ◽

Expiratory Flow

A computational model for expiration from lungs with mechanical nonhomogeneities was used to investigate the effect of such nonhomogeneities on the distribution of expiratory flow and the development of alveolar pressure differences between regions. The nonhomogeneities used were a modest constriction of the peripheral airways and a 50% difference in compliance between regions. The model contains only two mechanically different regions but allows these to be as grossly distributed as left lung-right lung or to be distributed as a set of identical pairs of parallel nonhomogeneous regions with flows from each merging in a specified bronchial generation. The site of flow merging had no effect on the flow-volume curve but had a significant effect on the development of alveolar pressure differences (delta PA). With the peripheral constriction, greater values of delta PA developed when flows were merged peripherally rather than centrally. The opposite was true in the case of a compliance nonhomogeneity. The delta PA values were smaller at submaximal flows. Plots of delta PA vs. lung volume were similar to those obtained experimentally. These results were interpreted in terms of the expression used for the fluid mechanics of the merging flows. delta PA was greater when the viscosity of the expired gas was increased or when its density was reduced. Partial forced expirations were shown to indicate the presence of mechanical nonhomogeneity.

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