Relative hysteresis of the airways and lung parenchyma in normal subjects

We evaluated the mechanical properties of the airways sequentially from the glottis toward the main bronchi in 10 normal subjects. Plots of airway cross-sectional area vs. lung volume, measured during inspiration and expiration, were used to determine the relative magnitude of the airways vs. parenchymal hysteresis. Airway cross-sectional area was measured by means of the acoustic reflection technique. We found that the hysteresis of the proximal part of the trachea was greater than that of the lung parenchyma, whereas the hysteresis of the distal trachea and subcarinal segments of the airways was smaller than that of the lung parenchyma. The transition zone between the proximal and the more distal airway properties occurred 8-26 cm distal to the glottis. This transition zone was reproducible in its location on repeated testing in each subject but varied among subjects. To the extent that relative hysteresis of the airways depends on bronchomotor tone, our findings suggest that the bronchomotor tone is inhomogeneous, being maximal at the proximal part of the trachea and gradually decreasing toward the more distal trachea and subcarinal airway segments.     

Effects of hypercarbia on arterial and alveolar oxygen tensions in a model of gram-negative pneumonia

Inspired CO2 causing changes from hypo- to normocapnia has previously been shown to improve arterial O2 tension (PaO2) and to reduce alveolar-arterial O2 difference. The effect of further increases in inspired CO2 to hypercarbic levels has not been studied in inflammatory lung disease. Three days after induction of sublobar Pseudomonas pneumonia, Suffolk sheep were anesthetized and ventilated with a fixed-volume ventilator. After 2.5 h, CO2 was added to the inspired gas to raise arterial CO2 tension (PaCO2) to 60-65 Torr. Four hours later the CO2 was withdrawn and ventilation continued for an additional 2 h. Constant minute ventilation and inspired O2 fraction were maintained. Regional lung perfusion was measured by injection of radioactive microspheres. With the administration of CO2, PaO2 increased significantly from 65.5 to 77.5 Torr as did alveolar O2 tension (from 109.7 to 120.0 Torr) with no significant change in alveolar-arterial O2 difference. There were no significant changes in cardiac output, shunt fraction, O2 uptake, O2 delivery, respiratory quotient, or distribution of regional lung perfusion. We conclude that the increases in alveolar O2 tension and PaO2 with the added CO2 resulted from improved alveolar ventilation.     

Pressure-flow relationships of endotracheal tubes during high-frequency ventilation

We studied the pressure-flow relationships of various endotracheal tubes (ETT) at frequencies (f) and tidal volumes (VT) in the range used for high-frequency ventilation (HFV) (f: 2-32 Hz, VT: 15-100 ml). Sinusoidal flows were applied to ETT inserted into a rigid bottle or into the tracheae of three anesthetized paralyzed dogs, while pressure fluctuations were measured both proximal and distal to the ETT. The pressure drops in the ETT were nonlinearly related to the peak flow rate and were VT dependent, suggesting that turbulent frictional head loss and convective acceleration were important. The pressure drops measured in vitro were found to be in good agreement with the predictions of a nonlinear oscillatory pressure-flow equation (derived herein), which incorporate the effects of turbulent frictional losses, convective acceleration, inertance, and compliance. The pressure drops measured in situ were 30-50% higher than with the corresponding f-VT combinations in vitro. Possible explanations of these differences are junctional losses at the tip of the ETT or the nonrigid character of the trachea.     

Chemical biology: Paper alert

A selection of interesting papers that were published in the two months before our press date in major journals most likely to report significant results in chemical biology.