Journal of applied physiology
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We tested the hypothesis that features of upper airway and tracheal geometry can be inferred from acoustic reflection data recorded at the mouth. In six subjects we computed inferences of airway cross-sectional area vs. distance and compared them with measurements obtained from orthogonal radiographic projections of the trachea. The acoustic data show local area maxima at the uvula and hypopharynx and local minima at the oropharynx and the glottis. ⋯ With subjects breathing 80% He-20% O2 there was good intrasubject agreement between acoustic and radiographic data in spite of large intersubject variability. The average coefficient of variation of tracheal area determinations for five trials in all subjects was 0.16. These studies suggest that features of airway geometry between the mouth and carina can be determined accurately and noninvasively in individual subjects from high-frequency reflection data measured at the mouth.
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We have attempted to determine both experimentally and theoretically whether a significant quantity of oxygen enters the pulmonary blood before it reaches the alveolar wall capillaries. We built a microspectrophotometer that allowed us to record oxyhemoglobin saturation values with light reflected from transected frozen pulmonary arteries as small as 100 microns in diameter. We prepared anesthetized cats to provide optimal conditions for precapillary oxygenation, quickly froze their lungs with chilled liquid propane, and removed these lungs. ⋯ These data did not tell us how much this process normally contributes to total lung oxygenation because propane did not freeze the lungs fast enough to capture conditions exactly as they are in life. We therefore made several calculations to estimate the extent of precapillary oxygenation using available data on pulmonary arterial geometry and diffusing capacity. We concluded that pulmonary arterial blood may be as much as 15% oxygenated by this process at rest and as much as 100% during oxygen breathing.
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Bradykinin is released in the lungs in asthma and pulmonary anaphylaxis. It has negligible direct bronchoconstrictor effects in humans or dogs, but inhaled as aerosol it causes cough and reflex bronchoconstriction in asthmatics and some normal subjects. The afferent nerves responsible for these reflex effects have not been identified. ⋯ Bradykinin caused a small increase in firing of some rapidly adapting (irritant) receptors, but the effect appeared to be secondary to vascular changes. Bradykinin had variable effects on slowly adapting stretch receptors, but did not stimulate them directly. Thus vagally mediated sensory or reflex effects initiated by bradykinin in the lung are probably due to stimulation of "bronchial" C-fibers.
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Distributions of ventilation and perfusion relative to Va/Q were determined in seven young healthy volunteers (24-33 yr) while they were either in the supine or right lateral decubitus position. The subjects were studied first awake and then while anesthetized-paralyzed and breathing 30% oxygen and again while breathing 100% oxygen. ⋯ Ventilating the lungs with 100% oxygen further increased the dispersion of blood flow distribution during anesthesia-paralysis; lung units with low Va/Q or right-to-left intrapulmonary shunts (or both) developed. With induction of anesthesia-paralysis and intubation of the trachea, the anatomic dead space was decreased and the alveolar dead space increased.
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We perfused the left lower lobe of the dog lung with constant flow. When the lobar venous outflow was occluded, the lobar venous pressure rose suddenly to a level somewhere below the arterial pressure, and then the arterial and venous pressures began to rise more slowly. A possible explanation for this response is that, when the outflow was occluded, flow through some downstream segment of the bed ceased. ⋯ In an attempt to better understand the meaning of the upstream and downstream pressure drops, we examined the influence of pulmonary vasoconstriction and flow direction on the size of the upstream and downstream pressure drops. We also compared these pressure drops with the pressure drops occurring upstream and downstream from the midpoint of the lobar vascular volume, using the low-viscosity bolus technique. The results indicate that changes in the upstream and downstream pressure drops, as evaluated by outflow occlusion, reflect changes in the lobar arterial and venous resistances.