Dynamics of heat, water, and soluble gas exchange in the human airways: 1. A model study

• Published in: Annals of biomedical engineering Vol. 16; no. 6; p. 547
• Main Authors: Tsu, M E, Babb, A L, Ralph, D D, Hlastala, M P
• Format: Journal Article
• Language: English
• Published: United States 01.01.1988
• Subjects: Body Temperature Regulation; Body Water - physiology; Energy Metabolism; Ethanol - pharmacology; Humans; Models, Biological; Pulmonary Gas Exchange - drug effects; Respiratory Physiological Phenomena
• ISSN: 0090-6964
• DOI: 10.1007/BF02368015

In order to provide a means for analysis of heat, water, and soluble gas exchange with the airways during tidal ventilation, a one dimensional theoretical model describing heat and water exchange in the respiratory airways has been extended to include soluble gas exchange with the airway mucosa and water exchange with the mucous layer lining the airways. Not only do heat, water, and gas exchange occur simultaneously, but they also interact. Heating and cooling of the airway surface and mucous lining affects both evaporative water and soluble gas exchange. Water evaporation provides a major source of heat exchange. The model-predicted mean airway temperature profiles agree well with literature data for both oral and nasal breathing validating that part of the model. With model parameters giving the best fit to experimental data, the model shows: (a) substantial heat recovery in the upper airways, (b) minimal respiratory heat and water loss, and (c) low average mucous temperatures and maximal increases in mucous thickness. For resting breathing of room air, heat and water conservation appear to be more important than conditioning efficiency. End-tidal expired partial pressures of very soluble gases eliminated by the lungs are predicted to be lower than the alveolar partial pressures due to the absorption of the expired gases by the airway mucosa. The model may be usable for design of experiments to examine mechanisms associated with the local hydration and dehydration dynamics of the mucosal surface, control of bronchial perfusion, triggering of asthma, mucociliary clearance and deposition of inhaled pollutant gases.