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European Journal of Applied Physiology
Erschienen in: European Journal of Applied Physiology 2-3/2004

01.03.2004 | Original Article

Effects of the ventilation pattern and pulmonary blood flow on lung heat transfer

verfasst von: V. B. Serikov, N. W. Fleming, V. A. Talalov, F. A. Stawitcke

Erschienen in: European Journal of Applied Physiology | Ausgabe 2-3/2004

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Abstract

To investigate the relative role of pulmonary perfusion compared to ventilation on lung heat exchange, we determined the effects of blood flow, tidal volume and frequency of ventilation on the rate of lung heat transfer. In anesthetized dogs and isolated, perfused lungs, we investigated the dependence of the overall lung heat transfer coefficient (HTC) and lung thermal capacitance upon ventilation and pulmonary blood flow. The relationship between the HTC and pulmonary blood flow was strongly dependent on ventilation parameters. A distributed model of non-steady-state heat exchange adequately described these observations and demonstrated that changes in pulmonary blood flow may be considered as changes in the effective conductivity of the bronchial walls as 0.4 (0.1) J s−1m−1 K−1 per (l/min−1) of pulmonary blood flow. Our model describes the complex relationship between HTC, ventilation pattern, and effective thermal conductivity of the bronchial walls, all of which present limitations for the use of lung heat transfer to determine pulmonary blood flow.
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Literatur
Bernard SL, Glenny RW, Polisar N, Luchtel DL, Lakshminarayan S (1996) Distribution of pulmonary and bronchial blood supply to airways measured by microspheres. J Appl Physiol 80:430–436PubMed
Bui T, Dabdub D, George S (1998) Modeling bronchial circulation with application to soluble gas exchange: description and sensitivity analysis. J Appl Physiol 84:2070–2088PubMed
Cano A, Kambara K, Arakawa M, Ando F, Ohno M, Tsuchiya M, Nishigaki K, Fujiwara H (1995) Effects of ventilation and pleural effusion on measurements of airway thermal volume and blood flow in dogs lungs. J Appl Physiol 79:1320–1329PubMed
Chato JC (1981) Heat transfer to blood vessels. Trans ASME 102:110–118
Cropp GJA, Burton AC (1966) Theoretical considerations and model experiments on the validity of indicator dilution methods for measurements of variable flow. Circ Res 18:26–48PubMed
Daviscas E, Gonda I, Anderson SD (1990) Mathematical modeling of heat and water transport in human respiratory tract. J Appl Physiol 69:362–372PubMed
Eisner AD (1989) Simulation of heat and mass transfer processes in a surrogate bronchial system developed for hygroscopic aerosol studies. Aerosol Sci Technol 11:39–57
Eschenbacher WL, Sheppard D (1985) Respiratory heat loss is not the sole stimulus for bronchoconstriction induced by isocapnic hyperpnea with dry air. Am Rev Respir Dis 131:894-901PubMed
Ferrus L, Guenard H, Vardon G, Varene P (1980) Respiratory water loss. Respir Physiol 39:367-381CrossRefPubMed
Ganapati Mauze, Serikov VB (2000) Thermometric apparatus and method for determining the concentration of a vapor in a gas stream. US Patent 6038922
Ganapati Mauze, Serikov VB, Greenstein M (1998) A fast miniature sensor for real-time monitoring of humidity in human breathing circuits. Proceedings 3rd International Symposium of Humidity and Moisture. National Physical Laboratory, London, UK, pp. 343–344
George SG, Babb AL, Hlastala MP (1990) Dynamics of soluble gas exchange in the airways. III. Single exhalation maneuver. J Appl Physiol 75:2439–2449
Hanna LM, Scherer WP (1986) A theoretical model of localized heat and water vapor transport in the human respiratory tract. J Biomech Eng 108:12-18PubMed
Holman JP (1968) Heat transfer. McGraw-Hill, New York, pp 156–169
Horsfield K, Cumming G (1976) Morphology of the bronchial tree in the dog. Respir Physiol 26:173–182CrossRefPubMed
Huang PH (1990) Humidity sensing measurements and calibration standards. Sensors 2:12–22
Ingenito EP, Solway J, McFadden JR, Drazen JM, Cravalho EG (1986) Finite difference analysis of respiratory heat transfer. J Appl Physiol 61:2252-2259PubMed
Ingenito EP, Solway J, McFadden ER, Pichurko B, Bowman HF, Michaels D, Drazen JM (1987) Indirect assessment of mucosal surface temperature in the airways: theory and tests. J Appl Physiol 63:2075–2083PubMed
McFadden ER Jr, Pichurko BM (1985) Intra-airway thermal profiles during exercise and hyperventilation in normal man. J Clin Invest 76:1007–1010PubMed
McFadden ER Jr, Pichurko BM, Bowman HF, Ingenito E, Burns S, Dowling N, Solway J (1985) Thermal mapping of the airways in humans. J Appl Physiol 58:564-570CrossRefPubMed
Parish OO, Putnam WT (1977) Equations for the determination of humidity from dew point and psychrometric data. Technical Notes TN D-8401 NASA
Perl W (1962) Heat and matter distribution in body tissues and determination of tissue blood flow by local clearance methods. J Theor Biol 2:201-235
Primiano FP, Saidel GM, Montague FW, Kruse KL, Green CG, Horowitz JG (1988) Water vapor and temperature dynamics in the upper airways of normal and CF subjects. Eur Respir J 1:407–414PubMed
Ramm MS, Serikov VB, Shulga VP, Belyakov NA (1989) Simulation of non-steady-state heat and mass exchange of air in the lungs. Physiologich J (Kiev) 35:113–119
Ray DW, Ingenito EP, Strek M, Schumacker PM, Solway J (1989) Longitudinal distribution of canine respiratory heat and water exchange. J Appl Physiol 66:2788-2798PubMed
Serikov VB, Jerome EH (1997) Non-invasive measurements of cardiac output in sheep: a new improved method. J Biomed Eng 19:618–629CrossRef
Serikov VB, Ramm MS, Kambara K, Bootomo MI, Osmack AR, Staub NC (1992) Application of respiratory heat exchange for the measurement of lung water. J Appl Physiol 72:943–955
Serikov VB, Jerome EH, Fleming NW, Moore PG, Stawitcke FA, Staub NC (1997) Airway thermal volume in humans and its relation to body size. J Appl Physiol 83:668–676PubMed
Solway J, Pichurko BM, Ingenito EP, McFadden ER, Fanta CH, Ingram RH, Drazen JM (1985) Breathing pattern affects airway wall temperature during cold air hyperpnea in humans. Am Rev Respir Dis 132:853–857PubMed
Solway J, Leff AR, Dreshaj I, Munoz NM, Ingenito EP, Michaels D, Ingram RH, Drazen JM (1986) Circulatory heat sources for canine respiratory heat exchange. J Clin Invest 78:1015-1019PubMed
Tsu ME, Babb AL, Ralph DD, Hlastala MP (1988) Dynamics of heat water and soluble gas exchange in the human airways: I a model study. Ann Biomed Eng 16:547-571PubMed
Von Hayek H (1960) The human lung. Hafner, New York
Weibel ER (1963) Morphometry of the human lung. Springer, Berlin Heidelberg New York
Metadaten
Titel
Effects of the ventilation pattern and pulmonary blood flow on lung heat transfer
verfasst von
V. B. Serikov
N. W. Fleming
V. A. Talalov
F. A. Stawitcke
Publikationsdatum
01.03.2004
Verlag
Springer-Verlag
Erschienen in
European Journal of Applied Physiology / Ausgabe 2-3/2004
Print ISSN: 1439-6319
Elektronische ISSN: 1439-6327
DOI
https://doi.org/10.1007/s00421-003-0966-4

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