Validation of a two-compartment model of ventilation/perfusion distribution

Ventilation ( V ˙ A ) to perfusion ( Q ˙ ) heterogeneity ( V ˙ A / Q ˙ ) analyses by a two-compartment lung model (2C), utilizing routine gas exchange measurements and a computer solution to account for O 2 and CO 2 measurements, were compared with multiple inert gas elimination technique (MIGET) an...

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Bibliographic Details
Published in:	Respiratory physiology & neurobiology Vol. 151; no. 1; pp. 74 - 92
Main Authors:	Loeppky, Jack A., Caprihan, Arvind, Altobelli, Stephen A., Icenogle, Milton V., Scotto, Pietro, Vidal Melo, Marcos F.
Format:	Journal Article
Language:	English
Published:	Amsterdarm Elsevier B.V 28-03-2006 Elsevier
Subjects:	[formula omitted] models Adult Air breathing Alveolar–arterial PO 2 difference Animals Arterial–alveolar PCO 2 difference Biological and medical sciences Chronic obstructive pulmonary disease Diffusion limitation Dogs Fundamental and applied biological sciences. Psychology Humans Hypoxemia Lung - physiology Models, Biological Pulmonary Disease, Chronic Obstructive - physiopathology Pulmonary Gas Exchange - physiology Reproducibility of Results Respiration Respiratory system: anatomy, metabolism, gas exchange, ventilatory mechanics, respiratory hemodynamics Ventilation-Perfusion Ratio - physiology Vertebrates: respiratory system Chronic obstructive pulmonary disease Diffusion limitation Hypoxemia Arterial–alveolar PCO 2 difference V ˙ A / Q ˙ models Alveolar–arterial PO 2 difference Human Fissipedia Ventilation perfusion relationship VA/Q models Carnivora Oxygen Lung Arterial-alveolar PCO2 difference Respiratory system Heterogeneity Vertebrata Compartmental model Mammalia Perfusion Distribution Gas exchange Pulmonary ventilation Respiration Diffusion Dog Alveolar-arterial PO2 difference
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Summary:	Ventilation ( V ˙ A ) to perfusion ( Q ˙ ) heterogeneity ( V ˙ A / Q ˙ ) analyses by a two-compartment lung model (2C), utilizing routine gas exchange measurements and a computer solution to account for O 2 and CO 2 measurements, were compared with multiple inert gas elimination technique (MIGET) analyses and a multi-compartment (MC) model. The 2C and MC estimates of V ˙ A / Q ˙ mismatch were obtained in 10 healthy subjects, 43 patients having chronic obstructive pulmonary disease (COPD) and in 14 dog experiments where hemodynamics and acid–base status were manipulated with gas mixtures, fluid loading and tilt-table stressors. MIGET comparisons with 2C were made on 6 patients and 32 measurements in healthy subjects before and after exercise at normoxia and altitude hypoxia. Statistically significant correlations for logarithmic standard deviations of V ˙ A / Q ˙ distributions ( SD ( V ˙ A / Q ˙ ) ) were obtained for all 2C comparisons, with similar values between 2C and both other methods in the 1.1–1.5 range, compatible with mild to moderate COPD. 2C tended to overestimate MC and MIGET values at low and underestimate them at high SD ( V ˙ A / Q ˙ ) values. SD ( V ˙ A / Q ˙ ) weighted by Q ˙ agreed better with MC and MIGET estimates in the normal range, whereas SD ( V ˙ A / Q ˙ ) weighted by V ˙ A was closer to MC at higher values because the V ˙ A -weighted SD ( V ˙ A / Q ˙ ) is related to blood-to-gas PCO 2 differences that are elevated in disease, thereby allowing better discrimination. The 2C model accurately described functional V ˙ A / Q ˙ characteristics in 26 normal and bronchoconstricted dogs during non-steady state rebreathing and could be used to quantify the effect of reduced O 2 diffusing capacity in diseased lungs. These comparisons indicate that 2C adequately describes V ˙ A / Q ˙ mismatch and can be useful in clinical or experimental situations where other techniques are not feasible.
Bibliography:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23
ISSN:	1569-9048 1878-1519
DOI:	10.1016/j.resp.2005.06.002