Topic
Pulmonary diffusion
About: Pulmonary diffusion is a research topic. Over the lifetime, 335 publications have been published within this topic receiving 10656 citations.
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TL;DR: In this article, the authors describe the long-term health consequences of patients with COVID-19 who have been discharged from hospital and investigate the associated risk factors, in particular disease severity.
2,933 citations
TL;DR: An equation, i/Dm + i/θVc = i/L, has been derived which relates the measured pulmonary diffusing capacity (Dl), the true diffusingcapacity of the pulmonary membrane (Dm), the rate of uptake of CO...
Abstract: An equation, i/Dm + i/θVc = i/Dl, has been derived which relates the measured pulmonary diffusing capacity (Dl), the true diffusing capacity of the pulmonary membrane (Dm), the rate of uptake of CO...
970 citations
TL;DR: The fine structure of the human lung parenchyma as seen by scanning and transmission electron microscopy is described, and total pulmonary diffusion capacity for 02 seems to agree with physiological estimates of human dl in exercise.
535 citations
TL;DR: The elevated alveolar-arterial oxygen difference that is seen in subjects who are in conditions of extreme hypoxia may represent a degree of subclinical high-altitude pulmonary edema or a functional limitation in pulmonary diffusion.
Abstract: Background: The level of environmental hypobaric hypoxia that affects climbers at the summit of Mount Everest (8848 m [29,029 ft]) is close to the limit of tolerance by humans. We performed direct field measurements of arterial blood gases in climbers breathing ambient air on Mount Everest. Methods: We obtained samples of arterial blood from 10 climbers during their ascent to and descent from the summit of Mount Everest. The partial pressures of arterial oxygen (PaO2) and carbon dioxide (PaCO2), pH, and hemoglobin and lactate concentrations were measured. The arterial oxygen saturation (SaO2), bicarbonate concentration, base excess, and alveolar-arterial oxygen difference were calculated. Results: PaO2 fell with increasing altitude, whereas SaO2 was relatively stable. The hemoglobin concentration increased such that the oxygen content of arterial blood was maintained at or above sea-level values until the climbers reached an elevation of 7100 m (23,294 ft). In four samples taken at 8400 m (27,559 ft) - at which altitude the barometric pressure was 272 mm Hg (36.3 kPa) - the mean PaO2 in subjects breathing ambient air was 24.6 mm Hg (3.28 kPa), with a range of 19.1 to 29.5 mm Hg (2.55 to 3.93 kPa). The mean PaCO2 was 13.3 mm Hg (1.77 kPa), with a range of 10.3 to 15.7 mm Hg (1.37 to 2.09 kPa). At 8400 m, the mean arterial oxygen content was 26% lower than it was at 7100 m (145.8 ml per liter as compared with 197.1 ml per liter). The mean calculated alveolar-arterial oxygen difference was 5.4 mm Hg (0.72 kPa). Conclusions: The elevated alveolar-arterial oxygen difference that is seen in subjects who are in conditions of extreme hypoxia may represent a degree of subclinical high-altitude pulmonary edema or a functional limitation in pulmonary diffusion. Copyright © 2009 Massachusetts Medical Society.
397 citations
TL;DR: A model and method for estimating pulmonary diffusion capacity from morphometric information gathered on fixed lung specimens is presented and the introduction of appropriate physical coefficients permits calculation of morphometric values of pulmonary and membrane diffusion capacities which can be used in attempts of quantitative structure-function correlation.
374 citations