Effects of gravity, inertia, and surfactant on steady plug propagation in a two-dimensional channel

Liquid plugs may form in pulmonary airways during the process of liquid instillation or removal in many clinical treatments. Studies have shown that the effectiveness of these treatments may depend on how liquids distribute in the lung. Better understanding of the fundamental fluid mechanics of liqu...

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Bibliographic Details
Published in:Physics of fluids (1994) 2007-08, Vol.19 (8)
Main Authors: Zheng, Y., Fujioka, H., Grotberg, J. B.
Format: Article
Language:English
Subjects:
Biological and medical sciences
Biomechanics. Biorheology
Fundamental and applied biological sciences. Psychology
Tissues, organs and organisms biophysics
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Summary:Liquid plugs may form in pulmonary airways during the process of liquid instillation or removal in many clinical treatments. Studies have shown that the effectiveness of these treatments may depend on how liquids distribute in the lung. Better understanding of the fundamental fluid mechanics of liquid plug transport will facilitate treatment strategies. In this paper, we develop a numerical model of steady plug propagation driven by gravity and pressure in a two-dimensional liquid-lined channel oriented at an angle α with respect to gravity. We investigate the effects of gravity through the Bond number, Bo, and α ; the plug propagation speed through the capillary number, Ca, or the Reynolds number, Re; the plug length L P , and the surfactant concentration C 0 . Without gravity, i.e., Bo = 0 , the plug is symmetric, and there are two regimes for the flow: two wall layers and two trapped vortices in the core. There is no flow interaction between the upper and lower half plug domains. When Bo ≠ 0 and α ≠ 0 , π , fluid is found to flow from the upper precursor film, through the core and into the lower trailing film. Then the number of vortices can be zero, one, or two, depending on the flow parameters. The vortices have stagnation points on the interface when C 0 = 0 , however when the surfactant is present ( C 0 > 0 ) , the vortices detach from the interface and create saddle points inside the core. The front meniscus develops a capillary surface wave extending into the precursor film. This is where the film is thinnest and thus the wall shear stress is highest, as high as ∼ 100 dyn ∕ cm 2 in adult airways, which indicates a significant risk of pulmonary airway epithelial cell damage. Adding surfactant can decrease the peak magnitude of the shear stress, thus reducing the risk of cell damage. The prebifurcation asymmetry of the plug is quantified by the volume ratio, Vr, defined as the ratio of the liquid above to that below the center line of the channel. Vr is found to increase with L P , Ca, Re, and C 0 , while it decreases with Bo. The total mass left behind in the trailing films increases with Bo for any α at α > 2 π ∕ 5 , Ca and α for any value of Bo > 0 .
ISSN:1070-6631
1089-7666
DOI:10.1063/1.2762256