Effects of gravity and surface tension on steady microbubble propagation inasymmetric bifurcating airways

Mechanical ventilation is nowadays a well-developed, safe, and necessary strategy foracute respiratory distress syndrome patients to survive. However, the propagation ofmicrobubbles in airway bifurcations during mechanical ventilation makes the existing lunginjury more severe. In this paper, finite...

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Veröffentlicht in:	Physics of fluids (1994) 2020-07, Vol.32 (7)
Hauptverfasser:	Bacha, Munir, Xu, Yong
Format:	Artikel
Sprache:	eng
Schlagworte:	Asymmetry Bifurcations Capillary pressure Computational fluid dynamics Computer simulation Fluid dynamics Gravitation Gravitational effects Physics Pressure gradients Propagation Respiratory therapy Shear stress Stress propagation Surface tension Ventilation Viscous fluids
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container_title	Physics of fluids (1994)
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creator	Bacha, Munir Xu, Yong
description	Mechanical ventilation is nowadays a well-developed, safe, and necessary strategy foracute respiratory distress syndrome patients to survive. However, the propagation ofmicrobubbles in airway bifurcations during mechanical ventilation makes the existing lunginjury more severe. In this paper, finite element and direct interface tracking techniqueswere utilized to simulate steady microbubble propagation in a two-dimensional asymmetricbifurcating airway filled with a viscous fluid. Inertial effects were neglected, and thenumerical solution of Stokes’s equations was used to investigate how gravity and surfacetension defined by a Bond (Bo) number and capillary (Ca) number influence the magnitudesof pressure gradients, shear stresses, and shear stress gradients on the bifurcatingdaughter airway wall. It is found that increasing Bo significantly influenced both thebubble shape and hydrodynamic stresses, where Bo ≥ 0.25 results in a significant increasein bubble elevation and pressure gradient in the upper daughter wall. Although for both Boand Ca, the magnitude of the pressure gradient is always much larger in the upper daughterairway wall, Ca has a great role in amplifying the magnitude of the pressure gradient. Inconclusion, both gravity and surface tension play a key role in the steady microbubblepropagation and hydrodynamic stresses in the bifurcating airways.
doi_str_mv	10.1063/5.0012796
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However, the propagation ofmicrobubbles in airway bifurcations during mechanical ventilation makes the existing lunginjury more severe. In this paper, finite element and direct interface tracking techniqueswere utilized to simulate steady microbubble propagation in a two-dimensional asymmetricbifurcating airway filled with a viscous fluid. Inertial effects were neglected, and thenumerical solution of Stokes’s equations was used to investigate how gravity and surfacetension defined by a Bond (Bo) number and capillary (Ca) number influence the magnitudesof pressure gradients, shear stresses, and shear stress gradients on the bifurcatingdaughter airway wall. It is found that increasing Bo significantly influenced both thebubble shape and hydrodynamic stresses, where Bo ≥ 0.25 results in a significant increasein bubble elevation and pressure gradient in the upper daughter wall. Although for both Boand Ca, the magnitude of the pressure gradient is always much larger in the upper daughterairway wall, Ca has a great role in amplifying the magnitude of the pressure gradient. Inconclusion, both gravity and surface tension play a key role in the steady microbubblepropagation and hydrodynamic stresses in the bifurcating airways.</description><identifier>ISSN: 1070-6631</identifier><identifier>EISSN: 1089-7666</identifier><identifier>DOI: 10.1063/5.0012796</identifier><language>eng</language><publisher>Melville: American Institute of Physics</publisher><subject>Asymmetry ; Bifurcations ; Capillary pressure ; Computational fluid dynamics ; Computer simulation ; Fluid dynamics ; Gravitation ; Gravitational effects ; Physics ; Pressure gradients ; Propagation ; Respiratory therapy ; Shear stress ; Stress propagation ; Surface tension ; Ventilation ; Viscous fluids</subject><ispartof>Physics of fluids (1994), 2020-07, Vol.32 (7)</ispartof><rights>2020 Author(s). 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Although for both Boand Ca, the magnitude of the pressure gradient is always much larger in the upper daughterairway wall, Ca has a great role in amplifying the magnitude of the pressure gradient. Inconclusion, both gravity and surface tension play a key role in the steady microbubblepropagation and hydrodynamic stresses in the bifurcating airways.</abstract><cop>Melville</cop><pub>American Institute of Physics</pub><doi>10.1063/5.0012796</doi></addata></record>
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subjects	Asymmetry Bifurcations Capillary pressure Computational fluid dynamics Computer simulation Fluid dynamics Gravitation Gravitational effects Physics Pressure gradients Propagation Respiratory therapy Shear stress Stress propagation Surface tension Ventilation Viscous fluids
title	Effects of gravity and surface tension on steady microbubble propagation inasymmetric bifurcating airways
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