Kinematically irreversible acinar flow: a departure from classical dispersive aerosol transport theories

doi:10.1152/japplphysiol.00385.2001

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J Appl Physiol 92: 835-845, 2002. First published October 26, 2001; doi:10.1152/japplphysiol.00385.2001
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Vol. 92, Issue 2, 835-845, February 2002

Kinematically irreversible acinar flow: a departure from classical dispersive aerosol transport theories

F. S. Henry¹, J. P. Butler², and A. Tsuda²

¹ School of Engineering, City University, London EC1V 0HB, United Kingdom; and ² Physiology Program, Harvard School of Public Health, Boston, Massachusetts 02115

Current theories describe aerosol transport in the lung as a dispersive (diffusion-like) process, characterized by an effectivediffusion coefficient in the context of reversible alveolar flow.Our recent experimental data, however, question the validity ofthese basic assumptions. In this study, we describe the behaviorof fluid particles (or bolus) in a realistic, numerical, alveolatedduct model with rhythmically expanding walls. We found acinarflow exhibiting multiple saddle points, characteristic of chaoticflow, resulting in substantial flow irreversibility. Computationsof axial variance of bolus spreading indicate that the growthof the variance with respect to time is faster than linear, afinding inconsistent with dispersion theory. Lateral behaviorof the bolus shows fine-scale, stretch-and-fold striations, exhibitingfractal-like patterns with a fractal dimension of 1.2, which compareswell with the fractal dimension of 1.1 observed in our experimentalstudies performed with rat lungs. We conclude that kinematic irreversibilityof acinar flow due to chaotic flow may be the dominant mechanismof aerosol transport deep in thelungs.

lung; deposition; chaos; fractal; particulate pollution

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