Thin-film dynamics above a periodically-stretched alveolar substrate

During last few years several new respiratory diseases including SARS and avian flu have appeared in various parts of the world. With deteriorating environmental conditions and increased air travel, more and more people will suffer breathing disorders, leading to an increased demand for methods to p...

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Bibliographic Details
Main Author: Luo, Lu
Format: Text
Language:unknown
Published: University of New Hampshire Scholars' Repository 2007
Subjects:
Online Access:https://scholars.unh.edu/thesis/304
https://scholars.unh.edu/context/thesis/article/1303/viewcontent/1447895.pdf
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Summary:During last few years several new respiratory diseases including SARS and avian flu have appeared in various parts of the world. With deteriorating environmental conditions and increased air travel, more and more people will suffer breathing disorders, leading to an increased demand for methods to prevent and treat these diseases. To properly address this problem, it is necessary to gain a more complete understanding of the mechanics of respiration. This research constitutes a further step toward this goal by focusing on the coupled solid/liquid micromechanics of an idealized piece of lung tissue. Gas exchange in mammalian lungs is efficient because 90% of lung volume is partitioned into a labyrinth of small, systematically connected air spaces termed alveoli. Because these air spaces are (at least partially) lined with a thin liquid film, the lung contains an extensive and a highly curved liquid-gas interface. Surface tension forces acting at this interface play a central role in respiratory mechanics, and it is of fundamental as well as practical interest to establish the mechanisms by which surface tension moderates the distribution of the liquid lining. Further research on the fluid dynamics of the alveolar liquid lining is needed to enable a complete understanding of the mechanical force balance, surfactant distribution and particulate transport within the lung parenchyma. Anatomical studies have shown that the liquid lining accumulates in pools in the corners of polyhedral alveoli. During respiration, the alveolar walls (or septa) are subjected to a periodic strain, and liquid is drawn into and out of these pools by the wall movement. The objective of this research is to investigate how surface tension forces compete with the viscous stresses associated with substrate stretching to control the thin film distribution in the vicinity of an alveolar corner, where septal planes meet. For this purpose, a mathematical model is proposed that couples thin-film fluid dynamics to a stretching substrate; this model ...