Active mucus–cilia hydrodynamic coupling drives self-organization of human bronchial epithelium

The respiratory tract is protected by mucus, a complex fluid transported along the epithelial surface by the coordinated beating of millions of microscopic cilia, hence the name of mucociliary clearance. Its impairment is associated with all severe chronic respiratory diseases. Yet, the relationship...

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Bibliographic Details
Published in:Nature physics 2020-11, Vol.16 (11), p.1158-1164
Main Authors: Loiseau, Etienne, Gsell, Simon, Nommick, Aude, Jomard, Charline, Gras, Delphine, Chanez, Pascal, D’Ortona, Umberto, Kodjabachian, Laurent, Favier, Julien, Viallat, Annie
Format: Article
Language:English
Subjects:
631/57
639/301/923/966
639/766/747
Atomic
Biological Physics
Classical and Continuum Physics
Complex Systems
Condensed Matter Physics
Epithelium
Mathematical and Computational Physics
Molecular
Mucus
Optical and Plasma Physics
Phase diagrams
Physics
Physics and Astronomy
Physiology
Respiratory diseases
Respiratory tract
Theoretical
Two dimensional models
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Summary:The respiratory tract is protected by mucus, a complex fluid transported along the epithelial surface by the coordinated beating of millions of microscopic cilia, hence the name of mucociliary clearance. Its impairment is associated with all severe chronic respiratory diseases. Yet, the relationship between ciliary density and the spatial scale of mucus transport, as well as the mechanisms that drive ciliary-beat orientations are much debated. Here, we show on polarized human bronchial epithelia that mucus swirls and circular orientational order of the underlying ciliary beats emerge and grow during ciliogenesis, until a macroscopic mucus transport is achieved for physiological ciliary densities. By establishing that the macroscopic ciliary-beat order is lost and recovered by removing and adding mucus, respectively, we demonstrate that cilia–mucus hydrodynamic interactions govern the collective dynamics of ciliary-beat directions. We propose a two-dimensional model that predicts a phase diagram of mucus transport in accordance with the experiments. This paves the way to a predictive in silico modelling of bronchial mucus transport in health and disease. The flow of fluid, such as mucus in the human respiratory tract, can affect biological function. Here the authors show that the hydrodynamic interactions mediated by mucus are essential for the directional coordination of ciliary beating in the lungs.
ISSN:1745-2473
1745-2481
1476-4636
DOI:10.1038/s41567-020-0980-z