Abstract
To study the mass transport of mucociliary clearance of the human upper respiratory tract, a two-dimensional mass transport model based on the ciliated movement was established by using the immersed boundary-lattice Boltzmann method (IB-LBM). In this model, different characteristics of the mucus layer (ML) and the periciliary liquid (PCL) were taken into account. A virtual elastic membrane was introduced to divide the two layers dynamically. All moving boundaries that were involved in the present simulation were modeled with the immersed boundary. The Newtonian fluid was used to model the flow in PCL, and the viscoelastic fluid based on the Oldroyd-B model was used for the flow in ML; the two types of flow were both solved by the LBM framework. Based on the model, the ML thickness, the cilia density, and the phase difference of adjacent cilia were regulated, respectively, to study the transport velocity of the ML. In addition, the motion law of solid particles in PCL was also studied. According to the results, four primary conclusions were drawn. (1) At a given beating pattern, the increase of the ML thickness will decrease its transport velocity. (2) Increasing the cilia density can promote the mean transport velocity of the ML. (3) By raising the phase difference of adjacent cilia to a certain scope, the transport of ML can be accelerated. (4) In PCL, particles initially located on the upper part of the cilia tend to migrate upward and then get close to the ML. The above study can provide some reasonable explanations for the mechanism of the mucociliary clearance system, which is also helpful to the further understanding of the mass transport principle of the human upper respiratory tract.
Highlights
Mucociliary clearance (MCC) system is an important part of the human immune system, which is responsible for the removal of bacteria, viruses, dust, and various harmful particles in the inhaled air
(4) In periciliary liquid (PCL), particles initially located on the upper part of the cilia tend to migrate upward and get close to the mucus layer (ML). e above study can provide some reasonable explanations for the mechanism of the mucociliary clearance system, which is helpful to the further understanding of the mass transport principle of the human upper respiratory tract
It plays an important role in protecting human health [1]. e MCC mainly consists of cilia and mucus attached to the respiratory tract surface. e mucus is made up of two layers, i.e., the mucus layer (ML) and the periciliary liquid (PCL)
Summary
Mucociliary clearance (MCC) system is an important part of the human immune system, which is responsible for the removal of bacteria, viruses, dust, and various harmful particles in the inhaled air. To model the beating cilia, the immersed boundary method (IBM) is one of the most popular research methods Peskin introduced this method for the first time to study the cardiac blood flow around the heart valve [9]. By applying the immersed boundary-lattice Boltzmann method (IB-LBM) framework, Shahmardan et al [14] studied the effect of mucus thickness on its transport efficiency. Besides the cilia and flow, some floating rigid particles are usually found in MCC [18], which may be the foreign matter or come from the respiratory tract surface. By changing the thickness of ML, the density of cilia, and the phase difference of adjacent cilia, the transport efficiency of the ML was studied in detail.
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