Effects of kinematic hardening of mucus polymers in an airway closure model

IF 2.7 2区 工程技术 Q2 MECHANICS
Bartu Fazla , Oguzhan Erken , Daulet Izbassarov , Francesco Romanò , James B. Grotberg , Metin Muradoglu
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Abstract

The formation of a liquid plug inside a human airway, known as airway closure, is computationally studied by considering the elastoviscoplastic (EVP) properties of the pulmonary mucus covering the airway walls for a range of liquid film thicknesses and Laplace numbers. The airway is modeled as a rigid tube lined with a single layer of an EVP liquid. The Saramito–Herschel–Bulkley (Saramito-HB) model is coupled with an Isotropic Kinematic Hardening model (Saramito-HB-IKH) to allow energy dissipation at low strain rates. The rheological model is fitted to the experimental data under healthy and cystic fibrosis (CF) conditions. Yielded/unyielded regions and stresses on the airway wall are examined throughout the closure process. Yielding is found to begin near the closure in the Saramito-HB model, whereas it occurs noticeably earlier in the Saramito-HB-IKH model. The kinematic hardening is seen to have a notable effect on the closure time, especially for the CF case, with the effect being more pronounced at low Laplace numbers and initial film thicknesses. Finally, standalone effects of rheological properties on wall stresses are examined considering their physiological values as baseline.

气道关闭模型中粘液聚合物运动硬化的影响
通过考虑覆盖气道壁的肺粘液在一系列液膜厚度和拉普拉斯数下的弹性粘塑性(EVP)特性,对人体气道内液塞的形成(即气道闭合)进行了计算研究。气道被模拟为内衬单层 EVP 液体的刚性管。Saramito-Herschel-Bulkley (Saramito-HB) 模型与各向同性运动硬化模型 (Saramito-HB-IKH) 相结合,允许在低应变速率下耗散能量。该流变模型适用于健康和囊性纤维化(CF)条件下的实验数据。在整个闭合过程中,对气道壁上的屈服/不屈服区域和应力进行了研究。在萨拉米托-HB 模型中,屈服是在接近闭合时开始的,而在萨拉米托-HB-IKH 模型中,屈服明显发生得更早。运动硬化对闭合时间有显著影响,尤其是在 CF 情况下,在拉普拉斯数和初始薄膜厚度较低时影响更为明显。最后,以生理值为基准,研究了流变特性对壁面应力的独立影响。
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来源期刊
CiteScore
5.00
自引率
19.40%
发文量
109
审稿时长
61 days
期刊介绍: The Journal of Non-Newtonian Fluid Mechanics publishes research on flowing soft matter systems. Submissions in all areas of flowing complex fluids are welcomed, including polymer melts and solutions, suspensions, colloids, surfactant solutions, biological fluids, gels, liquid crystals and granular materials. Flow problems relevant to microfluidics, lab-on-a-chip, nanofluidics, biological flows, geophysical flows, industrial processes and other applications are of interest. Subjects considered suitable for the journal include the following (not necessarily in order of importance): Theoretical, computational and experimental studies of naturally or technologically relevant flow problems where the non-Newtonian nature of the fluid is important in determining the character of the flow. We seek in particular studies that lend mechanistic insight into flow behavior in complex fluids or highlight flow phenomena unique to complex fluids. Examples include Instabilities, unsteady and turbulent or chaotic flow characteristics in non-Newtonian fluids, Multiphase flows involving complex fluids, Problems involving transport phenomena such as heat and mass transfer and mixing, to the extent that the non-Newtonian flow behavior is central to the transport phenomena, Novel flow situations that suggest the need for further theoretical study, Practical situations of flow that are in need of systematic theoretical and experimental research. Such issues and developments commonly arise, for example, in the polymer processing, petroleum, pharmaceutical, biomedical and consumer product industries.
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