Fluid-structure interaction modelling of neighboring tubes with primary cilium analysis-Reference-Cited by-同舟云学术

Fluid-structure interaction modelling of neighboring tubes with primary cilium analysis

Published:2022 Issue:2 Volume:20 Page:3677-3699
ISSN:1551-0018
Container-title:Mathematical Biosciences and Engineering
language:
Short-container-title:MBE

Author:

Zekaj Nerion¹,Ryan Shawn D.²,Resnick Andrew³⁴

Affiliation:

1. Department of Mathematics, University of North Carolina at Chapel Hill, Chapel Hill 27599, USA

2. Department of Mathematics and Statistics, Cleveland State University, Cleveland OH 44115, USA

3. Department of Physics, Cleveland State University, Cleveland OH 44115, USA

4. Center for Gene Regulation in Health and Disease, Cleveland State University, Cleveland OH 44115, USA

Abstract

<abstract><p>We have developed a numerical model of two osculating cylindrical elastic renal tubules to investigate the impact of neighboring tubules on the stress applied to a primary cilium. We hypothesize that the stress at the base of the primary cilium will depend on the mechanical coupling of the tubules due to local constrained motion of the tubule wall. The objective of this work was to determine the in-plane stresses of a primary cilium attached to the inner wall of one renal tubule subject to the applied pulsatile flow, with a neighboring renal tube filled with stagnant fluid in close proximity to the primary tubule. We used the commercial software COMSOL<sup>Ⓡ</sup> to model the fluid-structure interaction of the applied flow and tubule wall, and we applied a boundary load to the face of the primary cilium during this simulation to produces a stress at its base. We confirm our hypothesis by observing that on average the in-plane stresses are greater at the base of the cilium when there is a neighboring renal tube versus if there is no neighboring tube at all. In combination with the hypothesized function of a cilium as a biological fluid flow sensor, these results indicate that flow signaling may also depend on how the tubule wall is constrained by neighboring tubules. Our results may be limited in their interpretation due to the simplified nature of our model geometry, and further improvements to the model may potentially lead to the design of future experiments.</p></abstract>

Publisher

American Institute of Mathematical Sciences (AIMS)

Subject

Applied Mathematics,Computational Mathematics,General Agricultural and Biological Sciences,Modeling and Simulation,General Medicine

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