Mitran Sorin M
Applied Mathematics Program, Department of Mathematics, University of North Carolina at Chapel Hill, Chapel Hill, NC 27599-3250, United States.
Comput Struct. 2007;85(11-14):763-774. doi: 10.1016/j.compstruc.2007.01.015.
A three-dimensional simulation of the formation of metachronal waves in rows of pulmonary cilia is presented. The cilia move in a two-layer fluid model. The fluid layer adjacent to the cilia bases is purely viscous while the tips of the cilia move through a viscoelastic fluid. An overlapping fixed-moving grid formulation is employed to capture the effect of the cilia on the surrounding fluid. In contrast with immersed boundary methods, this technique allows a natural enforcement of boundary conditions without the need for smoothing of singular force distributions. The fluid domains are discretized using a finite volume method. The 9 + 2 internal microtubule structure of an individual cilium is modeled using large-deflection, curved, finite-element beams. The microtubule skeleton is cross-linked to itself and to the cilium membrane through spring elements which model nexin links. The cilium membrane itself is considered to be elastic and subject to fluid stresses computed from the moving grid formulation as well as internal forces transmitted from the microtubule skeleton. A cilium is set into motion by the action of dynein molecules exerting forces between adjacent microtubules. Realistic models of the forces exerted by dynein molecules are extracted from measurements of observed cilia shapes.
本文呈现了肺纤毛排中相继波动形成的三维模拟。纤毛在两层流体模型中移动。与纤毛基部相邻的流体层是纯粘性的,而纤毛尖端在粘弹性流体中移动。采用重叠固定 - 移动网格公式来捕捉纤毛对周围流体的影响。与浸入边界方法不同,该技术允许自然地施加边界条件,而无需对奇异力分布进行平滑处理。流体域使用有限体积法离散化。单个纤毛的9 + 2内部微管结构使用大挠度、弯曲的有限元梁进行建模。微管骨架通过模拟连接蛋白连接的弹簧元件与自身以及纤毛膜交联。纤毛膜本身被认为是有弹性的,并受到根据移动网格公式计算的流体应力以及从微管骨架传递的内力的作用。纤毛通过动力蛋白分子在相邻微管之间施加力的作用而运动。动力蛋白分子施加的力的现实模型是从观察到的纤毛形状测量中提取的。