Giant enhancement of bacterial upstream swimming in macromolecular flows

Ding Cao, Ran Tao, Albane Théry, Song Liu, Arnold J. T. M. Mathijssen, Yilin Wu
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Abstract

Many bacteria live in natural and clinical environments with abundant macromolecular polymers. Macromolecular fluids commonly display viscoelasticity and non-Newtonian rheological behavior; it is unclear how these complex-fluid properties affect bacterial transport in flows. Here we combine high-resolution microscopy and numerical simulations to study bacterial response to shear flows of various macromolecular fluids. In stark contrast to the case in Newtonian shear flows, we found that flagellated bacteria in macromolecular flows display a giant capacity of upstream swimming (a behavior resembling fish swimming against current) near solid surfaces: The cells can counteract flow washing at shear rates up to ~65 $s^{-1}$, one order of magnitude higher than the limit for cells swimming in Newtonian flows. The significant enhancement of upstream swimming depends on two characteristic complex-fluid properties, namely viscoelasticity and shear-thinning viscosity; meanwhile, increasing the viscosity with a Newtonian polymer can prevent upstream motion. By visualizing flagellar bundles and modeling bacterial swimming in complex fluids, we explain the phenomenon as primarily arising from the augmentation of a "weathervane effect" in macromolecular flows due to the presence of a viscoelastic lift force and a shear-thinning induced azimuthal torque promoting the alignment of bacteria against the flow direction. Our findings shed light on bacterial transport and surface colonization in macromolecular environments, and may inform the design of artificial helical microswimmers for biomedical applications in physiological conditions.
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细菌在大分子流中逆流而上的巨大增强效应
许多细菌生活在大分子聚合物丰富的自然和临床环境中。大分子流体通常具有粘弹性和非牛顿流变行为;目前还不清楚这些复杂的流体特性如何影响细菌在流体中的迁移。在这里,我们结合高分辨率显微镜和数值模拟来研究细菌对各种高分子流体剪切流的反应。与牛顿剪切流中的情况形成鲜明对比的是,我们发现高分子流中的鞭毛细菌在固体表面附近显示出巨大的逆流游动能力(类似于鱼类逆流游动的行为):细胞在剪切速率高达~65 s^{-1}$的情况下可以抵消水流冲刷,比细胞在牛顿流中游动的极限高出一个数量级。上游游动能力的显著增强取决于两种复杂流体的特性,即粘弹性和剪切稀化粘度;同时,用牛顿聚合物增加粘度可以阻止上游运动。通过对扇形束的可视化和复杂流体中细菌游动的建模,我们解释了这一现象主要源于大分子流中 "风向标效应 "的增强,这是由于粘弹性提升力和剪切稀化诱导的方位角力矩的存在促进了细菌逆流向排列。我们的发现揭示了细菌在大分子环境中的迁移和表面定植,并为设计生理条件下生物医学应用的人工螺旋微泳道提供了参考。
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