Ding Cao, Ran Tao, Albane Théry, Song Liu, Arnold J. T. M. Mathijssen, Yilin Wu
{"title":"Giant enhancement of bacterial upstream swimming in macromolecular flows","authors":"Ding Cao, Ran Tao, Albane Théry, Song Liu, Arnold J. T. M. Mathijssen, Yilin Wu","doi":"arxiv-2408.13694","DOIUrl":null,"url":null,"abstract":"Many bacteria live in natural and clinical environments with abundant\nmacromolecular polymers. Macromolecular fluids commonly display viscoelasticity\nand non-Newtonian rheological behavior; it is unclear how these complex-fluid\nproperties affect bacterial transport in flows. Here we combine high-resolution\nmicroscopy and numerical simulations to study bacterial response to shear flows\nof various macromolecular fluids. In stark contrast to the case in Newtonian\nshear flows, we found that flagellated bacteria in macromolecular flows display\na giant capacity of upstream swimming (a behavior resembling fish swimming\nagainst current) near solid surfaces: The cells can counteract flow washing at\nshear rates up to ~65 $s^{-1}$, one order of magnitude higher than the limit\nfor cells swimming in Newtonian flows. The significant enhancement of upstream\nswimming depends on two characteristic complex-fluid properties, namely\nviscoelasticity and shear-thinning viscosity; meanwhile, increasing the\nviscosity with a Newtonian polymer can prevent upstream motion. By visualizing\nflagellar bundles and modeling bacterial swimming in complex fluids, we explain\nthe phenomenon as primarily arising from the augmentation of a \"weathervane\neffect\" in macromolecular flows due to the presence of a viscoelastic lift\nforce and a shear-thinning induced azimuthal torque promoting the alignment of\nbacteria against the flow direction. Our findings shed light on bacterial\ntransport and surface colonization in macromolecular environments, and may\ninform the design of artificial helical microswimmers for biomedical\napplications in physiological conditions.","PeriodicalId":501040,"journal":{"name":"arXiv - PHYS - Biological Physics","volume":"59 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-08-25","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"arXiv - PHYS - Biological Physics","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/arxiv-2408.13694","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
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.