Microrheology reveals microscale viscosity gradients in planktonic systems

Guadayol, Òscar; Mendonça, Tânia; Segura-Noguera, Mariona; Wright, Amanda J.; Tassieri, Manlio; Humphries, Stuart

doi:10.1073/pnas.2011389118

Cited by 31 publications

(42 citation statements)

References 41 publications

(41 reference statements)

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“…In yield-stress materials a swimmer also can create a nearby fluidized region [89], and swimmers moving across an interface of fluids with different viscosities may drag a surrounding amount of different-viscosity fluid with them [90]. Active remodeling of local material properties can also be caused by thermal or chemical effects; plankton and bacteria can exude or consume viscosity-altering substances [57][58][59][60], thermal heating of microrobots can locally decrease viscosity, and the degelling strategy of H. pylori has been mimicked in magnetically rotated microrobots [56].…”

Section: Discussionmentioning

confidence: 99%

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Fore-aft clearance controls how three-dimensional confinement affects micropropulsion

Kamarapu¹,

Jabbarzadeh²,

Fu³

2022

Preprint

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Systems of active particles are often affected by confinement due to nearby boundaries. Recently, there has been interest in the effect of confinement by complex three dimensional geometries, as might occur in structured environments such as porous media, foams, gels, or biological tissues and ducts. The effects of confinement for particles moving along boundaries has been extensively studied, but in three dimensions active particles move not only parallel to boundaries, but also towards or away from boundaries. The consequences of this fore-aft clearance is less well understood. Swimmers that actively remodel their environment create an ideal situation to study the effect of clearance, since they maintain a steady clearance while translating. By numerically studying the locomotion of the bacterium Helicobacter pylori, which de-gels surrounding gastric mucus to make a comoving pocket of fluid around itself, we show that the effect of three-dimensional confinement is controlled by clearance, rather than distance from a parallel boundary. Analytical calculations show that the effect of clearance can be understood in terms of flow structures, such as the generic pusher and puller flows of active particles, indicating that our results should apply to a wide range of confined active particles.

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Section: Discussionmentioning

confidence: 99%

“…1b). Local modification of material parameters also occurs chemically near microrobots [56], in the phycospheres of plankton [57][58][59][60], and by thermal [61,62] and mechanical effects [26,63].…”

mentioning

confidence: 99%

Fore-aft clearance controls how three-dimensional confinement affects micropropulsion

Kamarapu¹,

Jabbarzadeh²,

Fu³

2022

Preprint

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“…The inert probes can be embedded in the hydrogel during encapsulation 6,[19][20][21] or even internalised into cells 22 to probe intra-cellular viscoelasticity. In suspension cultures, an optical trap can be used to hold the probe in the field of view within the cells' microniche during the measurement time-window 23 . This approach makes the instrument suitable for micro-mechanical sensing in a wide range of cell culture substrates such as those commonly employed in the biomedical field.…”

Section: Introductionmentioning

confidence: 99%

OptoRheo: Simultaneousin situmicro-mechanical sensing and imaging of live 3D biological systems

Mendonça

Lis-Slimak

Matheson

et al. 2022

Preprint

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Biomechanical cues from the extracellular matrix (ECM) are essential for directing many cellular processes, from normal development and repair to disease progression. To better understand cell-matrix interactions, we have developed an optical instrument combining light sheet fluorescence microscopy with particle tracking microrheology. We name this new instrument OptoRheo. OptoRheo lets us image cells in 3D as they proliferate over several days while simultaneously sensing the biomechanical properties of the surrounding extracellular and pericellular matrix at a sub-cellular scale. OptoRheo can be used in two operational modalities to extend the dynamic range of microrheology measurements, making the instrument suitable for different cell culture systems. We corroborated this by characterising the ECM surrounding live breast cancer cells in two distinct culture systems, 3D hydrogels and suspension culture. This cutting-edge instrument will transform the exploration of drug transport through complex cell culture matrices and optimise the design of the next-generation disease models.

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“…Another successful application of optical tweezers is in the field of "hybrid" microrheology, whereby an optically trapped bead acts as a probe, revealing the thermal fluctuations of the molecules in the suspending fluid. Microrheology with OT (MOT) has been used with growing popularity to study the rheology of complex biological materials such as the vitreous humor [11], biopolymer networks [12], and extracellular secretions from phytoplankton [13] at the microscale.…”

Section: Introductionmentioning

confidence: 99%

Microrheology With an Anisotropic Optical Trap

et al. 2021

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Microrheology with optical tweezers (MOT) measurements are usually performed using optical traps that are close to isotropic across the plane being imaged, but little is known about what happens when this is not the case. In this work, we investigate the effect of anisotropic optical traps on microrheology measurements. This is an interesting problem from a fundamental physics perspective, but it also has practical ramifications because in 3D all optical traps are anisotropic due to the difference in the intensity distribution of the trapping laser along axes parallel and perpendicular to the direction of beam propagation. We find that attempting viscosity measurements with highly anisotropic optical traps will return spurious results, unless the axis with maximum variance in bead position is identified. However, for anisotropic traps with two axes of symmetry such as traps with an elliptical cross section, the analytical approach introduced in this work allows us to explore a wider range of time scales than those accessible with symmetric traps. We have also identified a threshold level of anisotropy in optical trap strength of ~30%, below which conventional methods using a single arbitrary axis can still be used to extract valuable microrheological results. We envisage that the outcomes of this study will have important practical ramifications on how all MOT measurements should be conducted and analyzed in future applications.

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Microrheology reveals microscale viscosity gradients in planktonic systems

Cited by 31 publications

References 41 publications

Fore-aft clearance controls how three-dimensional confinement affects micropropulsion

Fore-aft clearance controls how three-dimensional confinement affects micropropulsion

OptoRheo: Simultaneousin situmicro-mechanical sensing and imaging of live 3D biological systems

Microrheology With an Anisotropic Optical Trap

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