Scale-Dependent Nonaffine Elasticity of Semiflexible Polymer Networks

Atakhorrami, M.; Koenderink, G. H.; Palierne, Jean-François; MacKintosh, F. C.; Schmidt, Christoph F.

doi:10.1103/physrevlett.112.088101

Cited by 26 publications

(26 citation statements)

References 43 publications

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“…The elastic modulus G'(f) shows a power-law slope between 1 and 3/4 in the relatively noisy low-frequency range and appears to approach an elastic plateau at high frequencies between 100 and 1000 Hz. This behavior distinctly differs from what is seen in differentiated cells (42) or in strongly entangled or cross-linked in-vitro F-actin networks (22,34) and is more comparable with the response of dilute weakly entangled polymer solutions such as filamentous virus (43) where internal filament dynamics become visible at short times, below a characteristic disentanglement time. We therefore conclude that the parts of the embryo we could access with our 1 mm probe beads contain at most loosely entangled cytoskeletal networks.…”

Section: Shear Moduli In Different Layers Of the Embryomentioning

confidence: 70%

“…The compressional modulus is assumed to be negligible because of the incompressibility of water, as usual (16). 1PMR can both underand overestimate shear moduli in the presence of semiflexible filaments because of depletion and local nonaffinity effects (34). 2PMR avoids such problems (21,22,35,36), but because it involves extensive ensemble-and time averaging, the approach is not feasible in the rather inhomogenous interior of the rapidly developing embryos.…”

Section: Microrheology Analysismentioning

confidence: 99%

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The Mechanical Properties of Early Drosophila Embryos Measured by High-Speed Video Microrheology

Wessel

Gumalla

Großhans

et al. 2015

Biophysical Journal

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In early development, Drosophila melanogaster embryos form a syncytium, i.e., multiplying nuclei are not yet separated by cell membranes, but are interconnected by cytoskeletal polymer networks consisting of actin and microtubules. Between division cycles 9 and 13, nuclei and cytoskeleton form a two-dimensional cortical layer. To probe the mechanical properties and dynamics of this self-organizing pre-tissue, we measured shear moduli in the embryo by high-speed video microrheology. We recorded position fluctuations of injected micron-sized fluorescent beads with kHz sampling frequencies and characterized the viscoelasticity of the embryo in different locations. Thermal fluctuations dominated over nonequilibrium activity for frequencies between 0.3 and 1000 Hz. Between the nuclear layer and the yolk, the cytoplasm was homogeneous and viscously dominated, with a viscosity three orders of magnitude higher than that of water. Within the nuclear layer we found an increase of the elastic and viscous moduli consistent with an increased microtubule density. Drug-interference experiments showed that microtubules contribute to the measured viscoelasticity inside the embryo whereas actin only plays a minor role in the regions outside of the actin caps that are closely associated with the nuclei. Measurements at different stages of the nuclear division cycle showed little variation.

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Section: Shear Moduli In Different Layers Of the Embryomentioning

confidence: 70%

Section: Microrheology Analysismentioning

confidence: 99%

The Mechanical Properties of Early Drosophila Embryos Measured by High-Speed Video Microrheology

Wessel

Gumalla

Großhans

et al. 2015

Biophysical Journal

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“…For instance, cells are active soft materials, and the protein filaments that compose the cytoskeleton display fast dynamics unique to semiflexible polymers (Koenderink et al 2006;Kollmannsberger and Fabry 2011). Atakhorrami et al (2014) studied the Fig. 12 High-frequency rheology of living fibroblasts, measured by AFM (Reprinted by permission from the Licensor: Springer Nature, Rigato et al (2017), Copyright (2017)).…”

Section: Applicationsmentioning

confidence: 99%

Bulk rheometry at high frequencies: a review of experimental approaches

et al. 2019

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High-frequency rheology is a form of mechanical spectroscopy which provides access to fast dynamics in soft materials and hence can give valuable information about the local scale microstructure. It is particularly useful for systems where timetemperature superposition cannot be used, when there is a need to extend the frequency range beyond what is possible with conventional rotational devices. This review gives an overview of different approaches to high-frequency bulk rheometry, i.e. mechanical rheometers that can operate at acoustic (20 Hz-20 kHz) or ultrasound (> 20 kHz) frequencies. As with all rheometers, precise control and know-how of the kinematic conditions are of prime importance. The inherent effects of shear wave propagation that occur in oscillatory measurements will hence be addressed first, identifying the gap and surface loading limits. Different high-frequency techniques are then classified based on their mode of operation. They are reviewed critically, contrasting ease of operation with the dynamic frequency range obtained. A comparative overview of the different types of techniques in terms of their operating window aims to provide a practical guide for selecting the right approach for a given problem. The review ends with a more forward looking discussion of selected material classes for which the use of high-frequency rheometry has proven particularly valuable or holds promise for bringing physical insights.

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“…Several macro-and microrheology studies have reported agreement with the c 7/5 scaling, 23,34,44 and recent microrheology measurements of the microscale creep compliance of entangled actin reported that viscosity scales as η ∼ c 7/5 . 20 On the other hand, other recent microrheology measurements 8,44,45 reported scaling of G ∼ c while still others [46][47][48][49] showed G ∼ c 11/5 and G ∼ c 9/16 . Further, the majority of experimental and theoretical studies have reported stress softening of entangled actin rather than stiffening in the nonlinear regime, understood to be due to the available non-affine bending modes not present in crosslinked or rigid rod networks.…”

Section: Introductionmentioning

confidence: 96%

Entanglement Density Tunes Microscale Nonlinear Response of Entangled Actin

et al. 2016

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We optically drive a microsphere at constant speed through entangled actin networks of 0.2 -1.4 mg/ml at rates faster than the critical rate controlling the onset of a nonlinear response. By measuring the resistive force exerted on the microsphere during and following strain we reveal a critical concentration c * 0.4 mg/ml for nonlinear features to emerge. For c > c * , entangled actin stiffens at short times with the degree of stiffening S and corresponding timescale t sti f f scaling with the entanglement tube density, i.e. S ∼ t sti f f ∼ d

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Scale-Dependent Nonaffine Elasticity of Semiflexible Polymer Networks

Cited by 26 publications

References 43 publications

The Mechanical Properties of Early Drosophila Embryos Measured by High-Speed Video Microrheology

The Mechanical Properties of Early Drosophila Embryos Measured by High-Speed Video Microrheology

Bulk rheometry at high frequencies: a review of experimental approaches

Entanglement Density Tunes Microscale Nonlinear Response of Entangled Actin

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