Forces and torques on rigid inclusions in an elastic environment: Resulting matrix-mediated interactions, displacements, and rotations

Puljiz, Mate; Menzel, Andreas M.

doi:10.1103/physreve.95.053002

Cited by 36 publications

(36 citation statements)

References 82 publications

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“…They are distinct from active, stochastic forces generated by overlapping microtubule baskets being pushed apart by motor proteins. To model the passive forces, we describe the nuclei as inclusions within an elastic matrix motivated by models for cell arrangements (24)(25)(26)(27). The active force is described as an internuclear force with a constant activity time but a stochastic on-rate of a determined frequency to model the microtubule motor processivity and hopping rate.…”

Section: Introductionmentioning

confidence: 99%

Mechanical Model of Nuclei Ordering in Drosophila Embryos Reveals Dilution of Stochastic Forces

Kaiser

Rodrigues

et al. 2018

Biophysical Journal

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During the initial development of syncytial embryos, nuclei go through cycles of nuclear division and spatial rearrangement. The arising spatial pattern of nuclei is important for subsequent cellularization and morphing of the embryo. Although nuclei are contained within a common cytoplasm, cytoskeletal proteins are nonuniformly packaged into regions around every nucleus. In fact, cytoskeletal elements like microtubules and their associated motor proteins exert stochastic forces between nuclei, actively driving their rearrangement. Yet, it is unknown how the stochastic forces are balanced to maintain nuclear order in light of increased nuclear density upon every round of divisions. Here, we investigate the nuclear arrangements in Drosophila melanogaster over the course of several nuclear divisions starting from interphase 11. We develop a theoretical model in which we distinguish long-ranged passive forces due to the nuclei as inclusions in the elastic matrix, namely the cytoplasm, and active, stochastic forces arising from the cytoskeletal dynamics mediated by motor proteins. We perform computer simulations and quantify the observed degree of orientational and spatial order of nuclei. Solely doubling the nuclear density upon nuclear division, the model predicts a decrease in nuclear order. Comparing results to experimental recordings of tracked nuclei, we make contradictory observations, finding an increase in nuclear order upon nuclear divisions. Our analysis of model parameters resulting from this comparison suggests that overall motor protein density as well as relative active-force amplitude has to decrease by a factor of about two upon nuclear division to match experimental observations. We therefore expect a dilution of cytoskeletal motors during the rapid nuclear division to account for the increase in nuclear order during syncytial embryo development. Experimental measurements of kinesin-5 cluster lifetimes support this theoretical finding.

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Section: Introductionmentioning

confidence: 99%

Mechanical Model of Nuclei Ordering in Drosophila Embryos Reveals Dilution of Stochastic Forces

Kaiser

Rodrigues

et al. 2018

Biophysical Journal

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“…Using linear elasticity theory, Puljiz et.al. obtained an analytic expression considering in first approximation mutual 2and 3-body elastic interactions among spherical particles [30,88]. In our present work, we assume an isotropic and incompressible elastic medium.…”

Section: Explicit Particle Structures-balance Of Local Forcesmentioning

confidence: 99%

“…Accordingly, we set ν = 0.5 and 3µ = E, where ν denotes the Poisson ratio, µ the shear modulus, and E the elastic modulus. From [88], we then find for each particle in the sample a linear dependency of the form:…”

Section: Explicit Particle Structures-balance Of Local Forcesmentioning

confidence: 99%

“…Contribution f el i shall provide the 'restoring' force due to the elastic matrix when the particles change their positions ({r 0 j } → {r j }). To implement f el i , we make use of the approximate results from the linear elasticity model as obtained by Puljiz et al [30,88]. For an incompressible, isotropic matrix material, Equation (31) provides the superimposed relations between the set of locally applied forces {f j } and the set of displacements {∆r j } including hydrodynamic 2-and 3-body interactions.…”

Section: Informed Consent Statement: Not Applicablementioning

confidence: 99%

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Magneto-Mechanical Coupling in Magneto-Active Elastomers

et al. 2021

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In the present work, the magneto-mechanical coupling in magneto-active elastomers is investigated from two different modeling perspectives: a micro-continuum and a particle–interaction approach. Since both strategies differ significantly in their basic assumptions and the resolution of the problem under investigation, they are introduced in a concise manner and their capabilities are illustrated by means of representative examples. To motivate the application of these strategies within a hybrid multiscale framework for magneto-active elastomers, their interchangeability is then examined in a systematic comparison of the model predictions with regard to the magneto-deformation of chain-like helical structures in an elastomer surrounding. The presented results show a remarkable agreement of both modeling approaches and help to provide an improved understanding of the interactions in magneto-active elastomers with chain-like microstructures.

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“…Additionally, they showed that their formalism holds for the inclusion of net torques on the rigid particles. The specified examples for twoand three-particle systems in [59,60] are of particular importance in providing a solid theoretical basis for the systems described in this work.…”

Section: Elastic Interaction Mediated By the Matrixmentioning

confidence: 99%

Collision and separation of nickel particles embedded in a polydimethylsiloxan matrix under a rotating magnetic field: A strong magneto active function

et al. 2021

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In order to function as soft actuators, depending on their field of use, magnetorheological elastomers (MREs) must fulfill certain criteria. To name just a few, these can include rapid response to external magnetic fields, mechanical durability, mechanical strength, and/or large deformation. Of particular interest are MREs which produce macroscopic deformation for small external magnetic field variations. This work demonstrates how this can be achieved by just a small change in magnetic field orientation. To achieve this, (super)paramagnetic nickel particles of size ≈ 160 μm were embedded in a non-magnetic polydimethylsiloxan (PDMS) (661–1301 Pa) and their displacement in a stepwise rotated magnetic field (170 mT) recorded using a video microscope. Changes in particle aggregation resulting from very small variations in magnetic field orientation led to the observation of a new strongly magneto-active effect. This configuration is characterized by an interparticle distance in relation to the angle difference between magnetic field and particle axis. This causes a strong matrix deformation which in turn demonstrates hysteresis on relaxation. It is shown that the occurrence strongly depends on the particle size, particle distance, and stiffness of the matrix. Choosing the correct parameter combination, the state can be suppressed and the particle-matrix system demonstrates no displacement or hysteresis. In addition, evidences of non-negligible higher order magnetization effects are experimentally ascertained which is qualitatively in agreement with similar, already theoretically described, particle systems. Even at larger particle geometries, the new strongly magneto-active configuration is preserved and could create macroscopic deformation changes.

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Forces and torques on rigid inclusions in an elastic environment: Resulting matrix-mediated interactions, displacements, and rotations

Cited by 36 publications

References 82 publications

Mechanical Model of Nuclei Ordering in Drosophila Embryos Reveals Dilution of Stochastic Forces

Mechanical Model of Nuclei Ordering in Drosophila Embryos Reveals Dilution of Stochastic Forces

Magneto-Mechanical Coupling in Magneto-Active Elastomers

Collision and separation of nickel particles embedded in a polydimethylsiloxan matrix under a rotating magnetic field: A strong magneto active function

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