Measurement of Local Viscoelasticity and Forces in Living Cells by Magnetic Tweezers

Bausch, Andreas R.; Möller, Winfried; Sackmann, E.

doi:10.1016/s0006-3495(99)77225-5

Cited by 707 publications

(520 citation statements)

References 20 publications

Supporting

Mentioning

492

Contrasting

Unclassified

Order By: Relevance

“…The experimental setup was described previously [25,32]. The inhomogeneous field is generated with a soft iron core exhibiting a sharp wedge-shaped edge.…”

Section: The Magnetic Bead Microrheometermentioning

confidence: 99%

“…A variety of colloidal probe microrheometry techniques have been developed over the last few years based on the analysis of Brownian motion [10,23,24] or of the viscoelastic responses evoked by local forces applied through optical traps [10,23] and magnetic tweezers. With magnetic tweezers, viscoelastic responses can be evoked by linear [25] or by torsional [26,27] excitations. The viscoelastic response to force pulses yield relaxation moduli G(t) and relaxation times, while oscillatory force scenarios yield complex viscoelastic impedances.…”

Section: Introductionmentioning

confidence: 99%

“…Microrheometric studies of the cytoplasm of mammalian cells by magnetic tweezer microrheometry [25] and force free laser tracking [10] have been interpreted in terms of the models of viscoelastic bodies exhibiting shear moduli of the order of 100 Pa. However, shear field mapping experiments did not provide any evidence for elastic coupling between intracellular compartments over distances of 0.5 lm [25]. More recent microrheological studies of Dictyostelia cells immobilized by agar overlays provided evidence that the cytoplasmic space behaves rather as a viscoplastic body [29].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Active mechanical stabilization of the viscoplastic intracellular space of Dictyostelia cells by microtubule–actin crosstalk

Heinrich

Sackmann²

2006

Acta Biomaterialia

Self Cite

View full text Add to dashboard Cite

The micro-viscoelasticity of the intracellular space of Dictyostelium discoideum cells is studied by evaluating the intracellular transport of magnetic force probes and their viscoelastic responses to force pulses of 20-700 pN. The role of the actin cortex, the microtubule (MT) aster and their crosstalk is explored by comparing the behaviour of wild-type cells, myosin II null mutants, latrunculin A and benomyl treated cells. The MT coupled beads perform irregular local and long range directed motions which are characterized by measuring their velocity distributions (P(v)). The correlated motion of the MT and the centrosome are evaluated by microfluorescence of GFP-labelled MTs. P(v) can be represented by log-normal distributions with long tails and it is determined by random sweeping motions (v $ 0.5 lm/s) of the MTs (caused by tangential forces on the filament ends coupled to the actin cortex) and by intermittent bead transports parallel to the MTs (v max $ 1.5 lm/s). The tails are due to spontaneous filament deflections (with speeds up to 10 lm/s) attributed to pre-stressing of the MT by local cortical tensions, generated by dynactin motors generating plus-end directed forces in the MTs. The viscoelastic responses are strongly non-linear and are mostly directed opposite or perpendicular to the force, showing that the cytoplasm behaves as an active viscoplastic body with time and force dependent drag coefficients. Nano-Newton loads exerted on the soft MT are balanced by traction forces arising at the MT ends coupled to the actin cortex and the centrosome, respectively. The mechanical coupling between the soft microtubules and the viscoelastic actin cortex provides cells with high mechanical stability despite the softness of the cytoplasm.

show abstract

“…The experimental setup was described previously [25,32]. The inhomogeneous field is generated with a soft iron core exhibiting a sharp wedge-shaped edge.…”

Section: The Magnetic Bead Microrheometermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Active mechanical stabilization of the viscoplastic intracellular space of Dictyostelia cells by microtubule–actin crosstalk

Heinrich

Sackmann²

2006

Acta Biomaterialia

Self Cite

View full text Add to dashboard Cite

show abstract

“…The mechanical properties of the cellular cortex have been measured by several techniques such as cell poking [12,13], micropipette aspiration [14,15], optical tweezers [16][17][18] and magnetic beads twisting [19][20][21]. However, the temporal and/or spatial resolutions of these techniques do not suffice for a thorough understanding of the variations in mechanical properties caused by cellular functions.…”

Section: Introductionmentioning

confidence: 99%

Contribution of cellular contractility to spatial and temporal variations in cellular stiffness

Nagayama

Haga

Takahashi

et al. 2004

Experimental Cell Research

View full text Add to dashboard Cite

Scanning probe microscopy and immunofluorescence observations indicated that cellular stiffness was attributed to a contractile network structure consisting of stress fibers. We measured temporal variations in cellular stiffness when cellular contractility was regulated by dosing with lysophosphatidic acid or Y-27632. This experiment reveals a clear relation between cellular stiffness and contractility: Increases in contractility cause cells to stiffen. On the other hand, decreases in contractility reduce cellular stiffness. In both cases, not only the stiffness of the stress fibers but also that of the whole of the cell varies. Immunofluorescence observations of myosin II and vinculin indicated that the stiffness variations induced by the regulation of cellular contractility were mainly due to rearrangements of the contractile actin network on the dorsal surface. Taken together, our findings provide evidence that the actin cytoskeletal network and its contractility features provide and modulate the mechanical stability of adherent cells.

show abstract

“…Therefore, in these cases the Young modulus of the cells is described as a function of their state with respect to time. Furthermore, the Young modulus E ECM and the viscosity μ ECM of the ECM have been fixed to 10 Pa and 3 × 10 5 Pa s (Bausch et al 1999;Drury and Dembo 2001), respectively, and the density of the cells is equal to 1000 kg/m 3 (Fukui et al 2000). Finally, the intensity of the cyclic active strain e a0 and the duration of a migration cycle T have been set to 0.5 (Allena 2013; Allena and Aubry 2012) and 60 s (Allena 2013;Allena and Aubry 2012;Dong et al 2002) respectively (except for the fifth mode of migration as described in Sect.…”

Section: Resultsmentioning

confidence: 99%

On the Mechanical Interplay Between Intra- and Inter-Synchronization During Collective Cell Migration: A Numerical Investigation

2013

View full text Add to dashboard Cite

is an open access repository that collects the work of Arts et Métiers ParisTech researchers and makes it freely available over the web where possible. Abstract Collective cell migration is a fundamental process that takes place during several biological phenomena such as embryogenesis, immunity response, and tumorogenesis, but the mechanisms that regulate it are still unclear. Similarly to collective animal behavior, cells receive feedbacks in space and time, which control the direction of the migration and the synergy between the cells of the population, respectively. While in single cell migration intra-synchronization (i.e. the synchronization between the protrusion-contraction movement of the cell and the adhesion forces exerted by the cell to move forward) is a sufficient condition for an efficient migration, in collective cell migration the cells must communicate and coordinate their movement between each other in order to be as efficient as possible (i.e. intersynchronization). Here, we propose a 2D mechanical model of a cell population, which is described as a continuum with embedded discrete cells with or without motility phenotype. The decomposition of the deformation gradient is employed to reproduce the cyclic active strains of each single cell (i.e. protrusion and contraction). We explore different modes of collective migration to investigate the mechanical interplay between intra-and inter-synchronization. The main objective of the paper is to evaluate the efficiency of the cell population in terms of covered distance and how the

show abstract

Measurement of Local Viscoelasticity and Forces in Living Cells by Magnetic Tweezers

Cited by 707 publications

References 20 publications

Active mechanical stabilization of the viscoplastic intracellular space of Dictyostelia cells by microtubule–actin crosstalk

Active mechanical stabilization of the viscoplastic intracellular space of Dictyostelia cells by microtubule–actin crosstalk

Contribution of cellular contractility to spatial and temporal variations in cellular stiffness

On the Mechanical Interplay Between Intra- and Inter-Synchronization During Collective Cell Migration: A Numerical Investigation

Contact Info

Product

Resources

About