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BP: Fachverband Biologische Physik
BP 37: Biomaterials
BP 37.7: Vortrag
Freitag, 26. März 2010, 12:00–12:15, H43
Using microtubules to measure actin viscoelasticity — Felix Zörgiebel1, •Marcel Bremerich1, Frederick C. MacKintosh2, and Christoph F. Schmidt1 — 1III. Physikalisches Institut, Georg-August-Universität, 37077 Göttingen — 2Department of Physics & Astronomy, Vrije Universiteit, 1081 HV Amsterdam
In conventional active and passive microrheology techniques, micron-sized particles are embedded in biological samples for probing their viscoelastic properties. These methods are not always well suited for investigating the interior of living cells because the probe particles can perturb their neighborhood and because surface interactions can occur. Such problems can be elegantly circumvented by using natural constituents of the cellular system as local probes. The thermal bending fluctuations of microtubules, for instance, intrinsically carry information about the mechanical properties of the surrounding medium. It turns out that one can investigate local shear moduli and stress fluctuations in biopolymer networks by a detailed analysis of the spatial and temporal bending fluctuations of just one point of a microtubule, largely without introducing probe artifacts. To test this new method, we sparsely seeded an in vitro network of filamentous actin with microtubules which were again sparsely labeled with nanometer-sized gold particles. The displacements of these particles were then tracked by laser interferometry using an optical trap. Knowing the microtubule elastic properties, the observed bending dynamics allowed us to estimate the complex shear modulus of the surrounding actin network.