An active biopolymer network controlled by molecular motors.
about
Cell mechanics and the cytoskeletonDiastolic filling vortex forces and cardiac adaptations: probing the epigenetic nexusEmergent material properties of developing epithelial tissues.Collective dynamics of active cytoskeletal networksContractile and mechanical properties of epithelia with perturbed actomyosin dynamicsMacroscopic stiffening of embryonic tissues via microtubules, RhoGEF and the assembly of contractile bundles of actomyosin.Active multistage coarsening of actin networks driven by myosin motorsActin network architecture can determine myosin motor activityAnalysis of the local organization and dynamics of cellular actin networksActomyosin sliding is attenuated in contractile biomimetic cortices.Probing the stochastic, motor-driven properties of the cytoplasm using force spectrum microscopy.Isotropic actomyosin dynamics promote organization of the apical cell cortex in epithelial cellsSurprisingly simple mechanical behavior of a complex embryonic tissue.Response of biopolymer networks governed by the physical properties of cross-linking moleculesViscoelastic response of contractile filament bundles.Actin filament length tunes elasticity of flexibly cross-linked actin networks.Documentation and localization of force-mediated filamin A domain perturbations in moving cells.Actin-myosin spatial patterns from a simplified isotropic viscoelastic modelQuantification of surface tension and internal pressure generated by single mitotic cells.Statistics of active transport in Xenopus melanophores cells.The value of mechanistic biophysical information for systems-level understanding of complex biological processes such as cytokinesis.Dynamic network morphology and tension buildup in a 3D model of cytokinetic ring assembly.Reconstitution of contractile actomyosin bundlesDifferential mechanical stability of filamin A rod segments.Measurement of subcellular force generation in neurons.Physics and the canalization of morphogenesis: a grand challenge in organismal biology.Model for adhesion clutch explains biphasic relationship between actin flow and traction at the cell leading edge.Actin Mechanics and Fragmentation.Mechanotransduction Mechanisms for Intraventricular Diastolic Vortex Forces and Myocardial Deformations: Part 2.Active contractility in actomyosin networksDetermining Physical Properties of the Cell Cortex.Mechanics and dynamics of reconstituted cytoskeletal systems.Multiscale mechanobiology: computational models for integrating molecules to multicellular systems.Active, motor-driven mechanics in a DNA gelFiber networks amplify active stress.Microrheology of highly crosslinked microtubule networks is dominated by force-induced crosslinker unbinding.Stress generation by myosin minifilaments in actin bundles.Spontaneous Formation of a Globally Connected Contractile Network in a Microtubule-Motor System.Active compaction of crosslinked driven filament networks.Cell-sized liposomes reveal how actomyosin cortical tension drives shape change.
P2860
Q24601132-F7894AF5-D2C2-4CD8-ABC1-12EF52CCE9DDQ27025551-4497F8E4-9058-4D8F-AC94-A991FB5D3950Q27305138-ED4DBCD4-7C3C-48B8-97DE-D8365BBBADFBQ27323256-FFCC9DCB-7F77-4687-BC3F-8DC66A6C7D04Q27335608-6BD435B9-FD2B-49AD-AE12-0E9D82747454Q30495705-DB23769B-5A2D-4A16-95C9-A625D822E985Q30500968-D528FBE1-A29B-423C-809A-444FB3C29A51Q30539662-63874E01-8F64-49DC-83D0-D4D4C962F4ACQ30547708-BAAD8FF8-BD63-4E5D-88A1-8A6149BCD6EDQ30580573-DCB83CF8-7AA6-4952-9392-46366C84B3DFQ30588682-4999A907-CF3A-48EE-98DA-21EEED0E9DEDQ30591643-767DDB8B-988E-49B3-86B9-07C6A7F59AE1Q33784340-DF28D407-B66C-48BE-A07B-6164AA1830AAQ33889510-08DA11B5-571D-41BB-8B1C-3E6893183FF6Q33950684-7A9CFCB9-0123-4944-BFB5-159B78FE37BDQ34062523-DC7B3806-D7DF-4EEA-A1FD-47FC78861119Q34069659-D9BEE0D8-9D95-4507-B070-7F3E49D44403Q34080070-568AB86C-0AEB-4EF3-985D-432292B95DA6Q34106458-E28AFA0F-C8F1-4886-B4B7-16CDED957099Q34306987-A95313B7-EF14-4F49-A63D-469E5FF8EF3AQ34628885-311EBD22-8098-4E61-9520-040BA5BB9736Q34628891-4331B070-5098-4837-A423-29669ECD5414Q35051293-720FA345-0C94-4B05-9643-389181DB1101Q35187627-34C0BF6C-6C97-4D9F-B8F8-493CA0330FDAQ35221891-17F7406A-222E-4FF4-ABBC-0BAA8D27E0F2Q35435973-ED56D80D-3038-4A2F-8DF3-522BFF5FC959Q35673829-71577306-C5A8-4121-ABA3-723A6D737248Q35837098-EE69A273-AB31-400C-AB1C-FEA2AB0AF48BQ35901064-E144928E-F228-4F38-AB23-2B50EE0EE7BBQ35921973-3D3620BB-8D55-4EF7-9B44-5B5F7C4A695FQ35974179-8217B966-5FEA-4D0D-8CFF-156120C4DA76Q36352213-0D814962-AE4E-4EFF-8639-C74A79E7B5B5Q36366590-0907BA0F-6744-409F-92F6-A9BA3BA9B268Q36378501-52075048-09B5-4864-9826-76263A852CCDQ36710475-B462C81C-7974-45AF-A03A-B6240C6ADC9AQ36746399-12786A33-642B-4E1B-9786-14D1760060ACQ36963011-EFD14A01-8879-42A8-BD8E-C202D8B21C0FQ37141997-A2E85D41-7429-4332-8F06-3B17F8D5D017Q37172791-B4928BFF-0235-43E5-85B4-465B7BEA50B4Q37236578-6C0352A7-BF70-4B53-B868-CEB84689E618
P2860
An active biopolymer network controlled by molecular motors.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 10 August 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
An active biopolymer network controlled by molecular motors.
@en
An active biopolymer network controlled by molecular motors.
@nl
type
label
An active biopolymer network controlled by molecular motors.
@en
An active biopolymer network controlled by molecular motors.
@nl
prefLabel
An active biopolymer network controlled by molecular motors.
@en
An active biopolymer network controlled by molecular motors.
@nl
P2093
P2860
P356
P1476
An active biopolymer network controlled by molecular motors
@en
P2093
David A Weitz
Frederick C MacKintosh
Fumihiko Nakamura
Gijsje H Koenderink
John H Hartwig
Thomas P Stossel
Zvonimir Dogic
P2860
P304
15192-15197
P356
10.1073/PNAS.0903974106
P407
P577
2009-08-10T00:00:00Z