Keratocytes pull with similar forces on their dorsal and ventral surfaces.
about
Locomotion guidance by extracellular matrix is adaptive and can be restored by a transient change in Ca2+ levelWeak force stalls protrusion at the leading edge of the lamellipodium.Tetraspanin CD151 regulates alpha6beta1 integrin adhesion strengtheningCytoskeletal coherence requires myosin-IIA contractility.Intracellular fluid flow in rapidly moving cells.Probing cellular traction forces by micropillar arrays: contribution of substrate warping to pillar deflection.A microfluidic imaging chamber for the direct observation of chemotactic transmigrationUsing optics to measure biological forces and mechanics.Slipping or gripping? Fluorescent speckle microscopy in fish keratocytes reveals two different mechanisms for generating a retrograde flow of actin.Tracking retrograde flow in keratocytes: news from the front.Resource Letter: LBOT-1: Laser-based optical tweezersForce transmission in migrating cellsA new dimension in retrograde flow: centripetal movement of engulfed particles.Computational model for cell migration in three-dimensional matrices.Lamellipodial contractions during crawling and spreadingMicroscope-based techniques to study cell adhesion and migration.A POROELASTIC MODEL FOR CELL CRAWLING INCLUDING MECHANICAL COUPLING BETWEEN CYTOSKELETAL CONTRACTION AND ACTIN POLYMERIZATIONTraction forces of neutrophils migrating on compliant substrates.Membrane tension, myosin force, and actin turnover maintain actin treadmill in the nerve growth cone.The relationship between force and focal complex development.Ankyrin binding mediates L1CAM interactions with static components of the cytoskeleton and inhibits retrograde movement of L1CAM on the cell surface.Slow local movements of collagen fibers by fibroblasts drive the rapid global self-organization of collagen gels.Force transduction by Triton cytoskeletons.Local photorelease of caged thymosin beta4 in locomoting keratocytes causes cell turningActin-myosin viscoelastic flow in the keratocyte lamellipodRegulation of RhoA activity by adhesion molecules and mechanotransduction.Positively and negatively modulating cell adhesion to type I collagen via peptide grafting.The desmoplakin/intermediate filament linkage regulates cell mechanics.Computational model for migration of a cell cluster in three-dimensional matrices.Cell contraction forces in scaffolds with varying pore size and cell density.MULTISCALE TWO-DIMENSIONAL MODELING OF A MOTILE SIMPLE-SHAPED CELL.Cytoskeletal mechanics in adherent human airway smooth muscle cells: probe specificity and scaling of protein-protein dynamics.Causes of retrograde flow in fish keratocytes.Motion of an adhesive gel in a swelling gradient: a mechanism for cell locomotion.Two-Phase Acto-Cytosolic Fluid Flow in a Moving Keratocyte: A 2D Continuum Model.Viscoelastic gel-strip model for the simulation of migrating cells.Modeling emergent tissue organization involving high-speed migrating cells in a flow equilibrium.
P2860
Q27340061-C99C8AB3-06AB-458D-B447-60DA41AD9219Q30476825-4860EC79-482B-4E93-A64F-996963EABCBFQ30478308-FD397704-87D5-4CA2-8318-CA2A9F0A00FFQ30492983-3268202F-05BF-4EDF-8180-97198C4FF946Q30494402-3D60CD65-ED9A-4AF0-8ADA-EED797677C50Q30494788-B956C43D-9297-4B6A-8D69-03D7F84F3BF3Q30494912-4D38A2D0-66AC-471E-94BB-8ACB82DA6262Q30716494-0E3601B0-597C-488E-A9F9-832AD268E708Q30854642-D3B4EF9A-7F32-4C13-B2FF-3A46F887F388Q30856501-02F954AE-9834-42E2-AA31-87C72B547CE4Q33257540-796F5BF1-CA59-4252-9163-FC43CB699E2DQ33615104-3D3FDF1D-BAF3-4ACB-9011-CB0F6A8B0653Q34176510-8A5AD286-965F-453C-9841-0FE84934C020Q34350841-A48FB0CF-5E18-4171-806E-9A2B4BA0A39FQ34351048-F6A96AFF-7F28-42E8-8FF8-A9898B343664Q34594627-BAEAB820-B271-4C41-B7DF-AA9B5FDE848AQ35100804-4E68AD5C-9391-4536-A0B1-9A72FF41630DQ35132807-D09CAF40-B55D-46F9-AF1B-6573A65A85AEQ35866817-1A687380-944E-4950-8F31-B9EBE416078BQ36323790-5A09BA74-3849-46D7-A7E5-BD8E69647579Q36325097-7D1367D8-6001-4931-A7AE-3F5966836BE7Q36325732-E34A52E2-8474-49DE-8F42-CEDDBA0B0CD8Q36325783-59A60BE4-A86A-4B2E-944D-CE966CA35406Q36326382-ADDE8BC8-9F3D-49D6-B204-F098B581DE97Q37373433-C2E023CA-7545-429C-95B1-06C32BD17862Q38182134-AEA83AC5-268C-4C46-BFE8-D67B4142B213Q38435882-8179C77B-8B5C-4560-A5C0-9000D6C75D6BQ38791020-EE5736E5-9DB9-4EC9-8A3B-FD528016F000Q39769527-A16634C5-E1F3-4542-A1BA-17292C59CA68Q40227873-E3F57051-C971-4BD3-BF7A-6504ED97E877Q40457945-E5D05548-7A28-40F0-B5C7-7EC778DEFBA9Q44919365-0A614D18-18E5-4A10-BCA7-86F842BBB929Q48932644-72F8F8E4-C900-4692-B6FD-92D0086FD906Q50797322-9AFB8A5F-ABBC-4BB4-A5C2-0765C9CADC8AQ50849604-48D169FF-308F-4746-B64D-C9A4768204ACQ51544090-9FF56704-5EAD-41F7-8C14-DC90F4411166Q51904139-0C11424D-6E2A-4E1C-B6C3-A8BF382B33CA
P2860
Keratocytes pull with similar forces on their dorsal and ventral surfaces.
description
1999 nî lūn-bûn
@nan
1999 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած
@hyw
1999 թվականի դեկտեմբերին հրատարակված գիտական հոդված
@hy
1999年の論文
@ja
1999年論文
@yue
1999年論文
@zh-hant
1999年論文
@zh-hk
1999年論文
@zh-mo
1999年論文
@zh-tw
1999年论文
@wuu
name
Keratocytes pull with similar forces on their dorsal and ventral surfaces.
@ast
Keratocytes pull with similar forces on their dorsal and ventral surfaces.
@en
type
label
Keratocytes pull with similar forces on their dorsal and ventral surfaces.
@ast
Keratocytes pull with similar forces on their dorsal and ventral surfaces.
@en
prefLabel
Keratocytes pull with similar forces on their dorsal and ventral surfaces.
@ast
Keratocytes pull with similar forces on their dorsal and ventral surfaces.
@en
P2860
P356
P1476
Keratocytes pull with similar forces on their dorsal and ventral surfaces.
@en
P2093
C G Galbraith
M P Sheetz
P2860
P304
P356
10.1083/JCB.147.6.1313
P407
P577
1999-12-01T00:00:00Z