Roles of cell confluency and fluid shear in 3-dimensional intracellular forces in endothelial cells
about
Cyclic stretch of embryonic cardiomyocytes increases proliferation, growth, and expression while repressing Tgf-β signalingControl of cell-cell forces and collective cell dynamics by the intercellular adhesome.Integrated micro/nanoengineered functional biomaterials for cell mechanics and mechanobiology: a materials perspective.Flow-dependent cellular mechanotransduction in atherosclerosis.Fluid shear stress on endothelial cells modulates mechanical tension across VE-cadherin and PECAM-1.Probing cell-cell communication with microfluidic devices.Measuring cell-generated forces: a guide to the available toolsGEF-H1 controls focal adhesion signaling that regulates mesenchymal stem cell lineage commitment.The effect of enterohemorrhagic E. coli infection on the cell mechanics of host cellsShear-induced force transmission in a multicomponent, multicell model of the endotheliumMonolayer stress microscopy: limitations, artifacts, and accuracy of recovered intercellular stresses.Three-dimensional quantification of cellular traction forces and mechanosensing of thin substrata by fourier traction force microscopy.Mapping the dynamics of force transduction at cell-cell junctions of epithelial clusters.High resolution, large deformation 3D traction force microscopy.Fluid shear, intercellular stress, and endothelial cell alignmentβ-PIX controls intracellular viscoelasticity to regulate lung cancer cell migration.Toward single cell traction microscopy within 3D collagen matrices.A contact line pinning based microfluidic platform for modelling physiological flows.P2Y₂ and Gq/G₁₁ control blood pressure by mediating endothelial mechanotransduction.Cells gain traction in 3D.For whom the cells pull: Hydrogel and micropost devices for measuring traction forces.Shp2 plays a crucial role in cell structural orientation and force polarity in response to matrix rigidityHigh throughput physiological screening of iPSC-derived cardiomyocytes for drug development.Two-Layer Elastographic 3-D Traction Force Microscopy.P2Y2 receptor modulates shear stress-induced cell alignment and actin stress fibers in human umbilical vein endothelial cells.Regulation of the endothelial barrier function: a filum granum of cellular forces, Rho-GTPase signaling and microenvironment.Flow-induced stress on adherent cells in microfluidic devices.Cell-cell junctional mechanotransduction in endothelial remodeling.Microfluidic traction force microscopy to study mechanotransduction in angiogenesis.Measuring cellular traction forces on non-planar substratesProgress in Integrative Biomaterial Systems to Approach Three-Dimensional Cell Mechanotransduction.Traction Forces of Endothelial Cells under Slow Shear Flow.Perfusion pressure and blood flow determine microvascular apparent viscosity.Three-dimensional forces exerted by leukocytes and vascular endothelial cells dynamically facilitate diapedesis.Mechanotransduction in small intestinal submucosa scaffolds: fabrication parameters potentially modulate the shear-induced expression of PECAM-1 and eNOS.Oscillatory shear stress mediates directional reorganization of actin cytoskeleton and alters differentiation propensity of mesenchymal stem cells.Mechanical interactions between bacteria and hydrogels
P2860
Q27302374-62A230B6-3551-4A21-A81F-175197DEBDDBQ27313331-6B3FAEEA-3F6D-4FD8-B164-AA7583323389Q30356846-67D4C2A1-D354-4C78-B6A9-A3936B2D1DBDQ30409536-5BAB118A-2FB9-49FF-BFEC-7B38E9E0AAE3Q30412646-0F3BDE2D-8D1B-46C6-8E08-1D6416A2C0C9Q30432716-BE056D82-43FC-4409-9AFF-FED97FC4AB87Q33809070-F6B4F3DA-4667-4990-9E77-B72ED9474E94Q34264512-D986F514-FC02-4C7B-AD56-105D444D206CQ34450914-2F97EA5D-7159-401A-A705-EEAEE2BDC21EQ34520946-A53761CD-354F-48C9-981E-6C235DB60BEEQ34611354-3CDB7CAB-ADE8-449E-BF1A-22149334A1CFQ34983832-F999B16E-DBA0-45ED-A2A2-A5566D78D990Q34991367-A9D3A340-03E6-4FBD-ACFE-4C214DB36E55Q35150844-8318C28D-2340-4373-AB3C-0ACC98F0EED0Q35437173-8F9FD5FB-83FB-40BC-98FC-933AC51BD7EEQ35571905-226DE21F-1252-4D51-B3CD-F8E61073AA30Q35835728-94A6DB31-7A37-4744-810F-D1B158DC4EFBQ35861871-4D9F52BF-72F0-46F8-8C73-EAA4C67B7817Q36040517-0C376FA3-3575-4002-84F2-80DBADA6093CQ36094238-31797BE0-ACC1-4FC7-9730-8EAF40604640Q36558517-3BA75946-E423-47F6-A506-51FB9DF3AC78Q36637373-2927D448-59E4-48DF-8138-79A85CE45D26Q36948480-907744F4-394E-4626-B885-1D84A19BBA9CQ37578854-3624257C-C4A1-4277-A599-685F8AB7B622Q37610836-CA9BD476-0F2C-48ED-B288-CC86A5DC2D97Q38196358-B323940D-0233-4CF8-ACEE-3E9E2B30C33EQ38579572-8A9F4132-BAE6-4685-A061-51F985F2003EQ38923130-0D1D78CC-0026-4F16-96A3-102CFECF3DE4Q39121488-177628E6-5D33-4148-8A8F-866A5F8DD5AEQ39318179-BCCC10C4-285C-4AE1-9BD1-EF8FD7856308Q41670145-FA18E9DD-AA14-4EFC-B96C-47A1DCEA4947Q42040292-57D2ECB7-674D-44D9-B71E-2A8FB150B6C3Q46059416-C80DD7EC-FD70-456C-B575-0D6C61115193Q47236833-07CF1F52-56F1-40D2-83F1-0DF6A1813FDFQ51829959-9B89E934-6C71-4DAB-965D-CC07F247C201Q55070738-4C036099-4641-4CBC-96B0-0C073B28750FQ57331333-B352B749-9462-48D1-B289-4478D0198109
P2860
Roles of cell confluency and fluid shear in 3-dimensional intracellular forces in endothelial cells
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
2012年论文
@zh
2012年论文
@zh-cn
name
Roles of cell confluency and f ...... ar forces in endothelial cells
@ast
Roles of cell confluency and f ...... ar forces in endothelial cells
@en
type
label
Roles of cell confluency and f ...... ar forces in endothelial cells
@ast
Roles of cell confluency and f ...... ar forces in endothelial cells
@en
prefLabel
Roles of cell confluency and f ...... ar forces in endothelial cells
@ast
Roles of cell confluency and f ...... ar forces in endothelial cells
@en
P2093
P2860
P356
P1476
Roles of cell confluency and f ...... ar forces in endothelial cells
@en
P2093
Baldomero Alonso-Latorre
Hong A Nguyen
Joon Seok Park
Juan C Lasheras
Juan C del Álamo
Kuei-Chun Wang
Leona Flores
Sung Sik Hur
P2860
P304
11110-11115
P356
10.1073/PNAS.1207326109
P407
P577
2012-06-04T00:00:00Z