Appreciating force and shape—the rise of mechanotransduction in cell biology.
about
Interkinetic nuclear migration generates and opposes ventricular-zone crowding: insight into tissue mechanicsSuper-Resolved Traction Force Microscopy (STFM)Evidence for the mechanosensor function of filamin in tissue development.Nanoscale optomechanical actuators for controlling mechanotransduction in living cellsIntegrin-beta3 clusters recruit clathrin-mediated endocytic machinery in the absence of traction force.In-situ coupling between kinase activities and protein dynamics within single focal adhesions.On-Chip Quantitative Measurement of Mechanical Stresses During Cell Migration with Emulsion Droplets.Human Pluripotent Stem Cell Mechanobiology: Manipulating the Biophysical Microenvironment for Regenerative Medicine and Tissue Engineering ApplicationsSmall but Mighty: Nanoparticles Probe Cellular Signaling PathwaysBeyond Turing: mechanochemical pattern formation in biological tissuesLinearized texture of three-dimensional extracellular matrix is mandatory for bladder cancer cell invasion.Optogenetic control of cellular forces and mechanotransduction.Mechanosensing Controlled Directly by Tyrosine Kinases.Cell geometry dictates TNFα-induced genome response.Age-Associated Increase in Skin Fibroblast-Derived Prostaglandin E2 Contributes to Reduced Collagen Levels in Elderly Human SkinKnowing one's place: a free-energy approach to pattern regulationThe shifting geography and language of cell biology.The interplay of extracellular matrix and microbiome in urothelial bladder cancer.Age-associated reduction of cell spreading induces mitochondrial DNA common deletion by oxidative stress in human skin dermal fibroblasts: implication for human skin connective tissue agingSpatio-Temporal Control of LbL Films for Biomedical Applications: From 2D to 3DRheological properties of cells measured by optical tweezers.The mechanotransduction machinery at work at adherens junctions.Micropatterning of TCR and LFA-1 ligands reveals complementary effects on cytoskeleton mechanics in T cells.Differences in the Mechanical Properties of the Developing Cerebral Cortical Proliferative Zone between Mice and Ferrets at both the Tissue and Single-Cell LevelsFactors influencing the determination of cell traction forces.Simple agarose micro-confinement array and machine-learning-based classification for analyzing the patterned differentiation of mesenchymal stem cellsElectrical and mechanical stimulation of cardiac cells and tissue constructs.Reduction of fibroblast size/mechanical force down-regulates TGF-β type II receptor: implications for human skin aging.Pushing, pulling, and squeezing our way to understanding mechanotransductionConversion of nanoscale topographical information of cluster-assembled zirconia surfaces into mechanotransductive events promotes neuronal differentiationPrimary cilia are not calcium-responsive mechanosensorsA Mechanogenetic Toolkit for Interrogating Cell Signaling in Space and Time.The actin crosslinking protein palladin modulates force generation and mechanosensitivity of tumor associated fibroblasts.Combined optical micromanipulation and interferometric topography (COMMIT).Matrix mechanics controls FHL2 movement to the nucleus to activate p21 expression.α-Actinin links extracellular matrix rigidity-sensing contractile units with periodic cell-edge retractions.Contractile forces at tricellular contacts modulate epithelial organization and monolayer integrity.High-resolution traction force microscopy on small focal adhesions - improved accuracy through optimal marker distribution and optical flow tracking.How to Train a Cell-Cutting-Edge Molecular Tools.Engineered Models of Confined Cell Migration.
P2860
Q26859279-B602747B-1AA4-4DB3-8092-5E6D5E213D7BQ27300864-63C7E0E2-9B72-4A40-81A9-E0AA26AAE37FQ27312558-1FC89E75-80D4-4252-BFAC-7606FBEEC8B2Q27313636-7D597360-FBA4-45F9-88C0-1A186833B594Q27320491-09868D13-D56A-43E1-AEAB-6AE12B9B1B1FQ27331739-978EC0CF-9CD7-4831-B6E6-716D92D824B6Q27333574-FD1372DC-10EF-4248-B56B-A41B4CE07C8DQ28086780-3891C82F-7670-4163-95D1-C3499551FD8EQ28590316-0A2B420C-F0E0-4661-9E0D-DA194A4C1860Q28833520-EC273A02-2039-4735-B1D0-8162B43D8C61Q30371525-F599873E-050D-4F56-8C20-32042BF28492Q30838711-3CCE670F-1859-4E31-930C-7E8DA6D75496Q30840180-789D8689-55EA-440D-9114-69921ECEB2A9Q33719406-DFD2FCAF-82D9-4E05-AAE5-649F483DA401Q34473373-97CEF79E-D1D1-4DAE-96DF-9F289C39EDBFQ35291647-5C01B631-DF47-4019-B0D8-914834013B03Q35594565-1D13ACAB-5669-4CBC-B559-CABAE8FE7238Q35868405-8A766214-9057-4981-97EE-15F9150947A1Q35896422-F4A97839-16D3-4031-BDEA-894603C6B503Q35965771-A5B4A730-3EA3-4ED0-A9A7-5A9DBE508A56Q36060792-0DF19CD3-EC00-4288-9A9B-43DD20782C55Q36122409-4AEF89F1-0F10-42F0-94BF-42F0CD3F21C4Q36122457-898EAE13-43EE-40DE-8AD8-9645A309E9FBQ36216947-F326C741-6E05-4C65-8C77-FDC47AF86631Q36289935-FACD770A-D040-44B4-AA93-C3A80B5768FAQ36336068-FB00F6FD-800A-4689-AB65-75370C2E1316Q36421781-137E0EF8-2AF2-4658-BCE6-31EC901DAD2DQ36475231-93D2F4BE-801D-4D04-83E5-6B77C42508C2Q36601156-1214EA15-C731-4795-9390-D760F576375DQ36668008-4C2C79D0-615A-4773-AD01-3DD27585BE71Q36852774-3A2889AE-2248-4C1B-A39F-F97A3C1C01ACQ36968356-3E3ED39D-AD27-4244-8EFD-582293813E49Q37050026-198D0767-3AF5-4D4F-86B3-6D3671749C64Q37057619-1A946075-25FA-435B-81DB-6CA7A8CC8930Q37398116-9556CB46-DC07-43EB-8BEE-B7A5B057185BQ37573244-DCE67C0D-8E4A-4B48-988E-35F492F85B69Q37591401-26D59037-E450-4E81-B7EE-E493AB70D053Q37625651-DCE837AA-AFFA-4119-929C-693C6C6F3D46Q37692030-95983021-3D8C-4B6A-99A6-FAECD56C865FQ37724995-834E979A-FF35-4D7C-94E5-5ABCAF45BCF8
P2860
Appreciating force and shape—the rise of mechanotransduction in cell biology.
description
2014 nî lūn-bûn
@nan
2014年の論文
@ja
2014年学术文章
@wuu
2014年学术文章
@zh
2014年学术文章
@zh-cn
2014年学术文章
@zh-hans
2014年学术文章
@zh-my
2014年学术文章
@zh-sg
2014年學術文章
@yue
2014年學術文章
@zh-hant
name
Appreciating force and shape—the rise of mechanotransduction in cell biology.
@en
Appreciating force and shape—the rise of mechanotransduction in cell biology.
@nl
type
label
Appreciating force and shape—the rise of mechanotransduction in cell biology.
@en
Appreciating force and shape—the rise of mechanotransduction in cell biology.
@nl
prefLabel
Appreciating force and shape—the rise of mechanotransduction in cell biology.
@en
Appreciating force and shape—the rise of mechanotransduction in cell biology.
@nl
P2860
P356
P1476
Appreciating force and shape—the rise of mechanotransduction in cell biology.
@en
P2093
Haguy Wolfenson
Michael P Sheetz
P2860
P2888
P304
P356
10.1038/NRM3903
P577
2014-10-30T00:00:00Z
P6179
1010899080