about
Nanotopographical modulation of cell function through nuclear deformationBioinspired membrane-based systems for a physical approach of cell organization and dynamics: usefulness and limitationsPhysical biology in cancer. 5. The rocky road of metastasis: the role of cytoskeletal mechanics in cell migratory response to 3D matrix topographyDiastolic filling vortex forces and cardiac adaptations: probing the epigenetic nexusDevelopmental heterogeneity in DNA packaging patterns influences T-cell activation and transmigrationRole of actin dependent nuclear deformation in regulating early gene expressionCardiomyocyte-specific expression of lamin a improves cardiac function in Lmna-/- miceRemodeling of nuclear landscapes during human myelopoietic cell differentiation maintains co-aligned active and inactive nuclear compartmentsCytoskeletal tension induces the polarized architecture of the nucleus.Volume regulation and shape bifurcation in the cell nucleus.The embryological basis of subclinical hypertrophic cardiomyopathyExtracellular Forces Cause the Nucleus to Deform in a Highly Controlled Anisotropic Manner.Lamina-associated polypeptide (LAP)2α and other LEM proteins in cancer biologyEngineering three-dimensional stem cell morphogenesis for the development of tissue models and scalable regenerative therapeutics.Heading in the Right Direction: Understanding Cellular Orientation Responses to Complex Biophysical EnvironmentsModeling of the mechano-chemical behaviour of the nuclear pore complex: current research and perspectivesThe nuclear envelope at a glanceNuclear envelope structural proteins facilitate nuclear shape changes accompanying embryonic differentiation and fidelity of gene expressionA sub-cellular viscoelastic model for cell population mechanicsThe major transitions of life from a network perspectivePlasticity of cell migration: a multiscale tuning modelCellular enrichment through microfluidic fractionation based on cell biomechanical properties.Conception and development of the Second Life® Embryo Physics Course.Finite-element modeling of viscoelastic cells during high-frequency cyclic strainImage-based multiscale modeling predicts tissue-level and network-level fiber reorganization in stretched cell-compacted collagen gels.Deformation of stem cell nuclei by nanotopographical cues.Motor-driven motility of fungal nuclear pores organizes chromosomes and fosters nucleocytoplasmic transport.Nuclear and cellular alignment of primary corneal epithelial cells on topography.Defined topologically-complex protein matrices to manipulate cell shape via three-dimensional fiber-like patterns.Probing the biomechanical contribution of the endothelium to lymphocyte migration: diapedesis by the path of least resistance.Confinement and deformation of single cells and their nuclei inside size-adapted microtubesAlpha-helical protein networks are self-protective and flaw-tolerant.Emergence of a prestressed eukaryotic nucleus during cellular differentiation and developmentMechanical Strain Promotes Oligodendrocyte Differentiation by Global Changes of Gene ExpressionDifferentiation Potential of Mesenchymal Stem Cells Is Related to Their Intrinsic Mechanical Properties.The Soft- and Hard-Heartedness of Cardiac Fibroblasts: Mechanotransduction Signaling Pathways in Fibrosis of the Heart.Nuclear envelope and lamin B2 function in the central nervous system.PDGF-BB and TGF-{beta}1 on cross-talk between endothelial and smooth muscle cells in vascular remodeling induced by low shear stress.Compliant 3D microenvironment improves β-cell cluster insulin expression through mechanosensing and β-catenin signaling.Advantages of evaluating mean nuclear volume as an adjunct parameter in prostate cancer.
P2860
Q23915828-F79D37D0-0CF3-46DD-ACC8-C32A234C4082Q26783319-07C9DC79-8985-4C34-BB4F-AC5D21470FA0Q27021875-7459AF83-1CCB-4323-B3F8-E6DD1E2B63D3Q27025551-6F1EC414-C8ED-40A4-9D93-D607FF670E31Q27322579-AA79A832-B6AD-4418-820C-FB88DAC23417Q27323169-46D17C06-3893-452A-A238-B8D4A7B576D5Q27324330-4D3683CD-9E45-4374-82BF-F687EE67FA52Q27327205-3A3FE385-F400-4376-855B-483DD1C3FE3AQ27330134-021DB6C7-F521-454B-87C4-2A86EBD792E9Q27340415-5483FFEA-9165-4620-9C1F-7BFC6ABA1656Q27342687-79C800BC-EF7C-46E9-8392-0A91604BE65AQ27348514-AE5BE037-C1AC-4099-95CF-132E443C482BQ27687804-59041B0E-C55D-407C-B38E-8A9FA3A7665EQ27692626-7083E869-4A34-48FE-BE35-A63D6FEF7CD7Q28072132-F2EC13AA-1939-4B60-A03D-F5917E13A471Q28079471-975F5A18-18E9-41BB-96EF-963713AB7DCAQ28284110-65A6D8F6-F9B0-424B-A493-C95E25E9BD68Q28468582-C866D650-F424-4D96-82D0-AB06871A3BEDQ28475497-D3832E66-444E-4FCA-9865-8E9332E82B35Q28730689-E575640C-06A2-4A7E-81EC-B43369C56CE6Q29620332-71096F48-AF5A-48CF-91BD-2B81559B2917Q30360906-E27616F7-1FF2-4E87-8D7C-46D89376967DQ30429409-FE76C1EA-CFB9-4F01-8296-250906EE0C16Q30436834-F288963D-3A64-4CE6-AF93-AAAE0544C307Q30491082-1B4A7CE6-DBFF-4AC4-AE92-C59487443F10Q30498072-9164EF3A-AF0F-4352-8132-E3E82A5BD38DQ30524014-17CF1729-A89A-441D-8BA4-0B82942CAFADQ30536524-859E260D-A3FB-4C04-9D6B-4E9AF55AE5F0Q30579631-F39B718F-AB8A-47F2-A421-40640905E417Q30586671-F48DBBAB-6D88-45B1-9E0E-17C1A76D550AQ30597332-A84FFC71-2858-4357-9079-7710E5B5AECFQ33472682-FACA28A6-53A5-40DB-A4E4-C189FC162328Q33548222-F416C691-DF23-4507-B656-6044CBA03EEBQ33581205-D7BF683D-7B31-4E69-92B4-9BC7615A7915Q33662550-9A6FDF9E-05B5-4649-A955-13A058CF690CQ33737254-7380C571-1EBB-4DA0-A778-95E2C973C1A2Q33778642-BF9B8447-A058-459F-A117-8716AD903997Q33796288-41692032-A9D8-43CA-BA7E-20A7940C76EBQ33860312-B732413F-5353-43A0-9431-FAF3CF6040F0Q33874522-2DB6F05B-073C-4DDC-926E-2F5FC9881779
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on June 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Nuclear shape, mechanics, and mechanotransduction.
@en
Nuclear shape, mechanics, and mechanotransduction.
@nl
type
label
Nuclear shape, mechanics, and mechanotransduction.
@en
Nuclear shape, mechanics, and mechanotransduction.
@nl
prefLabel
Nuclear shape, mechanics, and mechanotransduction.
@en
Nuclear shape, mechanics, and mechanotransduction.
@nl
P2093
P2860
P1433
P1476
Nuclear shape, mechanics, and mechanotransduction.
@en
P2093
Alexandre J S Ribeiro
Jan Lammerding
Kris Noel Dahl
P2860
P304
P356
10.1161/CIRCRESAHA.108.173989
P577
2008-06-01T00:00:00Z