Fabrication of hydrogels with steep stiffness gradients for studying cell mechanical response.
about
Local 3D matrix microenvironment regulates cell migration through spatiotemporal dynamics of contractility-dependent adhesions.The extracellular microscape governs mesenchymal stem cell fate.Tissue elasticity regulated tumor gene expression: implication for diagnostic biomarkers of primitive neuroectodermal tumorMesenchymal stem cell durotaxis depends on substrate stiffness gradient strength.Stem cell migration and mechanotransduction on linear stiffness gradient hydrogelsAlbumin hydrogels formed by electrostatically triggered self-assembly and their drug delivery capability.Complex dynamic substrate control: dual-tone hydrogel photoresists allow double-dissociation of topography and modulusFibroblasts probe substrate rigidity with filopodia extensions before occupying an area.Precise positioning of cancerous cells on PDMS substrates with gradients of elasticity.Vascular smooth muscle cell durotaxis depends on extracellular matrix composition.Multiwell stiffness assay for the study of cell responsiveness to cytotoxic drugs.Advances in techniques for probing mechanoregulation of tissue morphogenesis.Microplatforms for gradient field generation of various properties and biological applications.Scaffolds for hand tissue engineering: the importance of surface topography.Comparison of viscoelastic properties of cancer and normal thyroid cells on different stiffness substrates.Dissecting the stem cell niche with organoid models: an engineering-based approach.Physical and Chemical Gradients in the Tumor Microenvironment Regulate Tumor Cell Invasion, Migration, and Metastasis.Nanoindentation and finite element modelling of chitosan-alginate multilayer coated hydrogels.Simple polyacrylamide-based multiwell stiffness assay for the study of stiffness-dependent cell responses.Hybrid Tissue Engineering Scaffolds by Combination of Three-Dimensional Printing and Cell Photoencapsulation.Biophysical Regulation of Cell Behavior-Cross Talk between Substrate Stiffness and Nanotopography.Lateral migration of electrospun hydrogel nanofilaments in an oscillatory flow.Toward Customized Extracellular Niche Engineering: Progress in Cell-Entrapment Technologies.Hydrogel-colloid interfacial interactions: a study of tailored adhesion using optical tweezers.Regulation of Endothelial Cell Adherence and Elastic Modulus by Substrate Stiffness.Mechanical Deformation of Cultured Cells with Hydrogels.Influence of microenvironment topography and stiffness on the mechanics and motility of normal and cancer renal cells.Bioengineered Systems and Designer Matrices That Recapitulate the Intestinal Stem Cell Niche.Modulation of surface stiffness and cell patterning on polymer films using micropatterns.Bioconjugating Thiols to Poly(acrylamide) Gels for Cell Culture Using Methylsulfonyl Co-monomers.Multi-compartment scaffold fabricated via 3D-printing as in vitro co-culture osteogenic model
P2860
Q27319852-1A102D72-F107-43C6-8610-4C740186620FQ28073455-91C8A95E-ABD9-46CE-AAB7-87F50D472AEBQ28544403-CDD183A0-5C82-4885-8DDB-6C27AF487D26Q30543312-67A6691D-C0A1-4457-A18C-506FBB54D1ECQ33782557-0897CBBB-02B2-42FE-A9D7-FB818AA9F46DQ34331275-8E3D6D75-75DA-4F04-B865-A39C1EA0FA9DQ34344426-02887055-1D73-4CD1-AE4C-E4791E903C39Q34661460-AEA10FAF-D6B1-4C25-BEBB-751552212186Q37250451-82F40117-C374-4260-A2CC-BC0C2AAE5C08Q37322985-D614A5FC-F338-4960-98FA-8A38929FBAF3Q37600858-263540E8-DB3D-4F68-8999-B2171CC73B38Q38261549-7A9A25F7-8C37-4F1C-8E47-3B6ED17F6316Q38289128-A6BF1AD5-556B-4269-82A6-7FFFF326D9D0Q38377690-0037E28F-491F-4D93-B78F-BA085FCA6840Q38745026-37E06C74-9C1D-4389-AF1A-D3295B1F6DF6Q39178364-80C34C6E-868D-4C49-A3DF-5CF3B43356E5Q39251086-F633BA20-0FBE-479E-967F-DB7519C5C39AQ39512901-033EA0ED-FC80-4E4B-B520-F121B81E8EC5Q39743560-AB484807-479F-4D0E-9D61-9BAE6266477EQ41846018-8730324E-9979-4830-A446-3729BD1D16C5Q45071015-A8863DC5-DA00-4A00-AC7F-7542171C6030Q47098386-72AC250D-D7C4-4960-8FCB-9B0937940934Q47294565-5B9EFCDF-19E6-48D8-9FC9-7C9B7E1A0969Q51245528-D2D97A91-D9E5-4EB2-8DC4-4F8B81D6304DQ51269766-AAE74C87-417E-4A17-AE8A-CE9FA600C88AQ51801231-CEDE5DD2-6BDC-4E78-9E7F-3B93C49E8571Q51818212-CD483768-9043-4750-8DC7-ACB29B469086Q52314668-E8089421-A1A8-44E3-88F1-7EC4E9F7F07AQ53312109-4C95F09C-19F3-4F77-97E6-D718C969345EQ54709243-9E6601ED-2AFD-44D8-9D69-959C0E627CAFQ57477046-1D45DF9A-DDDE-4663-AD2B-C56FD6776AA3
P2860
Fabrication of hydrogels with steep stiffness gradients for studying cell mechanical response.
description
2012 nî lūn-bûn
@nan
2012 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2012 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
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
name
Fabrication of hydrogels with ...... ying cell mechanical response.
@ast
Fabrication of hydrogels with ...... ying cell mechanical response.
@en
Fabrication of hydrogels with ...... ying cell mechanical response.
@nl
type
label
Fabrication of hydrogels with ...... ying cell mechanical response.
@ast
Fabrication of hydrogels with ...... ying cell mechanical response.
@en
Fabrication of hydrogels with ...... ying cell mechanical response.
@nl
prefLabel
Fabrication of hydrogels with ...... ying cell mechanical response.
@ast
Fabrication of hydrogels with ...... ying cell mechanical response.
@en
Fabrication of hydrogels with ...... ying cell mechanical response.
@nl
P2860
P1433
P1476
Fabrication of hydrogels with ...... ying cell mechanical response.
@en
P2093
Dan L Sackett
Ralph Nossal
P2860
P304
P356
10.1371/JOURNAL.PONE.0046107
P407
P577
2012-10-04T00:00:00Z