Improved endothelial cell adhesion and proliferation on patterned titanium surfaces with rationally designed, micrometer to nanometer features.
about
A novel in vitro model for microvasculature reveals regulation of circumferential ECM organization by curvatureNano- and microstructured materials for in vitro studies of the physiology of vascular cellsNanostructured substrates for isolation of circulating tumor cells.Surface wettability of plasma SiOx:H nanocoating-induced endothelial cells' migration and the associated FAK-Rho GTPases signalling pathways.Nanowell-trapped charged ligand-bearing nanoparticle surfaces: a novel method of enhancing flow-resistant cell adhesion.Micro- and nanoengineering approaches to control stem cell-biomaterial interactions.Engineering substrate topography at the micro- and nanoscale to control cell function.Engineering cellular response using nanopatterned bulk metallic glassNanotopography-guided tissue engineering and regenerative medicine.Emerging applications of nanotechnology for the diagnosis and management of vulnerable atherosclerotic plaques.Modulation of human vascular endothelial cell behaviors by nanotopographic cues.Nanotopographical modification: a regulator of cellular function through focal adhesions.Effects of microtopographic patterns on platelet adhesion and activation on titanium oxide surfaces.Endothelial retention and phenotype on carbonized cardiovascular implant surfaces.Harmonizing HeLa cell cytoskeleton behavior by multi-Ti oxide phased nanostructure synthesized through ultrashort pulsed laser.Combined technologies for microfabricating elastomeric cardiac tissue engineering scaffoldsThe evaluation of prepared microgroove pattern by femtosecond laser on alumina-zirconia nano-composite for endosseous dental implant application.Microfabrication and nanotechnology in stent designSilver nanoparticle-enriched diamond-like carbon implant modification as a mammalian cell compatible surface with antimicrobial propertiesInfluence of membrane cholesterol and substrate elasticity on endothelial cell spreading behavior.Microfabrication of nanoporous gold patterns for cell-material interaction studiesInvestigating surface topology and cyclic-RGD peptide functionalization on vascular endothelializationTailoring biomaterial surface properties to modulate host-implant interactions: implication in cardiovascular and bone therapy.Microfabricated implants for applications in therapeutic delivery, tissue engineering, and biosensing.Surface projections of titanium substrates increase antithrombotic endothelial function in response to shear stress.Nanotechnologies in regenerative medicine.Nanotechnology and its relationship to interventional radiology. Part II: Drug Delivery, Thermotherapy, and Vascular Intervention.In situ endothelialization of intravascular stents from progenitor stem cells coated with nanocomposite and functionalized biomolecules.Micro-/nano-engineered cellular responses for soft tissue engineering and biomedical applications.Physical aspects of cell culture substrates: topography, roughness, and elasticity.Nano-regenerative medicine towards clinical outcome of stem cell and tissue engineering in humans.Functionalized nanostructures with application in regenerative medicine.Surface chemical and physical modification in stent technology for the treatment of coronary artery disease.Surface modification of implanted cardiovascular metal stents: from antithrombosis and antirestenosis to endothelialization.25th anniversary article: scalable multiscale patterned structures inspired by nature: the role of hierarchy.Integrating mechanical and biological control of cell proliferation through bioinspired multieffector materials.Reduced adhesion of macrophages on anodized titanium with select nanotube surface features.Direct Laser Interference Patterning of CoCr Alloy Surfaces to Control Endothelial Cell and Platelet Response for Cardiovascular Applications.Biocompatibility study of three distinct carbon pastes for application as electrode material in neural stimulations and recordings.The development of polymeric biomaterials inspired by the extracellular matrix.
P2860
Q27301419-C127D50A-326E-4379-90C8-2E43F16BA7CBQ28817186-F225F13C-2A97-4F8C-814A-C97C2E76DFA0Q30436669-DE3EE07C-9458-480D-A6DD-AED108AD636FQ30458402-6141247C-9906-4FCD-8FB7-34F7409A46EBQ30582202-26D1DE91-B442-494E-AF98-BAC31C52E46BQ33649732-15CF957F-FA57-4170-904C-8ED0C668FBBCQ33711373-8C6BF26F-B7C1-401C-8BF5-302C89EBB9A5Q33716042-F2E6D568-9BA3-41ED-AF79-E446CBD02E0EQ33728767-7AA8A521-735C-4849-A22D-657B1D5173A7Q33839384-C81F0A97-7560-4C05-B0B9-732FA5A3ECBEQ34007293-5C60E54C-AB64-4318-BC03-C5E3B9851124Q34248067-6975F101-769B-4171-922D-0E16D5484DF0Q34394985-645F332D-59AB-48AC-9893-4344C5E23598Q35642221-84E10BD6-4636-4F61-9EE0-ADD1F1AD8AB1Q35808807-A46ECEBA-4419-4613-9707-DDF74F846CD9Q35860837-101A09EA-2CCA-4F31-BD46-55BC7F9A4A61Q36146262-8FFBB025-7A08-4E75-BF02-646546597635Q36344315-C5A84F51-82B4-48C7-AC1D-4AE420652F89Q36666774-2D373E1D-FAE2-4AEA-AFC6-D7A9C49180F6Q36729395-455DC0BC-8193-465B-81B0-89B4090B9029Q37075220-EF08D6FA-F7C9-459A-BE3A-0423C61B5B78Q37157758-8243C0D1-8D72-4FA8-A35F-57A9F9B05FB9Q37249147-8D18E4BC-4346-407E-BB81-FC1E5F9683E7Q37305450-87CD5C6D-011B-450D-A241-D23D260CC45BQ37498950-9FC60AFC-7E56-4106-AEAD-464314F306F4Q37760213-40706899-3CE6-4548-929F-01258B58C186Q37789181-BA0E2291-79D0-40CC-BFDD-4A5C4EE4FDE5Q37859059-70B84BF7-F193-4112-9D95-F1F9E65A71F5Q37871566-65D3B855-FCD5-4A37-8AAA-0C5BEAB090EAQ37967641-64AEFD52-27A1-419C-92D1-19C5FE79C782Q37977128-9A6F0244-1113-4B14-AF02-85CDD1C6F208Q38001430-10605E78-985A-4162-B73F-5CC4665E727AQ38040738-BFF54E16-0CCE-4B74-868A-D45D26E3C784Q38092061-4E73071E-889A-43EB-89CA-99CEED01E247Q38172460-F04D0F1C-E066-437E-BB36-505678F56875Q38393746-1814B8AE-4BAE-4BE3-A4C2-2D9267F7606FQ38608033-1EB5FF17-D740-43CB-AF2E-4F833233884BQ38656604-41D6A5EB-8C29-4447-A62C-5D0F65D036FAQ38720199-61BC5934-D1F2-42BB-9717-8BF6C723AD94Q38748329-F8FC5B62-60C5-4F45-9C2E-83A56CC7B106
P2860
Improved endothelial cell adhesion and proliferation on patterned titanium surfaces with rationally designed, micrometer to nanometer features.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年学术文章
@wuu
2007年学术文章
@zh
2007年学术文章
@zh-cn
2007年学术文章
@zh-hans
2007年学术文章
@zh-my
2007年学术文章
@zh-sg
2007年學術文章
@yue
2007年學術文章
@zh-hant
name
Improved endothelial cell adhe ...... rometer to nanometer features.
@en
Improved endothelial cell adhe ...... rometer to nanometer features.
@nl
type
label
Improved endothelial cell adhe ...... rometer to nanometer features.
@en
Improved endothelial cell adhe ...... rometer to nanometer features.
@nl
prefLabel
Improved endothelial cell adhe ...... rometer to nanometer features.
@en
Improved endothelial cell adhe ...... rometer to nanometer features.
@nl
P2093
P1433
P1476
Improved endothelial cell adhe ...... rometer to nanometer features.
@en
P2093
Dongwoo Khang
Noel C MacDonald
Thomas J Webster
P304
P356
10.1016/J.ACTBIO.2007.07.008
P50
P577
2007-08-02T00:00:00Z