The control of cell adhesion and viability by zinc oxide nanorods.
about
Growth of a Novel Nanostructured ZnO Urchin: Control of Cytotoxicity and Dissolution of the ZnO UrchinZinc oxide nanoparticles exhibit cytotoxicity and genotoxicity through oxidative stress responses in human lung fibroblasts and Drosophila melanogasterBiophysical mechanisms of single-cell interactions with microtopographical cues.In vitro epithelial organoid generation induced by substrate nanotopography.Engineering cellular response using nanopatterned bulk metallic glassDevelopment of magnesium calcium phosphate biocement for bone regenerationBi-phasic nanostructures for functional applications.Nanotopographical modification: a regulator of cellular function through focal adhesions.A novel injectable calcium phosphate cement-bioactive glass composite for bone regeneration.Cancer-targeted optical imaging with fluorescent zinc oxide nanowires.Nanotopography facilitates in vivo transdermal delivery of high molecular weight therapeutics through an integrin-dependent mechanismHarmonizing HeLa cell cytoskeleton behavior by multi-Ti oxide phased nanostructure synthesized through ultrashort pulsed laser.Zn or O? An Atomic Level Comparison on Antibacterial Activities of Zinc Oxides.Titanate nanowire scaffolds decorated with anatase nanocrystals show good protein adsorption and low cell adhesion capacity.Endothelialization of TiO2 Nanorods Coated with Ultrathin Amorphous Carbon Films.Fundamental Properties of One-Dimensional Zinc Oxide Nanomaterials and Implementations in Various Detection Modes of Enhanced Biosensing.Polyelectrolyte-coated gold nanorods and their interactions with type I collagen.Nanosized zinc oxide particles do not promote DHPN-induced lung carcinogenesis but cause reversible epithelial hyperplasia of terminal bronchioles.Synthesis, antibacterial activity, antibacterial mechanism and food applications of ZnO nanoparticles: a review.Electromechanical Nanogenerator-Cell Interaction Modulates Cell Activity.Understanding improved osteoblast behavior on select nanoporous anodic alumina.Graphene oxide assisted synthesis of GaN nanostructures for reducing cell adhesion.Modulating malignant epithelial tumor cell adhesion, migration and mechanics with nanorod surfaces.ZnO Nanostructure Templates as a Cost-Efficient Mass-Producible Route for the Development of Cellular Networks.The topographic effect of zinc oxide nanoflowers on osteoblast growth and osseointegration.Chitosan-collagen scaffolds with nano/microfibrous architecture for skin tissue engineering.Zinc oxide-doped poly(urethane) spider web nanofibrous scaffold via one-step electrospinning: a novel matrix for tissue engineering.ZnO Nanostructures for Tissue Engineering Applications.Tuning the response of osteoblast-like cells to the porous-alumina-assisted mixed-oxide nano-mound arrays.Antibacterial properties and human gingival fibroblast cell compatibility of TiO2/Ag compound coatings and ZnO films on titanium-based material.In vitro biocompatibility of chitosan/hyaluronic acid-containing calcium phosphate bone cements.The bifunctional regulation of interconnected Zn-incorporated ZrO2 nanoarrays in antibiosis and osteogenesis.
P2860
Q28393947-130AADE4-06B7-42F1-865A-33BCD81D8E1FQ29248295-DA2F94F9-674A-44AF-A7F2-1EE96FC62571Q30493571-830790B0-2C92-4D74-8B35-F0AD8551ABB8Q30629498-8A1F593D-F24D-4AB6-B2C1-9E8DE3E9F2D9Q33716042-E4F23082-6B67-4E44-B0D8-2369784890FBQ33952174-3CD948C8-B09C-4ED6-B8EC-5D7294B7B43BQ34217155-A7FDA434-1D37-41AD-8F14-5C909DB486C2Q34248067-5E9A01E6-56BC-46D3-A350-CF0CB07F8B23Q34701777-49DEB568-A99D-4B1D-BF6F-B658011B1D67Q35214391-D9D94696-9678-4B82-829B-26229A885420Q35772163-70725C7A-9503-439A-818C-34AC16ADED1CQ35808807-E7FF929A-7095-4316-8782-FD34256BBDC5Q36001890-D310506D-B701-4082-9C55-D3B771F87A58Q36613818-547F9CC1-8689-45BE-90D2-C21110E2B5FEQ36689944-2091122E-9E96-4E1B-A1FB-F4F4C78410C4Q36972404-11A9866D-6100-44A2-8744-A73C4347B866Q37369554-2F88AABE-12CE-4A7C-8EC8-B7C5B3FC4E3EQ37470705-AB6F20DC-1E76-4E3E-A94D-DD80C141EF37Q38161922-DE338B36-0E01-4995-B173-35EC6140BCE5Q38691622-0E56B46A-F3E6-432E-AAED-5929A8C886CCQ38973389-9FA85C31-5067-4499-81E5-F03122BAECD4Q39091765-62F53C03-9113-4FB6-8ADA-37E45FAA55A8Q39657318-E078D388-8ACC-4C96-A4F9-2A1A638FDC5DQ40967315-702F6AF3-BDA6-4D54-B860-8213F38AB4A9Q42820690-D3BEBB64-4127-4BE1-8C38-805B5A6D2F39Q42820844-239AC4C4-02FA-4083-A42E-477FEF0691EAQ42831392-433F4E36-39F7-498E-9F08-2B1C95861C2AQ47159529-43893CF6-B010-4A9F-B972-A4393E242007Q47758285-3B3153B7-19A4-436F-B6AD-8B38CB047F5BQ50284105-1ED0A217-9114-410D-AC55-73B4789EA4A8Q53642853-34287062-E7B6-4478-94E8-7D9520754988Q54263459-804070C5-DE17-4DE9-9768-D9E5371316F5
P2860
The control of cell adhesion and viability by zinc oxide nanorods.
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
2008年论文
@zh
2008年论文
@zh-cn
name
The control of cell adhesion and viability by zinc oxide nanorods.
@en
The control of cell adhesion and viability by zinc oxide nanorods.
@nl
type
label
The control of cell adhesion and viability by zinc oxide nanorods.
@en
The control of cell adhesion and viability by zinc oxide nanorods.
@nl
prefLabel
The control of cell adhesion and viability by zinc oxide nanorods.
@en
The control of cell adhesion and viability by zinc oxide nanorods.
@nl
P2093
P1433
P1476
The control of cell adhesion and viability by zinc oxide nanorods.
@en
P2093
Barrett Hicks
Benjamin G Keselowsky
Byung Hwan Chu
Hung-Ta Wang
Jiyeon Lee
Tanmay P Lele
Thomas F Chancellor
P304
P356
10.1016/J.BIOMATERIALS.2008.05.029
P577
2008-06-11T00:00:00Z