about
High Content Imaging (HCI) on Miniaturized Three-Dimensional (3D) Cell CulturesA microfluidic chamber for analysis of neuron-to-cell spread and axonal transport of an alpha-herpesvirusProtein and cell patterning in closed polymer channels by photoimmobilizing proteins on photografted poly(ethylene glycol) diacrylate.Biology-inspired microphysiological system approaches to solve the prediction dilemma of substance testingFull-range magnetic manipulation of droplets via surface energy traps enables complex bioassays.Exploitation of physical and chemical constraints for three-dimensional microtissue construction in microfluidics.Stem cells in microfluidics.An easy to assemble microfluidic perfusion device with a magnetic clamp.Single-molecule imaging of NGF axonal transport in microfluidic devices.A microfluidic positioning chamber for long-term live-cell imaging.Quantitative analysis of axonal transport by using compartmentalized and surface micropatterned culture of neurons.A Novel Microfluidic Cell Co-culture Platform for the Study of the Molecular Mechanisms of Parkinson's Disease and Other SynucleinopathiesCalpain-mediated cleavage of collapsin response mediator protein-2 drives acute axonal degenerationA microfluidic system enabling Raman measurements of the oxygenation cycle in single optically trapped red blood cells.A simple method of fabricating mask-free microfluidic devices for biological analysis.Cell Microarray Technologies for High-Throughput Cell-Based Biosensors.Monitoring the differentiation and migration patterns of neural cells derived from human embryonic stem cells using a microfluidic culture system.The pedestrian watchmaker: genetic clocks from engineered oscillators.Heat-shock protein 70 modulates toxic extracellular α-synuclein oligomers and rescues trans-synaptic toxicity.Co-culture of neurons and glia in a novel microfluidic platformA microfluidic culture platform for CNS axonal injury, regeneration and transport.Networked neural spheroid by neuro-bundle mimicking nervous system created by topology effect.Endothelial cell micropatterning: methods, effects, and applications.Organotypic liver culture models: meeting current challenges in toxicity testing.Microfabricated biomaterials for engineering 3D tissues.Narrow microtunnel technology for the isolation and precise identification of axonal communication among distinct hippocampal subregion networks.Microfabricated Systems and Assays for Studying the Cytoskeletal Organization, Micromechanics, and Motility Patterns of Cancerous Cells.Using living radical polymerization to enable facile incorporation of materials in microfluidic cell culture devices.Microtechnology: meet neurobiology.Spatial control over cell attachment by partial solvent entrapment of poly lysine in microfluidic channels.Axonal mRNA in uninjured and regenerating cortical mammalian axons.Laminar stream of detergents for subcellular neurite damage in a microfluidic device: a simple tool for the study of neuroregeneration.High content cell screening in a microfluidic device.Multiscale Cues Drive Collective Cell Migration.A microfluidic electrochemical device for high sensitivity biosensing: detection of nanomolar hydrogen peroxide.Microfluidics: a new cosset for neurobiology.Novel high-resolution micropatterning for neuron culture using polylysine adsorption on a cell repellant, plasma-polymerized background.Using a microfluidic device for high-content analysis of cell signalingBiological implications of polydimethylsiloxane-based microfluidic cell culture.Macro- and microscale fluid flow systems for endothelial cell biology.
P2860
Q26773298-40A6F4F3-E7CF-4E7D-A259-315A65A11861Q27301101-7B4640DC-B4EC-42BE-9F98-F595D3639FEBQ27332321-5D9C3446-1599-41E7-8861-BDDDF9C1A9AAQ30358385-04C3C17C-CBDA-47AE-B072-DAABDCE51E4BQ30430154-4B2D11F7-DD65-41E3-88DB-7446A0458F27Q30474710-60B7724A-56F2-46A4-8F58-F411BC5B4B94Q30475745-B3AF7084-25C2-4467-9462-7561AD9F20B9Q30490137-AB4D90C1-14EF-4115-AE90-0E7EF0745B1BQ30496483-5EA23774-8EBF-4C7A-9C00-0C1172AFE793Q30497909-83807255-DD15-446E-92C5-6E601EF10BA5Q30539499-766B39C3-4B7C-4FD5-8B53-FE59E617627EQ30828564-84F398B5-9872-46E7-80E8-3901E48C2FF1Q30828633-2B93688A-135E-4C40-B67A-FCA6831FB084Q31156208-7D35E426-B703-40A4-BC7A-05E2322D77F0Q33708926-46EB624C-BA45-4975-8D2F-C3F74BE9275AQ33858214-0961AFCE-63AD-4AB2-90A1-62569FFE0D94Q33861723-28456ACB-A406-48E6-A6F9-04E913C9AF83Q34066433-BFD235F3-4061-4F8B-BF4E-24F2C097D3AFQ34421765-90B65ECE-85DE-470A-86DE-7E6A8BA22352Q34591622-CD81EB7F-ED47-42AB-BDB7-F9BF19C07D1CQ35014942-8EA702B0-06E8-4758-9A3D-8C042F0BEF70Q35233752-73E22F58-8465-4A25-89DA-5B9F342ABE94Q35986487-B07DC4E4-1046-4018-86D8-90C6282FA3F6Q36178225-4DFF0549-BC26-4147-9B8E-25A70E17F83CQ36204086-36C6181C-7004-4BA0-8964-EA241A3F0D26Q36368936-7F595AFD-B521-41F6-AEE0-91790639F922Q36590531-EB029D06-4D86-4CFF-8545-EA0BF461DC0FQ36593350-BA0E594A-3A55-46CB-A407-CCF0D317098FQ36688464-7C1C0A3D-FC7F-4873-83D1-823C53C5042DQ36717984-8E143FBB-9A53-433F-AA58-744823BA4EEFQ36784476-A7FAF72D-BF5D-4397-898C-DED130E32279Q36943491-850ABE2D-BE0F-4EBC-9AE7-A3D5F5A46A29Q37113856-B561E8A7-1FA8-4C50-9D03-4C50ED472E4AQ37128619-6569441D-9F73-427B-84BD-B7494192CCACQ37327980-0666AE2B-F0A5-4932-81FA-6528F651B80BQ37395333-4EAFB6B2-AA2D-4FA3-8E09-6479BB1A8627Q37399007-EDF5ECF7-DFD0-4EA7-B930-0492C07971D2Q37521456-913CB20B-0D41-41CA-ABA7-2E84825A35A6Q37552775-C246AD4D-67B5-4CBF-945E-C633251B7DD7Q37672352-CEA08B94-05C3-42A0-AD2B-CF742F9FB347
P2860
description
2004 nî lūn-bûn
@nan
2004年の論文
@ja
2004年学术文章
@wuu
2004年学术文章
@zh-cn
2004年学术文章
@zh-hans
2004年学术文章
@zh-my
2004年学术文章
@zh-sg
2004年學術文章
@yue
2004年學術文章
@zh
2004年學術文章
@zh-hant
name
Patterned cell culture inside microfluidic devices.
@en
type
label
Patterned cell culture inside microfluidic devices.
@en
prefLabel
Patterned cell culture inside microfluidic devices.
@en
P2093
P356
P1433
P1476
Patterned cell culture inside microfluidic devices.
@en
P2093
Anne M Taylor
Carl W Cotman
Christina H Tu
David H Cribbs
Noo Li Jeon
Seog Woo Rhee
P304
P356
10.1039/B403091E
P577
2004-07-26T00:00:00Z