The influence of microchannels on neurite growth and architecture
about
A biomaterials approach to peripheral nerve regeneration: bridging the peripheral nerve gap and enhancing functional recoverySurface microstructures on planar substrates and textile fibers guide neurite outgrowth: a scaffold solution to push limits of critical nerve defect regeneration?Integration of topographical and biochemical cues by axons during growth on microfabricated 3-D substrates.Single-neuron axonal pathfinding under geometric guidance: low-dose-methylmercury developmental neurotoxicity test.Substrates coated with silver nanoparticles as a neuronal regenerative material.Biochip∕laser cell deposition system to assess polarized axonal growth from single neurons and neuron∕glia pairs in microchannels with novel asymmetrical geometriesQuantifying cellular alignment on anisotropic biomaterial platforms.Cell microenvironment engineering and monitoring for tissue engineering and regenerative medicine: the recent advances.Cellular scale anisotropic topography guides Schwann cell motility.Biomaterial design strategies for the treatment of spinal cord injuries.Topography, cell response, and nerve regenerationPolarization-controlled differentiation of human neural stem cells using synergistic cues from the patterns of carbon nanotube monolayer coating.Microtopographical features generated by photopolymerization recruit RhoA/ROCK through TRPV1 to direct cell and neurite growthFacile micropatterning of dual hydrogel systems for 3D models of neurite outgrowth.Patterned PLG substrates for localized DNA delivery and directed neurite extension.Modeling neural differentiation on micropatterned substrates coated with neural matrix components.Multiscale Analysis of Neurite Orientation and Spatial Organization in Neuronal ImagesBridging the lesion-engineering a permissive substrate for nerve regenerationA statistical algorithm for assessing cellular alignmentMicrotechnology: meet neurobiology.Engineering microscale topographies to control the cell-substrate interface.A neuron-in-capillary platform for facile collection and mass spectrometric characterization of a secreted neuropeptideEffective Spatial Separation of PC12 and NIH3T3 Cells by the Microgrooved Surface of Biocompatible Polymer Substrates.Conductive Core-Sheath Nanofibers and Their Potential Application in Neural Tissue Engineering.Microfluidics: a new cosset for neurobiology.Neurite outgrowth on nanofiber scaffolds with different orders, structures, and surface properties.Multiple channel bridges for spinal cord injury: cellular characterization of host response.The behavior of neuronal cells on tendon-derived collagen sheets as potential substrates for nerve regeneration.An injectable, calcium responsive composite hydrogel for the treatment of acute spinal cord injury.Orchestrating cell/material interactions for tissue engineering of surgical implants.Scaffolds and cells for tissue regeneration: different scaffold pore sizes-different cell effects.Quantification of Cardiomyocyte Alignment from Three-Dimensional (3D) Confocal Microscopy of Engineered Tissue.Self-assembling peptide nanostructures on aligned poly(lactide-co-glycolide) nanofibers for the functional regeneration of sciatic nerve.Nanostructured cavity devices for extracellular stimulation of HL-1 cells.Investigation of the competition between cell/surface and cell/cell interactions during neuronal cell culture on a micro-engineered surface.Interactions of Neurons with Physical Environments.Microchannel-patterned and heparin micro-contact-printed biodegradable composite membranes for tissue-engineering applications.Neurite outgrowth at the biomimetic interface.Characterization of dorsal root ganglion neurons cultured on silicon micro-pillar substrates.Material properties and electrical stimulation regimens of polycaprolactone fumarate-polypyrrole scaffolds as potential conductive nerve conduits.
P2860
Q24625076-35FBD79F-E401-40D6-9B6B-A47B98D3AFB0Q27333520-72A3FBA4-3D0C-4CB4-8817-0F918967A546Q30561860-E1F1848E-D4CA-4B92-B9CA-14DF7EA0763CQ30586576-36A91C4E-F90A-4AA3-A3C5-E16B7A468AC5Q33627656-A1056C0E-EEA4-4D34-A053-B27775E0019AQ33882554-12F0613A-3FCF-4564-BCFD-7932472EE12BQ33944567-3B9EF191-9FB6-41F1-B1F4-0AC7DC3739F7Q34014077-3F476596-FB7B-491C-A8E0-A50591EF6591Q34031310-0DA8BC1E-D374-4F38-B4A1-6FDE0B39AB1FQ34076638-FB229144-808F-4DC5-834A-8BCFC6FEB2F8Q34470324-8B5C9C54-4C4C-4739-9599-91D1957E0441Q35074874-8223E31F-BC55-4F14-ACA3-2BE5377A851CQ35516837-BB893743-DDBC-4E72-B2C5-71BA0861EE10Q35540962-8B36F25E-B085-4AB7-88AA-FC6A95227808Q35809461-3D2642CF-AE09-47F3-A003-A9701DD42805Q35828258-CA650512-B9DA-4F25-B729-4E0A91F358E9Q36066347-2DC1F3E3-242C-440A-9740-6456A8FC0BB7Q36345120-74461E69-75E6-472E-8F20-10C0FE17BECDQ36598747-5A80E8DD-2A56-41C1-97EA-A7DEA7E38CF9Q36688464-5145E13D-5F7F-406F-94FE-254F56E5BE48Q36747865-02DBD86E-720E-4368-B32F-18BDE60D0DC3Q36953675-26963806-3C1D-4964-8B89-CF681E635B67Q37045986-EC21B1D3-17FB-497A-9BEA-7F1B477846CDQ37384866-8C2FD13A-31A0-4D74-BA7C-B08FF69A9AB2Q37395333-5346CA81-F79A-4F4F-8A16-807554DA2186Q37395803-97F470CA-6F37-48D1-9876-97D6E9E0F183Q37471457-166405F4-A886-4D88-BA0E-98A142B17DD7Q37631240-232FBA07-F02E-4215-9CAA-36416BC02DA7Q37696838-EBB34CCF-53F1-4813-BBBE-7F3B6EDEC5A9Q38025039-A37A8427-28B6-4504-9C92-0BB735FB39E8Q38532297-7C2773E6-CD5F-41A6-BE75-627D532D3647Q38720689-C2CCD06F-9596-4A21-86A8-AED2220D443AQ38721002-C5B7E8DF-4FC7-4452-8A54-93C455871C10Q39011027-3AD86F11-04D4-4581-8669-A3B49C093625Q39095637-E68AC5E1-BDA0-4C01-996F-37257769CA2AQ39391085-ACAC27BE-49A4-40C6-91EA-BD79592C752BQ39538143-E2D7AB68-700B-4610-95FA-E257E0D0E22BQ39707875-B1F0B49F-751C-4636-AEA1-2CCC23E5BDC3Q39738445-9E4EE7BA-DB4B-4EEB-A593-9D453A373356Q39825320-42AA06C7-16FD-42C6-8C8C-572E28470AEF
P2860
The influence of microchannels on neurite growth and architecture
description
2005 nî lūn-bûn
@nan
2005 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
2005 թվականի մարտին հրատարակված գիտական հոդված
@hy
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
name
The influence of microchannels on neurite growth and architecture
@ast
The influence of microchannels on neurite growth and architecture
@en
The influence of microchannels on neurite growth and architecture
@nl
type
label
The influence of microchannels on neurite growth and architecture
@ast
The influence of microchannels on neurite growth and architecture
@en
The influence of microchannels on neurite growth and architecture
@nl
prefLabel
The influence of microchannels on neurite growth and architecture
@ast
The influence of microchannels on neurite growth and architecture
@en
The influence of microchannels on neurite growth and architecture
@nl
P2093
P3181
P1433
P1476
The influence of microchannels on neurite growth and architecture
@en
P2093
Melissa J Mahoney
Ruth R Chen
W Mark Saltzman
P3181
P356
10.1016/J.BIOMATERIALS.2004.03.015
P407
P577
2005-03-01T00:00:00Z