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Surface molecular tailoring using pH-switchable supramolecular dendron-ligand assemblies.Simultaneous impedance spectroscopy and fluorescence microscopy for the real-time monitoring of the response of cells to drugs.A Nanodot Array Modulates Cell Adhesion and Induces an Apoptosis-Like Abnormality in NIH-3T3 Cells.Dynamic mass redistribution assays decode surface influence on signaling of endogenous purinergic P2Y receptors.Learning the chemical language of cell-surface interactions.Systematic Study of Functionalizable, Non-Biofouling Agarose Films with Protein and Cellular Patterns on Glass Slides.Cadherin and integrin regulation of epithelial cell migration.Mass spectrometry of self-assembled monolayers: a new tool for molecular surface science.Integrating novel technologies to fabricate smart scaffolds.Resonant waveguide grating biosensor-enabled label-free and fluorescence detection of cell adhesionExternal compression-induced fracture patterning on the surface of poly(dimethylsiloxane) cubes and microspheres.Quantitative photochemical immobilization of biomolecules on planar and corrugated substrates: a versatile strategy for creating functional biointerfaces.Dynamic control over cell adhesive properties using molecular-based surface engineering strategies.Towards proteomics-on-chip: the role of the surface.Advances in polymeric systems for tissue engineering and biomedical applications.Enhanced Schwann cell attachment and alignment using one-pot "dual click" GRGDS and YIGSR derivatized nanofibers.Cell transfer printing from patterned poly(ethylene glycol)-oleyl surfaces to biological hydrogels for rapid and efficient cell micropatterning.Integrin organization: linking adhesion ligand nanopatterns with altered cell responses.Cytophobic surface modification of microfluidic arrays for in situ parallel peptide synthesis and cell adhesion assays.Spatiotemporal control over molecular delivery and cellular encapsulation from electropolymerized micro- and nanopatterned surfaces.Fabrication of reconfigurable protein matrices by cracking.Controlling protein retention on enzyme-responsive surfaces.Proteolytically stabilizing fibronectin without compromising cell and gelatin binding activity.Using self-assembled monolayers to model cell adhesion to the 9th and 10th type III domains of fibronectin.Xeno-Free Strategies for Safe Human Mesenchymal Stem/Stromal Cell Expansion: Supplements and Coatings.Optical imaging of surface chemistry and dynamics in confinement.Delivery of minimally dispersed liquid interfaces for sequential surface chemistry.Regulating the osteogenic function of rhBMP 2 by different titanium surface properties.Targeted grafting of thermoresponsive polymers from a penetrative honeycomb structure for cell sheet engineering.Performing DNA nanotechnology operations on a zebrafishPolymer Patterns and Scaffolds for Biomedical Applications and Tissue EngineeringMolecular dynamics imaging in micropatterned living cells
P2860
Q30581742-D816388D-4945-4DBD-9467-FAA665E03FE0Q33579124-C554F62D-EAD2-452E-B20B-39A29C9510C3Q33949517-858C86BE-E75A-4A58-A053-2A9D6C0269DEQ35751575-CB609FF9-88F7-42D1-BC3F-CC4F3C880C69Q36256391-235218C4-9414-4264-83DB-53CC53338A3CQ36285340-0387E724-7E29-457A-849F-DBB7C0832DC2Q36565684-A5803FB9-7F26-4149-971E-BB21F40C868CQ37011131-C2E8B7A3-59BB-4A9D-9FC6-AE706BAE33F7Q37141344-8A25CEA6-6556-453C-A0A6-C9C1110A1ACBQ37366719-7900D0BE-817D-4DB7-AB7C-873D66A983E9Q37409454-E6FD8FEA-2A10-47C4-B590-52824672D201Q37651610-2CCF18C3-36E9-4C75-83A9-42E03FB1CD8AQ37660002-4B2B4C84-C12C-4E41-8623-526E6980A5F4Q37780466-4E7D49B6-7A1F-4CD5-871C-5535911C024CQ37978818-B6F607FF-303F-44E9-AAAD-F9AD33059ECCQ38931950-BD9229D3-6588-4466-88E3-E8E1E6EF54ECQ39496529-3E784A50-9228-4925-9B7C-CA583DE3BBD6Q39604603-63BAF784-69EA-4F20-9328-6A81CF670CACQ39803198-94727274-BEC3-4C21-8635-9A90A417463AQ40324336-E413B009-3C26-4E8B-B2BE-10CCC83B6C12Q40434236-E34619B5-25E4-45B7-8FF0-407946D6411CQ41827097-BD0BB9C1-E7F2-4DD9-9EE4-400494C624B8Q42833706-603E7F91-2B70-4D09-9C2D-C210584AEF5AQ42958111-5A10A70C-3D8D-47CE-88FF-5192DD96B793Q47151826-566C809B-013E-4F33-A6A9-52DC64781913Q47900688-D8EC8810-8C0F-486E-9542-106B40D7E399Q51275791-7AFDE5C0-02EA-466A-8F4C-47696658248FQ51435435-CDDDE911-97EF-45A6-9325-840298DB0260Q51604467-F06D3568-B117-4D3E-8E50-892FCBD3A8F1Q57139031-41468FFA-9603-4568-B078-8399F8D83D0FQ57171453-BE5CC6F8-BE4C-41BC-B510-C789D1C0217EQ57974806-A1E4B1D8-016C-4420-B6E6-8C289F813F8C
P2860
description
2002 nî lūn-bûn
@nan
2002 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2002 թվականի դեկտեմբերին հրատարակված գիտական հոդված
@hy
2002年の論文
@ja
2002年論文
@yue
2002年論文
@zh-hant
2002年論文
@zh-hk
2002年論文
@zh-mo
2002年論文
@zh-tw
2002年论文
@wuu
name
What can surface chemistry do for cell biology?
@ast
What can surface chemistry do for cell biology?
@en
type
label
What can surface chemistry do for cell biology?
@ast
What can surface chemistry do for cell biology?
@en
prefLabel
What can surface chemistry do for cell biology?
@ast
What can surface chemistry do for cell biology?
@en
P1476
What can surface chemistry do for cell biology?
@en
P304
P356
10.1016/S1367-5931(02)00362-9
P577
2002-12-01T00:00:00Z