Hearing what you cannot see and visualizing what you hear: interpreting quartz crystal microbalance data from solvated interfaces.
about
Acoustic biosensorsUsing complementary acoustic and optical techniques for quantitative monitoring of biomolecular adsorption at interfaces.Reconstitution and Functional Analysis of a Full-Length Hepatitis C Virus NS5B Polymerase on a Supported Lipid Bilayer.Probing the Interaction between Nanoparticles and Lipid Membranes by Quartz Crystal Microbalance with Dissipation Monitoring.Cell and Protein Fouling Properties of Polymeric Mixtures Containing Supramolecular Poly(ethylene glycol) AdditivesA single molecule assay to probe monovalent and multivalent bonds between hyaluronan and its key leukocyte receptor CD44 under force.Processing and Characterization of Nanoparticle Coatings for Quartz Crystal Microbalance MeasurementsControlled Immobilization Strategies to Probe Short Hyaluronan-Protein Interactions.Colloidal Stability and Magnetic Field-Induced Ordering of Magnetorheological Fluids Studied with a Quartz Crystal MicrobalanceLipopolysaccharide Density and Structure Govern the Extent and Distance of Nanoparticle Interaction with Actual and Model Bacterial Outer Membranes.Attachment of pathogenic prion protein to model oxide surfaces.Elongation kinetics of polyglutamine peptide fibrils: a quartz crystal microbalance with dissipation study.Adhesion maturation of neutrophils on nanoscopically presented platelet glycoprotein Ibα.Incorporation of pentraxin 3 into hyaluronan matrices is tightly regulated and promotes matrix cross-linking.Assembly of RNA nanostructures on supported lipid bilayers.Carbohydrate-derived amphiphilic macromolecules: a biophysical structural characterization and analysis of binding behaviors to model membranes.Cytokines and growth factors cross-link heparan sulfate.Transient exposure of pulmonary surfactant to hyaluronan promotes structural and compositional transformations into a highly active state.Differential structural remodelling of heparan sulfate by chemokines: the role of chemokine oligomerization.Label-free characterization of biomembranes: from structure to dynamics.Nanomechanical properties of protein-DNA layers with different oligonucleotide tethers.A model derived from hydrodynamic simulations for extracting the size of spherical particles from the quartz crystal microbalance.The influence of polyanion molecular weight on polyelectrolyte multilayers at surfaces: protein adsorption and protein-polysaccharide complexation/stripping on natural polysaccharide films on solid supports.Probing the interactions of organic molecules, nanomaterials, and microbes with solid surfaces using quartz crystal microbalances: methodology, advantages, and limitations.Nanoplasmonic sensors for biointerfacial science.Unhindered copper uptake by glutaraldehyde-polyethyleneimine coatings in an artificial seawater model system with adsorbed swollen polysaccharides and competing ligand EDTA.In situ hydrodynamic spectroscopy for structure characterization of porous energy storage electrodes.Cellulose effects on morphology and elasticity of Vibrio fischeri biofilms.Relevance of glycosylation of S-layer proteins for cell surface properties.Tuning polyelectrolyte multilayer structure by exploiting natural variation in fucoidan chemistry.Adsorption of Milk Proteins (β-Casein and β-Lactoglobulin) and BSA onto Hydrophobic Surfaces.Binding of the chemokine CXCL12α to its natural extracellular matrix ligand heparan sulfate enables myoblast adhesion and facilitates cell motility.A method to tune the shape of protein-encapsulated polymeric microspheres.Cohesiveness tunes assembly and morphology of FG nucleoporin domain meshworks - Implications for nuclear pore permeabilityCombined QCM-D/GE as a tool to characterize stimuli-responsive swelling of and protein adsorption on polymer brushes grafted onto 3D-nanostructures.In situ real-time gravimetric and viscoelastic probing of surface films formation on lithium batteries electrodes.Strategies for a direct characterization of phosphoproteins on hydroxyapatite surfaces.Adsorption and diffusion in thin films of nanoporous metal-organic frameworks: ferrocene in SURMOF Cu2(ndc)2(dabco).Dynamic interactions of amelogenin with hydroxyapatite surfaces are dependent on protein phosphorylation and solution pH.Self-assembly and elasticity of hierarchical proteoglycan–hyaluronan brushes† †Electronic supplementary information (ESI) available: Variations in areal mass density upon SLB and SAv monolayer formation determined by SE (Fig. S1). See DOI: 10.1039/c
P2860
Q26745855-8A6EB30C-8D18-4F00-B85C-88740AB733B5Q26849991-F46CFB57-72F0-465C-A82B-D774A1D93B12Q27469069-CFDD2310-7B38-4375-96E4-2A713809D331Q28071780-E4EC5CA9-7F4B-464D-9E1E-E28A00DC4F87Q30357179-AA38627E-1B2E-4AD6-A28D-061847862258Q30373484-CCAD95F8-4B69-42B9-8396-A6805FE52D1DQ30388831-9292F2CB-0F81-4E93-8BA9-8A8D75FC599DQ30390394-3C5FF6B0-6B01-43E2-9F35-BE6A83E5F69AQ30393116-9019C307-F800-402B-A0BB-81ABDCABD16FQ30398842-F15235C0-FB7F-493F-AC9B-FC755F177A00Q30435061-BE7D4E1C-8E26-4657-8074-DC28AD297A89Q30450982-F5E21DE6-7795-4078-BE8B-0554938E7304Q34006362-D18CE707-F153-4199-873B-40CDBBAD3EA7Q34430984-E0463ADF-2D3A-45DE-A6E4-D2ADB6C05588Q34760145-AD0B6A35-9875-4CC9-B85B-11FA7BA7C557Q35824486-7D6C9012-971F-4329-BE6C-46C34A563430Q36011762-DF8FD321-66CC-40FE-959F-E64D0CA848BCQ37226241-BB7AA120-181A-4916-AE2D-F392A6F56608Q37637122-FBC54C52-0104-4DE2-ADBD-30CB97A5574DQ38164199-A0393D8E-8D9F-4529-A268-4A844491C68FQ38289456-0B9E4224-9988-4A32-A534-077934B6F456Q38598437-28C7AE28-CD00-4D9A-A52C-B955B1B6FE70Q38664580-1DF28AC8-1FD7-41E3-AF38-49BAC2AE6966Q38685728-E7881969-5AA7-4C85-9900-F4017066EE6AQ38734207-9172A9EE-7426-4E07-BD94-755EDDDDCAD7Q38757356-F1B5E48E-882F-48C6-B6C6-DE91760CD4A3Q38901704-2C8086BC-84C7-49CF-8FD7-70C7EB3318BFQ39631938-950A1CC1-A401-4C9F-8293-47C01909F797Q40079620-21E2A0DF-82C6-476F-845D-2929A4253640Q41564537-F846C11D-2C50-4EDE-99D1-990D0CA6D976Q41574996-9896A40A-E098-47E2-86C6-F0139CEAEB8EQ41634261-140DF81F-34D6-46B0-B8FC-3A02F29E8162Q42407223-FF5DC414-DCA9-4622-A553-1E83B9D38670Q42678653-87E7B312-AAC2-470D-A1A8-DB748EEEA0F7Q44020542-94A6D92C-C7D6-478D-87F2-28FC0072E0B3Q44650270-C1A2575B-741B-4123-874A-6179976E0C87Q45217686-F10916CF-DCB7-4900-AB3B-0610744CD726Q45773221-867B6C82-F043-4EEE-B14B-B868B35186B6Q46276385-7100D57A-1B2F-4503-935A-83AE67D10AE2Q46896464-0D3BCE7C-72D5-4BFE-8046-9BA7C6E53A7F
P2860
Hearing what you cannot see and visualizing what you hear: interpreting quartz crystal microbalance data from solvated interfaces.
description
2011 nî lūn-bûn
@nan
2011 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2011 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2011年の論文
@ja
2011年論文
@yue
2011年論文
@zh-hant
2011年論文
@zh-hk
2011年論文
@zh-mo
2011年論文
@zh-tw
2011年论文
@wuu
name
Hearing what you cannot see an ...... data from solvated interfaces.
@ast
Hearing what you cannot see an ...... data from solvated interfaces.
@en
Hearing what you cannot see an ...... data from solvated interfaces.
@nl
type
label
Hearing what you cannot see an ...... data from solvated interfaces.
@ast
Hearing what you cannot see an ...... data from solvated interfaces.
@en
Hearing what you cannot see an ...... data from solvated interfaces.
@nl
prefLabel
Hearing what you cannot see an ...... data from solvated interfaces.
@ast
Hearing what you cannot see an ...... data from solvated interfaces.
@en
Hearing what you cannot see an ...... data from solvated interfaces.
@nl
P356
P1433
P1476
Hearing what you cannot see an ...... data from solvated interfaces.
@en
P2093
Diethelm Johannsmann
P304
P356
10.1021/AC201778H
P407
P577
2011-10-17T00:00:00Z