about
Gold-nanorod-assisted near-infrared stimulation of primary auditory neurons.Laser exposure of gold nanorods can induce intracellular calcium transients.Gold Nanorod-assisted Optical Stimulation of Neuronal CellsBacterial response to different surface chemistries fabricated by plasma polymerization on electrospun nanofibers.Development of a microtiter plate-based glycosaminoglycan array for the investigation of glycosaminoglycan-protein interactions.Towards proteomics-on-chip: the role of the surface.Surface modification and chemical surface analysis of biomaterials.Electrospun nanofibers as dressings for chronic wound care: advances, challenges, and future prospects.Imaging the action of antimicrobial peptides on living bacterial cells.Development of a bioreactor for evaluating novel nerve conduits.Methods for generating protein molecular ions in ToF-SIMS.Colloidal crystal based plasma polymer patterning to control Pseudomonas aeruginosa attachment to surfaces.Electrospun polystyrene fiber diameter influencing bacterial attachment, proliferation, and growth.Stable low-fouling plasma polymer coatings on polydimethylsiloxane.Polymersome production on a microfluidic platform using pH sensitive block copolymers.Culture on fibrin matrices maintains the colony-forming capacity and osteoblastic differentiation of mesenchymal stem cells.The effect of metal microstructure on the initial attachment of Escherichia coli to 1010 carbon steel.Limits of detection for time of flight secondary ion mass spectrometry (ToF-SIMS) and X-ray photoelectron spectroscopy (XPS): detection of low amounts of adsorbed protein.Ultrasensitive probing of the protein resistance of PEG surfaces by secondary ion mass spectrometry.Studies of electroosmotic flow and the effects of protein adsorption in plasma-polymerized microchannel surfaces.Editorial: In Focus Issue on Bacterial-Surface Interactions.Arginine functionalization of hydrogels for heparin binding--a supramolecular approach to developing a pro-angiogenic biomaterial.Chitosan-coated amyloid fibrils increase adipogenesis of mesenchymal stem cells.Some changes, but still communicating exciting key insights from the biointerface.pH-dependent lipid vesicle interactions with plasma polymerized thin films.Non-fouling microfluidic chip produced by radio frequency tetraglyme plasma deposition.Characterization of fibrinogen adsorption onto glass microcapillary surfaces by ELISA.Rapid fabrication of glass/PDMS hybrid µIMER for high throughput membrane proteomics.Cavitation and non-cavitation regime for large-scale ultrasonic standing wave particle separation systems--In situ gentle cavitation threshold determination and free radical related oxidation.Ultrasonically enhanced fractionation of milk fat in a litre-scale prototype vessel.Toward Immunocompetent 3D Skin Models.Fabrication of a platform to isolate the influences of surface nanotopography from chemistry on bacterial attachment and growth.Temperature effects on the ultrasonic separation of fat from natural whole milk.Versatile SERS sensing based on black siliconCovalent Coupling and Characterization of Supported Lipid LayersGeneration of Bioactive Materials with Rapid Self-Assembling Resorcinarene-PeptidesThree-Dimensional Alignment of Schwann Cells Using Hydrolysable Microfiber Scaffolds: Strategies for Peripheral Nerve RepairSynthesis and Characterization of Polypyrrole-Coated Sulfur-Rich Latex Particles: New Synthetic Mimics for Sulfur-Based MicrometeoritesIn Focus: Women in biointerface scienceSynthesis and characterization of immobilized PAMAM dendrons
P50
Q31160317-54EC40C2-CAEE-4BD7-A947-1A825F071F21Q34782372-FC26F3A9-129E-4850-8808-4A6F47827470Q35621780-648DA537-8595-445F-9F1A-91AFE801E727Q35739475-38682705-B205-4631-B2DA-F0B7ED8C4DA5Q36193415-E81263F1-DB70-4985-BDFA-8EEB6A834A72Q37780466-2B049B8C-4B60-48C9-AD8A-1B52019C34F3Q37915032-6ED2DB84-AEA3-4252-9D7B-7A95071D6A2BQ38200082-9D230B58-2597-4753-980F-9FFB1CFD8FB0Q39329479-7DB8504C-208C-41AF-8F3E-765C3F52193DQ40069224-6CA54223-D5B1-4673-BCC4-33F06FC428C8Q40425050-49EE2144-50CD-42A5-9C95-98A99D3ADFB8Q40883788-2DFC1A5B-8956-4007-B6F7-D5F745759AD2Q41179240-85B8CC3D-949E-423B-A1BC-EB47EFD3EC36Q42427099-6FECEC5A-11D7-41ED-994B-D6FF2566A348Q43060839-FB325141-FB6F-4D21-8135-F52498835DD4Q43783454-283D8D8D-C744-46D0-9E05-ABEF8E8528E4Q43853861-EA2A31FD-8D5B-42C8-9EC6-3FFB737A038FQ44087757-CB76FAC0-28B5-409D-A557-9AE7CEBF9DE4Q44166175-2CC00032-4FA1-40FB-89E5-535B9CE9633FQ45973759-5BE62893-3546-4B88-8994-6AE9D4436B7AQ47245362-4EAA8C87-7F7F-45A9-B353-E6D4E13C6785Q47427231-2B4F57B2-B487-40F4-B121-824E0DC18C0AQ48005545-654C289A-52D7-4ADA-812A-3D4EF8F9C4BAQ50189985-03D4D695-7710-4C6D-BDDB-4A0FB2D2A2F5Q50848769-51EBEA2E-0E35-4A6C-A96A-12F85BEF1617Q51037113-8A931C44-48FC-41E4-BC2A-58C85E13331CQ51092672-26D79CCA-1F68-409D-AB15-CEC8577B6E20Q51554063-A52943F9-5F14-465E-952B-DD6DF48B15B0Q51715084-CEC97157-B93F-4AF3-B727-BE7BAFEB299AQ51715146-9E12BF62-63A9-4397-B368-20CE0B4FB2A0Q52354810-B9CA2F13-6695-478B-B5B3-A2D19094ECB5Q53304432-51ABF4D4-8908-4208-A1D3-B7F58527AAE7Q53602346-3560E441-F5DC-4057-A00E-8DB1F483FEC6Q57160568-1EDDC58D-BB57-42D5-B7CF-85B893D4D5F9Q57393742-FC494FFA-BC75-41D7-8E02-60A3AED55D94Q58486587-D6023362-1F06-4EA8-8A4B-2DA8B26A5673Q59661084-073AE8B0-5F6A-49E0-936D-AF662D15A6F3Q59941286-7318AB35-6532-400D-8550-8CC66DCE56E4Q62032393-c30bc660-4350-7db9-1591-1d33c99663b2Q80467096-25800E23-7499-402C-BCBC-12ECEEDC7C1F
P50
description
hulumtuese
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
S L. McArthur
@nl
S L. McArthur
@sl
Sally L. McArthur
@en
Sally L. McArthur
@es
Sally McArthur
@de
type
label
S L. McArthur
@nl
S L. McArthur
@sl
Sally L. McArthur
@en
Sally L. McArthur
@es
Sally McArthur
@de
altLabel
S McArthur
@en
SL McArthur
@en
Sally L McArthur
@en
Sally Mcarthur
@en
prefLabel
S L. McArthur
@nl
S L. McArthur
@sl
Sally L. McArthur
@en
Sally L. McArthur
@es
Sally McArthur
@de
P1053
B-6848-2008
P106
P1153
7006668393
P21
P31
P3829
P496
0000-0002-4914-6989