about
Polyelectrolyte multilayers generated in a microfluidic device with pH gradients direct adhesion and movement of cells.Submicron patterning of DNA oligonucleotides on silicon.PEG molecular net-cloth grafted on polymeric substrates and its bio-merits.Characterization of cellular chemical dynamics using combined microfluidic and Raman techniquesThe Initiator Methionine tRNA Drives Secretion of Type II Collagen from Stromal Fibroblasts to Promote Tumor Growth and Angiogenesis.Efficient self-assembly of DNA-functionalized fluorophores and gold nanoparticles with DNA functionalized silicon surfaces: the effect of oligomer spacers.Secreted CLIC3 drives cancer progression through its glutathione-dependent oxidoreductase activity.Microfluidics for single cell analysis.2- and 3-dimensional synthetic large-scale de novo patterning by mammalian cells through phase separation.Gradient microfluidics enables rapid bacterial growth inhibition testing.Raman activated cell sorting.Polarized cell motility induces hydrogen peroxide to inhibit cofilin via cysteine oxidation.Creating "living" polymer surfaces to pattern biomolecules and cells on common plastics.3D mapping of microfluidic flow in laboratory-on-a-chip structures using optical tweezers.The importance of lag time extension in determining bacterial resistance to antibiotics.Single-cell genomics based on Raman sorting reveals novel carotenoid-containing bacteria in the Red Sea.Symmetry-breaking in branching epithelia: cells on micro-patterns under flow challenge the hypothesis of positive feedback by a secreted autocrine inhibitor of motility.Generation of primary hepatocyte microarrays by piezoelectric printing.Control of crystal polymorph in microfluidics using molluscan 28 kDa Ca²(+)-binding protein.Microfluidic-based measurements of cytochrome P450 enzyme activity of primary mammalian hepatocytes.Screening of biomineralization using microfluidics.Quantitative comparison between microfluidic and microtiter plate formats for cell-based assays.Single-Cell Microfluidics to Study the Effects of Genome Deletion on Bacterial Growth Behavior.Continuous Fabrication and Assembly of Spatial Cell-Laden Fibers for a Tissue-Like Construct via a Photolithographic-Based Microfluidic Chip.Effect of laser irradiation on cell function and its implications in Raman spectroscopy.Single cell growth rate and morphological dynamics revealing an "opportunistic" persistence.Continuous cell sorting in a flow based on single cell resonance Raman spectra.Influence of hydrodynamic conditions on quantitative cellular assays in microfluidic systems.An integrated microspectrometer for localised multiplexing measurements.Integrated microspectrometer for fluorescence based analysis in a microfluidic format.A microfluidic-based system for analysis of single cells based on Ca2+ flux.Can common adhesion molecules and microtopography affect cellular elasticity? A combined atomic force microscopy and optical study.A novel culture system for modulating single cell geometry in 3D.Restoration of chondrocytic phenotype on a two-dimensional micropatterned surface.Raman-activated cell sorting based on dielectrophoretic single-cell trap and release.Miniaturized optoelectronic tweezers controlled by GaN micro-pixel light emitting diode arraysReal-Time Study of Rapid Spread of Antibiotic Resistance Plasmid in Biofilm Using MicrofluidicsSpontaneous assembly and real-time growth of micrometre-scale tubular structures from polyoxometalate-based inorganic solidsA one-step procedure to probe the viscoelastic properties of cells by Atomic Force MicroscopyMutant p53s generate pro-invasive niches by influencing exosome podocalyxin levels
P50
Q30318329-D88B51C2-DBB8-4164-8789-653C285D2FA5Q31105989-D5232736-8568-44DA-8C92-16E4C47FE6A4Q33640305-FE0D8990-8339-48F1-B11F-292DAE534CD0Q36428403-55A08705-6A0C-462B-B488-78BEE529AF83Q36761574-42AB5BBE-E89C-475D-BD62-172BA4F1ABD0Q36769405-89B96809-628D-41D6-8D6D-D40A76C9CC2AQ37651981-F35C9DD1-8103-4370-AE03-29CB98029BF3Q37963604-E26D8943-3F8F-451A-A22C-058895A5D0CBQ38300095-6743EB4F-9443-4599-A387-A498BB5B9624Q38784008-6D08CD5E-A100-4DA0-8350-04F99E5C0222Q38813692-A8CE2EFE-FBF3-48BA-80FE-D5BCB2CDB278Q38874002-91C24CD6-9CE8-40EB-A1F9-4C676BB8860CQ39180764-187A829C-E947-4766-B666-9E7BCD4F9CF8Q40098283-0DC48A56-13B0-4C64-8E9F-F9EEBD16F1D8Q40715166-D3971576-D360-4AD2-9F35-5B87339302CAQ41977466-01207BB5-DB0C-44CA-B7DE-EE3B9F1E1673Q42037443-3636719D-24E4-456E-8CD6-36BFFD8A0644Q42804425-C36A9145-7057-4704-820F-0D66BFF4DF0CQ42916020-12F57A7E-B1FE-42F3-8BEA-3AE842F226D2Q43094586-3CBF67FF-FF5C-4D5E-8853-C21DF8BDE16FQ46178647-E6C5C198-5C4C-4D19-B793-2A4762B8C01DQ46871827-BCBCD14B-B2A2-4D9E-89C1-AD0A31741BE4Q47750276-A2B28744-0AC4-405E-82A5-609759D82FC8Q48279414-B8842BBF-2EC9-4F6B-AB9B-F3EB8EE5096DQ50050069-FEB76387-E726-483B-9A12-2B6EE74EE1B5Q50619334-4E39687C-7069-402D-AA3F-343259218460Q50869955-D3B5A960-42B4-4DF9-9754-DDA2D3EC02F6Q50949596-932FA032-8FC2-4719-8EEF-4C2921CA3A7DQ51505693-7565C6BB-2262-44D8-BBA0-FF12F0B4E71EQ51539663-75AF91D4-6142-491E-BFA5-3AB82C8A1750Q51582945-5F1267E2-E313-4E12-A927-F3F52D1497E0Q51680731-C175A2A0-2C36-4597-A11A-054F46CECD48Q52936189-A1275B0B-5C6A-4710-999D-763DE5D67936Q53602555-9B58BED6-85C1-417F-9812-B607E48AE8D0Q53639043-5A3040D7-20AF-4EA7-B1A4-6865D5FD4AC3Q56892075-5E3B8DD6-6368-46F3-BBBD-6DF8D8DAB83EQ57046009-08EBAAD1-8048-4827-BD8C-5F46320B17F1Q57383295-36FFF3E5-2FED-4813-B3F3-60C43D377AE8Q57979740-51451FFD-2B41-4E54-9B77-6D354AF463F2Q59801568-6F222469-9795-4025-BE2A-CCBD362DDB76
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Huabing Yin
@ast
Huabing Yin
@en
Huabing Yin
@es
Huabing Yin
@nl
Huabing Yin
@sl
type
label
Huabing Yin
@ast
Huabing Yin
@en
Huabing Yin
@es
Huabing Yin
@nl
Huabing Yin
@sl
prefLabel
Huabing Yin
@ast
Huabing Yin
@en
Huabing Yin
@es
Huabing Yin
@nl
Huabing Yin
@sl
P1053
J-7843-2016
P106
P31
P3829
P496
0000-0001-7693-377X