about
Bacteria concentration using a membrane type insulator-based dielectrophoresis in a plastic chipA microfluidic chip for screening individual cancer cells via eavesdropping on autophagy-inducing crosstalk in the stroma niche.Make caffeine visible: a fluorescent caffeine "traffic light" detector.Multifunctional microvalves control by optical illumination on nanoheaters and its application in centrifugal microfluidic devices.One-step pathogen specific DNA extraction from whole blood on a centrifugal microfluidic device.A fully automated immunoassay from whole blood on a disc.Fully integrated lab-on-a-disc for simultaneous analysis of biochemistry and immunoassay from whole blood.Circulating tumor cells detected by lab-on-a-disc: Role in early diagnosis of gastric cancer.In situ dynamic measurements of the enhanced SERS signal using an optoelectrofluidic SERS platform.Lab-on-a-disc for simultaneous determination of nutrients in water.Surface charge, electroosmotic flow and DNA extension in chemically modified thermoplastic nanoslits and nanochannels.Fully integrated lab-on-a-disc for nucleic acid analysis of food-borne pathogens.Flexible fabrication and applications of polymer nanochannels and nanoslitsHuman breast cancer-derived soluble factors facilitate CCL19-induced chemotaxis of human dendritic cells.Centrifugal microfluidics for biomedical applications.Pumps for microfluidic cell culture.Emerging techniques in the isolation and characterization of extracellular vesicles and their roles in cancer diagnostics and prognostics.All-in-one centrifugal microfluidic device for size-selective circulating tumor cell isolation with high purity.RhoA and Rac1 play independent roles in lysophosphatidic acid-induced ovarian cancer chemotaxis.Three dimensional multicellular co-cultures and anti-cancer drug assays in rapid prototyped multilevel microfluidic devices.Characterization of DNA immobilization and subsequent hybridization using in situ quartz crystal microbalance, fluorescence spectroscopy, and surface plasmon resonance.Aminosilane layers on the plasma activated thermoplastics: influence of solvent on its structure and morphology.Clinical evaluation of micro-scale chip-based PCR system for rapid detection of hepatitis B virus.Flow-enhanced electrochemical immunosensors on centrifugal microfluidic platforms.Electrochemical velocimetry on centrifugal microfluidic platforms.CUT-PCR: CRISPR-mediated, ultrasensitive detection of target DNA using PCR.Enzyme leaps fuel antichemotaxis.Exodisc for Rapid, Size-Selective, and Efficient Isolation and Analysis of Nanoscale Extracellular Vesicles from Biological Samples.FAST: Size-Selective, Clog-Free Isolation of Rare Cancer Cells from Whole Blood at a Liquid-Liquid Interface.Lab-on-a-disc for fully integrated multiplex immunoassays.Correction to All-in-One Centrifugal Microfluidic Device for Size-Selective Circulating Tumor Cell Isolation with High Purity.Productive chemical interaction between a bacterial microcolony couple is enhanced by periodic relocation.Lab-on-a-disc for simultaneous determination of total phenolic content and antioxidant activity of beverage samples.Fully Automated Centrifugal Microfluidic Device for Ultrasensitive Protein Detection from Whole Blood.Cell migration in microengineered tumor environments.A lab-on-a-disc with reversible and thermally stable diaphragm valves.An electrochemical-sensor system for real-time flow measurements in porous materials.Electrospun TiO2 nanofiber integrated lab-on-a-disc for ultrasensitive protein detection from whole blood.Paper on a disc: balancing the capillary-driven flow with a centrifugal force.Elastomeric membrane valves in a disc.
P50
Q29788143-5EBDEF53-857B-4D43-BD89-C2906F9A6616Q30356080-06AB8358-4C0F-41FA-9B6C-E87C4CDD4CD1Q30656724-2BA217FD-52CB-4A5B-B1F9-349BF2952CDAQ33283527-047D1038-CAA6-4F10-A83A-D4E5618FDEFFQ33283528-EC1845B4-7D80-4931-95D2-1B310D8259F0Q33449410-5B052F0F-2493-427C-BA9B-2E9F24153471Q33735995-2E5C9301-1741-403A-942D-5907ABEF3800Q33853543-C4522686-1C2D-4651-AC0E-6358A546A07AQ33933132-909F58EE-14C3-456E-B0B2-4F6848F1E938Q34548521-FD76FC55-C2A7-4D7E-8CF9-CC984311A875Q34794654-B5CC2EA3-00AA-438E-B722-5C70FF149C7CQ35122274-35213060-990C-4572-ABAD-E710FEB860F9Q36638719-194ED31D-C8C4-4C4B-9133-1D0D2CDA7D68Q37121744-BB6E74BC-4411-4792-9729-5CE63F2CE8D2Q37761633-6F772B88-13F7-484E-8442-BDE650902813Q38124802-A15698A0-442E-4555-8C88-6CF0930B5AB2Q38624837-A4C1255D-CF52-4817-8FFE-00333DD983B1Q38947731-7CC2A703-BF61-423E-8C73-A9CC02757C7DQ39029939-90951AC9-1745-4AAD-9555-AEAD57E5C3D4Q39227692-45EB41FE-627B-46C8-A335-AA7D380ED1ABQ39692274-867F8184-B0E8-4DB8-95C8-A9664E837A5AQ44027741-4604C7C2-291D-4153-A8EF-BCA7BCCE7AB6Q45422476-A7D59B5D-E7A6-47A7-A841-A661D1F9119AQ46114217-DAE8BF9E-FA35-4A03-B797-1F35CCD2181AQ46600496-2F630063-CAB2-48F8-A222-51186918FBB7Q47162594-F25F2D4F-B4AB-4886-871C-C86558D30119Q47236870-F55148CF-EC54-4B80-ACC9-6C57EA81DEA5Q47244795-1C530105-E006-4382-81C5-F456D85C98A6Q47251398-96C98180-D76C-4E63-B5E9-B9E8E8A165ECQ48692834-3B4F3BB6-3325-4786-BE59-A5349677119AQ49987222-5E88DA88-DB95-466F-84BB-C19AB3739F90Q50485253-9F2CB42A-FB46-4837-8617-2A06FE65C2FFQ51248934-31789E6C-A8A1-4153-819F-108BA92BCF74Q51336272-1C38AEA5-EDCD-45B2-879F-6C8265307D16Q51429442-81F17D0D-A61A-4BBE-9598-B1E23641FC50Q51456090-6E5DBB25-E81B-444E-8047-52DC589B443DQ51496950-14F7AF6B-56CC-4725-A7C2-6117431E0EDEQ51504796-7210F274-DC57-4CEC-A544-FFDC2F9D27C1Q51546324-C6A8C430-6C90-4E30-933E-20484A7FB819Q51550436-0604E975-A6BD-4E4A-B3B5-4B84F9D3FA3A
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Yoon-kyoung Cho
@ast
Yoon-kyoung Cho
@en
Yoon-kyoung Cho
@es
Yoon-kyoung Cho
@nl
Yoon-kyoung Cho
@sl
type
label
Yoon-kyoung Cho
@ast
Yoon-kyoung Cho
@en
Yoon-kyoung Cho
@es
Yoon-kyoung Cho
@nl
Yoon-kyoung Cho
@sl
prefLabel
Yoon-kyoung Cho
@ast
Yoon-kyoung Cho
@en
Yoon-kyoung Cho
@es
Yoon-kyoung Cho
@nl
Yoon-kyoung Cho
@sl
P106
P31
P496
0000-0001-6423-1834