about
Single-Molecule Studies of Intrinsically Disordered Proteins Using Solid-State NanoporesNanopore sensing at ultra-low concentrations using single-molecule dielectrophoretic trapping.Single particle confocal fluorescence spectroscopy in microchannels: dependence of burst width and burst area distributions on particle size and flow rate.High spatial resolution observation of single-molecule dynamics in living cell membranes.Single molecule studies of quantum dot conjugates in a submicrometer fluidic channel.Resizing metal-coated nanopores using a scanning electron microscope.Micrometer-sized supported lipid bilayer arrays for bacterial toxin binding studies through total internal reflection fluorescence microscopyA fully unsupervised compartment-on-demand platform for precise nanoliter assays of time-dependent steady-state enzyme kinetics and inhibition.Label-free Pb(II) whispering gallery mode sensing using self-assembled glutathione-modified gold nanoparticles on an optical microcavity.Precise attoliter temperature control of nanopore sensors using a nanoplasmonic bullseye.Synchronized optical and electronic detection of biomolecules using a low noise nanopore platform.Fluorescence detection methods for microfluidic droplet platforms.Template-Stripped Multifunctional Wedge and Pyramid Arrays for Magnetic Nanofocusing and Optical Sensing.Microdroplets: a sea of applications?Opportunities for microfluidic technologies in synthetic biology.Single molecule sensing with solid-state nanopores: novel materials, methods, and applications.Fundamentals and applications of self-assembled plasmonic nanoparticles at interfaces.Tuneable 2D self-assembly of plasmonic nanoparticles at liquid|liquid interfaces.Self-assembly of nanoparticle arrays for use as mirrors, sensors, and antennas.A microdroplet dilutor for high-throughput screening.Droplet dispensing in digital microfluidic devices: Assessment of long-term reproducibility.Nanopore extended field-effect transistor for selective single-molecule biosensing.Selective single molecule nanopore sensing of proteins using DNA aptamer-functionalised gold nanoparticles.DNA tunneling detector embedded in a nanopore.Selectively Sized Graphene-Based Nanopores for in Situ Single Molecule Sensing.Detection and identification of nucleic acid engineered fluorescent labels in submicrometre fluidic channels.A microfluidic approach for high-throughput droplet interface bilayer (DIB) formation.Single molecule multiplexed nanopore protein screening in human serum using aptamer modified DNA carriers.Droplet-interfaced microchip and capillary electrophoretic separations.Thin-film polymer light emitting diodes as integrated excitation sources for microscale capillary electrophoresis.Integrated on-chip derivatization and electrophoresis for the rapid analysis of biogenic amines.Superhydrophobic surfaces as an on-chip microfluidic toolkit for total droplet control.Self-assembly and applications of ultraconcentrated nanoparticle solutions.Label-free in-flow detection of single DNA molecules using glass nanopipettes.Droplet-based microfluidic platform for high-throughput, multi-parameter screening of photosensitizer activity.Monitoring of real-time streptavidin-biotin binding kinetics using droplet microfluidics.Plasmonic ruler at the liquid-liquid interface.Single Molecule Trapping and Sensing Using Dual Nanopores Separated by a Zeptoliter Nanobridge.Graphene-edge dielectrophoretic tweezers for trapping of biomolecules.Covalently Attached Antimicrobial Surfaces Using BODIPY: Improving Efficiency and Effectiveness.
P50
Q22061738-DAD92340-1F2C-4CAD-A670-326BD5A654E8Q27336476-4818A7D7-F9FB-475B-8802-A438D987F714Q31150520-CD2CA656-4D58-4472-909D-BA3AA2BEDC96Q31158814-4A129DE9-0451-4A14-8873-F75926EC06B2Q33212208-C4B36D81-4F35-4C7E-81AE-3054139367A4Q34033387-CD003457-E8AA-44AD-9C06-087E80261A29Q34350439-78A5D678-77D1-431D-93B9-B1DE13BDA0D1Q34686148-FD7C9704-EA0B-49B8-870F-48B0F249957AQ35175514-D7106681-4BAB-436D-AB05-B61C5E3C431EQ35482144-61805DF7-7DAE-4B6D-9D18-CC57D3BB91AEQ35551883-585DB9DF-C88D-436B-9970-134D3BFE7C16Q35939659-7022159C-5D46-4FEA-ABE9-6C8DF82210B0Q36800181-20E57CE8-4E96-4B3D-972E-F1C8A842330DQ37225409-AC6FC195-C23D-4703-BFD8-9BD0D3FD2AEDQ37497761-BC842954-B54E-4D5E-BB05-F1A3DE5D1872Q38044661-FB856BFB-E405-40E3-810C-0EB4BAD2FCBBQ38710277-36192BA7-3F4B-47E9-B149-AA9286376098Q39272127-A09F3510-2701-48A6-803C-D54B6521FEF7Q39314498-2A7D218A-1C4E-4692-A5D3-EA8D2EB492F8Q39984076-4DB29B22-EA24-4C0B-B195-DBAEA2931AC2Q40038412-900A0CB2-0E33-4C48-8C66-25065DD581E0Q41701213-8E6AAE1A-6521-482B-9043-D65C335FAD6DQ42126328-4F21BBD9-41D6-4341-807B-5DC8F18DDFC2Q42166793-E48AB3AC-EBC0-48DC-BFB0-B75D297DFA51Q42577400-942C4F27-7192-4725-AB5B-70C47C66226EQ42731182-738612F4-5B0F-4CC0-B35D-02D7807FF759Q43153349-AE2B0183-320D-405E-A7CD-D3B36FC7D925Q44201355-E955C414-FE45-48A6-A140-A6C50E0D9D3DQ44412670-878B5B1C-BAFA-4D33-B57D-772A8891F5C0Q44820674-01762CE0-B3F3-4283-95A5-1591E9BE1E82Q44993040-D97ED663-7219-440E-87EA-C8DFF5C71622Q45028782-B7A3D2D8-2A8B-4A3C-8AEC-B9DD6AE0CED0Q45231067-B5FB9CA5-FE82-4470-9B2E-F6BCBA8C1F42Q45777176-BFF7C62B-0300-4EE2-807B-BD265B7116F4Q45804855-4EECE05D-6F94-4312-A8BD-45A30D056029Q46422439-1D35570B-E736-4E00-BDDD-F2595AFC5B50Q46434565-DBF8B518-18EE-450E-84B3-FA34FD27DA22Q47109275-44F53E76-28C8-4A2F-B0A9-CA4B245858BDQ47165493-190FEEB1-5508-43B4-B3E0-49A3D8083A1EQ47279573-62B7F7E4-99EB-4683-8910-72F730530BE0
P50
description
Forscher
@de
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Joshua Edel
@ast
Joshua Edel
@en
Joshua Edel
@es
Joshua Edel
@nl
Joshua Edel
@sl
type
label
Joshua Edel
@ast
Joshua Edel
@en
Joshua Edel
@es
Joshua Edel
@nl
Joshua Edel
@sl
prefLabel
Joshua Edel
@ast
Joshua Edel
@en
Joshua Edel
@es
Joshua Edel
@nl
Joshua Edel
@sl
P1053
I-7699-2012
P106
P21
P31
P3829
P496
0000-0001-5870-8659