about
From immobilized cells to motile cells on a bed-of-nails: effects of vertical nanowire array density on cell behaviour.Nanofluidics in hollow nanowires.Single-molecule denaturation mapping of DNA in nanofluidic channels.Lipid-based passivation in nanofluidics.Sorting cells by their dynamical properties.Single-molecule studies of repressor-DNA interactions show long-range interactions.Electrodeless dielectrophoresis of single- and double-stranded DNACompetitive binding-based optical DNA mapping for fast identification of bacteria--multi-ligand transfer matrix theory and experimental applications on Escherichia coli.Fibroblasts cultured on nanowires exhibit low motility, impaired cell division, and DNA damageA fast and scalable kymograph alignment algorithm for nanochannel-based optical DNA mappingsBandpass filtering of DNA elastic modes using confinement and tensionDirected self-organization of single DNA molecules in a nanoslit via embedded nanopit arraysFrom the Cover: The dynamics of genomic-length DNA molecules in 100-nm channels.DNA in nanochannels--directly visualizing genomic information.Probing concentration-dependent behavior of DNA-binding proteins on a single-molecule level illustrated by Rad51.New technologies for DNA analysis--a review of the READNA Project.Fluorescence nanoscopy of single DNA molecules by using stimulated emission depletion (STED).A single-step competitive binding assay for mapping of single DNA molecules.Single-molecule detection and mismatch discrimination of unlabeled DNA targets.Extension of nanoconfined DNA: Quantitative comparison between experiment and theory.A method improving the accuracy of fluorescence recovery after photobleaching analysis.Microfluidics-Based Approaches to the Isolation of African Trypanosomes.Visualizing the entire DNA from a chromosome in a single frame.Quantitation of bacterial adhesion to polymer surfaces by bioluminescence.Fluorescence enhancement of single DNA molecules confined in Si/SiO2 nanochannels.Generic surface modification strategy for sensing applications based on AuSiO2 nanostructures.Fluorescence microscopy of nanochannel-confined DNA.Protein depositions on one hydrocephalus shunt and on fifteen temporary ventricular catheters.Fluorescent nanowire heterostructures as a versatile tool for biology applications.Solute transport on the sub 100 ms scale across the lipid bilayer membrane of individual proteoliposomes.Mechanical behavior of a supported lipid bilayer under external shear forces.Separation of parasites from human blood using deterministic lateral displacement.Local conformation of confined DNA studied using emission polarization anisotropy.Controlled microfluidic switching in arbitrary time-sequences with low drag.Separation of pathogenic bacteria by chain length.Sorting cells by size, shape and deformability.Open channel deterministic lateral displacement for particle and cell sorting.Bacterial chromosome extraction and isolation.Tuneable separation in elastomeric microfluidics devices.Fluorescence Microscopy of Nanochannel-Confined DNA.
P50
Q27303186-C7F0E3D4-C457-445A-969D-F26B0762A3B8Q30484442-4EFB8B81-2372-4A0D-A108-F712209845EDQ30496076-EC917CFB-E05F-4BD7-A4DC-8C44E1E85991Q30514005-ECE1CE17-D435-4E91-96A1-1BE151E34424Q30818995-62FB17D9-54F4-417D-AB66-9DDB75C5AC37Q33884491-3E4D19D4-64DC-493C-AF80-4B1CCCB6A630Q34178942-88A36FA5-AEA7-4478-980F-D1C6811CFA9CQ34428720-40909AED-7357-4F36-879F-571D040D78E7Q34806861-0DE6C470-89DF-45EC-B0C8-D69FEC6057D8Q35602432-27C6C340-0887-4706-B8A4-BAA27E80F702Q35649540-6434D37C-CB38-4DD4-A9C2-867A09E5342BQ37068262-EEA5D4AB-A798-47A6-8C9E-184739D460BCQ37285030-6B70ECD0-D6FC-4F4B-BBF8-6BDD6735FDA4Q37697535-110F08EB-3F43-44FF-861F-880F132F236EQ38312924-FE8F9709-97A7-4CBA-B4C2-B0DA13C4A10FQ38619509-50ED75BD-8187-4401-BC80-8404AB4588AAQ39578140-FC0408C8-64F8-4F2D-8238-887A11CC4BC9Q39676095-BA513286-B303-48B3-AC7D-ED3B3F9056FCQ40143106-3B80B6D7-EAB5-460F-85BB-8920592076D3Q40978662-CB118C21-339F-46A0-A996-938D7542F277Q41668719-E12CEE2B-8098-458F-ADDF-C4749C42FBF0Q41990830-4A8BF10F-71A7-44D1-95F4-765AF6A39041Q42182302-037C4BD3-0F96-42D4-8028-7FED9FEF40B2Q42453324-E3980C5A-D522-42E6-B830-0AA0BE353733Q43026846-8ED1C1E1-8E90-47D6-A432-C3E54995A924Q43090633-46779003-D0F1-4C83-9B8B-691539A0F0F4Q44245313-5D7E677A-B0DD-43AE-B446-6BE290A61C3FQ45037045-242CAFAF-198F-4AC5-9C6C-FB7AA7632344Q45215235-A84AA977-EFB4-44B9-997E-6901700E0619Q45908587-88D2B7EE-EA07-4E0A-B18C-666585FEA8DBQ46028901-38183B09-5930-465F-9BB0-5651F1C69D67Q46190624-BA9993FD-980B-4EC9-B407-9F1F4958724BQ46203460-97A0497E-FF89-42C8-9C35-ADAECEA7A3F0Q46979451-BFFA38F4-6F56-4B76-8A8C-2F59DA050FF2Q47208733-21E6F21D-381A-4B72-B1ED-ABAD466B47F5Q47326964-73FB021A-E14B-4717-BEEB-8030DBB302E8Q47632718-EE795B7F-E399-4C45-B271-07346DB00BF6Q47724069-B15756F3-8248-4429-98C7-0E0D487DE121Q47754942-BF5DB8DD-A16C-4CAA-AE4F-15826D49F072Q47757670-FF0F1624-B273-4CBB-B82A-159A4B2ED466
P50
description
Zweeds onderzoeker
@nl
hulumtues
@sq
researcher
@en
taighdeoir
@ga
հետազոտող
@hy
name
Jonas O. Tegenfeldt
@ast
Jonas O. Tegenfeldt
@en
Jonas O. Tegenfeldt
@es
Jonas O. Tegenfeldt
@ga
Jonas O. Tegenfeldt
@nl
Jonas O. Tegenfeldt
@sl
Jonas O. Tegenfeldt
@sq
type
label
Jonas O. Tegenfeldt
@ast
Jonas O. Tegenfeldt
@en
Jonas O. Tegenfeldt
@es
Jonas O. Tegenfeldt
@ga
Jonas O. Tegenfeldt
@nl
Jonas O. Tegenfeldt
@sl
Jonas O. Tegenfeldt
@sq
prefLabel
Jonas O. Tegenfeldt
@ast
Jonas O. Tegenfeldt
@en
Jonas O. Tegenfeldt
@es
Jonas O. Tegenfeldt
@ga
Jonas O. Tegenfeldt
@nl
Jonas O. Tegenfeldt
@sl
Jonas O. Tegenfeldt
@sq
P1053
B-9506-2008
P106
P108
P1153
7003633618
P21
P27
P31
P3829
P496
0000-0002-3695-6886