about
Magnetic forces and DNA mechanics in multiplexed magnetic tweezersRecent advances in magnetic tweezersMechanism of homology recognition in DNA recombination from dual-molecule experimentsSingle-stranded DNA library preparation uncovers the origin and diversity of ultrashort cell-free DNA in plasmaMonitoring pharmacologically induced immunosuppression by immune repertoire sequencing to detect acute allograft rejection in heart transplant patients: a proof-of-concept diagnostic accuracy studyTorsional regulation of hRPA-induced unwinding of double-stranded DNA.Taxonomic and functional diversity provides insight into microbial pathways and stress responses in the saline Qinghai Lake, China.Annealing helicase HARP closes RPA-stabilized DNA bubbles non-processively.Temporal response of the human virome to immunosuppression and antiviral therapySkewed brownian fluctuations in single-molecule magnetic tweezers.Scanning a DNA molecule for bound proteins using hybrid magnetic and optical tweezersCirculating cell-free DNA enables noninvasive diagnosis of heart transplant rejection.A quantitative comparison of single-cell whole genome amplification methods.Non-bias-limited tracking of spherical particles, enabling nanometer resolution at low magnification.Noninvasive monitoring of infection and rejection after lung transplantationSingle-Cell-Genomics-Facilitated Read Binning of Candidate Phylum EM19 Genomes from Geothermal Spring Metagenomes.Highly parallel magnetic tweezers by targeted DNA tethering.Numerous uncharacterized and highly divergent microbes which colonize humans are revealed by circulating cell-free DNA.Precision monitoring of immunotherapies in solid organ and hematopoietic stem cell transplantation.Quantification of transplant-derived circulating cell-free DNA in absence of a donor genotype.Multifunctional nanomechanical systems via tunably coupled piezoelectric actuation.Localized surface plasmon resonance biosensor integrated with microfluidic chip.Myriad Applications of Circulating Cell-Free DNA in Precision Organ Transplant Monitoring.Applying rigor and reproducibility standards to assay donor-derived cell-free DNA as a non-invasive method for detection of acute rejection and graft injury after heart transplantation.Tunable optical forces between nanophotonic waveguides.Urinary cell-free DNA is a versatile analyte for monitoring infections of the urinary tract.Simultaneous multiplexed amplicon sequencing and transcriptome profiling in single cellsStructure and diversity of urinary cell-free DNA informative of host-pathogen interactions in human urinary tract infectionVast population genetic diversity underlies the treatment dynamics of ETV6-RUNX1 ALLNano-Scale Electrical Transducers of Surface Plasmons for Integrated BiosensingElectrical detection of confined gap plasmons in metal–insulator–metal waveguidesFabrication and Optical Properties of Gold SemishellsFocusing Plasmons in Nanoslits for Surface-Enhanced Raman ScatteringLocal Electrical Detection of Single Nanoparticle Plasmon ResonanceBiopsy-free screening for gliomaSeparating the signal from the noise in metagenomic cell-free DNA sequencingSimultaneous multiplexed amplicon sequencing and transcriptome profiling in single cellsGut uropathogen abundance is a risk factor for development of bacteriuria and urinary tract infection
P50
Q27331997-64E70E4B-D5FD-4676-B024-AB7D745E51E6Q28262696-0F4E5141-9711-4451-9665-E1349B824DE5Q28266079-59CC8DFB-0E61-4109-B260-15CFB3194403Q28601304-C6BFB67F-E0A7-4E6F-B5B7-B9CCB07D485AQ28611470-601A3E76-154C-4ACC-A8CD-C9C1DAE6ADBEQ30495260-3B072FFC-A525-436C-9256-4D560ADB677CQ30866978-D8927C1C-A945-448E-B327-FE220E344832Q33635826-AF57A234-F128-4E2A-A818-AADE3EC9E179Q33902789-82E558CB-B9E2-4B00-BB34-1CF7D98CBFB0Q34270255-F1880851-E50F-430C-9FC4-A23FE4E7E581Q34766398-B8BD30F2-4B4B-44D0-A166-2ACAA8023A70Q35078413-70764AD5-6896-4996-9B88-43CD8FC8D733Q35227833-1D1F2149-27BA-4E2E-91CA-E8C3671ADF9AQ35962752-B38F4CBA-AECA-483E-86AB-7DFEAE92760AQ36238500-D582085B-0191-4917-AE39-1F5C67A99F56Q36575141-A4646129-059D-4D4D-87D4-5354BD8ED557Q38330965-57A5A2D5-16B2-4571-B74C-EF2947D1EC00Q38613374-63DE31FE-147B-4125-873C-C01431DABD97Q39381261-68E1A35B-51EB-47C5-9049-CA50F1338B14Q41235268-2065AB2B-80DB-4672-AA40-41B6052831A6Q44184252-EAD2388E-33CF-41EF-90C5-378F88125FAAQ46057499-2D5CA7D5-2AD6-4158-AADB-793F2FB09D3DQ46106628-0464B4BC-43AB-40A4-97DF-8BDDDB9AC55FQ46327120-903DA1C3-2D75-4385-BD7B-26B70FD1ED5BQ49128310-C68F8617-F099-4DEF-AC7C-1604C57E8609Q55311645-1275496E-930E-4C49-A556-2632B1C9F161Q57516074-B4963383-2378-488F-9EB8-486256F39157Q57516077-9F3215F8-29FB-45CF-99D5-C801BB92C38CQ57516078-E7F154FE-EE3C-4282-9A10-DA0BB7BE35B7Q57516089-9165F14C-C97D-428B-9482-E0B6C87AA558Q57516099-02290BE1-3D81-4CB0-8D58-6D732424BD8EQ57516102-AF01B29A-00DC-4E79-9180-25ED06DD6881Q57516105-12C74314-3D0B-4D27-B5F2-7C6609642129Q57516117-16D5FEF8-6D00-415F-AC24-DB0A8ED8CE6EQ58606616-68512D41-FB1D-41FB-B15F-B3DEB333A79DQ89662507-E56E7D4A-054D-47D0-BE36-E2F43BB43194Q90596807-8B25105F-6F7E-441D-A871-DA7F9CC2FC86Q91666009-7F466320-D0FE-47C6-A90B-557DC4B76AEF
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Iwijn De Vlaminck
@ast
Iwijn De Vlaminck
@en
Iwijn De Vlaminck
@es
Iwijn De Vlaminck
@nl
Iwijn De Vlaminck
@sl
type
label
Iwijn De Vlaminck
@ast
Iwijn De Vlaminck
@en
Iwijn De Vlaminck
@es
Iwijn De Vlaminck
@nl
Iwijn De Vlaminck
@sl
prefLabel
Iwijn De Vlaminck
@ast
Iwijn De Vlaminck
@en
Iwijn De Vlaminck
@es
Iwijn De Vlaminck
@nl
Iwijn De Vlaminck
@sl
P1053
P-6479-2015
P106
P31
P3829
P496
0000-0001-6085-7311