Velocity effect on aptamer-based circulating tumor cell isolation in microfluidic devices.
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Advances in plasmonic technologies for point of care applicationsEngineering long shelf life multi-layer biologically active surfaces on microfluidic devices for point of care applicationsNanostructured substrates for isolation of circulating tumor cells.Characterization of microfluidic shear-dependent epithelial cell adhesion molecule immunocapture and enrichment of pancreatic cancer cells from blood cells with dielectrophoresis.Effects of nanopillar array diameter and spacing on cancer cell capture and cell behaviors.Proliferation and migration of tumor cells in tapered channels.Enhancing sensitivity and specificity in rare cell capture microdevices with dielectrophoresis.Ex Vivo Culture of CTCs: An Emerging Resource to Guide Cancer TherapyElectrical detection of cancer biomarker using aptamers with nanogap break-junctions.Alternating current electrohydrodynamics in microsystems: Pushing biomolecules and cells around on surfaces.Capture, isolation and release of cancer cells with aptamer-functionalized glass bead array.A biomimetic mechanism for antibody immobilization on lipid nanofibers for cell capture.Advances in Candida detection platforms for clinical and point-of-care applicationsParametric control of collision rates and capture rates in geometrically enhanced differential immunocapture (GEDI) microfluidic devices for rare cell capture.Frontiers of optofluidics in synthetic biology.Enrichment, detection and clinical significance of circulating tumor cells.Nucleic acid aptamers in cancer research, diagnosis and therapy.Paper-based analytical devices for clinical diagnosis: recent advances in the fabrication techniques and sensing mechanisms.Circulating tumor cell detection: A direct comparison between negative and unbiased enrichment in lung cancerA simple packed bed device for antibody labelled rare cell capture from whole blood.Brain Tumor Genetic Modification Yields Increased Resistance to Paclitaxel in Physical Confinement.Urinary micro-RNA biomarker detection using capped gold nanoslit SPR in a microfluidic chip.Detection of single tumor cell resistance with aptamer biochipAptamer-conjugated extracellular nanovesicles for targeted drug delivery.A transfer function approach for predicting rare cell capture microdevice performance.Biocompatible TiO2 nanoparticle-based cell immunoassay for circulating tumor cells capture and identification from cancer patients.Efficient microfluidic negative enrichment of circulating tumor cells in blood using roughened PDMS.Electrical fingerprinting, 3D profiling and detection of tumor cells with solid-state micropores.Circulating tumor cell isolation, culture, and downstream molecular analysis.Preparation of Homogeneous Nanostructures in 5 Minutes for Cancer Cells Capture
P2860
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P2860
Velocity effect on aptamer-based circulating tumor cell isolation in microfluidic devices.
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年学术文章
@wuu
2011年学术文章
@zh-cn
2011年学术文章
@zh-hans
2011年学术文章
@zh-my
2011年学术文章
@zh-sg
2011年學術文章
@yue
2011年學術文章
@zh
2011年學術文章
@zh-hant
name
Velocity effect on aptamer-bas ...... ation in microfluidic devices.
@en
Velocity effect on aptamer-bas ...... ation in microfluidic devices.
@nl
type
label
Velocity effect on aptamer-bas ...... ation in microfluidic devices.
@en
Velocity effect on aptamer-bas ...... ation in microfluidic devices.
@nl
prefLabel
Velocity effect on aptamer-bas ...... ation in microfluidic devices.
@en
Velocity effect on aptamer-bas ...... ation in microfluidic devices.
@nl
P2093
P356
P1476
Velocity effect on aptamer-bas ...... ation in microfluidic devices.
@en
P2093
Samir M Iqbal
Waseem Asghar
Yaling Liu
Young-tae Kim
P304
13891-13896
P356
10.1021/JP205511M
P407
P50
P577
2011-11-07T00:00:00Z