Capture and stimulated release of circulating tumor cells on polymer-grafted silicon nanostructures
about
Clinical Applications of NanoVelcro Rare-Cell Assays for Detection and Characterization of Circulating Tumor CellsFast and selective cell isolation from blood sample by microfiber fabric system with vacuum aspiration.Nanotechnology for enrichment and detection of circulating tumor cells.Microfluidics for single-cell genetic analysisDifferential detection of tumor cells using a combination of cell rolling, multivalent binding, and multiple antibodies.Liquid biopsy genotyping in lung cancer: ready for clinical utility?3D bioelectronic interface: capturing circulating tumor cells onto conducting polymer-based micro/nanorod arrays with chemical and topographical controlHigh-purity prostate circulating tumor cell isolation by a polymer nanofiber-embedded microchip for whole exome sequencing.Nanostructure embedded microchips for detection, isolation, and characterization of circulating tumor cells.Applications of zero-valent silicon nanostructures in biomedicine.An integrated microfluidic chip system for single-cell secretion profiling of rare circulating tumor cells.Programming thermoresponsiveness of NanoVelcro substrates enables effective purification of circulating tumor cells in lung cancer patientsTunable nanostructured coating for the capture and selective release of viable circulating tumor cellsA chip assisted immunomagnetic separation system for the efficient capture and in situ identification of circulating tumor cells.Development of individualized anti-metastasis strategies by engineering nanomedicinesRecent advances in nanotechnology-based detection and separation of circulating tumor cellsEnzymatic cleavage of uracil-containing single-stranded DNA linkers for the efficient release of affinity-selected circulating tumor cellsMicrofluidic devices to enrich and isolate circulating tumor cells.Interfacing Inorganic Nanowire Arrays and Living Cells for Cellular Function AnalysisGraphene Oxide Nanosheets Modified with Single-Domain Antibodies for Rapid and Efficient Capture of Cells.Aptamer-polymer functionalized silicon nanosubstrates for enhanced recovered circulating tumor cell viability and in vitro chemosensitivity testingSupramolecular nanosubstrate-mediated delivery for reprogramming and transdifferentiation of mammalian cells.Specific capture and release of circulating tumor cells using aptamer-modified nanosubstrates.Highly efficient and selective isolation of rare tumor cells using a microfluidic chip with wavy-herringbone micro-patterned surfaces.Rational Design of Materials Interface for Efficient Capture of Circulating Tumor Cells.Emerging role of nanomaterials in circulating tumor cell isolation and analysisBiosensor technology: recent advances in threat agent detection and medicine.Cell death induced by AC magnetic fields and magnetic nanoparticles: current state and perspectives.Technologies for detection of circulating tumor cells: facts and vision.Capturing Cancer: Emerging Microfluidic Technologies for the Capture and Characterization of Circulating Tumor Cells.Silicon nanostructures for cancer diagnosis and therapy.Beyond the Capture of Circulating Tumor Cells: Next-Generation Devices and Materials.Microfluidic technologies in cell isolation and analysis for biomedical applications.Thermoresponsive release of viable microfiltrated Circulating Tumor Cells (CTCs) for precision medicine applications.Nanotentacle-structured magnetic particles for efficient capture of circulating tumor cells.Aptamer-functionalized barcode particles for the capture and detection of multiple types of circulating tumor cells.Surface design of antibody-immobilized thermoresponsive cell culture dishes for recovering intact cells by low-temperature treatment.On-off affinity binding modulation on thermoresponsive polymer-grafted surfaces for capture and release of proteins and cells.Materials and microfluidics: enabling the efficient isolation and analysis of circulating tumour cells.A 3D graphene oxide microchip and a Au-enwrapped silica nanocomposite-based supersandwich cytosensor toward capture and analysis of circulating tumor cells.
P2860
Q26744828-67DF80DC-2C62-4AA5-BFC4-2AF74B5CBC23Q30368315-F6F0BDCF-2DF5-493E-8839-2963108514F5Q30382502-667DBCEC-6004-42B8-ACFA-3E8C1A8E0F93Q30403381-E8C71DC8-9A72-4C68-8116-618FACF47905Q30581258-1BC6DB8B-469C-4BDF-B1CB-A30DA39C29FFQ33567037-4784A99B-3C0F-4B72-887B-A74ACB51BEA1Q34016976-98D840E9-5A38-4BAD-B120-EB7728EE47D0Q34335350-9BEC9F3D-C2EA-4D6E-8CA0-22C9D72FE04BQ34379915-A100F813-AA9B-4914-A082-7074D4A90CFAQ34490443-CFCA32AB-8E0C-478C-ADC1-A03DBBD4AA8DQ34706426-67DD4BD4-5A19-46D5-8419-17E3C8654C0DQ35027161-2002FC22-D63B-46B5-A41A-3843B5FFA079Q35820728-148C0976-BC3E-458B-84A4-6F8742604E4BQ35940227-CC33469B-AABB-49F0-A5C1-C248EA5057DDQ35967474-7F0A2553-6B8F-43E6-A867-557FBB39BA92Q35994516-1EB66088-F30C-40E3-B22B-D3E485DF10F9Q36002894-55986AB8-CF3A-4E64-8ADA-F0395A796057Q36332676-27EE4E5E-9317-4C73-B308-0700554D0CCDQ36365943-3427EA7F-A8FD-4B2D-AF3E-5E44285B3D09Q36470622-062C0866-9AC0-45AC-90C4-A20FA795D604Q36926601-85257A72-9E9E-44E9-AA97-E71DA7A757DAQ37126920-813E0DE6-8613-4B7F-9DE6-737CBD47A9E0Q37206771-55EEFBD0-C988-43EB-8BA6-27AB5FACE154Q37312795-A9159BE6-E6DE-4E6E-97D6-D9BFA1FD0BB2Q37422977-069FFA4D-B2B0-4684-A00B-3DBF3502E9C4Q37731678-435BFAED-1E87-479F-A0B0-4FF7EDFEB5B1Q38121489-D6B2E408-9D9F-427D-A109-B0601745FA7DQ38153091-69A5EF46-E4EB-46E9-9272-3B8A9FC29E31Q38154493-7F9744BB-BB9A-4453-B13C-A6611D91C34FQ38494213-45602734-0677-4928-9E82-E78B3A41D0C6Q38541957-F34F2F5E-1A72-41DD-A763-99A76EACA4B6Q38661356-9532BF59-4CE1-49F7-81A4-CE745661912DQ38789186-17768BF4-4432-4EB3-9C30-101D7406F153Q38831076-D7064C59-ACFD-4F3D-8D83-36214BC8B3F7Q38928618-C4921883-F09B-4B9A-BD4E-4488D3C0482FQ38953769-5470680B-8C6D-4B84-90B7-CE50A61C221AQ39043078-C7DAF945-A796-49ED-8040-3E5F8D12CC78Q39170375-8372F407-064B-429B-A31B-8BB7A3463F61Q39385781-68312DB5-C1D7-4D5A-A0A7-82AD86239692Q40517887-1547113F-610E-4BE8-BC90-2D295A9377C8
P2860
Capture and stimulated release of circulating tumor cells on polymer-grafted silicon nanostructures
description
2012 nî lūn-bûn
@nan
2012 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2012 թվականի դեկտեմբերին հրատարակված գիտական հոդված
@hy
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
name
Capture and stimulated release ...... grafted silicon nanostructures
@ast
Capture and stimulated release ...... grafted silicon nanostructures
@en
Capture and stimulated release ...... grafted silicon nanostructures
@nl
type
label
Capture and stimulated release ...... grafted silicon nanostructures
@ast
Capture and stimulated release ...... grafted silicon nanostructures
@en
Capture and stimulated release ...... grafted silicon nanostructures
@nl
prefLabel
Capture and stimulated release ...... grafted silicon nanostructures
@ast
Capture and stimulated release ...... grafted silicon nanostructures
@en
Capture and stimulated release ...... grafted silicon nanostructures
@nl
P2093
P2860
P50
P356
P1433
P1476
Capture and stimulated release ...... grafted silicon nanostructures
@en
P2093
Aiko Nakao
Daniel Y Suh
Hsian-Rong Tseng
Hsiao-hua Yu
Kevin S Wei
Mitch A Garcia
P2860
P304
P356
10.1002/ADMA.201203185
P407
P577
2012-12-17T00:00:00Z