Actively targeted in vivo multiplex detection of intrinsic cancer biomarkers using biocompatible SERS nanotags.
about
Clinical instrumentation and applications of Raman spectroscopyRecent developments in multiplexing techniques for immunohistochemistry.A real-time clinical endoscopic system for intraluminal, multiplexed imaging of surface-enhanced Raman scattering nanoparticlesFluorescence-Raman dual modal endoscopic system for multiplexed molecular diagnostics.3D multiplexed immunoplasmonics microscopy.Ag@Au core-shell dendrites: a stable, reusable and sensitive surface enhanced Raman scattering substrateRaman spectroscopy using plasmonic and carbon-based nanoparticles for cancer detection, diagnosis, and treatment guidance.Part 1: Diagnosis.Online Flowing Colloidosomes for Sequential Multi-analyte High-Throughput SERS Analysis.Sensing of p53 and EGFR Biomarkers Using High Efficiency SERS Substrates.Rational design of Raman-labeled nanoparticles for a dual-modality, light scattering immunoassay on a polystyrene substrate.Development of nanostars as a biocompatible tumor contrast agent: toward in vivo SERS imaging.The many facets of Raman spectroscopy for biomedical analysis.Raman technologies in cancer diagnostics.Raman spectroscopy: an evolving technique for live cell studies.An unusual role of folate in the self-assembly of heparin-folate conjugates into nanoparticles.Bioorthogonal SERS Nanoprobes for Mulitplex Spectroscopic Detection, Tumor Cell Targeting, and Tissue Imaging.Dye-free near-infrared surface-enhanced Raman scattering nanoprobes for bioimaging and high-performance photothermal cancer therapy.Surface-Enhanced Raman Scattering-Based Immunoassay Technologies for Detection of Disease BiomarkersFabrication of ordered mullite nanowhisker array with surface enhanced Raman scattering effect.Fabrication of hexagonally patterned flower-like silver particle arrays as surface-enhanced Raman scattering substrates.Au@pNIPAM SERRS Tags for Multiplex Immunophenotyping Cellular Receptors and Imaging Tumor Cells.MUC1 Aptamer Targeted SERS Nanoprobes.Ultrasensitive NIR-SERRS Probes with Multiplexed Ratiometric Quantification for In Vivo Antibody Leads Validation.Multiplexing determination of cancer-associated biomarkers by surface-enhanced Raman scattering using ordered gold nanohoneycomb arrays.Combination of Mass Signal Amplification and Isotope-Labeled Alkanethiols for the Multiplexed Detection of miRNAs.3D Plasmon Coupling Assisted Sers on Nanoparticle-Nanocup Array Hybrids.Multiplex bioassays encoded by photonic crystal beads and SERS nanotags.Emergence of two near-infrared windows for in vivo and intraoperative SERS.Direct Detection of Unamplified Pathogen RNA in Blood Lysate using an Integrated Lab-in-a-Stick Device and Ultrabright SERS Nanorattles.Raman Spectroscopy and Imaging for Cancer Diagnosis.Nanostructure-based surface-enhanced Raman scattering biosensors for nucleic acids and proteinsOnline Flowing Colloidosomes for Sequential Multi-analyte High-Throughput SERS AnalysisApplication of nanoparticles in cancer detection by Raman scattering based techniquesLipid Reconstitution-Enabled Formation of Gold Nanoparticle Clusters for Mimetic Cellular Membrane
P2860
Q26752924-426560D2-0933-4763-B065-7AB2D7543D92Q26796393-417DA7FE-03A1-4E9D-BC13-4EEE591B1EF8Q27309979-8E53D592-AED0-4EE5-99A1-05491007C27FQ30632994-77F79E0B-1E64-4165-A318-69AE1B23C7D2Q36059946-605C43E9-9269-4A98-9F2D-A68D4359F92EQ36100151-E6CB7E43-F934-4337-BFFF-71524C1DD6C4Q36298664-5941FAFD-960B-4A6C-BAB3-6EBF8036B551Q36343137-FCF1ACBF-6433-4499-AAD6-1D5488F834CEQ36419208-516CA2A4-4A3D-425A-A203-A92DA73A78C6Q36443172-9DEFD97E-0867-4042-BA98-3630C6459BCBQ37158927-74279D76-D3ED-420F-8BDC-D89FC618CB2DQ38271852-C317D04D-BDDB-4BE1-8ADA-B6DD8A5F4E80Q38625830-46B348D4-29C7-4A5B-A727-B545F5E927ABQ38806902-ED850A50-CB18-4349-B780-3026824566F0Q38840381-713C1438-BF14-417F-B24A-5F042B695D1BQ38848166-6156CFEC-F6BD-4B17-B92F-0741A7E4B398Q38895692-939E4A88-744E-48A7-B332-78D5613576D5Q39085671-AB0FFCB5-6B5D-424E-B738-33EA6BE5644BQ42292726-018B3503-901A-40A5-9069-C1A0CDFF578CQ42382241-0C1ABBD0-5A53-4609-8D60-63962120F2CBQ42827647-203EE7B8-CA44-4A6A-8DCC-96BAB04117AFQ46534963-D12E7ECB-DF34-4F52-B6F6-A2F08EE6E4F7Q47294319-7E3D7652-FAD2-4D56-BDBD-C298DA157E97Q47408519-2B776615-2B80-4FE6-99EE-C53F250BCC8FQ48308505-FBE2093B-7DB0-4D86-8589-002A31D5C018Q50153900-8550D4CB-4852-45D0-A0E5-9ED2910A6544Q51192566-D3D879BD-F112-423E-BC81-E1AE506F849BQ52598520-B4B56412-CB08-410A-955E-2E05B8E739C5Q52671114-F4D1D381-2AAE-4A13-81AB-D47B41823265Q55492534-95E9D3FE-51D4-45CC-8516-74DE3C8A3F45Q57156389-09D721C4-F6A0-4836-BBA4-124730EE93E0Q58492673-6F0F9D87-5DED-4E68-9E49-4F7CB7D5F219Q58584648-12BF5EA8-E1B5-4D9F-9B3C-CEE4FB4B7712Q59127254-5BB20D9D-DEBD-4485-A6C4-4D7703D5B607
P2860
Actively targeted in vivo multiplex detection of intrinsic cancer biomarkers using biocompatible SERS nanotags.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 12 February 2014
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Actively targeted in vivo mult ...... g biocompatible SERS nanotags.
@en
Actively targeted in vivo mult ...... g biocompatible SERS nanotags.
@nl
type
label
Actively targeted in vivo mult ...... g biocompatible SERS nanotags.
@en
Actively targeted in vivo mult ...... g biocompatible SERS nanotags.
@nl
prefLabel
Actively targeted in vivo mult ...... g biocompatible SERS nanotags.
@en
Actively targeted in vivo mult ...... g biocompatible SERS nanotags.
@nl
P2860
P356
P1433
P1476
Actively targeted in vivo mult ...... g biocompatible SERS nanotags.
@en
P2093
Ghayathri Balasundaram
U S Dinish
P2860
P2888
P356
10.1038/SREP04075
P407
P577
2014-02-12T00:00:00Z