Au nanorod design as light-absorber in the first and second biological near-infrared windows for in vivo photothermal therapy.
about
Spatial temperature mapping within polymer nanocomposites undergoing ultrafast photothermal heating via gold nanorods.Three-photon luminescence of gold nanorods and its applications for high contrast tissue and deep in vivo brain imaging.Simulation of nanoparticle-mediated near-infrared thermal therapy using GATENanoparticles for inhibition of in vitro tumour angiogenesis: synergistic actions of ligand function and laser irradiation.Gold nanorods as a theranostic platform for in vitro and in vivo imaging and photothermal therapy of inflammatory macrophages.Rational assembly of a biointerfaced core@shell nanocomplex towards selective and highly efficient synergistic photothermal/photodynamic therapy.Cu-Au alloy nanostructures coated with aptamers: a simple, stable and highly effective platform for in vivo cancer theranostics.Seed-Mediated Growth of Silver Nanocubes in Aqueous Solution with Tunable Size and Their Conversion to Au Nanocages with Efficient Photothermal Property.Cancer Cell Internalization of Gold Nanostars Impacts Their Photothermal Efficiency In Vitro and In Vivo: Toward a Plasmonic Thermal Fingerprint in Tumoral Environment.Transdermal thiol-acrylate polyethylene glycol hydrogel synthesis using near infrared light.Innovative strategy with potential to increase hemodialysis efficiency and safety.A Comparative Study of Clinical Intervention and Interventional Photothermal Therapy for Pancreatic Cancer.Nanostructures for NIR light-controlled therapies.Structural-Engineering Rationales of Gold Nanoparticles for Cancer Theranostics.Cellular uptake behaviour, photothermal therapy performance, and cytotoxicity of gold nanorods with various coatings.Fluorescence and Sensing Applications of Graphene Oxide and Graphene Quantum Dots: A Review.Controlled Living Nanowire Growth: Precise Control over the Morphology and Optical Properties of AgAuAg Bimetallic NanowiresSingle-crystal caged gold nanorods with tunable broadband plasmon resonances.Polydopamine-Enabled Approach toward Tailored Plasmonic Nanogapped Nanoparticles: From Nanogap Engineering to Multifunctionality.Copper Manganese Sulfide Nanoplates: A New Two-Dimensional Theranostic Nanoplatform for MRI/MSOT Dual-Modal Imaging-Guided Photothermal Therapy in the Second Near-Infrared Window.Synthesis of Small Au-Ag Core-Shell Cubes, Cuboctahedra, and Octahedra with Size Tunability and Their Optical and Photothermal Properties.Yolk-Shell Nanostructures: Design, Synthesis, and Biomedical Applications.Dynamically tuning near-infrared-induced photothermal performances of TiO2 nanocrystals by Nb doping for imaging-guided photothermal therapy of tumors.Mesoporous Carbon Nanospheres as a Multifunctional Carrier for Cancer Theranostics.Photothermal effects from Au-Cu2O core-shell nanocubes, octahedra, and nanobars with broad near-infrared absorption tunability.Facet-dependent optical properties of Pd-Cu2O core-shell nanocubes and octahedra.Biotin-decorated silica coated PbS nanocrystals emitting in the second biological near infrared window for bioimaging.Micro/Nanoparticle-Augmented Sonodynamic Therapy (SDT): Breaking the Depth Shallow of Photoactivation.Assembly-Induced Thermogenesis of Gold Nanoparticles in the Presence of Alternating Magnetic Field for Controllable Drug Release of Hydrogel.Light-Triggered Inactivation of Enzymes with Photothermal Nanoheaters.Design of TPGS-functionalized Cu3BiS3 nanocrystals with strong absorption in the second near-infrared window for radiation therapy enhancement.Plasmonic caged gold nanorods for near-infrared light controlled drug delivery.Plasmonic rod-in-shell nanoparticles for photothermal therapy.Facet-Dependent Optical Properties Revealed through Investigation of Polyhedral Au-Cu₂O and Bimetallic Core-Shell Nanocrystals.Detection of Intracellular Gold Nanoparticles: An Overview.One-Step Synthesis of Au-Ag Nanowires through Microorganism-Mediated, CTAB-Directed ApproachSelf-assembly of gold supraparticles with crystallographically aligned and strongly coupled nanoparticle building blocks for SERS and photothermal therapyA Theoretical Model of Laser Heating Carbon NanotubesPhotothermally induced accumulation and retention of polymeric nanoparticles in tumors for long-term fluorescence imagingExploring the photothermal hot spots of graphene in the first and second biological window to inactivate cancer cells and pathogens
P2860
Q30395638-2B9DA11A-43D8-411C-AEE6-6C3E4C02160BQ30611999-43DC0259-3DB1-492C-B3D5-CB7798D1CC25Q33824801-E26A6171-A02E-41EE-969B-6A090004D46CQ35723548-D7571C41-8315-4A5E-B0AD-BD49E14BD64BQ35728244-C53DB49E-E457-4D19-AE8B-7D736EE1AE19Q35843374-39FCA5BE-651A-40E0-97F7-0BD0D8526489Q35888517-5B4A8029-864C-4349-BCFF-54B65906FA12Q35891471-8384D274-EC49-44BD-81F8-FC452336E527Q35962185-6C5E1919-AB6A-4427-94A6-F8AB161A2C63Q36070589-E342022A-D880-4092-9ACE-0459DDB2AEF2Q37653458-29C99C67-4B9C-4FA0-B576-6E1F136F3E2BQ38662058-F6116E92-D48F-4F8E-A768-26C252F4FA90Q38748878-3198D456-2254-48BD-92DD-3C2CB6477819Q38909736-48040862-6FE5-4C0C-B65B-71E896C9D61BQ38962939-8256F732-624D-4809-855B-0B5AFF92AEF7Q39457669-2D2E1230-CFB3-4FAC-A5C8-0624D84EB8BEQ41948938-C1A996D2-9FB6-4F13-8205-1BFAB58C69F5Q44244588-53CFBEB8-909A-46E2-9D7B-E8B41EBFD605Q45174158-1253A358-078F-45AB-9491-7CC3AF726F74Q47114781-79225127-7FF5-48FA-954B-A618A87E74F7Q47355527-3379629D-09A0-4FCC-8172-A7101B1DA8AEQ47762822-D114E9D0-AB14-4D0D-BCAD-769CD4A48B19Q47986902-FEF753DC-E00C-4853-948E-478F3B4F3956Q48533196-D4DCD658-14E5-438F-B2E0-22C44F0B6D7CQ50206476-4DD5D4B4-1A91-45A6-BEA2-3356F42B48E7Q50443176-92895DDA-38A0-4698-B36A-6E58D23B9FBAQ50455206-BAEB56E7-BB1A-418A-BFF2-140DE29332A4Q50788001-6781229C-32B6-4246-94F3-EA3F0F8538FCQ51139443-9AC356DA-3C37-4151-A695-9FB78F7D8739Q51157022-214ECFBA-BFFE-4BE1-92EC-7264B5BD0190Q52940780-DD67AFEE-73FE-4D4F-BE76-F6385D4B90B5Q53044187-51892351-63E9-47A1-B4A6-A984E8CC3C22Q53553483-424BDFD9-75E1-4B09-813B-DB28A1CD1430Q53608254-424A8BB3-85D7-4AE7-BEFC-4E500E636170Q55515774-622FCC23-0A47-4147-BBFB-529D45302D17Q57144536-B7834F1C-6520-499A-9D5F-14106F154423Q57155475-4AB9EF5B-E53D-4DF5-8BF1-B72DCD122593Q57174319-44EF5B60-A317-4584-98A2-857C23AFA644Q57367581-36BB325E-F9E5-4CAF-BDF5-C3801446F536Q57377175-1009B59E-91D5-4026-B7D6-975337391C0F
P2860
Au nanorod design as light-absorber in the first and second biological near-infrared windows for in vivo photothermal therapy.
description
2013 nî lūn-bûn
@nan
2013 թուականի Մայիսին հրատարակուած գիտական յօդուած
@hyw
2013 թվականի մայիսին հրատարակված գիտական հոդված
@hy
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
name
Au nanorod design as light-abs ...... in vivo photothermal therapy.
@ast
Au nanorod design as light-abs ...... in vivo photothermal therapy.
@en
Au nanorod design as light-abs ...... in vivo photothermal therapy.
@nl
type
label
Au nanorod design as light-abs ...... in vivo photothermal therapy.
@ast
Au nanorod design as light-abs ...... in vivo photothermal therapy.
@en
Au nanorod design as light-abs ...... in vivo photothermal therapy.
@nl
prefLabel
Au nanorod design as light-abs ...... in vivo photothermal therapy.
@ast
Au nanorod design as light-abs ...... in vivo photothermal therapy.
@en
Au nanorod design as light-abs ...... in vivo photothermal therapy.
@nl
P2093
P356
P1433
P1476
Au nanorod design as light-abs ...... r in vivo photothermal therapy
@en
P2093
Chen-Sheng Yeh
Chia-Hao Su
Fong-Yu Cheng
Shih-Hui Gilbert Chang
Vijayakumar Shanmugam
Yu-Sheng Cheng
P304
P356
10.1021/NN401187C
P407
P577
2013-05-10T00:00:00Z