Radiofrequency field-induced thermal cytotoxicity in cancer cells treated with fluorescent nanoparticles
about
A New Imaging Platform for Visualizing Biological Effects of Non-Invasive Radiofrequency Electric-Field Cancer HyperthermiaTiO2 nanotube platforms for smart drug delivery: a reviewNon-Invasive Radiofrequency Field Treatment to Produce Hepatic Hyperthermia: Efficacy and Safety in SwineBionanotechnology and the future of glioma.A radio-frequency coupling network for heating of citrate-coated gold nanoparticles for cancer therapy: design and analysis.Phase-shift, stimuli-responsive drug carriers for targeted delivery.The ongoing history of thermal therapy for cancerNon-invasive radiofrequency ablation of malignancies mediated by quantum dots, gold nanoparticles and carbon nanotubes.Imaging heterostructured quantum dots in cultured cells with epifluorescence and transmission electron microscopy.Quantum dots and carbon nanotubes in oncology: a review on emerging theranostic applications in nanomedicine.The effects of non-invasive radiofrequency treatment and hyperthermia on malignant and nonmalignant cells.Towards real-time detection of tumor margins using photothermal imaging of immune-targeted gold nanoparticles.Cooperative, nanoparticle-enabled thermal therapy of breast cancer.Tumor selective hyperthermia induced by short-wave capacitively-coupled RF electric-fields.Gold nanoparticles stabilized with MPEG-grafted poly(l-lysine): in vitro and in vivo evaluation of a potential theranostic agentNoncovalent functionalization of carbon nanovectors with an antibody enables targeted drug deliveryNanotechnology for energy-based cancer therapiesQuantum dots-based tissue and in vivo imaging in breast cancer researches: current status and future perspectives.Radiofrequency heating pathways for gold nanoparticles.Magnetic fluid hyperthermia induced by radiofrequency capacitive field for the treatment of transplanted subcutaneous tumors in ratsHyperthermia sensitizes Rhizopus oryzae to posaconazole and itraconazole action through apoptosis.A review of therapeutic aptamer conjugates with emphasis on new approaches.Synergy in cancer treatment between liposomal chemotherapeutics and thermal ablation.Non-invasive radiofrequency-induced targeted hyperthermia for the treatment of hepatocellular carcinoma.Nanoparticle systems as tools to improve drug delivery and therapeutic efficacy.Current progress in nanotechnology applications for diagnosis and treatment of kidney diseases.Radiofrequency ablation of drug-resistant cancer cells using molecularly targeted carboxyl-functionalized biodegradable graphene.Noninvasive radiofrequency treatment effect on mitochondria in pancreatic cancer cells(89)Zr-labeled anti-endoglin antibody-targeted gold nanoparticles for imaging cancer: implications for future cancer therapy.Protocols for assessing radiofrequency interactions with gold nanoparticles and biological systems for non-invasive hyperthermia cancer therapy.QD-filled micelles which combine SPECT and optical imaging with light-induced activation of a platinum(IV) prodrug for anticancer applications.Synthesis and characterization of anti-EGFR fluorescent nanoparticles for optical molecular imaging.Luciferase-based protein denaturation assay for quantification of radiofrequency field-induced targeted hyperthermia: developing an intracellular thermometer.Noninvasive radiofrequency field destruction of pancreatic adenocarcinoma xenografts treated with targeted gold nanoparticlesGold-gold sulfide nanoshell as a novel intensifier for anti-tumor effects of radiofrequency fieldsBiodistribution and acute toxicity of naked gold nanoparticles in a rabbit hepatic tumor model.Nanoparticle-mediated hyperthermia in cancer therapy.Comparative evaluation of the impact on endothelial cells induced by different nanoparticle structures and functionalization.Nanohybridization of Low-Dimensional Nanomaterials: Synthesis, Classification, and ApplicationRadiofrequency electric-field heating behaviors of highly enriched semiconducting and metallic single-walled carbon nanotubes
P2860
Q27321706-6F63189B-6583-44DF-817D-0DEC577A1262Q28066800-791E28FE-9DF6-405A-8672-0B78FBDC9CC3Q30356280-75A1E9A2-B559-4B01-B172-89A8A5216DBAQ30417964-D3FFDDB3-C9CA-474C-9BAE-3F7103D955FEQ30426213-90111690-3B28-4D77-9B33-53BD267594E1Q30466278-EF08EAA9-5857-4DDE-ADDD-D4B5AE6F59B2Q30469171-97F774F8-A0BD-4064-A73E-07D63DBC0C11Q33874638-07648FF9-7926-4C4F-A3A5-73DAA76DE359Q33978384-DCC6FA7F-7951-4406-842B-9E578F3869B6Q34033804-75654360-2EE6-400A-B206-8E8EB5DAE13EQ34348124-D06F14CD-FAD5-4092-933F-44B8B3E2F534Q34407725-2038EBA4-7EE5-4E56-8021-6237387575C2Q34489386-3B8ECA25-E25B-4216-84A9-4174C85D2E90Q34827662-77BC1FB1-2EC4-4F5E-873A-5F43C590D8C8Q35013476-BC5F748A-23A9-4D3D-929D-0E5C18BC7576Q35177908-643EF5E1-FDB2-442C-A1BD-A8221880C819Q35264028-C47B678B-6CEB-4598-B138-A3AE938AC60FQ35533782-A44213BD-A1F9-4A99-B82D-E22D51C63E3AQ36219041-D70EFB1A-FC8F-46BE-BE94-709054C24251Q36224797-BEBD919F-CF0A-4F76-8F8C-E071308A16EBQ37124159-4C84C2D2-B048-487F-9187-839B8B70E618Q37277378-E94DF9E1-9772-4682-AC49-0DE5470CD9B6Q37727030-E613833F-0D30-48E1-A459-85EF8955D9C1Q37945248-847D7466-BEE3-4F41-9B7A-1A82120B7C15Q38123458-07C6A759-9B8E-4D95-B4A6-D2677915F6F2Q38539866-33EDC08F-389B-4349-9F2C-0CD7541BE31AQ38920218-B0D07096-230A-4E3C-BF2C-98B35713371DQ38978897-36B4DF3D-E394-4865-AB95-CFE6FCADE373Q39023017-C6A91FF3-0CEB-4E8A-AB43-6E950DF5A592Q39097649-D3C87A66-5B3F-4C2D-ACF7-D8647DAAF647Q39172084-06332A9B-2F42-4BFD-9EB5-A9827E9700C3Q39219348-0061E408-7205-4AC3-8FCE-7DFEE5654E65Q39362264-3B4B8D0F-E989-4EA0-902D-607025FFB1E6Q39622805-E6755A0B-0612-49B3-B429-A778F4BBD5BBQ41928500-A7ADF387-55C3-4892-B584-E0DCC6F5FF58Q41940569-D3644B94-CA20-4ED5-86F8-672EFF65E6F9Q42551606-9D3D1C95-15A7-47B3-9A4C-9529C42544E5Q43189563-B55A689B-A4D7-49BF-BB0C-9BA3544061A7Q57370700-93781B40-8DE1-4175-9DC0-5FEB99C25D01Q57693657-D833BD81-39F1-473D-9AF1-0AAD5FD3090D
P2860
Radiofrequency field-induced thermal cytotoxicity in cancer cells treated with fluorescent nanoparticles
description
2010 nî lūn-bûn
@nan
2010 թուականի Յուլիսին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի հուլիսին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年学术文章
@wuu
2010年学术文章
@zh-cn
2010年学术文章
@zh-hans
2010年学术文章
@zh-my
2010年学术文章
@zh-sg
2010年學術文章
@yue
name
Radiofrequency field-induced t ...... with fluorescent nanoparticles
@ast
Radiofrequency field-induced t ...... with fluorescent nanoparticles
@en
type
label
Radiofrequency field-induced t ...... with fluorescent nanoparticles
@ast
Radiofrequency field-induced t ...... with fluorescent nanoparticles
@en
prefLabel
Radiofrequency field-induced t ...... with fluorescent nanoparticles
@ast
Radiofrequency field-induced t ...... with fluorescent nanoparticles
@en
P2860
P356
P1433
P1476
Radiofrequency field-induced t ...... with fluorescent nanoparticles
@en
P2093
Steven A Curley
P2860
P304
P356
10.1002/CNCR.25135
P407
P577
2010-07-01T00:00:00Z