about
Noble metal nanoparticles applications in cancerMultifunctional iron oxide nanoparticles for diagnostics, therapy and macromolecule deliveryResonant vortex-core reversal in magnetic nano-spheres as robust mechanism of efficient energy absorption and emission.TiO2 nanotube platforms for smart drug delivery: a reviewHyperthermia using nanoparticles--Promises and pitfalls.In vitro controlled release of cisplatin from gold-carbon nanobottles via cleavable linkagesModelling mass and heat transfer in nano-based cancer hyperthermiaA radio-frequency coupling network for heating of citrate-coated gold nanoparticles for cancer therapy: design and analysis.Externally modulated theranostic nanoparticlesPlasmonic nanobubbles enhance efficacy and selectivity of chemotherapy against drug-resistant cancer cells.Plasmonic nanobubbles rapidly detect and destroy drug-resistant tumorsSuperparamagnetic iron oxide nanoparticles: magnetic nanoplatforms as drug carriers.The ongoing history of thermal therapy for cancerRainbow Plasmonic Nanobubbles: Synergistic Activation of Gold Nanoparticle Clusters.Tunable plasmonic nanoprobes for theranostics of prostate cancer.Inorganic nanocrystals as contrast agents in MRI: synthesis, coating and introduction of multifunctionality.Application of iron oxide nanoparticles in glioma imaging and therapy: from bench to bedside.Morphological effect of oscillating magnetic nanoparticles in killing tumor cells.Non-invasive radiofrequency ablation of malignancies mediated by quantum dots, gold nanoparticles and carbon nanotubes.Beating cancer in multiple ways using nanogold.Thermal enhancement with optically activated gold nanoshells sensitizes breast cancer stem cells to radiation therapyThe potential of nanomedicine therapies to treat neovascular disease in the retina.Core-shell nanoparticle-based peptide therapeutics and combined hyperthermia for enhanced cancer cell apoptosis.HSP70 promoter-driven activation of gene expression for immunotherapy using gold nanorods and near infrared light.Characterizing the localized surface plasmon resonance behaviors of Au nanorings and tracking their diffusion in bio-tissue with optical coherence tomography.Design maps for the hyperthermic treatment of tumors with superparamagnetic nanoparticles.Temperature-dependent and time-dependent effects of hyperthermia mediated by dextran-coated La0.7Sr0.3MnO3: in vitro studiesMulti-photon excited luminescence of magnetic FePt core-shell nanoparticles.Radio frequency radiation-induced hyperthermia using Si nanoparticle-based sensitizers for mild cancer therapy.Polysaccharide-Coated Magnetic Nanoparticles for Imaging and Gene Therapy.Metal nanoparticle-induced micronuclei and oxidative DNA damage in mice.Nitric oxide release: part I. Macromolecular scaffoldsThree strategies to stabilise nearly monodispersed silver nanoparticles in aqueous solution.Nanotechnology-based approaches in anticancer researchRadiofrequency heating pathways for gold nanoparticles.Magnetic fluid hyperthermia induced by radiofrequency capacitive field for the treatment of transplanted subcutaneous tumors in ratsNew bipolar tissue ligator combines constant tissue compression and temperature guidance: histologic study and implications for treatment of hemorrhoids.Tailoring nanoparticle designs to target cancer based on tumor pathophysiology.Hyperthermia mediated by dextran-coated La0.7Sr0.3MnO3 nanoparticles: in vivo studies.Hyperthermia sensitizes Rhizopus oryzae to posaconazole and itraconazole action through apoptosis.
P2860
Q21284977-02E267D8-73C6-446D-8AAB-5E5D1897582FQ26830434-F833652B-F1FE-459E-8F7D-B8BF843ABA4AQ27317559-401A94C7-B0B6-4D73-83AC-5753721C94EDQ28066800-E7D57F78-2C80-4A63-A5F0-48CDFFF343E6Q28384618-D715014A-FAE0-4954-A7FF-387DE44E7F25Q28397158-3722F2CD-7F25-4952-A719-CFD57DFB843FQ28608079-5B9F5259-5DBD-4AA9-A0DA-06A37BB4ED72Q30426213-F4748FA8-1BB3-4543-8582-299B6A385427Q30438597-71BB2DF6-9288-4DD1-8E3B-364E4C5D47F2Q30451813-C405DA4B-3A3D-42BC-BD95-812485FB33E5Q30461227-E7E79A8D-BB92-40CF-8284-8C4A9BC848D9Q30465367-ABD3911C-9585-491A-BBAF-C31033C7B7D1Q30469171-A6A5F553-195A-42D7-BA20-5400E2656EF5Q30474726-4E9C3E33-4A34-4BC8-9DBF-167455910C47Q30475573-D3A0B10C-93F2-48BC-B339-994BC753DF6DQ30585395-70BC3740-B112-46E5-9681-D8123B8CD22BQ31065446-23E7EC8C-75C1-4B0D-852C-B4FBA980F30BQ33603783-E91237AB-7212-4396-9297-3A39095C2756Q33874638-1F7B71E2-A8C8-498C-B9A6-8003E5592F8BQ33918483-AC458B07-2604-4059-8C16-22C23F13A210Q34008528-869BD126-4894-4CF2-950F-E43F0630CF28Q34220590-F83EBD98-60E2-42CE-BB4E-786BC1F8100AQ34239163-B5A02B20-DCAF-4340-9107-C5F1C2FE5327Q34350680-FB7B924E-1671-4CC3-AD11-EA4110194194Q34476428-8DAD9DDD-56A1-459D-B026-AED98EA232A5Q34603392-37CD81A5-8932-4D4A-B87F-BCE374AF30D7Q35137269-151DD736-7E97-4FE0-AC22-069516537C94Q35214793-72412F15-A164-47E0-A05A-7B204248BE9AQ35415508-4537C278-E12D-4AFA-A71C-A8DFC81A6282Q35674709-CEFE631A-114E-44CE-A754-C280113570CAQ35906927-3F427400-0A48-4A24-98B7-704E3F6A9E19Q35926045-2C3E09AB-ED9F-46D0-AB0E-E8F863D3883FQ35955422-9CFD6478-B4CD-47DE-8276-251D58E9524BQ36168983-21FFAAB6-629F-4B34-834C-9D85753BF25DQ36219041-60E6C392-6D76-4B49-B727-2D9A4D0A4006Q36224797-D2014F74-EF91-40AE-AFCD-D09693749BCFQ36395652-089DE966-C193-40A4-A52E-7B3D49C26090Q36659002-CD650933-EFE5-4BCA-9187-C4AC61412C22Q36861918-3B14C80A-9631-4CEC-A013-08639B985B2EQ37124159-D0F8455D-740B-4EB0-B32C-0D52ED2D8E45
P2860
description
2009 nî lūn-bûn
@nan
2009年の論文
@ja
2009年学术文章
@wuu
2009年学术文章
@zh-cn
2009年学术文章
@zh-hans
2009年学术文章
@zh-my
2009年学术文章
@zh-sg
2009年學術文章
@yue
2009年學術文章
@zh
2009年學術文章
@zh-hant
name
Targeted hyperthermia using metal nanoparticles.
@en
Targeted hyperthermia using metal nanoparticles.
@nl
type
label
Targeted hyperthermia using metal nanoparticles.
@en
Targeted hyperthermia using metal nanoparticles.
@nl
prefLabel
Targeted hyperthermia using metal nanoparticles.
@en
Targeted hyperthermia using metal nanoparticles.
@nl
P2093
P2860
P1476
Targeted hyperthermia using metal nanoparticles.
@en
P2093
Evan S Glazer
Paul Cherukuri
Steven A Curley
P2860
P304
P356
10.1016/J.ADDR.2009.11.006
P407
P577
2009-11-10T00:00:00Z