In vivo monitoring of pH, redox status, and glutathione using L-band EPR for assessment of therapeutic effectiveness in solid tumors. - Wikidata - awgldk - TriplyDB

In vivo monitoring of pH, redox status, and glutathione using L-band EPR for assessment of therapeutic effectiveness in solid tumors.

In vivo monitoring of pH, redox status, and glutathione using L-band EPR for assessment of therapeutic effectiveness in solid tumors.

http://www.wikidata.org/entity/Q35834783

about

Janus-faced tumor microenvironment and redox Interstitial Inorganic Phosphate as a Tumor Microenvironment Marker for Tumor Progression Nitroxyl radicals-modified dendritic poly(l-lysine) as a contrast agent for Overhauser-enhanced MRI.In vivo electron paramagnetic resonance oximetry and applications in the brain Involvement of tumor macrophage HIFs in chemotherapy effectiveness: mathematical modeling of oxygen, pH, and glutathione.Proton-Electron Double-Resonance Imaging of pH using phosphonated trityl probe.Redox-activated manganese-based MR contrast agent Methods for detection of mitochondrial and cellular reactive oxygen species.Nitrones reverse hyperglycemia-induced endothelial dysfunction in bovine aortic endothelial cells.Assessing Oxidative Stress in Tumors by Measuring the Rate of Hyperpolarized [1-13C]Dehydroascorbic Acid Reduction Using 13C Magnetic Resonance Spectroscopy.Orthogonal resonators for pulse in vivo electron paramagnetic imaging at 250 MHz Dual-function pH and oxygen phosphonated trityl probe.In vivo proton-electron double-resonance imaging of extracellular tumor pH using an advanced nitroxide probe.Phosphonated trityl probes for concurrent in vivo tissue oxygen and pH monitoring using electron paramagnetic resonance-based techniques.In vivo tumour extracellular pH monitoring using electron paramagnetic resonance: the effect of X-ray irradiation.Functional electron paramagnetic resonance imaging of ischemic rat heart: Monitoring of tissue oxygenation and pH.Fourier transform EPR spectroscopy of trityl radicals for multifunctional assessment of chemical microenvironment.Exchange Phenomena in the Electron Paramagnetic Resonance Spectra of the Nitroxyl and Trityl Radicals: Multifunctional Spectroscopy and Imaging of Local Chemical Microenvironment.Visualization of oxidative stress in ex vivo biopsies using electron paramagnetic resonance imaging.Noninvasive mapping of the redox status of dimethylnitrosamine-induced hepatic fibrosis using in vivo dynamic nuclear polarization-magnetic resonance imaging.Rapid Scan Electron Paramagnetic Resonance Opens New Avenues for Imaging Physiologically Important Parameters In Vivo.Spectral modeling for accelerated pH spectroscopy using EPR Imaging disulfide dinitroxides at 250 MHz to monitor thiol redox status.Imaging of nitroxides at 250MHz using rapid-scan electron paramagnetic resonance.Gear Up for a pH Shift: A Responsive Iron(II) 2-Amino-6-picolyl-Appended Macrocyclic paraCEST Agent That Protonates at a Pendent Group.Concurrent Longitudinal EPR Monitoring of Tissue Oxygenation, Acidosis, and Reducing Capacity in Mouse Xenograft Tumor Models.Imaging thiol redox status in murine tumors in vivo with rapid-scan electron paramagnetic resonance.In Vivo Application of Proton-Electron Double-Resonance Imaging.In vivo molecular EPR-based spectroscopy and imaging of tumor microenvironment and redox using functional paramagnetic probes.Cellular accumulation and antioxidant activity of acetoxymethoxycarbonyl pyrrolidine nitroxides.Designing Molecular Probes To Prolong Intracellular Retention: Application to Nitroxide Spin Probes.Contribution of Harold M. Swartz to In Vivo EPR and EPR Dosimetry.In vivo EPR extracellular pH-metry in tumors using a triphosphonated trityl radical.In Vivo EPR Assessment of pH, pO2, Redox Status, and Concentrations of Phosphate and Glutathione in the Tumor Microenvironment.

P2860

Q28390231-5B51E9FD-511A-445E-8ADA-FAD6221CA731 Q28818464-8098E07F-B460-4C07-BCEE-4CCA0CFBDC3F Q30840493-17126D7C-D5BD-4917-9CAC-E042387829CF Q33594541-636907A5-BD67-4061-9EE7-4B268ECF7D7F Q34306854-BDF19D95-34B4-48EA-B2AB-3D6FCB913748 Q34715470-0C6D9B22-FD20-40D8-9F07-A94FBDBD3209 Q36755361-4F2022A4-5310-4278-A641-71A78C7B7803 Q37460117-2D1F992F-4603-46A1-BA87-8B7526FA18C5 Q37595822-07FD821D-5581-46F2-B54C-5624A34A23DB Q37623373-B341F25E-E4FB-4F36-AF96-74836DA63DA5 Q37681833-C1C047CC-374C-4E65-B6BC-0E416BCFE9D4 Q37682657-5A7C023B-EBCF-41AB-8145-D587BB1CCA5A Q37694499-7E82A80F-1E17-4BA0-BDFB-CDFE1F819CD4 Q37695857-6A88B0AF-8090-4937-B939-9E4FDCCBEF93 Q38370504-77D01E61-CBCC-4236-A295-618E218594B2 Q38618957-67C2F755-5B5D-4F79-91B0-EA41D28F20A4 Q38730709-1B8FD44A-AFDF-48C0-9AEC-11A1484C10CD Q38737125-68824976-1259-495B-B34A-D83991A339E6 Q39206012-2725114A-75CE-4380-9524-AA18C4A731EE Q40554348-6A16E8D5-EBAA-430F-9492-D7E8FC576335 Q41689385-C27F80AA-37B3-42AE-B11A-800630323BA1 Q42161569-B3864032-2129-4D7D-97B0-C89712620C77 Q42698005-F3C13014-53BE-4CEA-BDA0-ACF36E3DD7F6 Q42719783-313E949B-2F9E-47EF-A3DD-3D5A535C3134 Q43760618-FAEDE901-9469-40AD-BCBE-9B05EFCDF99F Q45034289-67292CA8-B503-4DE7-9DED-C946966B59AD Q45050836-ACF68EBA-EE22-456E-B540-E2D6F12DE7C8 Q45069548-E06723A2-0212-43A7-B68A-B73307A5B53A Q45072821-46F2229A-3D02-4EA7-8126-C81CF6A2A37A Q47664376-84545906-2CF3-48E8-9595-8FECFBE13B6F Q48133139-CF122284-2022-40E7-83A1-68D724AAD79A Q48281913-5A5686E6-4D07-4976-BB74-4DF078F166BE Q53779091-20053F2D-2318-48EA-BBF6-0CABA988EFC6 Q53874571-818CF23B-F7E2-4686-9033-A22BBF4BB461

P2860

In vivo monitoring of pH, redox status, and glutathione using L-band EPR for assessment of therapeutic effectiveness in solid tumors.

http://www.wikidata.org/entity/Q35834783

description

2011 nî lūn-bûn

@nan

2011年の論文

@ja

2011年論文

@yue

2011年論文

@zh-hant

2011年論文

@zh-hk

2011年論文

@zh-mo

2011年論文

@zh-tw

2011年论文

@wuu

2011年论文

@zh

2011年论文

@zh-cn

name

In vivo monitoring of pH, redo ...... effectiveness in solid tumors.

@ast

In vivo monitoring of pH, redo ...... effectiveness in solid tumors.

@en

type

label

In vivo monitoring of pH, redo ...... effectiveness in solid tumors.

@ast

In vivo monitoring of pH, redo ...... effectiveness in solid tumors.

@en

prefLabel

In vivo monitoring of pH, redo ...... effectiveness in solid tumors.

@ast

In vivo monitoring of pH, redo ...... effectiveness in solid tumors.

@en

P1433

Q35834783-C89E869B-2EC3-4E30-ABFB-40291B0DF41D

P1476

Q35834783-B9B2E668-FD83-4C91-910D-562C7D25CB23

P2093

Q35834783-2108A795-C47D-4DD8-867A-07AB6876CDC6

Q35834783-2291501B-33D9-4B31-86D2-89DD17FA5FFA

Q35834783-382C866B-D9B1-4FE9-88C6-D66F77D0A973

Q35834783-3CBD78E9-2C71-4AD9-98D3-2F6676E69F69

Q35834783-3D6C1CC3-D10B-4D9D-A367-51F8752D52E2

Q35834783-62D953F2-49ED-4107-8F9C-98C82200016F

Q35834783-7A5E29BF-5CC7-4278-938B-EBDDD6D5F327

Q35834783-8ACA8752-A73F-4FD5-9EDA-AC1D0BDFEB04

Q35834783-DCF749CB-6EC1-40A0-9411-68C4AEC6EBD0

P2860

Q35834783-06792CC2-4847-4111-A105-0D83AD1239B2

Q35834783-1E2647C2-A2C7-4128-8136-D09F738EB334

Q35834783-2BC972FB-8A63-4ADD-BC14-60DD04D63339

Q35834783-2F4EB7BB-7ED5-4331-B67F-00A954E8A4B2

Q35834783-3CC2E471-463B-47AA-9CDF-DA555071119B

Q35834783-4BE2793B-876E-4A22-B1C9-EC6C74AC3730

Q35834783-5C658D25-E3BC-496F-9F63-411881041A18

Q35834783-5FF4FFBF-0B57-492C-B3CE-07631FBCC526

Q35834783-62F98396-83F4-492B-B481-3AA25E9B6EF4

Q35834783-77F85A89-8496-410C-8C7E-0EF0FBF4FC79

P304

Q35834783-3EA7112E-73CD-4B30-A510-A8CE4D4DAC93

P31

Q35834783-99C8B6C5-B69F-41DB-B96B-419D605815EB

P356

Q35834783-6CE5A5E0-0AD6-4758-862B-726A35992174

P433

Q35834783-DAF06A11-B4EC-4447-8041-068396E62927

P478

Q35834783-3245B00A-A01C-4081-8C0F-40520220B456

P50

Q35834783-24E9B354-1C22-48B3-8FEC-F65C9D62B931

Q35834783-76A22AA8-B275-428D-8A52-917582D3DA44

Q35834783-AF631A4A-7A8A-40C8-AE2C-4B69C718642C

P577

Q35834783-FE2B5EE0-561F-4C84-8B89-175F82C1090E

P5875

Q35834783-F6B4AAC9-9DDB-481F-B4BE-85ED64D90BC4

P698

Q35834783-DB8554DF-62B1-4965-97FD-A6A80DE7A9ED

P932

Q35834783-2525FB92-887F-467F-9F6C-B4E134467A98

P356

P1433

Magnetic Resonance in Medicine

P1476

In vivo monitoring of pH, redo ...... effectiveness in solid tumors

@en

P2093

Alexandre Samouilov

http://www.w3.org/2001/XMLSchema#string

Clay B Marsh

http://www.w3.org/2001/XMLSchema#string

Dmitrii G Trofimiov

http://www.w3.org/2001/XMLSchema#string

Jay L Zweier

http://www.w3.org/2001/XMLSchema#string

Jeffrey L Voorhees

http://www.w3.org/2001/XMLSchema#string

Olga V Efimova

http://www.w3.org/2001/XMLSchema#string

Sergey Petryakov

http://www.w3.org/2001/XMLSchema#string

Timothy D Eubank

http://www.w3.org/2001/XMLSchema#string

Valery V Khramtsov

http://www.w3.org/2001/XMLSchema#string

P2860

Hypoxia in cancer: significance and impact on clinical outcome

Redox environment of the cell as viewed through the redox state of the glutathione disulfide/glutathione couple

Repetitive tissue pO2 measurements by electron paramagnetic resonance oximetry: current status and future potential for experimental and clinical studies

EPR and DNP properties of certain novel single electron contrast agents intended for oximetric imaging.

Variable Field Proton-Electron Double-Resonance Imaging: Application to pH mapping of aqueous samples.

Bicarbonate increases tumor pH and inhibits spontaneous metastases.

Variable radio frequency proton-electron double-resonance imaging: application to pH mapping of aqueous samples.

Free radical imaging.

EPR and Quantum Chemical Studies of the pH-sensitive Imidazoline and Imidazolidine Nitroxides with Bulky Substituents.

Molecular mechanisms of resistance and toxicity associated with platinating agents.

P304

1827-1836

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1002/MRM.23196

http://www.w3.org/2001/XMLSchema#string

P433

6

http://www.w3.org/2001/XMLSchema#string

P478

67

http://www.w3.org/2001/XMLSchema#string

P50

Igor A Kirilyuk

P577

2011-11-23T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

51825433

http://www.w3.org/2001/XMLSchema#string

P698

22113626

http://www.w3.org/2001/XMLSchema#string

P932

3305854

http://www.w3.org/2001/XMLSchema#string