Application of spin-echo nuclear magnetic resonance to whole-cell systems. Membrane transport. - Wikidata - awgldk - TriplyDB

Application of spin-echo nuclear magnetic resonance to whole-cell systems. Membrane transport.

Application of spin-echo nuclear magnetic resonance to whole-cell systems. Membrane transport.

http://www.wikidata.org/entity/Q42878841

about

Complete separation of intracellular and extracellular information in NMR spectra of perfused cells by diffusion-weighted spectroscopy Sewer pipe, wire, epoxy, and finger tapping: the start of fMRI at the Medical College of Wisconsin High resolution 1H n.m.r. studies of vertebrate blood and plasma 3H nuclear magnetic resonance study of anaerobic glycolysis in packed erythrocytes Comparative studies of water permeability of red blood cells from humans and over 30 animal species: an overview of 20 years of collaboration with Philip Kuchel.Magnetic relaxation in blood and blood clots.Human whole blood 1 H2 O transverse relaxation with gadolinium-based contrast reagents: Magnetic susceptibility and transmembrane water exchange.Transverse water relaxation in whole blood and erythrocytes at 3T, 7T, 9.4T, 11.7T and 16.4T; determination of intracellular hemoglobin and extracellular albumin relaxivities.Transverse relaxation of solvent protons induced by magnetized spheres: application to ferritin, erythrocytes, and magnetite.On the origin of paramagnetic inhomogeneity effects in whole blood.Does signal-attenuation on high-field T2-weighted MRI of the brain reflect regional cerebral iron deposition? Observations on the relationship between regional cerebral water proton T2 values and iron levels Bulk magnetic susceptibility shifts in NMR studies of compartmentalized samples: use of paramagnetic reagents.Oxygenation-sensitive contrast in magnetic resonance image of rodent brain at high magnetic fields.23Na and 39K nuclear magnetic resonance studies of perfused rat hearts. Discrimination of intra- and extracellular ions using a shift reagent Two-site exchange revisited: a new method for extracting exchange parameters in biological systems.Nuclear magnetic resonance spectroscopy in diagnostic and investigative medicine.Metabolic profiling, metabolomic and metabonomic procedures for NMR spectroscopy of urine, plasma, serum and tissue extracts.Probing lactate dehydrogenase activity in tumors by measuring hydrogen/deuterium exchange in hyperpolarized l-[1-(13)C,U-(2)H]lactate.Spin-echo proton NMR spectroscopy of urine samples. Water suppression via a urea-dependent T2 relaxation process.Studies of lactate dehydrogenase in the purified state and in intact erythrocytes.Studies of pyruvate-water isotope exchange catalysed by erythrocytes and proteins.Effects of hyperoxia on T2* and resonance frequency weighted magnetic resonance images of rodent tumours.Aqueous shift reagents for high-resolution cation NMR. VI. Titration curves for in vivo 23Na and 1H2O MRS obtained from rat blood.High-resolution 1H nuclear magnetic resonance study of cerebral hypoxia in vivo.NMR methods for measuring membrane transport rates.NMR studies of kinetics in cells and tissues.Glyoxalase I: mechanism-based inhibitors.The application of nuclear magnetic resonance to the study of cellular physiology.Application of in vivo NMR spectroscopy to cancer.Monocarboxylate transport in erythrocytes.Quantification of tumor tissue populations by multispectral analysis.Transport of lactate and other monocarboxylates across mammalian plasma membranes.Characterization of a microcarrier cell culture system for 23Na MR spectroscopy studies.A biochemical and NMR spectroscopic study of hydrazine in the isolated rat hepatocyte.A 1H n.m.r. study of isotope exchange catalysed by glycolytic enzymes in the human erythrocyte.Compartmentation of cerebral glutamate in situ as detected by 1H/13C n.m.r.Conflicting evidence regarding the transport of alpha-glutamyl-dipeptides by human erythrocytes.Incorporation of labelled glycine into reduced glutathione of intact human erythrocytes by enzyme-catalysed exchange. A nuclear-magnetic-resonance study.A p.m.r. isotope-exchange method for studying the kinetic properties of dehydrogenases in intact cells.The use of 1H spin echo NMR and HPLC to confirm doxorubicin induced depletion of glutathione in the intact HeLa cell.

P2860

Q24563568-70B85784-6295-4E51-AE0F-2C82C80CEBF0 Q26824650-8E97C352-647E-47B8-BF74-ADED5A3018E0 Q28366574-CE66B437-DB0C-4F1C-9D05-90F4E63878F0 Q30570364-6E712EED-78DA-4519-A475-4E4E8A20AEF1 Q30574948-43918026-F2C7-4908-868C-BA3424897857 Q30579396-0A883758-DEE2-4658-9E62-704B9D96869E Q31107900-08EFF769-AA01-4964-A461-A5052AACFD0A Q31150067-F483730D-6A48-4520-BF82-5869FA7EA1E4 Q31168797-2287D19F-0700-47BE-90B2-23396FCC0FAF Q33238555-214FB3D7-FEB2-4AB6-9C7C-2AA7DB6C0CEC Q33630181-8EB5FB99-0388-4B66-9AD3-CA384AD0AC85 Q33895688-79975AAC-099A-4BAA-888A-893A5B25AB74 Q33914577-F5F07CDD-2218-4B1E-9712-4658D2477DD4 Q34257110-E2AB10B8-8FB0-430C-8574-119C20CD1DF9 Q34261174-DD1D82C9-EC0E-42F5-8EDF-2332211C69C7 Q34616023-A982D9BC-D841-4653-B805-A78F590F2A06 Q34714204-0F1AE87D-477A-4C61-A9B7-D154EE19A993 Q35828620-E92AEB63-FC4E-47C4-867D-6D2782290A54 Q36467900-619A5C74-552B-4A5D-B6C2-877FD3E76438 Q36646974-520837E0-9A04-4329-B739-EBDF69ADC457 Q36660389-FED8C9AF-009A-48DA-AA85-38A4C327C924 Q36738061-7579C977-CFD8-4F9C-9CA1-E297A5941446 Q36778640-087DAA34-EF2E-40A1-9E34-9134135BAA50 Q37345616-E8BF3E81-3C11-42BE-AD47-DEA498BCDAB8 Q38001057-6F60768B-AE07-4419-84C3-41D4916C4247 Q39671531-322C54A9-A3A3-4A86-9220-9480654CA53E Q40157890-27788848-79DC-4ABD-B3A3-222132DCA23A Q40169742-90050AB8-86A4-464E-865B-43292F1A8D53 Q40205675-E3BB2684-1D03-4B5C-BB92-275401AD59E6 Q40255281-4D28095A-E258-46A8-A3FA-F1B53B83664E Q40581417-90DCF8B4-8404-4E0C-8376-3505E1F371EB Q40897800-596B0F7D-27E2-4A78-91CF-15ADCD51E6A0 Q41663381-234FA305-408B-4233-BF09-24F7FAFB3579 Q42129853-D2E3CE80-4DF6-4CAB-9138-A8286687F494 Q42160811-5D1AEC4F-5A15-4855-8FF8-E9D4EB0712D4 Q42833543-B726D6B0-721C-4351-8516-08FCE66C697F Q42855507-D08CB7E8-5649-415F-8400-1A213F55B618 Q42868794-401EB0AC-8D55-49BE-B293-DF3C385BDC0E Q42874571-5E04A836-A10F-489A-B062-F43140E90421 Q43050129-203128D7-9353-4853-B135-B4FA732AAC8F

P2860

Application of spin-echo nuclear magnetic resonance to whole-cell systems. Membrane transport.

http://www.wikidata.org/entity/Q42878841

description

1979 nî lūn-bûn

@nan

1979年の論文

@ja

1979年論文

@yue

1979年論文

@zh-hant

1979年論文

@zh-hk

1979年論文

@zh-mo

1979年論文

@zh-tw

1979年论文

@wuu

1979年论文

@zh

1979年论文

@zh-cn

name

Application of spin-echo nucle ...... l systems. Membrane transport.

@en

Application of spin-echo nucle ...... l systems. Membrane transport.

@nl

type

label

Application of spin-echo nucle ...... l systems. Membrane transport.

@en

Application of spin-echo nucle ...... l systems. Membrane transport.

@nl

prefLabel

Application of spin-echo nucle ...... l systems. Membrane transport.

@en

Application of spin-echo nucle ...... l systems. Membrane transport.

@nl

P1433

Q42878841-003919E7-AA02-4D53-9913-D4A74F118613

P1476

Q42878841-DD4EF7C9-E3DD-4508-BC2D-CF475E95B840

P2093

Q42878841-1C28166D-F5B4-4FA8-AED7-1D2990B0816A

Q42878841-58B0E240-5617-4662-8894-2C7D9CF57162

Q42878841-678C6DBD-379F-4FE1-B632-B6B11525A68F

Q42878841-99056B14-774E-4956-9B63-3BAACE9E9C1F

Q42878841-A10CF928-5A05-4872-954E-7BD8B30E779B

P2860

Q42878841-054F7A14-CF4C-4406-80F2-1645A6CAAB67

Q42878841-08FDA50F-586C-4B9F-B11A-F160DEF92A68

Q42878841-4483428C-623F-4B9A-A687-099218D2D1CB

Q42878841-4EA0A71B-D512-4115-A65B-7AD82ABF758F

Q42878841-513718B1-01E4-4F4B-B194-9049937BC50D

Q42878841-51604312-5659-412E-A780-5056C249CA26

Q42878841-52D43332-AB2C-4055-BD6C-BFC10FE29C8C

Q42878841-96C57C27-FA4C-42F4-9BE7-1C087A2B0086

Q42878841-9DB2956E-5452-4302-9828-F58FD9C8546B

Q42878841-9F3D6B7F-2CB8-4EC2-BBBB-1E101148F81D

P304

Q42878841-0C7A238C-1572-41BD-B2C9-0E783980073B

P31

Q42878841-84647B4D-B59D-4F02-94E9-A11B6F1B6DF3

P356

Q42878841-8358E16F-0A3C-492B-B5C8-261616EE6951

P407

Q42878841-E642C8E8-81D9-4462-AF42-9F7DDC956B6F

P433

Q42878841-54B5FAB9-7DB6-40B8-99BE-292C7F587D1E

P478

Q42878841-74A3DD7D-2ECE-4301-8D33-3F2311A9689A

P577

Q42878841-48AB20E6-FC63-4295-88D7-E4CC50E768CA

P5875

Q42878841-880363A4-78E1-4592-9EC8-B3E15BB4DF08

P698

Q42878841-69547216-5C1C-4EA1-B1D9-A86B58E8F286

P932

Q42878841-A032BB33-47F2-4297-8B38-5B95350DA524

P356

P1433

Biochemical Journal

P1476

Application of spin-echo nucle ...... l systems. Membrane transport.

@en

P2093

Brindle KM

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

Brown FF

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

Campbell ID

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

Grathwohl C

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

Kuchel PW

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

P2860

NMR study of -17-O from H2-17-O in human erythrocytes.

Phosphate metabolites in lymphoid, Friend erythroleukemia, and HeLa cells observed by high-resolution 31P nuclear magnetic resonance.

The effect of the unstirred layer on human red cell water permeability.

Water diffusion permeability of erythrocytes using an NMR technique.

Determination of intracellular pH by 31P magnetic resonance.

NMR studies of pH-induced transport of carboxylic acids across phospholipid vesicle membranes.

Human erythrocyte metabolism studies by 1H spin echo NMR.

NMR kinetic studies of the ionophore X-537A-mediated transport of manganous ions across phospholipid bilayers.

Kinetics of ionophore-mediated transport of Pr3+ ions through phospholipid membranes using 1h NMR spectroscopy.

Pulse methods for the simplification of protein NMR spectra.

P304

37-44

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

P31

scholarly article

P356

10.1042/BJ1800037

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

P407

P433

1

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

P478

180

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

P577

1979-04-01T00:00:00Z

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

P5875

22656386

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

P698

486105

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

P932

1161016

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