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Overhauser

Neuhaus D and Williamson M 1989 The Nuclear Overhauser Effect in Structural and Conformational Analysis (New York VCH)... [Pg.1464]

For large molecules, such as proteins, the main method in use is a 2D technique, called NOESY (nuclear Overhauser effect spectroscopy). The basic experiment [33, 34] consists of tluee 90° pulses. The first pulse converts die longitudinal magnetizations for all protons, present at equilibrium, into transverse magnetizations which evolve diirhig the subsequent evolution time In this way, the transverse magnetization components for different protons become labelled by their resonance frequencies. The second 90° pulse rotates the magnetizations to the -z-direction. [Pg.1510]

Noggle J H and Schirmer R E 1971 The Nuclear Overhauser Effect (New York Academic)... [Pg.1517]

Neuhaus D 1998 Nuclear Overhauser effect Encyclopedia of Nuclear Magnetic Resonance ed D M Grant and R K Harris (Chichester Wiley) pp 3290-301... [Pg.1517]

We make one important note here regarding nomenclature. Early explanations of CIDNP invoked an Overhauser-type mechanism, implying a dynamic process similar to spin relaxation hence the word dynamic m the CIDNP acronym. This is now known to be incorrect, but the acronym has prevailed in its infant fomi. [Pg.1591]

Floffman R A and Forsen S 1966 Transient and steady-state Overhauser experiments in the investigation of relaxation prooesses. Analogies between ohemioal exohange and relaxation J. Chem. Phys. 45 2049-60... [Pg.2113]

Sohaublin S, FIdhener A and Ernst R R 1974 Fourier speotrosoopy of non-equilibrium states. Applioation to CIDNP, Overhauser experiments and relaxation time measurements J. Magn. Reson. 13 196-216... [Pg.2113]

Dick B G and A W Overhauser 1958. Theory of the Dielectric Constants of Alkali Halide Crj stals. Physical Review 112 90-103. [Pg.267]

You can often use experimental data, such as Nuclear Overhauser Effect (NOE) signals from 2D NMR studies, as restraints. NOE signals give distances between pairs of hydrogens in a molecule. Use these distances to limit distances during a molecular mechanics geometry optimization or molecular dynamics calculation. Information on dihedral angles, deduced from NMR, can also limit a conformational search. [Pg.82]

The 2-D nuclear Overhauser effect spectroscopy (2-D-NOESY) experiment resembles the COSY however, the cross-peaks arise from... [Pg.408]

Another technique often used to examine the stmcture of double-heUcal oligonucleotides is two-dimensional nmr spectroscopy (see AfAGNETiC SPIN resonance). This method rehes on measurement of the nuclear Overhauser effects (NOEs) through space to determine the distances between protons (6). The stmcture of an oligonucleotide may be determined theoretically from a set of iaterproton distances. As a result of the complexities of the experiment and data analysis, the quality of the stmctural information obtained is debated. However, nmr spectroscopy does provide information pertaining to the stmcture of DNA ia solution and can serve as a complement to the stmctural information provided by crystallographic analysis. [Pg.250]

Nuclear Overhauser enhancement (NOE) spectroscopy has been used to measure the through-space interaction between protons at and the protons associated with the substituents at N (20). The method is also useful for distinguishing between isomers with different groups at and C. Reference 21 contains the chemical shifts and coupling constants of a considerable number of pyrazoles with substituents at N and C. NOE difference spectroscopy ( H) has been employed to differentiate between the two regioisomers [153076 5-0] (14) and [153076 6-1] (15) (22). N-nmr spectroscopy also has some utility in the field of pyrazoles and derivatives. [Pg.308]

N-protonation the absolute magnitude of the Ad values is larger than for Af-methylation <770MR(9)53>. Nuclear relaxation rates of and have been measured as a function of temperature for neat liquid pyridazine, and nuclear Overhauser enhancement has been used to separate the dipolar and spin rotational contributions to relaxation. Dipolar relaxation rates have been combined with quadrupole relaxation rates to determine rotational correlation times for motion about each principal molecular axis (78MI21200). NMR analysis has been used to determine the structure of phenyllithium-pyridazine adducts and of the corresponding dihydropyridazines obtained by hydrolysis of the adducts <78RTC116>. [Pg.8]

The nonnal mode NMR refinement method of Brueschweiler and Case [50] can be applied to experimentally measurable quantities such as order parameters or nuclear Overhauser spectroscopy (NOSEY) intensities. Unlike the X-ray case, the expression of these quanti-... [Pg.161]

Although experimental studies of DNA and RNA structure have revealed the significant structural diversity of oligonucleotides, there are limitations to these approaches. X-ray crystallographic structures are limited to relatively small DNA duplexes, and the crystal lattice can impact the three-dimensional conformation [4]. NMR-based structural studies allow for the determination of structures in solution however, the limited amount of nuclear overhauser effect (NOE) data between nonadjacent stacked basepairs makes the determination of the overall structure of DNA difficult [5]. In addition, nanotechnology-based experiments, such as the use of optical tweezers and atomic force microscopy [6], have revealed that the forces required to distort DNA are relatively small, consistent with the structural heterogeneity observed in both DNA and RNA. [Pg.441]

See other pages where Overhauser is mentioned: [Pg.289]    [Pg.1443]    [Pg.1460]    [Pg.1463]    [Pg.1502]    [Pg.1510]    [Pg.1511]    [Pg.2092]    [Pg.257]    [Pg.257]    [Pg.490]    [Pg.524]    [Pg.690]    [Pg.690]    [Pg.400]    [Pg.408]    [Pg.396]    [Pg.257]    [Pg.16]    [Pg.301]    [Pg.633]    [Pg.253]    [Pg.388]    [Pg.8]    [Pg.8]    [Pg.8]    [Pg.9]   
See also in sourсe #XX -- [ Pg.723 ]



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Application of the Nuclear Overhauser Effect

Carbon-13, Overhauser effect

Carbon-13, Overhauser effect spectroscopy

Chemically induced Overhauser experiments

Constraints from Nuclear Overhauser Effects

Contact nuclear Overhauser effects

Correlated spectroscopy nuclear Overhauser effect

Cross-Polarization Origin of the Nuclear Overhauser Effect

Dick-Overhauser shell model

Differential nuclear Overhauser effects

Gated decoupling, nuclear Overhauser effect

Gradient enhanced Overhauser effect spectroscopy

HOESY (Heteronuclear Overhauser

HOESY Overhauser enhancement

Heteronuclear Overhauser

Heteronuclear Overhauser SpectroscopY

Heteronuclear Overhauser SpectroscopY HOESY)

Heteronuclear Overhauser effect

Heteronuclear Overhauser effect pulse sequences

Heteronuclear Overhauser effect spectroscopy

Heteronuclear Overhauser enhancement

Heteronuclear Overhauser enhancement spectroscopy

Heteronuclear Overhauser experiment

Heteronuclear nuclear Overhauser

Heteronuclear nuclear Overhauser enhancement spectroscopy

Heteronuclear nuclear Overhauser principle

Homonuclear Overhauser enhancements

Induced nuclear-electron Overhauser experiments

Internal motion nuclear Overhauser effect

Magnetic resonance imaging Overhauser

Measurement of Nuclear Overhauser Enhancements

NMR spectroscopy nuclear Overhauser effect

NOE (nuclear Overhauser

NOE (nuclear Overhauser effect

NOE (nuclear Overhauser effect difference spectra

NOE (nuclear Overhauser effect suppression

NOESY (nuclear Overhauser enhancement

NOESY: nuclear Overhauser effect

Nuclear Overhauser

Nuclear Overhauser Effect (NOE) Difference Spectroscopy

Nuclear Overhauser Effect , hydration

Nuclear Overhauser Effect Difference Spectra

Nuclear Overhauser Effect assigning stereochemistry

Nuclear Overhauser Effect, Some Chemical Applications of (Bell and Saunders)

Nuclear Overhauser Enhancement Measurements

Nuclear Overhauser Enhancement cross peaks

Nuclear Overhauser effect

Nuclear Overhauser effect , NMR

Nuclear Overhauser effect 140. See

Nuclear Overhauser effect NOE difference

Nuclear Overhauser effect ROESY

Nuclear Overhauser effect analysis

Nuclear Overhauser effect and

Nuclear Overhauser effect carbonyl

Nuclear Overhauser effect chemical elucidation

Nuclear Overhauser effect conformational averaging

Nuclear Overhauser effect consequences

Nuclear Overhauser effect cross-relaxation

Nuclear Overhauser effect definition

Nuclear Overhauser effect description

Nuclear Overhauser effect difference

Nuclear Overhauser effect difference experiment

Nuclear Overhauser effect difference spectroscopy

Nuclear Overhauser effect distance constraints

Nuclear Overhauser effect distance dependence

Nuclear Overhauser effect dynamic

Nuclear Overhauser effect factor

Nuclear Overhauser effect feature

Nuclear Overhauser effect heteronuclear

Nuclear Overhauser effect homonuclear

Nuclear Overhauser effect intensity

Nuclear Overhauser effect interproton distances

Nuclear Overhauser effect kinetics

Nuclear Overhauser effect measurement, factor

Nuclear Overhauser effect mechanism

Nuclear Overhauser effect molecular motion

Nuclear Overhauser effect negative

Nuclear Overhauser effect positive

Nuclear Overhauser effect reaction

Nuclear Overhauser effect screening

Nuclear Overhauser effect sensitivity enhancement

Nuclear Overhauser effect simulations

Nuclear Overhauser effect single-frequency

Nuclear Overhauser effect spectra

Nuclear Overhauser effect spectroscopy Fourier transform

Nuclear Overhauser effect spectroscopy association

Nuclear Overhauser effect spectroscopy combination experiments

Nuclear Overhauser effect spectroscopy coupling constant determination

Nuclear Overhauser effect spectroscopy resonance

Nuclear Overhauser effect spectroscopy spin assignment

Nuclear Overhauser effect spin diffusion

Nuclear Overhauser effect steady-state

Nuclear Overhauser effect structural restraints

Nuclear Overhauser effect system

Nuclear Overhauser effect transferred

Nuclear Overhauser effect, removal

Nuclear Overhauser effects determination

Nuclear Overhauser enhancement

Nuclear Overhauser enhancement (nOe

Nuclear Overhauser enhancement constants

Nuclear Overhauser enhancement difference measurements

Nuclear Overhauser enhancement dipole interaction

Nuclear Overhauser enhancement effects

Nuclear Overhauser enhancement factor

Nuclear Overhauser enhancement mechanism

Nuclear Overhauser enhancement negative

Nuclear Overhauser enhancement positive

Nuclear Overhauser enhancement properties

Nuclear Overhauser enhancement proton decoupling

Nuclear Overhauser enhancement pulse sequence

Nuclear Overhauser enhancement relaxation

Nuclear Overhauser enhancement relaxation times

Nuclear Overhauser enhancement relaxation-rate measurements

Nuclear Overhauser enhancement spectra

Nuclear Overhauser enhancement spectroscopy

Nuclear Overhauser enhancement spectroscopy NOESY)

Nuclear Overhauser enhancement spectroscopy of conjugated dienes

Nuclear Overhauser enhancement spectroscopy of conjugated polyenes

Nuclear Overhauser enhancement spectroscopy of retinal Schiff bases

Nuclear Overhauser enhancement structure determination

Nuclear Overhauser experiment experimental method

Nuclear Overhauser experiments

Nuclear Overhauser spectra

Nuclear Overhauser spectroscopy (NOESY

Nuclear Quadrupole Relaxation and Overhauser Effect

Nuclear magnetic resonance Overhauser effect

Nuclear overhauser effect experiments

Nuclear overhauser effect measurements

Nuclear overhauser effect spectroscopy

Nuclear overhauser effect spectroscopy NOESY)

Nuclear overhauser effect spectroscopy structure determination

Nuclear overhauser effects NOEs)

Nuclear overhauser enhancement -based

Nuclear overhauser enhancement -based analysis

Nudear-Overhauser-effect

Overhauser DNP

Overhauser MRI

Overhauser dynamic nuclear polarization

Overhauser effect

Overhauser effect Paramagnetism

Overhauser effect parameters

Overhauser effect spectroscopic

Overhauser effect spectroscopic technique

Overhauser effect spectroscopy

Overhauser effect spectroscopy HOESY

Overhauser effect spectroscopy NOESY

Overhauser effect spectroscopy ROESY

Overhauser enhancement

Overhauser enhancement factor

Overhauser rate

Overhauser shift

Overhauser spectroscopy

Phosphorus-proton nuclear Overhauser effect

Polarization Transfer and the Nuclear Overhauser Effect

Poly nuclear Overhauser enhancement

Protein dynamics nuclear overhauser effect

ROESY (Rotating frame Overhauser Effect

ROESY (Rotation-frame Overhauser Effect

ROESY (rotating frame Overhauser enhanced

ROESY (rotating-frame nuclear Overhauser

ROESY Overhauser enhancement spectroscopy

ROESY- (rotating frame overhauser

ROESY- (rotating frame overhauser experiments

Rotating frame Overhauser

Rotating frame Overhauser effect

Rotating frame Overhauser effect spectroscopy

Rotating frame Overhauser effect spectroscopy (ROESY

Rotating frame Overhauser enhancement spectroscopy

Rotating frame Overhauser pulse sequence

Rotating frame nuclear Overhauser

Rotating frame nuclear Overhauser effect

Rotating frame nuclear Overhauser effect spectroscopy

Rotating frame nuclear Overhauser enhancement spectroscopy

Rotating-frame Overhauser enhancement

Rotating-frame Overhauser spectroscopy

Rotating-frame Overhauser spectroscopy ROESY)

Rotation-frame Overhauser Effect

Rotation-frame Overhauser Effect Spectroscopy

Sequential nuclear Overhauser effects

Spin polarization induced nuclear Overhauser

Spin polarization induced nuclear Overhauser effect

Structural information using overhauser

TWO-DIMENSIONAL NUCLEAR OVERHAUSER SPECTROSCOPY

The Homonuclear Nuclear Overhauser Effect (NOE)

The Nuclear Overhauser Effect (NOE)

The Nuclear Overhauser Effect and Associated Techniques

The Transferred Nuclear Overhauser Effect (trNOE)

The nuclear Overhauser effect

Through-space nuclear overhauser effect

TrNOE (transferred nuclear Overhauser

Transferred nuclear Overhauser effect trNOE)

Transient Overhauser

Transient Overhauser effect

Transient nuclear Overhauser effect

Two-dimensional nuclear Overhauser effect spectra

Two-dimensional, nuclear Overhauser

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