Exploiting level anti-crossings for efficient and selective transfer of hyperpolarization in coupled nuclear spin systems

Pravdivtsev, Andrey N.; Yurkovskaya, Alexandra V.; Kaptein, Robert; Miesel, K.; Vieth, Hans‐Martin; Ivanov, Konstantin L.

doi:10.1039/c3cp52026a

Cited by 31 publications

(38 citation statements)

References 46 publications

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“…Although this process is dynamic (in contrast to stochastic spin relaxation) it also relies on strong coupling (because polarization is evenly distributed among strongly coupled spins) and is particularly efficient at LACs. 30,[34][35][36][37][38][39] Thus, both concepts, strong coupling and LACs, are also of importance for other low-field NMR experiments.…”

Section: Discussionmentioning

confidence: 99%

High resolution NMR study of T1 magnetic relaxation dispersion. IV. Proton relaxation in amino acids and Met-enkephalin pentapeptide

Pravdivtsev

Yurkovskaya

Vieth

et al. 2014

The Journal of Chemical Physics

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Nuclear Magnetic Relaxation Dispersion (NMRD) of protons was studied in the pentapeptide Met-enkephalin and the amino acids, which constitute it. Experiments were run by using high-resolution Nuclear Magnetic Resonance (NMR) in combination with fast field-cycling, thus enabling measuring NMRD curves for all individual protons. As in earlier works, Papers I-III, pronounced effects of intramolecular scalar spin-spin interactions, J-couplings, on spin relaxation were found. Notably, at low fields J-couplings tend to equalize the apparent relaxation rates within networks of coupled protons. In Met-enkephalin, in contrast to the free amino acids, there is a sharp increase in the proton T1-relaxation times at high fields due to the changes in the regime of molecular motion. The experimental data are in good agreement with theory. From modelling the relaxation experiments we were able to determine motional correlation times of different residues in Met-enkephalin with atomic resolution. This allows us to draw conclusions about preferential conformation of the pentapeptide in solution, which is also in agreement with data from two-dimensional NMR experiments (rotating frame Overhauser effect spectroscopy). Altogether, our study demonstrates that high-resolution NMR studies of magnetic field-dependent relaxation allow one to probe molecular mobility in biomolecules with atomic resolution.

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Section: Discussionmentioning

confidence: 99%

High resolution NMR study of T1 magnetic relaxation dispersion. IV. Proton relaxation in amino acids and Met-enkephalin pentapeptide

Pravdivtsev

Yurkovskaya

Vieth

et al. 2014

The Journal of Chemical Physics

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“…2−4 In PHIP, detection of a product that contains two nuclei that were originally located in a single p -H 2 molecule is achieved and therefore a simultaneous change in the chemical identity is required. Nonetheless, this approach is very powerful, and detection of the true reaction intermediates has been achieved, 5−7 the development of NMR theoretical approaches facilitated, 8,9 and the monitoring of hydrogenation products in organic transformation enabled. 10,11 The latter situation has led to significant interest in PHIP as a tool for the in vivo monitoring of living systems.…”

Section: Introductionmentioning

confidence: 99%

Iridium(III) Hydrido N-Heterocyclic Carbene–Phosphine Complexes as Catalysts in Magnetization Transfer Reactions

et al. 2013

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The hyperpolarization (HP) method signal amplification by reversible exchange (SABRE) uses para-hydrogen to sensitize substrate detection by NMR. The catalyst systems [Ir(H)2(IMes)(MeCN)2(R)]BF4 and [Ir(H)2(IMes)(py)2(R)]BF4 [py = pyridine; R = PCy3 or PPh3; IMes = 1,3-bis(2,4,6-trimethylphenyl)imidazol-2-ylidene], which contain both an electron-donating N-heterocyclic carbene and a phosphine, are used here to catalyze SABRE. They react with acetonitrile and pyridine to produce [Ir(H)2(NCMe)(py)(IMes)(PPh3)]BF4 and [Ir(H)2(NCMe)(py)(IMes)(PCy3)]BF4, complexes that undergo ligand exchange on a time scale commensurate with observation of the SABRE effect, which is illustrated here by the observation of both pyridine and acetonitrile HP. In this study, the required symmetry breaking that underpins SABRE is provided for by the use of chemical inequivalence rather than the previously reported magnetic inequivalence. As a consequence, we show that the ligand sphere of the polarization transfer catalyst itself becomes hyperpolarized and hence that the high-sensitivity detection of a number of reaction intermediates is possible. These species include [Ir(H)2(NCMe)(py)(IMes)(PPh3)]BF4, [Ir(H)2(MeOH)(py)(IMes)(PPh3)]BF4, and [Ir(H)2(NCMe)(py)2(PPh3)]BF4. Studies are also described that employ the deuterium-labeled substrates CD3CN and C5D5N, and the labeled ligands P(C6D5)3 and IMes-d22, to demonstrate that dramatically improved levels of HP can be achieved as a consequence of reducing proton dilution and hence polarization wastage. By a combination of these studies with experiments in which the magnetic field experienced by the sample at the point of polarization transfer is varied, confirmation of the resonance assignments is achieved. Furthermore, when [Ir(H)2(pyridine-h5)(pyridine-d5)(IMes)(PPh3)]BF4 is examined, its hydride ligand signals are shown to become visible through para-hydrogen-induced polarization rather than SABRE.

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“…In these pairs, the states differ by projections of the H4-H7 and H5-H6 spins. For this reason, polarization exchange occurs predominantly within these pairs of spins; the coherences are excited by non-adiabatic passages through the corresponding LACs as has been shown before [77].…”

Section: E Polarization Transfer Among Strongly Coupled Spinsmentioning

confidence: 64%

“…Such a spin mixing is of coherent nature and it is mediated by zero-quantum coherences (ZQCs). Here we do not want to discuss all details of the transfer mechanism, as they can be found in previous publications [47,77]. We give only one example demonstrating advantages of our setup.…”

Section: E Polarization Transfer Among Strongly Coupled Spinsmentioning

confidence: 99%

“…The necessary prerequisites are: (i) spins are strongly coupled at the field where the spin mixing occurs and (ii) field variations are non-adiabatic. In two-spin ½ systems this method enables [47,77] complete transfer of net polarization between the spins; in higher-spin systems mixing of such a type usually occurs for pairs of levels, which have LACs at low fields, resulting in selective spin order transfer [47,78]. Although the formation of ZQCs requires relatively high field variation speed, it is feasible with our setup.…”

Section: E Polarization Transfer Among Strongly Coupled Spinsmentioning

confidence: 99%

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A fast field-cycling device for high-resolution NMR: Design and application to spin relaxation and hyperpolarization experiments

Kiryutin

Pravdivtsev

Ivanov

et al. 2016

Journal of Magnetic Resonance

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Exploiting level anti-crossings for efficient and selective transfer of hyperpolarization in coupled nuclear spin systems

Cited by 31 publications

References 46 publications

High resolution NMR study of T1 magnetic relaxation dispersion. IV. Proton relaxation in amino acids and Met-enkephalin pentapeptide

High resolution NMR study of T1 magnetic relaxation dispersion. IV. Proton relaxation in amino acids and Met-enkephalin pentapeptide

Iridium(III) Hydrido N-Heterocyclic Carbene–Phosphine Complexes as Catalysts in Magnetization Transfer Reactions

A fast field-cycling device for high-resolution NMR: Design and application to spin relaxation and hyperpolarization experiments

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