Magnetically Induced Alignment of Natural Products for Stereochemical Structure Determination via NMR

Anisotropic NMR has gained increasing popularity to determine the structure and specifically the configuration of small, flexible, non‐crystallizable molecules. However, it suffers from the necessity to dissolve the analyte in special media such as liquid crystals or polymer gels. Generally, small d...

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Veröffentlicht in:	Angewandte Chemie International Edition 2020-09, Vol.59 (37), p.15860-15864
Hauptverfasser:	Karschin, Niels, Wolkenstein, Klaus, Griesinger, Christian
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Sprache:	eng
Schlagworte:	Alignment anisotropic NMR parameters Anisotropy Biological Products - chemistry Chemical equilibrium Communication Communications configuration determination Configurations Couplings Crystals density functional calculations Density functional theory Gels Liquid crystals Magnetic permeability Magnetic Resonance Spectroscopy - methods Magnetic susceptibility magnetically induced alignment Magnetics Natural products NMR NMR spectroscopy Nuclear magnetic resonance Polymer gels Polymers Sample preparation Stereoisomerism Strychnine
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creator	Karschin, Niels Wolkenstein, Klaus Griesinger, Christian
description	Anisotropic NMR has gained increasing popularity to determine the structure and specifically the configuration of small, flexible, non‐crystallizable molecules. However, it suffers from the necessity to dissolve the analyte in special media such as liquid crystals or polymer gels. Generally, small degrees of alignment are also caused by an anisotropic magnetic susceptibility of the molecule, for example, induced by aromatic moieties. For this mechanism, the alignment can be predicted via density functional theory. Here we show that both residual dipolar couplings and residual chemical shift anisotropies can be acquired from natural products without special sample preparation using magnetically induced alignment. On the two examples of the novel natural product gymnochrome G and the alkaloid strychnine, these data, together with the predicted alignment, yield the correct configuration with high certainty. Properly aligned: Residual dipolar couplings and residual chemical shift anisotropies can be acquired from natural products without special sample preparation using magnetically induced alignment. On the basis of two examples—the novel natural product gymnochrome G and the alkaloid strychnine—these data, together with the predicted alignment, yield the correct configuration with high certainty.
doi_str_mv	10.1002/anie.202004881
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However, it suffers from the necessity to dissolve the analyte in special media such as liquid crystals or polymer gels. Generally, small degrees of alignment are also caused by an anisotropic magnetic susceptibility of the molecule, for example, induced by aromatic moieties. For this mechanism, the alignment can be predicted via density functional theory. Here we show that both residual dipolar couplings and residual chemical shift anisotropies can be acquired from natural products without special sample preparation using magnetically induced alignment. On the two examples of the novel natural product gymnochrome G and the alkaloid strychnine, these data, together with the predicted alignment, yield the correct configuration with high certainty. Properly aligned: Residual dipolar couplings and residual chemical shift anisotropies can be acquired from natural products without special sample preparation using magnetically induced alignment. 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subjects	Alignment anisotropic NMR parameters Anisotropy Biological Products - chemistry Chemical equilibrium Communication Communications configuration determination Configurations Couplings Crystals density functional calculations Density functional theory Gels Liquid crystals Magnetic permeability Magnetic Resonance Spectroscopy - methods Magnetic susceptibility magnetically induced alignment Magnetics Natural products NMR NMR spectroscopy Nuclear magnetic resonance Polymer gels Polymers Sample preparation Stereoisomerism Strychnine
title	Magnetically Induced Alignment of Natural Products for Stereochemical Structure Determination via NMR
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