Exploration of the close chemical space of tryptophan and tyrosine reveals importance of hydrophobicity in CW-photo-CIDNP performances

Exploration of the close chemical space of tryptophan and tyrosine reveals importance of hydrophobicity in CW-photo-CIDNP performances

<p>Sensitivity being one of the main hurdles of nuclear magnetic resonance (NMR) can be gained by polarization techniques including chemically induced dynamic nuclear polarization (CIDNP). Kaptein demonstrated that the basic mechanism of the CIDNP arises from spin sorting based on coherent ele...

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Main Authors: F. Torres, A. Renn, R. Riek
Format: Article
Language:English
Published: Copernicus Publications 2021-05-01
Series:Magnetic Resonance
Online Access:https://mr.copernicus.org/articles/2/321/2021/mr-2-321-2021.pdf
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spelling doaj-78494e83e8c24ba79640b1f33832c8ee2021-08-02T21:57:34ZengCopernicus PublicationsMagnetic Resonance2699-00162021-05-01232132910.5194/mr-2-321-2021Exploration of the close chemical space of tryptophan and tyrosine reveals importance of hydrophobicity in CW-photo-CIDNP performancesF. TorresA. RennR. Riek<p>Sensitivity being one of the main hurdles of nuclear magnetic resonance (NMR) can be gained by polarization techniques including chemically induced dynamic nuclear polarization (CIDNP). Kaptein demonstrated that the basic mechanism of the CIDNP arises from spin sorting based on coherent electron–electron nuclear spin dynamics during the formation and the recombination of a radical pair in a magnetic field. In photo-CIDNP of interest here the radical pair is between a dye and the molecule to be polarized. Here, we explore continuous-wave (CW) photo-CIDNP (denoted CW-photo-CIDNP) with a set of 10 tryptophan and tyrosine analogues, many of them newly identified to be photo-CIDNP active, and we observe not only signal enhancement of 2 orders of magnitude for <span class="inline-formula"><sup>1</sup></span>H at 600 MHz (corresponding to 10 000 times in measurement time) but also reveal that polarization enhancement correlates with the hydrophobicity of the molecules. Furthermore, the small chemical library established indicates the existence of many photo-CIDNP-active molecules.</p>https://mr.copernicus.org/articles/2/321/2021/mr-2-321-2021.pdf
collection DOAJ
language English
format Article
sources DOAJ
author F. Torres
A. Renn
R. Riek
spellingShingle F. Torres
A. Renn
R. Riek
Exploration of the close chemical space of tryptophan and tyrosine reveals importance of hydrophobicity in CW-photo-CIDNP performances
Magnetic Resonance
author_facet F. Torres
A. Renn
R. Riek
author_sort F. Torres
title Exploration of the close chemical space of tryptophan and tyrosine reveals importance of hydrophobicity in CW-photo-CIDNP performances
title_short Exploration of the close chemical space of tryptophan and tyrosine reveals importance of hydrophobicity in CW-photo-CIDNP performances
title_full Exploration of the close chemical space of tryptophan and tyrosine reveals importance of hydrophobicity in CW-photo-CIDNP performances
title_fullStr Exploration of the close chemical space of tryptophan and tyrosine reveals importance of hydrophobicity in CW-photo-CIDNP performances
title_full_unstemmed Exploration of the close chemical space of tryptophan and tyrosine reveals importance of hydrophobicity in CW-photo-CIDNP performances
title_sort exploration of the close chemical space of tryptophan and tyrosine reveals importance of hydrophobicity in cw-photo-cidnp performances
publisher Copernicus Publications
series Magnetic Resonance
issn 2699-0016
publishDate 2021-05-01
description <p>Sensitivity being one of the main hurdles of nuclear magnetic resonance (NMR) can be gained by polarization techniques including chemically induced dynamic nuclear polarization (CIDNP). Kaptein demonstrated that the basic mechanism of the CIDNP arises from spin sorting based on coherent electron–electron nuclear spin dynamics during the formation and the recombination of a radical pair in a magnetic field. In photo-CIDNP of interest here the radical pair is between a dye and the molecule to be polarized. Here, we explore continuous-wave (CW) photo-CIDNP (denoted CW-photo-CIDNP) with a set of 10 tryptophan and tyrosine analogues, many of them newly identified to be photo-CIDNP active, and we observe not only signal enhancement of 2 orders of magnitude for <span class="inline-formula"><sup>1</sup></span>H at 600 MHz (corresponding to 10 000 times in measurement time) but also reveal that polarization enhancement correlates with the hydrophobicity of the molecules. Furthermore, the small chemical library established indicates the existence of many photo-CIDNP-active molecules.</p>
url https://mr.copernicus.org/articles/2/321/2021/mr-2-321-2021.pdf
work_keys_str_mv AT ftorres explorationoftheclosechemicalspaceoftryptophanandtyrosinerevealsimportanceofhydrophobicityincwphotocidnpperformances
AT arenn explorationoftheclosechemicalspaceoftryptophanandtyrosinerevealsimportanceofhydrophobicityincwphotocidnpperformances
AT rriek explorationoftheclosechemicalspaceoftryptophanandtyrosinerevealsimportanceofhydrophobicityincwphotocidnpperformances
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