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In‐Phase Ultra High‐Resolution In Vivo NMR

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Zeitschriftentitel: Angewandte Chemie
Personen und Körperschaften: Fugariu, Ioana, Bermel, Wolfgang, Lane, Daniel, Soong, Ronald, Simpson, Andre J.
In: Angewandte Chemie, 129, 2017, 22, S. 6421-6425
Format: E-Article
Sprache: Englisch
veröffentlicht:
Wiley
Schlagwörter:
General Medicine
author_facet Fugariu, Ioana
Bermel, Wolfgang
Lane, Daniel
Soong, Ronald
Simpson, Andre J.
Fugariu, Ioana
Bermel, Wolfgang
Lane, Daniel
Soong, Ronald
Simpson, Andre J.
author Fugariu, Ioana
Bermel, Wolfgang
Lane, Daniel
Soong, Ronald
Simpson, Andre J.
spellingShingle Fugariu, Ioana
Bermel, Wolfgang
Lane, Daniel
Soong, Ronald
Simpson, Andre J.
Angewandte Chemie
In‐Phase Ultra High‐Resolution In Vivo NMR
General Medicine
author_sort fugariu, ioana
spelling Fugariu, Ioana Bermel, Wolfgang Lane, Daniel Soong, Ronald Simpson, Andre J. 0044-8249 1521-3757 Wiley General Medicine http://dx.doi.org/10.1002/ange.201701097 <jats:title>Abstract</jats:title><jats:p>Although current NMR techniques allow organisms to be studied in vivo, magnetic susceptibility distortions, which arise from inhomogeneous distributions of chemical moieties, prevent the acquisition of high‐resolution NMR spectra. Intermolecular single quantum coherence (iSQC) is a technique that breaks the sample's spatial isotropy to form long range dipolar couplings, which can be exploited to extract chemical shift information free of perturbations. While this approach holds vast potential, present practical limitations include radiation damping, relaxation losses, and non‐phase sensitive data. Herein, these drawbacks are addressed, and a new technique termed in‐phase iSQC (IP‐iSQC) is introduced. When applied to a living system, high‐resolution NMR spectra, nearly identical to a buffer extract, are obtained. The ability to look inside an organism and extract a high‐resolution metabolic profile is profound and should find applications in fields in which metabolism or in vivo processes are of interest.</jats:p> In‐Phase Ultra High‐Resolution In Vivo NMR Angewandte Chemie
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title In‐Phase Ultra High‐Resolution In Vivo NMR
title_unstemmed In‐Phase Ultra High‐Resolution In Vivo NMR
title_full In‐Phase Ultra High‐Resolution In Vivo NMR
title_fullStr In‐Phase Ultra High‐Resolution In Vivo NMR
title_full_unstemmed In‐Phase Ultra High‐Resolution In Vivo NMR
title_short In‐Phase Ultra High‐Resolution In Vivo NMR
title_sort in‐phase ultra high‐resolution in vivo nmr
topic General Medicine
url http://dx.doi.org/10.1002/ange.201701097
publishDate 2017
physical 6421-6425
description <jats:title>Abstract</jats:title><jats:p>Although current NMR techniques allow organisms to be studied in vivo, magnetic susceptibility distortions, which arise from inhomogeneous distributions of chemical moieties, prevent the acquisition of high‐resolution NMR spectra. Intermolecular single quantum coherence (iSQC) is a technique that breaks the sample's spatial isotropy to form long range dipolar couplings, which can be exploited to extract chemical shift information free of perturbations. While this approach holds vast potential, present practical limitations include radiation damping, relaxation losses, and non‐phase sensitive data. Herein, these drawbacks are addressed, and a new technique termed in‐phase iSQC (IP‐iSQC) is introduced. When applied to a living system, high‐resolution NMR spectra, nearly identical to a buffer extract, are obtained. The ability to look inside an organism and extract a high‐resolution metabolic profile is profound and should find applications in fields in which metabolism or in vivo processes are of interest.</jats:p>
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author Fugariu, Ioana, Bermel, Wolfgang, Lane, Daniel, Soong, Ronald, Simpson, Andre J.
author_facet Fugariu, Ioana, Bermel, Wolfgang, Lane, Daniel, Soong, Ronald, Simpson, Andre J., Fugariu, Ioana, Bermel, Wolfgang, Lane, Daniel, Soong, Ronald, Simpson, Andre J.
author_sort fugariu, ioana
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container_title Angewandte Chemie
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description <jats:title>Abstract</jats:title><jats:p>Although current NMR techniques allow organisms to be studied in vivo, magnetic susceptibility distortions, which arise from inhomogeneous distributions of chemical moieties, prevent the acquisition of high‐resolution NMR spectra. Intermolecular single quantum coherence (iSQC) is a technique that breaks the sample's spatial isotropy to form long range dipolar couplings, which can be exploited to extract chemical shift information free of perturbations. While this approach holds vast potential, present practical limitations include radiation damping, relaxation losses, and non‐phase sensitive data. Herein, these drawbacks are addressed, and a new technique termed in‐phase iSQC (IP‐iSQC) is introduced. When applied to a living system, high‐resolution NMR spectra, nearly identical to a buffer extract, are obtained. The ability to look inside an organism and extract a high‐resolution metabolic profile is profound and should find applications in fields in which metabolism or in vivo processes are of interest.</jats:p>
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imprint Wiley, 2017
imprint_str_mv Wiley, 2017
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spelling Fugariu, Ioana Bermel, Wolfgang Lane, Daniel Soong, Ronald Simpson, Andre J. 0044-8249 1521-3757 Wiley General Medicine http://dx.doi.org/10.1002/ange.201701097 <jats:title>Abstract</jats:title><jats:p>Although current NMR techniques allow organisms to be studied in vivo, magnetic susceptibility distortions, which arise from inhomogeneous distributions of chemical moieties, prevent the acquisition of high‐resolution NMR spectra. Intermolecular single quantum coherence (iSQC) is a technique that breaks the sample's spatial isotropy to form long range dipolar couplings, which can be exploited to extract chemical shift information free of perturbations. While this approach holds vast potential, present practical limitations include radiation damping, relaxation losses, and non‐phase sensitive data. Herein, these drawbacks are addressed, and a new technique termed in‐phase iSQC (IP‐iSQC) is introduced. When applied to a living system, high‐resolution NMR spectra, nearly identical to a buffer extract, are obtained. The ability to look inside an organism and extract a high‐resolution metabolic profile is profound and should find applications in fields in which metabolism or in vivo processes are of interest.</jats:p> In‐Phase Ultra High‐Resolution In Vivo NMR Angewandte Chemie
spellingShingle Fugariu, Ioana, Bermel, Wolfgang, Lane, Daniel, Soong, Ronald, Simpson, Andre J., Angewandte Chemie, In‐Phase Ultra High‐Resolution In Vivo NMR, General Medicine
title In‐Phase Ultra High‐Resolution In Vivo NMR
title_full In‐Phase Ultra High‐Resolution In Vivo NMR
title_fullStr In‐Phase Ultra High‐Resolution In Vivo NMR
title_full_unstemmed In‐Phase Ultra High‐Resolution In Vivo NMR
title_short In‐Phase Ultra High‐Resolution In Vivo NMR
title_sort in‐phase ultra high‐resolution in vivo nmr
title_unstemmed In‐Phase Ultra High‐Resolution In Vivo NMR
topic General Medicine
url http://dx.doi.org/10.1002/ange.201701097