Using a whole-body (31)P birdcage transmit coil and 16-element receive array for human cardiac metabolic imaging at 7T

PURPOSE: Cardiac phosphorus magnetic resonance spectroscopy ((31)P-MRS) provides unique insight into the mechanisms of heart failure. Yet, clinical applications have been hindered by the restricted sensitivity of the surface radiofrequency-coils normally used. These permit the analysis of spectra on...

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Autores principales: Valkovič, Ladislav, Dragonu, Iulius, Almujayyaz, Salam, Batzakis, Alex, Young, Liam A. J., Purvis, Lucian A. B., Clarke, William T., Wichmann, Tobias, Lanz, Titus, Neubauer, Stefan, Robson, Matthew D., Klomp, Dennis W. J., Rodgers, Christopher T.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2017
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5658155/
https://www.ncbi.nlm.nih.gov/pubmed/29073228
http://dx.doi.org/10.1371/journal.pone.0187153
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author Valkovič, Ladislav
Dragonu, Iulius
Almujayyaz, Salam
Batzakis, Alex
Young, Liam A. J.
Purvis, Lucian A. B.
Clarke, William T.
Wichmann, Tobias
Lanz, Titus
Neubauer, Stefan
Robson, Matthew D.
Klomp, Dennis W. J.
Rodgers, Christopher T.
author_facet Valkovič, Ladislav
Dragonu, Iulius
Almujayyaz, Salam
Batzakis, Alex
Young, Liam A. J.
Purvis, Lucian A. B.
Clarke, William T.
Wichmann, Tobias
Lanz, Titus
Neubauer, Stefan
Robson, Matthew D.
Klomp, Dennis W. J.
Rodgers, Christopher T.
author_sort Valkovič, Ladislav
collection PubMed
description PURPOSE: Cardiac phosphorus magnetic resonance spectroscopy ((31)P-MRS) provides unique insight into the mechanisms of heart failure. Yet, clinical applications have been hindered by the restricted sensitivity of the surface radiofrequency-coils normally used. These permit the analysis of spectra only from the interventricular septum, or large volumes of myocardium, which may not be meaningful in focal disease. Löring et al. recently presented a prototype whole-body (52 cm diameter) transmit/receive birdcage coil for (31)P at 7T. We now present a new, easily-removable, whole-body (31)P transmit radiofrequency-coil built into a patient-bed extension combined with a 16-element receive array for cardiac (31)P-MRS. MATERIALS AND METHODS: A fully-removable (55 cm diameter) birdcage transmit coil was combined with a 16-element receive array on a Magnetom 7T scanner (Siemens, Germany). Electro-magnetic field simulations and phantom tests of the setup were performed. In vivo maps of B(1)(+), metabolite signals, and saturation-band efficiency were acquired across the torsos of eight volunteers. RESULTS: The combined (volume-transmit, local receive array) setup increased signal-to-noise ratio 2.6-fold 10 cm below the array (depth of the interventricular septum) compared to using the birdcage coil in transceiver mode. The simulated coefficient of variation for B(1)(+) of the whole-body coil across the heart was 46.7% (surface coil 129.0%); and the in vivo measured value was 38.4%. Metabolite images of 2,3-diphosphoglycerate clearly resolved the ventricular blood pools, and muscle tissue was visible in phosphocreatine (PCr) maps. Amplitude-modulated saturation bands achieved 71±4% suppression of phosphocreatine PCr in chest-wall muscles. Subjects reported they were comfortable. CONCLUSION: This easy-to-assemble, volume-transmit, local receive array coil combination significantly improves the homogeneity and field-of-view for metabolic imaging of the human heart at 7T.
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spelling pubmed-56581552017-11-09 Using a whole-body (31)P birdcage transmit coil and 16-element receive array for human cardiac metabolic imaging at 7T Valkovič, Ladislav Dragonu, Iulius Almujayyaz, Salam Batzakis, Alex Young, Liam A. J. Purvis, Lucian A. B. Clarke, William T. Wichmann, Tobias Lanz, Titus Neubauer, Stefan Robson, Matthew D. Klomp, Dennis W. J. Rodgers, Christopher T. PLoS One Research Article PURPOSE: Cardiac phosphorus magnetic resonance spectroscopy ((31)P-MRS) provides unique insight into the mechanisms of heart failure. Yet, clinical applications have been hindered by the restricted sensitivity of the surface radiofrequency-coils normally used. These permit the analysis of spectra only from the interventricular septum, or large volumes of myocardium, which may not be meaningful in focal disease. Löring et al. recently presented a prototype whole-body (52 cm diameter) transmit/receive birdcage coil for (31)P at 7T. We now present a new, easily-removable, whole-body (31)P transmit radiofrequency-coil built into a patient-bed extension combined with a 16-element receive array for cardiac (31)P-MRS. MATERIALS AND METHODS: A fully-removable (55 cm diameter) birdcage transmit coil was combined with a 16-element receive array on a Magnetom 7T scanner (Siemens, Germany). Electro-magnetic field simulations and phantom tests of the setup were performed. In vivo maps of B(1)(+), metabolite signals, and saturation-band efficiency were acquired across the torsos of eight volunteers. RESULTS: The combined (volume-transmit, local receive array) setup increased signal-to-noise ratio 2.6-fold 10 cm below the array (depth of the interventricular septum) compared to using the birdcage coil in transceiver mode. The simulated coefficient of variation for B(1)(+) of the whole-body coil across the heart was 46.7% (surface coil 129.0%); and the in vivo measured value was 38.4%. Metabolite images of 2,3-diphosphoglycerate clearly resolved the ventricular blood pools, and muscle tissue was visible in phosphocreatine (PCr) maps. Amplitude-modulated saturation bands achieved 71±4% suppression of phosphocreatine PCr in chest-wall muscles. Subjects reported they were comfortable. CONCLUSION: This easy-to-assemble, volume-transmit, local receive array coil combination significantly improves the homogeneity and field-of-view for metabolic imaging of the human heart at 7T. Public Library of Science 2017-10-26 /pmc/articles/PMC5658155/ /pubmed/29073228 http://dx.doi.org/10.1371/journal.pone.0187153 Text en © 2017 Valkovič et al http://creativecommons.org/licenses/by/4.0/ This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/) , which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
spellingShingle Research Article
Valkovič, Ladislav
Dragonu, Iulius
Almujayyaz, Salam
Batzakis, Alex
Young, Liam A. J.
Purvis, Lucian A. B.
Clarke, William T.
Wichmann, Tobias
Lanz, Titus
Neubauer, Stefan
Robson, Matthew D.
Klomp, Dennis W. J.
Rodgers, Christopher T.
Using a whole-body (31)P birdcage transmit coil and 16-element receive array for human cardiac metabolic imaging at 7T
title Using a whole-body (31)P birdcage transmit coil and 16-element receive array for human cardiac metabolic imaging at 7T
title_full Using a whole-body (31)P birdcage transmit coil and 16-element receive array for human cardiac metabolic imaging at 7T
title_fullStr Using a whole-body (31)P birdcage transmit coil and 16-element receive array for human cardiac metabolic imaging at 7T
title_full_unstemmed Using a whole-body (31)P birdcage transmit coil and 16-element receive array for human cardiac metabolic imaging at 7T
title_short Using a whole-body (31)P birdcage transmit coil and 16-element receive array for human cardiac metabolic imaging at 7T
title_sort using a whole-body (31)p birdcage transmit coil and 16-element receive array for human cardiac metabolic imaging at 7t
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5658155/
https://www.ncbi.nlm.nih.gov/pubmed/29073228
http://dx.doi.org/10.1371/journal.pone.0187153
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