Oxygen Mapping within Healthy and Acutely Infarcted Brain Tissue in Humans Using the NMR Relaxation of Lipids: A Proof-Of-Concept Translational Study.

Oxygen Mapping within Healthy and Acutely Infarcted Brain Tissue in Humans Using the NMR Relaxation of Lipids: A Proof-Of-Concept Translational Study.

The clinical applicability of brain oxygenation mapping using the MOBILE (Mapping of Oxygen By Imaging Lipids relaxation Enhancement) magnetic resonance (MR) technique was assessed in the clinical setting of normal brain and of acute cerebral ischemia as a founding proof-of-concept translational stu...

Full description

Bibliographic Details
Main Authors: Florence Colliez, Marta M Safronova, Julie Magat, Nicolas Joudiou, André P Peeters, Bénédicte F Jordan, Bernard Gallez, Thierry Duprez
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2015-01-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC4534037?pdf=render
id doaj-605b39f3f10b4f8b8a5d419102144b32
record_format Article
spelling doaj-605b39f3f10b4f8b8a5d419102144b322020-11-24T21:56:04ZengPublic Library of Science (PLoS)PLoS ONE1932-62032015-01-01108e013524810.1371/journal.pone.0135248Oxygen Mapping within Healthy and Acutely Infarcted Brain Tissue in Humans Using the NMR Relaxation of Lipids: A Proof-Of-Concept Translational Study.Florence ColliezMarta M SafronovaJulie MagatNicolas JoudiouAndré P PeetersBénédicte F JordanBernard GallezThierry DuprezThe clinical applicability of brain oxygenation mapping using the MOBILE (Mapping of Oxygen By Imaging Lipids relaxation Enhancement) magnetic resonance (MR) technique was assessed in the clinical setting of normal brain and of acute cerebral ischemia as a founding proof-of-concept translational study. Changes in the oxygenation level within healthy brain tissue can be detected by analyzing the spin-lattice proton relaxation ('Global T1' combining water and lipid protons) because of the paramagnetic properties of molecular oxygen. It was hypothesized that selective measurement of the relaxation of the lipid protons ('Lipids T1') would result in enhanced sensitivity of pO2 mapping because of higher solubility of oxygen in lipids than in water, and this was demonstrated in pre-clinical models using the MOBILE technique. In the present study, 12 healthy volunteers and eight patients with acute (48-72 hours) brain infarction were examined with the same clinical 3T MR system. Both Lipids R1 (R1 = 1/T1) and Global R1 were significantly different in the infarcted area and the contralateral unaffected brain tissue, with a higher statistical significance for Lipids R1 (median difference: 0.408 s-1; p<0.0001) than for Global R1 (median difference: 0.154 s-1; p = 0.027). Both Lipids R1 and Global R1 values in the unaffected contralateral brain tissue of stroke patients were not significantly different from the R1 values calculated in the brain tissue of healthy volunteers. The main limitations of the present prototypic version of the MOBILE sequence are the long acquisition time (4 min), hampering robustness of data in uncooperative patients, and a 2 mm slice thickness precluding accurate measurements in small infarcts because of partial volume averaging effects.http://europepmc.org/articles/PMC4534037?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Florence Colliez
Marta M Safronova
Julie Magat
Nicolas Joudiou
André P Peeters
Bénédicte F Jordan
Bernard Gallez
Thierry Duprez
spellingShingle Florence Colliez
Marta M Safronova
Julie Magat
Nicolas Joudiou
André P Peeters
Bénédicte F Jordan
Bernard Gallez
Thierry Duprez
Oxygen Mapping within Healthy and Acutely Infarcted Brain Tissue in Humans Using the NMR Relaxation of Lipids: A Proof-Of-Concept Translational Study.
PLoS ONE
author_facet Florence Colliez
Marta M Safronova
Julie Magat
Nicolas Joudiou
André P Peeters
Bénédicte F Jordan
Bernard Gallez
Thierry Duprez
author_sort Florence Colliez
title Oxygen Mapping within Healthy and Acutely Infarcted Brain Tissue in Humans Using the NMR Relaxation of Lipids: A Proof-Of-Concept Translational Study.
title_short Oxygen Mapping within Healthy and Acutely Infarcted Brain Tissue in Humans Using the NMR Relaxation of Lipids: A Proof-Of-Concept Translational Study.
title_full Oxygen Mapping within Healthy and Acutely Infarcted Brain Tissue in Humans Using the NMR Relaxation of Lipids: A Proof-Of-Concept Translational Study.
title_fullStr Oxygen Mapping within Healthy and Acutely Infarcted Brain Tissue in Humans Using the NMR Relaxation of Lipids: A Proof-Of-Concept Translational Study.
title_full_unstemmed Oxygen Mapping within Healthy and Acutely Infarcted Brain Tissue in Humans Using the NMR Relaxation of Lipids: A Proof-Of-Concept Translational Study.
title_sort oxygen mapping within healthy and acutely infarcted brain tissue in humans using the nmr relaxation of lipids: a proof-of-concept translational study.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2015-01-01
description The clinical applicability of brain oxygenation mapping using the MOBILE (Mapping of Oxygen By Imaging Lipids relaxation Enhancement) magnetic resonance (MR) technique was assessed in the clinical setting of normal brain and of acute cerebral ischemia as a founding proof-of-concept translational study. Changes in the oxygenation level within healthy brain tissue can be detected by analyzing the spin-lattice proton relaxation ('Global T1' combining water and lipid protons) because of the paramagnetic properties of molecular oxygen. It was hypothesized that selective measurement of the relaxation of the lipid protons ('Lipids T1') would result in enhanced sensitivity of pO2 mapping because of higher solubility of oxygen in lipids than in water, and this was demonstrated in pre-clinical models using the MOBILE technique. In the present study, 12 healthy volunteers and eight patients with acute (48-72 hours) brain infarction were examined with the same clinical 3T MR system. Both Lipids R1 (R1 = 1/T1) and Global R1 were significantly different in the infarcted area and the contralateral unaffected brain tissue, with a higher statistical significance for Lipids R1 (median difference: 0.408 s-1; p<0.0001) than for Global R1 (median difference: 0.154 s-1; p = 0.027). Both Lipids R1 and Global R1 values in the unaffected contralateral brain tissue of stroke patients were not significantly different from the R1 values calculated in the brain tissue of healthy volunteers. The main limitations of the present prototypic version of the MOBILE sequence are the long acquisition time (4 min), hampering robustness of data in uncooperative patients, and a 2 mm slice thickness precluding accurate measurements in small infarcts because of partial volume averaging effects.
url http://europepmc.org/articles/PMC4534037?pdf=render
work_keys_str_mv AT florencecolliez oxygenmappingwithinhealthyandacutelyinfarctedbraintissueinhumansusingthenmrrelaxationoflipidsaproofofconcepttranslationalstudy
AT martamsafronova oxygenmappingwithinhealthyandacutelyinfarctedbraintissueinhumansusingthenmrrelaxationoflipidsaproofofconcepttranslationalstudy
AT juliemagat oxygenmappingwithinhealthyandacutelyinfarctedbraintissueinhumansusingthenmrrelaxationoflipidsaproofofconcepttranslationalstudy
AT nicolasjoudiou oxygenmappingwithinhealthyandacutelyinfarctedbraintissueinhumansusingthenmrrelaxationoflipidsaproofofconcepttranslationalstudy
AT andreppeeters oxygenmappingwithinhealthyandacutelyinfarctedbraintissueinhumansusingthenmrrelaxationoflipidsaproofofconcepttranslationalstudy
AT benedictefjordan oxygenmappingwithinhealthyandacutelyinfarctedbraintissueinhumansusingthenmrrelaxationoflipidsaproofofconcepttranslationalstudy
AT bernardgallez oxygenmappingwithinhealthyandacutelyinfarctedbraintissueinhumansusingthenmrrelaxationoflipidsaproofofconcepttranslationalstudy
AT thierryduprez oxygenmappingwithinhealthyandacutelyinfarctedbraintissueinhumansusingthenmrrelaxationoflipidsaproofofconcepttranslationalstudy
_version_ 1725859731371720704

Similar Items