Qualification of a noninvasive magnetic resonance imaging biomarker to assess tumor oxygenation

Although hypoxia has been long recognized as a crucial factor impairing tumor response in many therapeutic schemes, atraumatic and reliable methods of individually quantifying tumor oxygenation are still lacking in day-to-day clinical practice. The aim of this work was to investigate the potentially...

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Bibliographic Details
Published in:Clinical cancer research 2014-11, Vol.20 (21), p.5403-5411
Main Authors: Colliez, Florence, Neveu, Marie-Aline, Magat, Julie, Cao Pham, Thanh Trang, Gallez, Bernard, Jordan, Bénédicte F
Format: Article
Language:English
Subjects:
Animals
Biomarkers, Tumor - chemistry
Biomarkers, Tumor - metabolism
Cell Line, Tumor
Female
Humans
Lipids - chemistry
Magnetic Resonance Imaging - methods
Mice
Mice, Nude
Neoplasms - metabolism
Oxygen - metabolism
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Summary:Although hypoxia has been long recognized as a crucial factor impairing tumor response in many therapeutic schemes, atraumatic and reliable methods of individually quantifying tumor oxygenation are still lacking in day-to-day clinical practice. The aim of this work was to investigate the potentially quantitative properties of our recently described noninvasive magnetic resonance (MR) technique "MOBILE" (mapping of oxygen by imaging lipids relaxation enhancement) and to qualify this endogenous contrast as a tumor hypoxia marker. The "MOBILE" technique, which assesses the longitudinal MR relaxation rate, R1, of lipid protons, was benchmarked with the parent technique which assesses the global (or water) R1, in response to a hyperoxic challenge (carbogen breathing) and to a hypoxic challenge (combretastatin A4) in MDA-MB-231 xenografts and in NT2 mammary tumors. Electron paramagnetic resonance (EPR) oximetry was used to quantitatively assess the tumor pO2 in matching tumors longitudinally. Our study evidenced that (i) positive and negative changes in tumor oxygenation can be detected using MOBILE; (ii) a change in the R1 of lipids is positively correlated with a change in the tumor pO2 (P = 0.0217, r = 0.5097); (iii) measured lipid R1 values are positively correlated with absolute pO2 values in both tumor models (P = 0.0275, r = 0.3726); and (iv) changes in the R1 of lipids are more sensitive than changes in the global R1. As this technique presents unique translational properties, it seems promising for the individual longitudinal monitoring of tumor oxygenation in a clinical setting.
ISSN:1078-0432
1557-3265
DOI:10.1158/1078-0432.CCR-13-3434