Diffusion-weighted chemical shift imaging of human brain metabolites at 7T
© 2014 Wiley Periodicals, Inc. Purpose Diffusion-weighted chemical shift imaging (DW-CSI) of brain metabolites poses significant challenges associated with the acquisition of spectroscopic data in the presence of strong diffusion weighting gradients. We present a reproducible DW-CSI acquisition and...
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th-mahidol.364182018-11-23T17:43:25Z Diffusion-weighted chemical shift imaging of human brain metabolites at 7T Ayse Ece Ercan Aranee Techawiboonwong Maarten J. Versluis Andrew G. Webb Itamar Ronen Leiden University Medical Center - LUMC Mahidol University Medicine © 2014 Wiley Periodicals, Inc. Purpose Diffusion-weighted chemical shift imaging (DW-CSI) of brain metabolites poses significant challenges associated with the acquisition of spectroscopic data in the presence of strong diffusion weighting gradients. We present a reproducible DW-CSI acquisition and processing scheme that addresses most of the potential sources of instability and provides reproducible and anatomically meaningful diffusion-weighted and apparent diffusion coefficient (ADC) metabolite maps. Methods A real-time navigator-based acquisition scheme was used, allowing instantaneous reacquisition of corrupted k-space data and postprocessing correction of gradient-induced phase fluctuations. Eddy current correction based on residual water resonance was implemented and improved the quality of the data significantly. Results Highly reproducible diffusion-weighted metabolite maps of three highest concentration brain metabolites are shown. The navigator-based accept/reject strategy and the postacquisition corrections improved the stability of the DW-CSI signal and the reproducibility of the resulting DW-CSI maps significantly. The metabolite ADC values could be related to the underlying tissue cellular composition. Conclusion Robust investigation of DW-CSI of brain metabolites is feasible and may provide information complementary to that obtained from more sensitive but less specific methods such as diffusion tensor imaging. Magn Reson Med 73:2053-2061, 2015. 2018-11-23T10:43:25Z 2018-11-23T10:43:25Z 2015-06-01 Article Magnetic Resonance in Medicine. Vol.73, No.6 (2015), 2053-2061 10.1002/mrm.25346 15222594 07403194 2-s2.0-84929630421 https://repository.li.mahidol.ac.th/handle/123456789/36418 Mahidol University SCOPUS https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84929630421&origin=inward |
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Medicine Ayse Ece Ercan Aranee Techawiboonwong Maarten J. Versluis Andrew G. Webb Itamar Ronen Diffusion-weighted chemical shift imaging of human brain metabolites at 7T |
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© 2014 Wiley Periodicals, Inc. Purpose Diffusion-weighted chemical shift imaging (DW-CSI) of brain metabolites poses significant challenges associated with the acquisition of spectroscopic data in the presence of strong diffusion weighting gradients. We present a reproducible DW-CSI acquisition and processing scheme that addresses most of the potential sources of instability and provides reproducible and anatomically meaningful diffusion-weighted and apparent diffusion coefficient (ADC) metabolite maps. Methods A real-time navigator-based acquisition scheme was used, allowing instantaneous reacquisition of corrupted k-space data and postprocessing correction of gradient-induced phase fluctuations. Eddy current correction based on residual water resonance was implemented and improved the quality of the data significantly. Results Highly reproducible diffusion-weighted metabolite maps of three highest concentration brain metabolites are shown. The navigator-based accept/reject strategy and the postacquisition corrections improved the stability of the DW-CSI signal and the reproducibility of the resulting DW-CSI maps significantly. The metabolite ADC values could be related to the underlying tissue cellular composition. Conclusion Robust investigation of DW-CSI of brain metabolites is feasible and may provide information complementary to that obtained from more sensitive but less specific methods such as diffusion tensor imaging. Magn Reson Med 73:2053-2061, 2015. |
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Leiden University Medical Center - LUMC |
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Leiden University Medical Center - LUMC Ayse Ece Ercan Aranee Techawiboonwong Maarten J. Versluis Andrew G. Webb Itamar Ronen |
| format |
Article |
| author |
Ayse Ece Ercan Aranee Techawiboonwong Maarten J. Versluis Andrew G. Webb Itamar Ronen |
| author_sort |
Ayse Ece Ercan |
| title |
Diffusion-weighted chemical shift imaging of human brain metabolites at 7T |
| title_short |
Diffusion-weighted chemical shift imaging of human brain metabolites at 7T |
| title_full |
Diffusion-weighted chemical shift imaging of human brain metabolites at 7T |
| title_fullStr |
Diffusion-weighted chemical shift imaging of human brain metabolites at 7T |
| title_full_unstemmed |
Diffusion-weighted chemical shift imaging of human brain metabolites at 7T |
| title_sort |
diffusion-weighted chemical shift imaging of human brain metabolites at 7t |
| publishDate |
2018 |
| url |
https://repository.li.mahidol.ac.th/handle/123456789/36418 |
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1763487648386646016 |