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Literature DB >> 22851199

Reducing the object orientation dependence of susceptibility effects in gradient echo MRI through quantitative susceptibility mapping.

Jianqi Li¹, Shixin Chang, Tian Liu, Qianfeng Wang, Deqi Cui, Xiaoyue Chen, Moonsoo Jin, Baocheng Wang, Mengchao Pei, Cynthia Wisnieff, Pascal Spincemaille, Min Zhang, Yi Wang.

Abstract

This study demonstrates the dependence of non-local susceptibility effects on object orientation in gradient echo MRI and the reduction of non-local effects by deconvolution using quantitative susceptibility mapping. Imaging experiments were performed on a 3T MRI system using a spoiled 3D multi-echo GRE sequence on phantoms of known susceptibilities, and on human brains of healthy subjects and patients with intracerebral hemorrhages. Magnetic field measurements were determined from multiple echo phase data. To determine the quantitative susceptibility mapping, these field measurements were deconvolved through a dipole inversion kernel under a constraint of consistency with the magnitude images. Phantom and human data demonstrated that the hypointense region in GRE magnitude image corresponding to a susceptibility source increased in volume with TE and varied with the source orientation. The induced magnetic field extended beyond the susceptibility source and varied with its orientation. In quantitative susceptibility mapping, these blooming artifacts, including their dependence on object orientation, were reduced, and the material susceptibilities were quantified.

Entities: Chemical Disease Gene Species

Mesh：

Year: 2012 PMID： 22851199 PMCID： PMC3493252 DOI： 10.1002/mrm.24135

Source DB: PubMed Journal: Magn Reson Med ISSN： 0740-3194 Impact factor: 4.668

32 in total

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6. Rapid NMR imaging of dynamic processes using the FLASH technique.

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8. Improved sensitivity to magnetic susceptibility contrast.

Authors: A J de Crespigny; T P Roberts; J Kucharcyzk; M E Moseley
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9. T2*-based fiber orientation mapping.

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10. Comparison of MRI and CT for detection of acute intracerebral hemorrhage.

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4. Rapid automated liver quantitative susceptibility mapping.

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