Improving motion robustness of 3D MR fingerprinting with a fat navigator

Author:

Hu Siyuan1ORCID,Chen Yong2,Zong Xiaopeng3,Lin Weili4,Griswold Mark2,Ma Dan1

Affiliation:

1. Department of Biomedical Engineering Case Western Reserve University Cleveland Ohio USA

2. Department of Radiology Case Western Reserve University Cleveland Ohio USA

3. School of Biomedical Engineering ShanghaiTech University Shanghai China

4. Department of Radiology University of North Carolina Chapel Hill North Carolina USA

Abstract

PurposeTo develop a 3D MR fingerprinting (MRF) method in combination with fat navigators to improve its motion robustness for neuroimaging.MethodsA rapid fat navigator was developed using the stack‐of‐spirals acquisition and non‐Cartesian spiral GRAPPA. The fat navigator module was implemented in the 3D MRF sequence with high scan efficiency. The developed method was first validated in phantoms and five healthy subjects with intentional head motion. The method was further applied to infants with neonatal opioid withdrawal symptoms. The 3D MRF scans with fat navigators acquired with and without acceleration along the partition‐encoding direction were both examined in the study.ResultsBoth phantom and in vivo results demonstrated that the added fat navigator modules did not influence the quantification accuracy in MRF. In combination with non‐Cartesian spiral GRAPPA, a rapid fat navigator sampling with whole‐brain coverage was achieved in ˜0.5 s at 3T, reducing its sensitivity to potential motion. Based on the motion waveforms extracted from fat navigators, the motion robustness of the 3D MRF was largely improved. With the proposed method, the motion‐corrupted MRF datasets yielded T1 and T2 maps with significantly reduced artifacts and high correlations with measurements from the reference motion‐free MRF scans.ConclusionWe developed a 3D MRF method coupled with rapid fat navigators to improve its motion robustness for quantitative neuroimaging. Our results demonstrate that (1) accurate tissue quantification was preserved with the fat navigator modules and (2) the motion robustness for quantitative tissue mapping was largely improved with the developed method.

Funder

National Cancer Institute

National Institute of Biomedical Imaging and Bioengineering

National Institute of Neurological Disorders and Stroke

Siemens Healthineers

UK Research and Innovation

Publisher

Wiley

Subject

Radiology, Nuclear Medicine and imaging

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1. Beyond the Conventional Structural MRI;Investigative Radiology;2024-08-20

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