Deep learning‐assisted preclinical MR fingerprinting for sub‐millimeter <scp>T<sub>1</sub></scp> and <scp>T<sub>2</sub></scp> mapping of entire macaque brain

Gu, Yuning; Pan, Yongsheng; Fang, Zhenghan; Ma, Lei; Zhu, Yuran; Androjna, Charlie; Zhong, Kai; Yu, Xin; Shen, Dinggang

doi:10.1002/mrm.29905

Magnetic Resonance in Med

2023

DOI: 10.1002/mrm.29905

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Deep learning‐assisted preclinical MR fingerprinting for sub‐millimeter T₁ and T₂ mapping of entire macaque brain

Yuning Gu,

Yongsheng Pan,

Zhenghan Fang

et al.

Abstract: PurposePreclinical MR fingerprinting (MRF) suffers from long acquisition time for organ‐level coverage due to demanding image resolution and limited undersampling capacity. This study aims to develop a deep learning‐assisted fast MRF framework for sub‐millimeter T1 and T2 mapping of entire macaque brain on a preclinical 9.4 T MR system.MethodsThree dimensional MRF images were reconstructed by singular value decomposition (SVD) compressed reconstruction. T1 and T2 mapping for each axial slice exploited a self‐a… Show more

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2024

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3D MR fingerprinting for dynamic contrast‐enhanced imaging of whole mouse brain

Zhu,

Wang,

et al. 2024

Magnetic Resonance in Med

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PurposeQuantitative MRI enables direct quantification of contrast agent concentrations in contrast‐enhanced scans. However, the lengthy scan times required by conventional methods are inadequate for tracking contrast agent transport dynamically in mouse brain. We developed a 3D MR fingerprinting (MRF) method for simultaneous T1 and T2 mapping across the whole mouse brain with 4.3‐min temporal resolution.MethodWe designed a 3D MRF sequence with variable acquisition segment lengths and magnetization preparations on a 9.4T preclinical MRI scanner. Model‐based reconstruction approaches were employed to improve the accuracy and speed of MRF acquisition. The method's accuracy for T1 and T2 measurements was validated in vitro, while its repeatability of T1 and T2 measurements was evaluated in vivo (n = 3). The utility of the 3D MRF sequence for dynamic tracking of intracisternally infused gadolinium‐diethylenetriamine pentaacetic acid (Gd‐DTPA) in the whole mouse brain was demonstrated (n = 5).ResultsPhantom studies confirmed accurate T1 and T2 measurements by 3D MRF with an undersampling factor of up to 48. Dynamic contrast‐enhanced MRF scans achieved a spatial resolution of 192 × 192 × 500 μm3 and a temporal resolution of 4.3 min, allowing for the analysis and comparison of dynamic changes in concentration and transport kinetics of intracisternally infused Gd‐DTPA across brain regions. The sequence also enabled highly repeatable, high‐resolution T1 and T2 mapping of the whole mouse brain (192 × 192 × 250 μm3) in 30 min.ConclusionWe present the first dynamic and multi‐parametric approach for quantitatively tracking contrast agent transport in the mouse brain using 3D MRF.

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3D MR fingerprinting for dynamic contrast‐enhanced imaging of whole mouse brain

Zhu,

Wang,

et al. 2024

Magnetic Resonance in Med

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Synthesis of MR fingerprinting information from magnitude-only MR imaging data using a parallelized, multi network U-Net convolutional neural network

McGee,

Sui,

Witte

et al. 2024

Front. Radiol.

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BackgroundMR fingerprinting (MRF) is a novel method for quantitative assessment of in vivo MR relaxometry that has shown high precision and accuracy. However, the method requires data acquisition using customized, complex acquisition strategies and dedicated post processing methods thereby limiting its widespread application.ObjectiveTo develop a deep learning (DL) network for synthesizing MRF signals from conventional magnitude-only MR imaging data and to compare the results to the actual MRF signal acquired.MethodsA U-Net DL network was developed to synthesize MRF signals from magnitude-only 3D T1-weighted brain MRI data acquired from 37 volunteers aged between 21 and 62 years of age. Network performance was evaluated by comparison of the relaxometry data (T1, T2) generated from dictionary matching of the deep learning synthesized and actual MRF data from 47 segmented anatomic regions. Clustered bootstrapping involving 10,000 bootstraps followed by calculation of the concordance correlation coefficient were performed for both T1 and T2 MRF data pairs. 95% confidence limits and the mean difference between true and DL relaxometry values were also calculated.ResultsThe concordance correlation coefficient (and 95% confidence limits) for T1 and T2 MRF data pairs over the 47 anatomic segments were 0.8793 (0.8136–0.9383) and 0.9078 (0.8981–0.9145) respectively. The mean difference (and 95% confidence limits) were 48.23 (23.0–77.3) s and 2.02 (−1.4 to 4.8) s.ConclusionIt is possible to synthesize MRF signals from MRI data using a DL network, thereby creating the potential for performing quantitative relaxometry assessment without the need for a dedicated MRF pulse sequence.

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Deep learning‐assisted preclinical MR fingerprinting for sub‐millimeter T₁ and T₂ mapping of entire macaque brain

Cited by 2 publications

References 56 publications

3D MR fingerprinting for dynamic contrast‐enhanced imaging of whole mouse brain

3D MR fingerprinting for dynamic contrast‐enhanced imaging of whole mouse brain

Synthesis of MR fingerprinting information from magnitude-only MR imaging data using a parallelized, multi network U-Net convolutional neural network

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Deep learning‐assisted preclinical MR fingerprinting for sub‐millimeter T1 and T2 mapping of entire macaque brain

Cited by 2 publications

References 56 publications

3D MR fingerprinting for dynamic contrast‐enhanced imaging of whole mouse brain

3D MR fingerprinting for dynamic contrast‐enhanced imaging of whole mouse brain

Synthesis of MR fingerprinting information from magnitude-only MR imaging data using a parallelized, multi network U-Net convolutional neural network

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Product

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Deep learning‐assisted preclinical MR fingerprinting for sub‐millimeter T₁ and T₂ mapping of entire macaque brain