Repeatability and reproducibility of 3D MR fingerprinting relaxometry measurements in normal breast tissue

Panda, Ananya; Chen, Yong; Ropella-Panagis, Kathleen; Ghodasara, Satyam; Stopchinski, Marcie; Seyfried, Nicole; Wright, Katherine Landau; Seiberlich, Nicole; Griswold, Mark A.; Gulani, Vikas

doi:10.1002/jmri.26717

Cited by 34 publications

(38 citation statements)

References 32 publications

(84 reference statements)

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“…More recently, 3D MRF with Bloch–Siegert B 1 + map correction and fat suppression was used to acquire full‐volume, T 1 and T 2 maps in the breast at a spatial resolution of 1.6 × 1.6 × 3 mm 3 in ~6 minutes . Panda et al conducted both repeatability and reproducibility studies in healthy subjects . In the work by Chen et al, MRF maps were useful in characterizing the breast lesions: T 1 and T 2 relaxation times measured in healthy subjects agreed with previous literature, and the T 2 relaxation time was significantly higher in invasive ductal carcinoma than in healthy tissue …”

Section: Potential Clinical Usesmentioning

confidence: 99%

“…In a phantom, when ground truth values are available, the bias of that method from the ground truth values should be presented, as shown in Fig. using data from Ma et al Ideally, the phantom is used not for a single validation, but repeatedly removed and then positioned in the scanner and imaged to generate repeatability data, as done in one day by Anderson et al, over multiple days on one system by Jiang et al, and reproducibility data, as done across three MRI systems by Cloos et al Repeatability and reproducibility data are also needed in vivo, and some studies were recently completed . Cloos et al presented results from a small study using three healthy controls, with two measurements across three systems.…”

Section: Barriers To Clinical Adaptation and Recommendations For Progmentioning

confidence: 99%

“…Using the high‐resolution 3D MRF method, Ma et al performed repeatability studies using the ISMRM/NIST system phantom, and test–retest studies were completed in healthy volunteers . Panda et al conducted repeatability and reproducibility studies in the breast of healthy subjects, and they determined the coefficient of repeatability for T 1 to be 290 msec and for T 2 to be 14 msec . Thus, if an observed change was greater than the coefficient of repeatability (eg, ΔT 1 >290 msec or ΔT 2 >14 msec), it can be considered notable.…”

Section: Barriers To Clinical Adaptation and Recommendations For Progmentioning

confidence: 99%

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Magnetic resonance fingerprinting Part 1: Potential uses, current challenges, and recommendations

Poorman

Martin

et al. 2019

Magnetic Resonance Imaging

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Magnetic resonance fingerprinting (MRF) is a powerful quantitative MRI technique capable of acquiring multiple property maps simultaneously in a short timeframe. The MRF framework has been adapted to a wide variety of clinical applications, but faces challenges in technical development, and to date has only demonstrated repeatability and reproducibility in small studies. In this review, we discuss the current implementations of MRF and their use in a clinical setting. Based on this analysis, we highlight areas of need that must be addressed before MRF can be fully adopted into the clinic and make recommendations to the MRF community on standardization and validation strategies of MRF techniques. Level of Evidence: 2 Technical Efficacy: Stage 2 J. Magn. Reson. Imaging 2020;51:675–692.

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Section: Potential Clinical Usesmentioning

confidence: 99%

Section: Barriers To Clinical Adaptation and Recommendations For Progmentioning

confidence: 99%

Section: Barriers To Clinical Adaptation and Recommendations For Progmentioning

confidence: 99%

See 1 more Smart Citation

Magnetic resonance fingerprinting Part 1: Potential uses, current challenges, and recommendations

Poorman

Martin

et al. 2019

Magnetic Resonance Imaging

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“…Separate in vivo MRF studies on hip cartilage, 55 brain, 62,63 cardiac tissue 64 and breast 65 showed good repeatability and reproducibility across scanners. In particular, repeatability coefficients of variation for T 1 and T 2 in the brain study were below 8% and 14%, respectively, 62 while it was better in breast tissue, ranging from 3 to 4% for T 1 and 5 to 7% for T 2 .…”

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confidence: 91%

Magnetic resonance fingerprinting: from evolution to clinical applications

Hsieh

Svalbe

2020

J of Medical Radiation Sci

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In 2013, Magnetic Resonance Fingerprinting (MRF) emerged as a method for fast, quantitative Magnetic Resonance Imaging. This paper reviews the current status of MRF up to early 2020 and aims to highlight the advantages MRF can offer medical imaging professionals. By acquiring scan data as pseudorandom samples, MRF elicits a unique signal evolution, or 'fingerprint', from each tissue type. It matches 'randomised' free induction decay acquisitions against precomputed simulated tissue responses to generate a set of quantitative images of T 1 , T 2 and proton density (PD) with co-registered voxels, rather than as traditional relative T 1-and T 2-weighted images. MRF numeric pixel values retain accuracy and reproducibility between 2% and 8%. MRF acquisition is robust to strong undersampling of k-space. Scan sequences have been optimised to suppress sub-sampling artefacts, while artificial intelligence and machine learning techniques have been employed to increase matching speed and precision. MRF promises improved patient comfort with reduced scan times and fewer image artefacts. Quantitative MRF data could be used to define population-wide numeric biomarkers that classify normal versus diseased tissue. Certification of clinical centres for MRF scan repeatability would permit numeric comparison of sequential images for any individual patient and the pooling of multiple patient images across large, cross-site imaging studies. MRF has to date shown promising results in early clinical trials, demonstrating reliable differentiation between malignant and benign prostate conditions, and normal and sclerotic hippocampal tissue. MRF is now undergoing small-scale trials at several sites across the world; moving it closer to routine clinical application.

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“…. Additionally, sequences have been modified for areas beyond neuro, including applications in the abdomen, breast, prostate, cardiac, knee and hip, among others. Examples from several of these works are presented in Fig.…”

mentioning

confidence: 99%

Magnetic resonance fingerprinting review part 2: Technique and directions

McGivney

Boyacıoğlu

Jiang

et al. 2019

Magnetic Resonance Imaging

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Magnetic resonance fingerprinting (MRF) is a general framework to quantify multiple MR‐sensitive tissue properties with a single acquisition. There have been numerous advances in MRF in the years since its inception. In this work we highlight some of the recent technical developments in MRF, focusing on sequence optimization, modifications for reconstruction and pattern matching, new methods for partial volume analysis, and applications of machine and deep learning. Level of Evidence: 2 Technical Efficacy: Stage 2 J. Magn. Reson. Imaging 2020;51:993–1007.

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Repeatability and reproducibility of 3D MR fingerprinting relaxometry measurements in normal breast tissue

Cited by 34 publications

References 32 publications

Magnetic resonance fingerprinting Part 1: Potential uses, current challenges, and recommendations

Magnetic resonance fingerprinting Part 1: Potential uses, current challenges, and recommendations

Magnetic resonance fingerprinting: from evolution to clinical applications

Magnetic resonance fingerprinting review part 2: Technique and directions

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