Exploring linearity of deep neural network trained QSM: QSMnet+

Jung, Woojin; Yoon, Jaeyeon; Ji, Soo-Yeon; Choi, Joon Yul; Kim, Jae‐Myung; Nam, Yoonho; Kim, Eung Yeop; Lee, Jong-Ho

doi:10.1016/j.neuroimage.2020.116619

Cited by 60 publications

(52 citation statements)

References 48 publications

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“…Previous works have proposed to solve QSM dipole inversion with deep neural networks, including QSMnet, 26 QSMnet + , 28 QSMGAN, 29 VaNDI, 31 autoQSM 32 and DeepQSM 34 . The first five frameworks require reconstructing QSM first using conventional methods as the training labels, which may deviate from the ground truth.…”

Section: Discussionmentioning

confidence: 99%

xQSM: quantitative susceptibility mapping with octave convolutional and noise‐regularized neural networks

et al. 2020

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Quantitative susceptibility mapping (QSM) provides a valuable MRI contrast mechanism that has demonstrated broad clinical applications. However, the image reconstruction of QSM is challenging due to its ill‐posed dipole inversion process. In this study, a new deep learning method for QSM reconstruction, namely xQSM, was designed by introducing noise regularization and modified octave convolutional layers into a U‐net backbone and trained with synthetic and in vivo datasets, respectively. The xQSM method was compared with two recent deep learning (QSMnet+ and DeepQSM) and two conventional dipole inversion (MEDI and iLSQR) methods, using both digital simulations and in vivo experiments. Reconstruction error metrics, including peak signal‐to‐noise ratio, structural similarity, normalized root mean squared error and deep gray matter susceptibility measurements, were evaluated for comparison of the different methods. The results showed that the proposed xQSM network trained with in vivo datasets achieved the best reconstructions of all the deep learning methods. In particular, it led to, on average, 32.3%, 25.4% and 11.7% improvement in the accuracy of globus pallidus susceptibility estimation for digital simulations and 39.3%, 21.8% and 6.3% improvements for in vivo acquisitions compared with DeepQSM, QSMnet+ and iLSQR, respectively. It also exhibited the highest linearity against different susceptibility intensity scales and demonstrated the most robust generalization capability to various spatial resolutions of all the deep learning methods. In addition, the xQSM method also substantially shortened the reconstruction time from minutes using MEDI to only a few seconds.

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Section: Discussionmentioning

confidence: 99%

xQSM: quantitative susceptibility mapping with octave convolutional and noise‐regularized neural networks

et al. 2020

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“…One example is a recent study by Jung et al, reporting the effects of susceptibility range. 56 In the study, the network was trained using healthy volunteer data, limiting the training range to healthy tissue values (Figure 3a). When the network generated the susceptibility map of a hemorrhagic patient, it produced underestimated susceptibility values in hemorrhagic lesions, which have far higher susceptibility values than those of normal tissue ( Figure 3).…”

Section: Current Challenges Of Deep Learning Qsmmentioning

confidence: 99%

“…Similarly, Jung et al showed that data augmentation using susceptibility value scaled maps can cover a wider range of susceptibility values, successfully reconstructing QSM maps for pathology. 56 Different from other fields, which require additional data acquisition for data augmentation, QSM can be benefited from the dipole model in generating augmentation data.…”

Section: Generalization In Deep Learning Qsmmentioning

confidence: 99%

Overview of quantitative susceptibility mapping using deep learning: Current status, challenges and opportunities

2020

Self Cite

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Quantitative susceptibility mapping (QSM) has gained broad interests in the field by extracting biological tissue properties, predominantly myelin, iron and calcium from magnetic resonance imaging (MRI) phase measurements in vivo. Thereby, QSM can reveal pathological changes of these key components in a variety of diseases. QSM requires multiple processing steps such as phase unwrapping, background field removal and field-to-source-inversion. Current state of the art techniques utilize iterative optimization procedures to solve the inversion and background field correction, which are computationally expensive and require a careful choice of regularization parameters. With the recent success of deep learning using convolutional neural networks for solving ill-posed reconstruction problems, the QSM community also adapted these techniques and demonstrated that the QSM processing steps can be solved by efficient feed forward multiplications not requiring iterative optimization nor the choice of regularization parameters.Here, we review the current status of deep learning based approaches for processing QSM, highlighting limitations and potential pitfalls, and discuss the future directions the field may take to exploit the latest advances in deep learning for QSM.

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“…Another focus will be to explore the possibility to incorporate processing methods that are not developed in MATLAB. Emerging techniques using deep learning have already shown very promising results with further improvement in QSM artefact reduction (Bollmann et al, 2019;Chen et al, 2019;Jung et al, 2020;Polak et al, 2020;Wei et al, 2019;Yoon et al, 2018;Zhang et al, 2020). As the implementations of these methods are primarily in Python, while there are rich resources already available in MATLAB and supported in SEPIA to perform tasks such as phase unwrapping and background field removal, it would be valuable for SEPIA to connect the two.…”

Section: Discussionmentioning

confidence: 99%

“…As the implementations of these methods are primarily in Python, while there are rich resources already available in MATLAB and supported in SEPIA to perform tasks such as phase unwrapping and background field removal, it would be valuable for SEPIA to connect the two. Up to now, most deep learning methods do not yet have the flexibility to cope with arbitrary slice orientation and resolution (Jung et al, 2020;Yoon et al, 2018), this would therefore require data re-sampling to a pre-defined space which can be done with a plethora of software available for neuroimaging data, but we believe this is to be outside the scope of this toolbox. We also consider the compatibility between the SEPIA input and outputs data with BIDS (Gorgolewski et al, 2016), moving toward the standardisation of input and output phase data format and structure.…”

Section: Discussionmentioning

confidence: 99%

SEPIA - SuscEptibility mapping PIpeline tool for phAse images

Chan

Marques

2020

Preprint

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Quantitative susceptibility mapping (QSM) is a physics-driven computational technique that has a high sensitivity in quantifying iron deposition based on MRI phase images. Furthermore, it has a unique ability to distinguish paramagnetic and diamagnetic contributions such as haemorrhage and calcification based on image contrast. These properties have contributed to a growing interest to use QSM not only in research but also in clinical applications. However, it is challenging to obtain high quality susceptibility map because of its ill-posed nature, especially for researchers who have less experience with QSM and the optimisation of its pipeline. In this paper, we present an open-source processing pipeline tool called SuscEptibility mapping PIpeline tool for phAse images (SEPIA) dedicated to the post-processing of MRI phase images and QSM. SEPIA connects various QSM toolboxes freely available in the field to offer greater flexibility in QSM processing. It also provides an interactive graphical user interface to construct and execute a QSM processing pipeline, simplifying the workflow in QSM research. The extendable design of SEPIA also allows developers to deploy their methods in the framework, providing a platform for developers and researchers to share and utilise the state-of-the-art methods in QSM.

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Exploring linearity of deep neural network trained QSM: QSMnet+

Cited by 60 publications

References 48 publications

xQSM: quantitative susceptibility mapping with octave convolutional and noise‐regularized neural networks

xQSM: quantitative susceptibility mapping with octave convolutional and noise‐regularized neural networks

Overview of quantitative susceptibility mapping using deep learning: Current status, challenges and opportunities

SEPIA - SuscEptibility mapping PIpeline tool for phAse images

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