Vaddadi Venkatesh, Raji Susan Mathew, Phaneendra K. Yalavarthy
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This study aims to develop an effective model-based deep-learning framework to solve the inverse problem of QSM.</p><h3 data-test=\"abstract-sub-heading\">Materials and methods</h3><p>This work proposes a Schatten <span>\\(\\textit{p}\\)</span>-norm-driven model-based deep learning framework for QSM with a learnable norm parameter <span>\\(\\textit{p}\\)</span> to adapt to the data. In contrast to other model-based architectures that enforce the <i>l</i><span>\\(_{\\text {2}}\\)</span>-norm or <i>l</i><span>\\(_{\\text {1}}\\)</span>-norm for the denoiser, the proposed approach can enforce any <span>\\(\\textit{p}\\)</span>-norm (<span>\\(\\text {0}<\\textit{p}\\le \\text {2}\\)</span>) on a trainable regulariser.</p><h3 data-test=\"abstract-sub-heading\">Results</h3><p>The proposed method was compared with deep learning-based approaches, such as QSMnet, and model-based deep learning approaches, such as learned proximal convolutional neural network (LPCNN). Reconstructions performed using 77 imaging volumes with different acquisition protocols and clinical conditions, such as hemorrhage and multiple sclerosis, showed that the proposed approach outperformed existing state-of-the-art methods by a significant margin in terms of quantitative merits.</p><h3 data-test=\"abstract-sub-heading\">Conclusion</h3><p>The proposed SpiNet-QSM showed a consistent improvement of at least 5% in terms of the high-frequency error norm (HFEN) and normalized root mean squared error (NRMSE) over other QSM reconstruction methods with limited training data.</p>","PeriodicalId":18067,"journal":{"name":"Magnetic Resonance Materials in Physics, Biology and Medicine","volume":null,"pages":null},"PeriodicalIF":2.0000,"publicationDate":"2024-04-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Spinet-QSM: model-based deep learning with schatten p-norm regularization for improved quantitative susceptibility mapping\",\"authors\":\"Vaddadi Venkatesh, Raji Susan Mathew, Phaneendra K. Yalavarthy\",\"doi\":\"10.1007/s10334-024-01158-7\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<h3 data-test=\\\"abstract-sub-heading\\\">Objective</h3><p>Quantitative susceptibility mapping (QSM) provides an estimate of the magnetic susceptibility of tissue using magnetic resonance (MR) phase measurements. The tissue magnetic susceptibility (source) from the measured magnetic field distribution/local tissue field (effect) inherent in the MR phase images is estimated by numerically solving the inverse source-effect problem. This study aims to develop an effective model-based deep-learning framework to solve the inverse problem of QSM.</p><h3 data-test=\\\"abstract-sub-heading\\\">Materials and methods</h3><p>This work proposes a Schatten <span>\\\\(\\\\textit{p}\\\\)</span>-norm-driven model-based deep learning framework for QSM with a learnable norm parameter <span>\\\\(\\\\textit{p}\\\\)</span> to adapt to the data. In contrast to other model-based architectures that enforce the <i>l</i><span>\\\\(_{\\\\text {2}}\\\\)</span>-norm or <i>l</i><span>\\\\(_{\\\\text {1}}\\\\)</span>-norm for the denoiser, the proposed approach can enforce any <span>\\\\(\\\\textit{p}\\\\)</span>-norm (<span>\\\\(\\\\text {0}<\\\\textit{p}\\\\le \\\\text {2}\\\\)</span>) on a trainable regulariser.</p><h3 data-test=\\\"abstract-sub-heading\\\">Results</h3><p>The proposed method was compared with deep learning-based approaches, such as QSMnet, and model-based deep learning approaches, such as learned proximal convolutional neural network (LPCNN). 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Spinet-QSM: model-based deep learning with schatten p-norm regularization for improved quantitative susceptibility mapping
Objective
Quantitative susceptibility mapping (QSM) provides an estimate of the magnetic susceptibility of tissue using magnetic resonance (MR) phase measurements. The tissue magnetic susceptibility (source) from the measured magnetic field distribution/local tissue field (effect) inherent in the MR phase images is estimated by numerically solving the inverse source-effect problem. This study aims to develop an effective model-based deep-learning framework to solve the inverse problem of QSM.
Materials and methods
This work proposes a Schatten \(\textit{p}\)-norm-driven model-based deep learning framework for QSM with a learnable norm parameter \(\textit{p}\) to adapt to the data. In contrast to other model-based architectures that enforce the l\(_{\text {2}}\)-norm or l\(_{\text {1}}\)-norm for the denoiser, the proposed approach can enforce any \(\textit{p}\)-norm (\(\text {0}<\textit{p}\le \text {2}\)) on a trainable regulariser.
Results
The proposed method was compared with deep learning-based approaches, such as QSMnet, and model-based deep learning approaches, such as learned proximal convolutional neural network (LPCNN). Reconstructions performed using 77 imaging volumes with different acquisition protocols and clinical conditions, such as hemorrhage and multiple sclerosis, showed that the proposed approach outperformed existing state-of-the-art methods by a significant margin in terms of quantitative merits.
Conclusion
The proposed SpiNet-QSM showed a consistent improvement of at least 5% in terms of the high-frequency error norm (HFEN) and normalized root mean squared error (NRMSE) over other QSM reconstruction methods with limited training data.
期刊介绍:
MAGMA is a multidisciplinary international journal devoted to the publication of articles on all aspects of magnetic resonance techniques and their applications in medicine and biology. MAGMA currently publishes research papers, reviews, letters to the editor, and commentaries, six times a year. The subject areas covered by MAGMA include:
advances in materials, hardware and software in magnetic resonance technology,
new developments and results in research and practical applications of magnetic resonance imaging and spectroscopy related to biology and medicine,
study of animal models and intact cells using magnetic resonance,
reports of clinical trials on humans and clinical validation of magnetic resonance protocols.
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