Deep Learning Approach for Generating MRA Images From 3D Quantitative Synthetic MRI Without Additional Scans

Radiological images have been assessed qualitatively in most clinical settings by the expert eyes of radiologists and other clinicians. On the other hand, quantification of radiological images has the potential to detect early disease that may be difficult to detect with human eyes, complement or replace biopsy, and provide clear differentiation of disease stage. Further, objective assessment by quantification is a prerequisite of personalized/precision medicine. This review article aims to summarize and discuss how the variability of quantitative values derived from radiological images are induced by a number of factors and how these variabilities are mitigated and standardization of the quantitative values are achieved. We discuss the variabilities of specific biomarkers derived from magnetic resonance imaging and computed tomography, and focus on diffusion-weighted imaging, relaxometry, lung density evaluation, and computer-aided computed tomography volumetry. We also review the sources of variability and current efforts of standardization of the rapidly evolving techniques, which include radiomics and artificial intelligence.

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“… 128 , 129 Synthetic MR angiography constructed by deep learning is also feasible based on the 3D-QALAS data of high resolution. 130 …”

Section: Magnetic Resonance Imagingmentioning

confidence: 99%

Variability and Standardization of Quantitative Imaging

et al. 2020

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“…The synthesis of MRA from 3D-QALAS data is also feasible. 26 One of the strengths of synthetic MR imaging that remains to be studied is the possibility of adjusting the synthetic TR, TE, and TI parameters to optimize them for each pathology, which has been shown in 2D synthetic MR imaging. 11 Although we have used preset parameters for creating synthetic images in this study, optimization of the contrast may improve the detection and delineation of lesions over conventional imaging.…”

Section: Discussionmentioning

confidence: 99%

3D Quantitative Synthetic MRI in the Evaluation of Multiple Sclerosis Lesions

Fujita

Yokoyama

Hagiwara³

et al. 2021

AJNR Am J Neuroradiol

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“…A previous study that combined functional MRI and diffusion tensor imaging with T1-weighted and FLAIR images for a support vector machine algorithm, achieved an accuracy of 88% in distinguishing MS and NMOSD [20], but these advanced MRI modalities are difficult to be incorporated into routine clinical scans. The multi-dynamic multi-echo sequence is now a clinical routine in some institutions, because conventional contrast-weighted images, such as T1-weighted, T2-weighted, and FLAIR images, and even magnetic resonance angiography, can be created using synthetic MRI [9,21]. Including other modalities that are clinically available, such as lumbar puncture results, antibody status, and quantitative spinal cord measures, may further increase the performance of our algorithm.…”

Section: Discussionmentioning

confidence: 99%

Differentiation between multiple sclerosis and neuromyelitis optica spectrum disorders by multiparametric quantitative MRI using convolutional neural network

Hagiwara

Otsuka

Andica

et al. 2021

Journal of Clinical Neuroscience

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Multiple sclerosis and neuromyelitis optica spectrum disorders are both neuroinflammatory diseases and have overlapping clinical manifestations. We developed a convolutional neural network model that differentiates between the two based on magnetic resonance imaging data. Thirty-five patients with relapsing-remitting multiple sclerosis and eighteen age-, sex-, disease duration-, and Expanded Disease Status Scale-matched patients with anti-aquaporin-4 antibody-positive neuromyelitis optica spectrum disorders were included in this study. All patients were scanned on a 3-T scanner using a multidynamic multi-echo sequence that simultaneously measures R1 and R2 relaxation rates and proton density. R1, R2, and proton density maps were analyzed using our convolutional neural network model. To avoid overfitting on a small dataset, we aimed to separate features of images into those specific to an image and those common to the group, based on SqueezeNet. We used only common features for classification. Leave-one-out cross validation was performed to evaluate the performance of the model. The area under the receiver operating characteristic curve of the developed convolutional neural network model for differentiating between the two disorders was 0.859. The sensitivity to multiple sclerosis and neuromyelitis optica spectrum disorders, and accuracy were 80.0%, 83.3%, and 81.1%, respectively. In conclusion, we developed a convolutional neural network model that differentiates between multiple sclerosis and neuromyelitis optica spectrum disorders, and which is designed to avoid overfitting on small training datasets. Our proposed algorithm may facilitate a differential diagnosis of these diseases in clinical practice.

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Deep Learning Approach for Generating MRA Images From 3D Quantitative Synthetic MRI Without Additional Scans

Cited by 41 publications

References 33 publications

Variability and Standardization of Quantitative Imaging

Variability and Standardization of Quantitative Imaging

3D Quantitative Synthetic MRI in the Evaluation of Multiple Sclerosis Lesions

Differentiation between multiple sclerosis and neuromyelitis optica spectrum disorders by multiparametric quantitative MRI using convolutional neural network

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