Can Virtual Contrast Enhancement in Brain MRI Replace Gadolinium?

Kleesiek, Jens; Morshuis, Jan Nikolas; Isensee, Fabian; Deike-Hofmann, Katerina; Paech, Daniel; Kickingereder, Philipp; Köthe, Ullrich; Rother, Carsten; Forsting, Michael; Wick, Wolfgang; Bendszus, Martin; Radbruch, Alexander

doi:10.1097/rli.0000000000000583

Cited by 111 publications

(161 citation statements)

References 39 publications

(44 reference statements)

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“…DL methods have been used for improving PET image quality, reducing noise [54], removing streak artifacts from CT [55], and developing novel techniques for tomographic image reconstruction based on a reduced amount of acquired data. Other promising applications are a generation of synthetic images, such as synthetic CT from MRI [56], virtual contrast-enhanced images [57], and rigid/deformable intramodal and multimodal image registration [58], and extraction of the respiratory signal [21] that could be used for breathing motion compensation of images [59].…”

Section: Imagingmentioning

confidence: 99%

Artificial Intelligence and the Medical Physicist: Welcome to the Machine

et al. 2021

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: Artificial intelligence (AI) is a branch of computer science dedicated to giving machines or computers the ability to perform human-like cognitive functions, such as learning, problem-solving, and decision making. Since it is showing superior performance than well-trained human beings in many areas, such as image classification, object detection, speech recognition, and decision-making, AI is expected to change profoundly every area of science, including healthcare and the clinical application of physics to healthcare, referred to as medical physics. As a result, the Italian Association of Medical Physics (AIFM) has created the “AI for Medical Physics” (AI4MP) group with the aims of coordinating the efforts, facilitating the communication, and sharing of the knowledge on AI of the medical physicists (MPs) in Italy. The purpose of this review is to summarize the main applications of AI in medical physics, describe the skills of the MPs in research and clinical applications of AI, and define the major challenges of AI in healthcare.

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Section: Imagingmentioning

confidence: 99%

Artificial Intelligence and the Medical Physicist: Welcome to the Machine

et al. 2021

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“…Next, we retrained the same network architecture after adding brain MRI scans from 6 mice with glioblastoma multiforme (GBM) into the training set. Similar to a previous study 14 , we compared the similarity between the predicted and ground truth maps by performing a receiver operating characteristic (ROC) analysis to measure the similarity of the high-enhancement regions (Fig. 2f) in addition to the quantitative similarity metrics above ( Fig.…”

Section: Deepcontrast In the Mouse Brainmentioning

confidence: 99%

“…A deep learning model should therefore be able to learn how to optimally extract this information, by training the model on previously-acquired MRI datasets where GBCAs were administered. Indeed, a growing number of recent studies have begun validating this assumption [13][14][15] . Nevertheless, among these, one study managed to use deep learning to reduce the GBCA dose 13 , but not to completely substitute it.…”

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Deep Learning Substitutes Gadolinium in Detecting Functional and Structural Brain Lesions with MRI

Liu

Zhu

Sikka

et al. 2020

Preprint

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While MRI contrast agents such as those based on Gadolinium are needed to enhance the detection of structural and functional brain lesions, there are rising concerns over their safety. Here, we hypothesize that a deep learning model, trained using quantitative steady-state contrast-enhanced MRI datasets in mice and humans, could generate contrast-equivalent information from a single non-contrast MRI scan. The model was first trained, optimized, and validated in mice. It was then transferred and adapted to human data, and we find that it can substitute Gadolinium-based contrast agents for detecting functional lesions caused by aging, Schizophrenia, or Alzheimer’s disease, and, for enhancing structural lesions caused by brain or breast tumors. Since derived from a commonly-acquired MRI, this framework has the potential for broad clinical utility and can be applied retrospectively to research scans across a host of diseases.

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“…In diesem Kontext erscheint es als ein besonders interessantes Ziel, eine T1-gewichtete Sequenz nach Kontrastmittelgabe basierend auf nativer Bildgebung zu synthetisieren. Eine derartige Studie wurde kürzlich von Kleesiek et al für Gliome vorgestellt [50].…”

Section: Diskussion Und Ausblickunclassified

AI in Radiology: Where are we today in Multiple Sclerosis Imaging?

Eichinger

Zimmer

Wiestler

2020

Rofo

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Background MR imaging is an essential component in managing patients with Multiple sclerosis (MS). This holds true for the initial diagnosis as well as for assessing the clinical course of MS. In recent years, a growing number of computer tools were developed to analyze imaging data in MS. This review gives an overview of the most important applications with special emphasis on artificial intelligence (AI). Methods Relevant studies were identified through a literature search in recognized databases, and through parsing the references in studies found this way. Literature published as of November 2019 was included with a special focus on recent studies from 2018 and 2019. Results There are a number of studies which focus on optimizing lesion visualization and lesion segmentation. Some of these studies accomplished these tasks with high accuracy, enabling a reproducible quantitative analysis of lesion loads. Some studies took a radiomics approach and aimed at predicting clinical endpoints such as the conversion from a clinically isolated syndrome to definite MS. Moreover, recent studies investigated synthetic imaging, i. e. imaging data that is not measured during an MR scan but generated by a computer algorithm to optimize the contrast between MS lesions and brain parenchyma. Conclusion Computer-based image analysis and AI are hot topics in imaging MS. Some applications are ready for use in clinical routine. A major challenge for the future is to improve prediction of expected disease courses and thereby helping to find optimal treatment decisions on an individual level. With technical improvements, more questions arise about the integration of new tools into the radiological workflow. Key Points: Citation Format

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Can Virtual Contrast Enhancement in Brain MRI Replace Gadolinium?

Cited by 111 publications

References 39 publications

Artificial Intelligence and the Medical Physicist: Welcome to the Machine

Artificial Intelligence and the Medical Physicist: Welcome to the Machine

Deep Learning Substitutes Gadolinium in Detecting Functional and Structural Brain Lesions with MRI

AI in Radiology: Where are we today in Multiple Sclerosis Imaging?

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