Litcius/Paper detail

Deep-learning-based image quality enhancement of compressed sensing magnetic resonance imaging of vessel wall: comparison of self-supervised and unsupervised approaches

Da-in Eun, Ryoungwoo Jang, Woo‐Seok Ha, Hyunna Lee, Seung Chai Jung, Namkug Kim

2020Scientific Reports57 citationsDOIOpen Access PDF

Abstract

While high-resolution proton density-weighted magnetic resonance imaging (MRI) of intracranial vessel walls is significant for a precise diagnosis of intracranial artery disease, its long acquisition time is a clinical burden. Compressed sensing MRI is a prospective technology with acceleration factors that could potentially reduce the scan time. However, high acceleration factors result in degraded image quality. Although recent advances in deep-learning-based image restoration algorithms can alleviate this problem, clinical image pairs used in deep learning training typically do not align pixel-wise. Therefore, in this study, two different deep-learning-based denoising algorithms-self-supervised learning and unsupervised learning-are proposed; these algorithms are applicable to clinical datasets that are not aligned pixel-wise. The two approaches are compared quantitatively and qualitatively. Both methods produced promising results in terms of image denoising and visual grading. While the image noise and signal-to-noise ratio of self-supervised learning were superior to those of unsupervised learning, unsupervised learning was preferable over self-supervised learning in terms of radiomic feature reproducibility.

Topics & Concepts

Artificial intelligenceComputer scienceDeep learningUnsupervised learningSupervised learningPattern recognition (psychology)Compressed sensingPixelImage qualityFeature (linguistics)Noise reductionMagnetic resonance imagingMachine learningComputer visionImage (mathematics)Artificial neural networkMedicineRadiologyPhilosophyLinguisticsAdvanced MRI Techniques and ApplicationsCerebrovascular and Carotid Artery DiseasesMRI in cancer diagnosis